| 00:02 | Yes, yes, I'm here. couldn't figure out where the button |
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| 00:08 | Okay. So first of all I to apologize. My um location is |
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| 00:17 | by workmen on every side doing different . So if it gets too |
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| 00:23 | let me know and I'll try to a closet someplace, but if it's |
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| 00:28 | , I'd prefer to do it from desk. So um, last time |
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| 00:34 | were talking about fluid properties and before proceed, are there any questions by |
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| 00:41 | way? Um, you tie? , was the recording I posted to |
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| 00:48 | ? Did it finally show up? yet. Okay. I did something |
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| 00:57 | when I tried to move the recording dropbox, it started playing and I |
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| 01:04 | know. We'll have to discuss that another time how, how I'm supposed |
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| 01:09 | put things in Dropbox. I haven't that for a while. Okay, |
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| 01:15 | about that. Fortunately it was a recording. You, you tie took |
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| 01:20 | of most of it. All Stephanie, any questions from anything we've |
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| 01:28 | so far? Um Not really. everything seems to be making sense. |
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| 01:36 | because I'm a great instructor and you're great student. So of course that |
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| 01:42 | happen. I just feel like a of this stuff is um, I |
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| 01:47 | know this is like the most I practical class I've taken so far. |
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| 01:51 | I'm enjoying the material. So it's sense. I'm hoping that means |
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| 01:55 | you know, you know how to . Brownie points. That's really |
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| 02:01 | Um, so let me say a more words on oil properties and then |
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| 02:07 | do some exercises also to make sure get a good grade in this |
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| 02:12 | we're going to go over some practice . Okay we'll be doing some of |
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| 02:19 | uh today and tomorrow and next I'll ask you how's the exam I'm |
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| 02:25 | work and you want me to go campus for that or is it just |
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| 02:27 | be like online? Like we've been well since it's just you and |
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| 02:32 | I don't see any reason why we do it online and you'll just um |
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| 02:40 | you know we'll we'll be online together case you have any questions and when |
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| 02:44 | done you'll just email it to Okay. Yeah. Okay. |
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| 02:52 | Oh hold on hold on. I keep forgetting. I think maybe |
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| 03:00 | do this is a Wednesday night right? I and I think you |
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| 03:05 | have to come to campus wutai when the final? I mean you tai |
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| 03:12 | you tie? Yes. Sorry, you say the question again when when |
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| 03:17 | the final? I think proctor Right. It will be um November |
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| 03:26 | . And what day is that? a Wednesday? And usually on the |
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| 03:31 | is from 6 to 9 p.m. By time X, flexible you can we |
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| 03:38 | change it. Okay. Um I'm to do it at another time if |
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| 03:45 | and you you and wutai agree on time but you would have to come |
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| 03:50 | campus. So so I take that . I'm sorry about that, I |
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| 03:54 | which program I'm in. Okay. . I was just curious because like |
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| 03:58 | dr Thompson and doctors out, they kind of sent it to me and |
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| 04:02 | I just sent it to them whenever was done with it. But |
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| 04:05 | I can go to campus, that's . Well if they did it then |
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| 04:09 | don't see why I couldn't do So I'll just email it to you |
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| 04:14 | you'll send it back to me. grade it and give it to. |
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| 04:18 | I want you to do it during , you know an appointed time. |
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| 04:25 | if if Wednesday 6 to 9 is for you, I'll make sure you |
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| 04:31 | it before six and I want your by nine. I want to email |
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| 04:38 | to me and you know, wait me to confirm that I received |
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| 04:42 | We don't want any errors in Right, Okay. Yeah. So |
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| 04:47 | I receive it then then it's Okay. Alright. We'll do it |
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| 04:53 | way. So let me just make I have that on my calendar. |
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| 04:59 | Utah It's the Wednesday the 16th. . I will send you a reminder |
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| 05:08 | day before. Um And how many classes do we have? So we |
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| 05:18 | tomorrow and next friday. Yeah, what I thought. Okay. |
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| 05:24 | And by the way, Stephanie, while you're preparing for the final, |
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| 05:29 | feel free to email me any questions have and I'll get back to you |
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| 05:34 | . I'm good at responding to That's one of my better qualities. |
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| 05:43 | , okay. So to summarize fluid july uh this is a good summary |
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| 05:52 | . It covers brines and uh so see there's a wide range if we |
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| 05:59 | at the variation versus temperature a people often uses they use brian properties |
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| 06:06 | S. T. P. Standard and pressure and you know, that's |
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| 06:12 | the surface and they assume uh you , desktop and they assume uh pure |
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| 06:22 | . And so that doesn't really work we could get very saline waters in |
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| 06:29 | subsurface as we've seen. And the asse increases dramatically with salinity. So |
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| 06:37 | I have if I'm very saline and very high pressure you could see I |
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| 06:42 | , you know, I could almost the module asse. Right. And |
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| 06:48 | so there's a wide range there of module is so that needs to be |
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| 06:52 | to account of course those ma july the average except you know at low |
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| 06:59 | at low temperatures most of the time brian becomes more compressible as you heat |
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| 07:06 | up. Remember, water is a bit unusual, It expands when you |
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| 07:10 | um It also becomes at low temperatures pressures. It also becomes more um |
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| 07:19 | me, less compressible as you increase temperature, oils have a wide range |
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| 07:26 | low temperature and pressure. Um They to be more like brian's near the |
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| 07:33 | as you get deeper to higher they get more and more like |
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| 07:39 | Um The major factors controlling the oil asse, aside from temperature and pressure |
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| 07:45 | the gravity of the oil. Low is heavy oil, high gravity is |
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| 07:51 | oil. And also then the gas ratio, the amount of dissolved gas |
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| 07:57 | the oil. So that gives you fairly wide range for oils. And |
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| 08:03 | you have, you know, and are much more compressible right, Especially |
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| 08:08 | high temperature. Now, if you to just guess, and you had |
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| 08:13 | brine module asse and you had a module asse if you had to pull |
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| 08:17 | number out of the air, unless at very low temperature. Just assuming |
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| 08:24 | oil module asses about halfway between the modulates and the gas module asse you're |
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| 08:31 | gonna be too far wrong, so that at least will get you |
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| 08:35 | the ballpark for gasses. The pressure important uh Much more compressible than |
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| 08:45 | But the module asse does get significant low temperature and high pressure have for |
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| 08:53 | . Um We could pretty much ignore module asse. It's um when we |
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| 09:00 | about dry rocks, we we just that the air is so compressible that |
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| 09:06 | we just assume the module asses Alright, so then we went over |
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| 09:13 | last time, we uh mixed ma and if we have a mixture of |
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| 09:21 | phases. Uh And we pointed out woods equation is the same as the |
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| 09:30 | average and the Royce average is a weighted reciprocal average. So this is |
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| 09:37 | equation. Of course the density is linear average, right? But the |
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| 09:44 | ass's a reciprocal sub and therefore the can be extremely nonlinear. As we |
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| 09:53 | , suppose we're just mixing gas and . There are only two components |
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| 09:59 | So the volume of water is the saturation and the volume fraction of gas |
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| 10:04 | one minus the water saturation. So the volume weighted reciprocal some and gas |
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| 10:12 | , especially when gas is very So low pressure gas, it's essentially |
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| 10:18 | on off switch. Uh It's still significant that a little bit of gas |
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| 10:25 | the modulates a lot. So it , if the, if the rock |
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| 10:28 | is compressible, it will drop the a lot, a little bit of |
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| 10:34 | . But the higher the pressure the higher the pore pressure, the |
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| 10:38 | linear the effect is you can see nowhere near being linear. That would |
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| 10:42 | a straight line between there and there's still a lot of concave cavity |
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| 10:46 | it, but it's far more linear for a very compressible, like |
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| 10:57 | Okay, so let's look at some , logs, uh here we have |
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| 11:01 | gamma ray log, this is pretty responding to the volume of clay. |
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| 11:06 | high gamma rays are your shales, gamma rays are your reservoirs. So |
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| 11:13 | would be considered clean reservoirs. If look at the resistive ITty log uh |
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| 11:20 | shells have low resistive ITty, you into the top of the sand and |
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| 11:25 | becomes high resistive ITty you go further the sam sand and the resistive ITty |
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| 11:31 | way down even lower than the shells into the shale. The resistive ITty |
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| 11:37 | back, go into a sand, goes down again and in the underlying |
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| 11:42 | it comes back up. So what's these resistive Itty variations? Well just |
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| 11:49 | the gamma ray log and the resistive log, it's not obvious what's causing |
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| 11:55 | because we don't know the porosity. this high resistive Itty here could just |
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| 12:01 | low porosity sandstone. Whereas this is porosity sandstone. Um Of course with |
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| 12:09 | density log it gives us a sense the ferocity now. Right, so |
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| 12:13 | shells are high density, the sands low density but the top of the |
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| 12:20 | is even lower density than the bottom the sand. So if this high |
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| 12:25 | ITty were due to low porosity from mass balance equation it would be high |
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| 12:32 | but we see its low density. we interpret, so we interpret this |
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| 12:37 | being a porous rock that's filled with and it's very porous because the effect |
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| 12:42 | the density is significant. So then go, so this is a water |
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| 12:49 | here at the water contact. We from high resistive ITty to low resistive |
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| 12:55 | . And we go from low density high density. Okay, now, |
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| 12:59 | do our velocities do? This is sonic log, This is sonic transit |
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| 13:04 | , 100 to 200. Um 200 pretty, this is microseconds per |
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| 13:10 | so this is not velocity, this one over velocity And 200 microseconds per |
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| 13:17 | is pretty close to the velocity of . Okay, so we're in the |
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| 13:24 | and we were fast, right, transit time is fast. We go |
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| 13:29 | the top of the of the sand we said there was gas and the |
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| 13:34 | are low and by the way they around all over the place, we |
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| 13:39 | back into the sand and the velocities high again. So this is brown |
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| 13:44 | and its velocity is pretty similar to shell. Now shales varying composition, |
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| 13:50 | their velocities are varying, but the sand is not too much different from |
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| 13:56 | shell. Now we go into this sand and this lower sand, we |
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| 14:02 | have high resistive itty and we had density to the brian sand, except |
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| 14:08 | the very top. It looks like have abnormally low density and if we |
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| 14:14 | at the resistive Itty, it's slightly . So what's going on here is |
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| 14:20 | a with ology changes it, a change. Um What's happening? |
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| 14:27 | let's look at the sonic log and sonic log comes all the way back |
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| 14:31 | the velocity of the gas. And the way, this bouncing around up |
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| 14:36 | is called cycle skipping when you have in the drilling fluid that can attenuate |
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| 14:41 | acoustic signals. So we we get lot of scattering. So the sonic |
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| 14:47 | tend to be unreliable in gas but you can see kind of where |
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| 14:52 | average is, and that's what we're here. So the interpretation is that |
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| 14:59 | is a gas stand, but because resistance is low, because the gas |
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| 15:05 | is low, and that's why the hasn't come all the way back to |
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| 15:10 | it is over here. It's somewhere between. So this is what we |
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| 15:15 | call fizz gas. It's low saturation . Probably not enough to be |
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| 15:22 | but enough to affect your sonic So, this is one of the |
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| 15:28 | of seismic direct hydrocarbon indication. You , the velocity drop, it doesn't |
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| 15:34 | how much gas you have. A bit of gas drops, the |
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| 15:39 | that means the a little bit of drops, the impedance. So a |
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| 15:44 | bit of gas will give you a spot or other types of amplitude |
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| 15:50 | So the so, and the kinds amplitude anomalies we were talking about |
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| 15:56 | They don't really care how much gas there. They only care about the |
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| 16:02 | or absence of gas. So they tell you if you have commercial saturation |
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| 16:07 | not. But as we've seen, the gas lowers the modulation of the |
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| 16:18 | . If it's a if it's a water mixture, it lowers the |
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| 16:24 | And um but oil can also, the gas oil ratio is high |
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| 16:30 | So here's an example of a bright caused by oil. This is an |
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| 16:36 | reservoir, it's quite shallow. So fact that it might be, say |
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| 16:40 | the module lists of brian was enough produce an anomalous amplitude. Here's another |
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| 16:48 | of a bright spot due to This is an interesting case because you |
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| 16:54 | a sand which is pinching out of and so down dip, You have |
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| 17:02 | because you have a thick sand and the sand goes away the amplitude |
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| 17:07 | So appear there's no sand down we have a thick sand. So |
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| 17:12 | have a a gradual drop of amplitude you're coming up dip As the sand |
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| 17:18 | pinching out but superimposed on that gradual . Suddenly here is a big amplitude |
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| 17:25 | . That's an oil water contact. ? So this is an oil reservoir |
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| 17:31 | the ship. Shell field 91 field the Gulf of Mexico. Alright, |
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| 17:40 | if this were a homework assignment, would make you read Bachelor Alan Wong's |
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| 17:45 | paper on fluid properties, but I'm gonna make you read it. Um |
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| 17:52 | was gonna ask you to rewrite the . But instead, since we're here |
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| 17:57 | , let's go over the conclusions of paper together. Okay, so number |
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| 18:06 | , and this is really uh what would consider the most significant scientific conclusion |
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| 18:13 | the paper and everything else is more less discussion. But here is the |
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| 18:20 | . The primary seismic properties of poor which are density, bulk, modular |
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| 18:28 | and the viscosity of the fluid. haven't discussed that. That's a little |
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| 18:33 | more of an advanced topic. But and wong do in their paper and |
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| 18:38 | properties vary substantially and they vary systematically temperature, pressure and composition. So |
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| 18:51 | is the important conclusion from their And that's what we've been discussing in |
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| 18:56 | section. The most abundant pour fluids brines. There's always water you you |
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| 19:06 | never get 100% hydrocarbon saturation. So always some residual water in the formation |
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| 19:14 | you could have gas, you could oil. If you're doing well, |
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| 19:19 | analysis, you might have drilling fluid is permeated in the flush zone into |
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| 19:26 | small analysts around the wellbore. We're worrying about that in this class. |
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| 19:32 | we are worried about the bride the hydrocarbon effect and mixtures of the |
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| 19:38 | . And so I've shown you how do all of that. A conclusion |
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| 19:44 | the paper was that these enough attention in play placed on the temperature pressure |
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| 19:52 | dependence of these properties. So in past, before this paper came |
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| 19:59 | geophysicists would tend to oversimplify and go a handbook and read a value for |
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| 20:06 | , a value for gas and usually S. T. P. As |
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| 20:11 | temperature and pressure. So it's typically complicated than that, like as we've |
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| 20:18 | , they say in particular, white can absorb large quantities of gas and |
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| 20:25 | significantly reduces their modulates and density. as we saw before the gas oil |
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| 20:33 | in an oil is a key So it's not just the api gravity |
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| 20:37 | the oil, it's how much gas dissolved in the oil. That's a |
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| 20:42 | a big swinger. And of course reduction can be sufficient to cause amplitude |
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| 20:50 | , not just bright spots, amplitude of all kinds. Um So uh |
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| 20:58 | the equations that battle and wang give you have a rough estimate of the |
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| 21:05 | and a rough estimate of the institute and temperature, then you can calculate |
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| 21:11 | their equations more realistic properties to use fluid substitution, which is our next |
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| 21:20 | . Next we'll learn how we use oil properties to see how the velocity |
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| 21:27 | Iraq changes with the hydrocarbons. so I showed you uh maybe I |
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| 21:35 | show, you know, uh But an example of where we have a |
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| 21:41 | cap on top of an oil So the top of the section has |
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| 21:48 | in it and it's got oil under . So there's a gas oil contact |
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| 21:53 | an oil water contact. And if gas happened to be in equilibrium with |
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| 21:59 | oil uh where would you be on phase diagram? So another way to |
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| 22:05 | that is at what temperature and pressure the gas be in equilibrium with the |
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| 22:11 | ? And the answer is right there the with curves cross. So what |
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| 22:19 | happen here at this? This pressure temperature would be the bubble point for |
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| 22:25 | oil leg, but it would also the dew point for the gas |
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| 22:30 | So you drop uh the pressure and the gas leg would want to precipitate |
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| 22:39 | and the oil leg would wanna precipitate bubbles. So, an interesting |
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| 22:45 | Of course those gas bubbles would gravity cause them to rise and form a |
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| 22:50 | cap. Okay, so this one's you. Um you know, if |
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| 22:57 | were homework assignments, I would have people go home and think about it |
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| 23:01 | of giving the answer right off the . But here are some examples of |
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| 23:08 | substitution and we'll learn how to do in the next section. But these |
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| 23:12 | results from that fluid substitution. So start with different brian sands and we |
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| 23:21 | a bride sand with 12,000 ft per . Another 1 10,000 ft per |
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| 23:26 | Another 1 8000 ft per second. that's the velocity, that's what the |
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| 23:32 | horizontal line is. That's our That's the velocity of the bride saturated |
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| 23:39 | and then oil is added heavy Light oil drops it, the velocity |
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| 23:46 | , lighter oil drops it more. here is gas, you know, |
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| 23:50 | that's why I said, I mean oil, if you didn't know |
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| 23:54 | You know, if you just picked number halfway, you know, if |
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| 23:57 | picked this number here, I wouldn't too far wrong. Right halfway between |
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| 24:03 | brian and the gas. But you know, there is some distinctive |
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| 24:09 | on this graph. And so, of all, tell me what you |
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| 24:16 | if you see differences in behavior, also explain the velocities, explain the |
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| 24:23 | sand velocities and explain the change in with the hydrocarbons. So that's on |
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| 24:31 | to chew on and to think And uh, I also welcome you |
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| 24:39 | to, uh, to think about as well and whoever wants to explain |
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| 24:45 | happening, let me know. I think I would say the the |
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| 24:56 | the same rock sandstone, sandstone with velocity means it is have stronger |
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| 25:05 | So it is less influenced by the in the pores and with more gas |
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| 25:18 | the force velocity of the cubic will and the decrease. So let me |
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| 25:30 | what you're saying here. You're saying I have a high velocity rock, |
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| 25:34 | change with the gas from Bride to , that change is smaller than in |
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| 25:42 | high porosity rock, because the high rock is more compressible, right? |
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| 25:51 | why the velocity is lower. And why the change in velocity is |
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| 25:56 | Is that? What is that? you meant meant to say. |
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| 26:01 | so because I said it, I'll you're absolutely right. Yeah. So |
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| 26:09 | see what's happening, uh the lower ferocity, the higher the velocity and |
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| 26:14 | less compressible the rock frame is, the hydrocarbon effects are smaller. Of |
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| 26:21 | , the higher gravity oil is less and more compressible than the lower gravity |
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| 26:28 | gas is the most compressible. So has the lowest velocity and uh the |
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| 26:37 | compressible rock has a smaller fluid effect the more compressible rock. Okay, |
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| 26:44 | important conclusion. If there's one thing learn from this course, it should |
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| 26:49 | , this summarizes a lot of what need to pull away from the |
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| 26:58 | Okay, so thinking about a practical . Now, I have a brine |
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| 27:04 | with a velocity of 6000 ft per . So that's this guy, which |
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| 27:10 | so, say it started here and you could see that I would have |
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| 27:15 | hydrocarbon effect that might be even bigger that. Right? So, if |
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| 27:20 | have a brian sand with a velocity 6000 ft per second, Do you |
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| 27:25 | why the sonic log might have difficulty the correct velocity of the gas |
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| 27:33 | So the same rock skeleton as the sand fill it with gas. Do |
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| 27:40 | see why the sonic log might have with that? Can you explain |
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| 27:52 | Like one more time. Why? would be difficult. So, |
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| 27:56 | I'm asking you to think about So let me, no, |
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| 28:00 | I haven't. I haven't given you answer. I haven't discussed this. |
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| 28:06 | when we uh you know, we won't get too well log editing. |
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| 28:12 | if we got there, I would about the sonic logging tool and how |
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| 28:16 | works. And it is a refraction . The p waves that the is |
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| 28:26 | the velocity of our refracted waves along interface between their head waves, along |
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| 28:34 | interface between the drilling fluid and the . I don't know if you remember |
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| 28:39 | from Geophysics one but if the uh the formation has a lower velocity, |
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| 28:50 | about if I have a high velocity , over a low velocity layer, |
|
| 28:56 | you're not going to get that. head wave developed. What you'll see |
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| 29:00 | the direct arrival through the high velocity . So if the drilling fluid is |
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| 29:07 | velocity than the formation, you're not to see a refracted headway from the |
|
| 29:13 | , you're going to see a direct through the fluid. So the velocity |
|
| 29:17 | would measure would be fluid velocity. ? So fluid velocity is around 5000 |
|
| 29:27 | . That's approximately. I mean, varies with the type of drilling mud |
|
| 29:30 | everything, but it's in the vicinity 5000 ft per second. So if |
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| 29:35 | brian sand has a velocity of 6000 per second, what would my gas |
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| 29:41 | velocity be? Well here we saw change of over 1000 and the 6000 |
|
| 29:48 | per second stand is going to be more compressible. Right? So this |
|
| 29:53 | more than 1000 for the 6000 ft second is going to drop more than |
|
| 29:58 | . That means its velocity is going be less than 5000 ft per |
|
| 30:04 | So if its velocity is less than ft/s, the Santa Claus can't read |
|
| 30:11 | as a matter of fact, I'll you an example of that when we |
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| 30:14 | to the next section. So that's difficulty. The other difficulty of course |
|
| 30:21 | that if you've got a lot of in the borehole, you got gas |
|
| 30:27 | and you're propagating a wave through a mud with gas bubbles in it that |
|
| 30:32 | be highly attenuating. So you get skipping as we saw with the previous |
|
| 30:39 | . Okay, here we have an from a program that originated at |
|
| 30:49 | the company I worked for uh from Batt Cell there of the Battle and |
|
| 30:55 | equations Mike Batt Cell is the guy taught me how to do rock |
|
| 31:00 | Uh you know, I was a guy joined the Arco Research Center in |
|
| 31:07 | , took me under his wing. later went to be a professor at |
|
| 31:10 | colorado School of mines and he and han here at the University of Houston |
|
| 31:16 | great friends and ran a joint So actually this technology wound up being |
|
| 31:23 | a proprietary program that the University of has called flag and it is licensed |
|
| 31:31 | various oil companies and contractors, But when we were at Arco, |
|
| 31:37 | name of the program was fluid And what this program does is it |
|
| 31:44 | the battle and wang equations and you in the depth or the temperature and |
|
| 31:50 | . If you give it the it uses the geothermal gradient to calculate |
|
| 31:55 | temperature and pressure, um, you the oil gravity the gas oil ratio |
|
| 32:03 | the gas gravity that's dissolved in the . And it will input output the |
|
| 32:09 | of the oil. The uh, of the oil. So here it's |
|
| 32:14 | mega pascal's. All right. We've talking primarily about giga pascal's, |
|
| 32:21 | So 12 84 mega pascal's is 1.284 pascal's And there it is uh, |
|
| 32:31 | Giga Pascal's 1 1.2835. Uh, for the live oil with the dissolved |
|
| 32:40 | . Just for reference, the program tells you the dead oil module us |
|
| 32:45 | is without the dissolved gas in And you see here, it's |
|
| 32:50 | you know, 30% higher. One higher. Or yeah, about 1/3 |
|
| 32:57 | . So, um, okay, with this program. This is for |
|
| 33:04 | properties of oil. But you could do it for the properties of gas |
|
| 33:08 | the properties of bribe. So here have live and dead oil density and |
|
| 33:16 | . And I would like you to go to the charts and at just |
|
| 33:22 | to read off the charts and that require visual interpolation on your part. |
|
| 33:29 | know at the same sort of temperature the same sort of pressure. Try |
|
| 33:37 | read similar properties for fresh water and and for pressure. Um two units |
|
| 33:50 | given to you uh p. i. Where we have our pressure |
|
| 33:56 | and P. S. I. if that's not what's on the chart |
|
| 34:02 | would have to do a units So I'm gonna ask you to go |
|
| 34:07 | that process and then show me the you come up with. And then |
|
| 34:13 | you know on a chart you would pressure on one axis temperature on the |
|
| 34:19 | axis plot live and dead oil Asus live and dead oil density. |
|
| 34:28 | two charts, one for modulates, for density, live and dead oil |
|
| 34:34 | and freshwater and saline water properties. there would be four points on each |
|
| 34:41 | . So do you understand the Do you understand the what you have |
|
| 34:47 | do? Know what charts? so last time I showed you modular |
|
| 34:56 | temperature at different pressures and I showed to you for oils. And I |
|
| 35:02 | showed it to you for brides and . And I also gave you |
|
| 35:09 | So you would have to go to charts there in your notes. So |
|
| 35:13 | you could pull them up on your and visually read values off of those |
|
| 35:19 | . So I'll do it here. there there's a module asse. And |
|
| 35:32 | the units of pressure are in bars . I think they changed the units |
|
| 35:37 | their paper but in the figures I , they are in bars so it |
|
| 35:42 | um the the fluid vell output. , so basically visually if they give |
|
| 35:51 | a pressure, you know, interpolate in between at the temperature and the |
|
| 35:58 | and read the value of for module and do it for fresh water. |
|
| 36:04 | see that's this guy and do it saline water. That's this guy. |
|
| 36:12 | read off the module is do the thing uh with the density, do |
|
| 36:19 | same thing with the density and make chart with four points on it. |
|
| 36:24 | modular and a chart for density. see what I'm asking? Yes. |
|
| 36:33 | , so I'll come back to the and so just proceed. And when |
|
| 36:45 | ready to let me know when you're to have me look at um what |
|
| 36:50 | what you've done. Okay for that module asse? The freshwater was zero |
|
| 37:35 | the brian was 300,000. Yes. . That's parts per million of sodium |
|
| 37:44 | ions. Okay. Okay let's see I can do. Yeah, I |
|
| 45:27 | I got for values. I'm gonna sharing. You show your share your |
|
| 45:38 | . Okay. Oh sorry that was end of that section. So I'm |
|
| 45:47 | close that file and we want to , well where is it? I |
|
| 46:02 | I had it. Excuse me, open. We're gonna have to. |
|
| 46:20 | it is. Okay. So the order of business and I apologize, |
|
| 46:35 | slide could be misleading. That's not borehole, right? This is a |
|
| 46:39 | of the earth with a brine And this is the same piece of |
|
| 46:44 | where some of the brine has been out and has been replaced with |
|
| 46:49 | So this is what we call fluid . And the velocity of the bride |
|
| 46:56 | in this case is 8000 ft per . As an associated shear wave velocity |
|
| 47:02 | associated density we add gas. What the p wave velocity comes down, |
|
| 47:10 | shear wave velocity increases because the sheer doesn't care about the fluid module |
|
| 47:17 | But the density is lower when you gas. So the shear wave velocity |
|
| 47:22 | increases a little bit and the density down because it's a porous rock and |
|
| 47:29 | gas is lighter than the brine it . So that's what happens now, |
|
| 47:38 | wanna be able to calculate that So we want to go through the |
|
| 47:43 | to do this and by the way is from The work done in the |
|
| 47:52 | 60s by Mike Forrest, who was guy who discovered bright spots and um |
|
| 48:02 | interesting because he has shale and bride velocities that are around 6700 ft per |
|
| 48:11 | on a sonic log And he's got gas and velocities of 5000 ft/s. |
|
| 48:21 | , remember what I said about the log measurement chances are these gas and |
|
| 48:27 | were even lower, but the sonic couldn't read it, but you |
|
| 48:32 | it wasn't so wrong that it didn't him understand that the gas sand should |
|
| 48:36 | much lower impedance than the bride sand by the way, we do have |
|
| 48:41 | right there are contacts here. Um you have sand either filled with gas |
|
| 48:50 | filled with brian. You see when filled with gas of a very low |
|
| 48:54 | , when it's filled with brian, have a higher velocity. So, |
|
| 48:59 | this gave him the idea that, , the gas sand will then have |
|
| 49:05 | lower impedance than the brian sand. where I have a gas reservoir, |
|
| 49:11 | should have a stronger reflection coefficient of the shell and the gas sand. |
|
| 49:18 | shell gas sand reflection coefficient, it's big change in velocity with density, |
|
| 49:25 | shell to brian sand is a smaller in velocity and density. So you |
|
| 49:32 | have a higher reflection amplitude from the sent. And of course we've seen |
|
| 49:41 | in the laboratory as well. So we have the velocity of a sand |
|
| 49:47 | happens to be a sandstone from offshore in the south china sea. And |
|
| 49:55 | had the compression of velocities uh for dry rock or here they say gas |
|
| 50:03 | . So probably they really mean air . And you have the shear wave |
|
| 50:10 | for the dry rock or I should the gas saturated rock. So now |
|
| 50:17 | is versus pressure. They don't tell what type of pressure. It's either |
|
| 50:21 | confining pressure or differential pressure. But the velocities are increasing with pressure, |
|
| 50:28 | can assume that the differential pressure is . So um you uh fill these |
|
| 50:38 | measurements not calculations, you fill the with brine and the velocities increase and |
|
| 50:46 | increase more at low pressure than they at high pressure. Why is |
|
| 50:54 | Why do the velocities increase more at pressure than at high pressure? The |
|
| 51:04 | space? Yes, the low, , the low low pressure, the |
|
| 51:11 | is lower velocity. It's more Right? And so maybe the ferocity |
|
| 51:16 | a little bit higher. Which you see here on the chair wave will |
|
| 51:20 | to that next. The porosity is , but also the flatter pores are |
|
| 51:25 | open. Right? So as you the velocity, the velocities, I |
|
| 51:30 | as you increase the pressure, the increase, but the change in velocity |
|
| 51:37 | to the fluids decreases. Alright for the sheer wave things go the |
|
| 51:42 | way you add water and the shear velocity goes down. Uh Why |
|
| 51:58 | You add water? You increase the . The sheer module is doesn't |
|
| 52:03 | you increase the density and the velocity down and in high pressure, the |
|
| 52:10 | is less, so the density goes less. So you get less of |
|
| 52:14 | change. Okay, so We are to use uh equations that the industry |
|
| 52:27 | been using for the past 70 And these are called gas men's |
|
| 52:34 | And what gas mains equations do is calculate the bulk module asse of the |
|
| 52:43 | rock with whatever poor fluid you have bulk modules of the bulk rock and |
|
| 52:52 | a function of the porosity of the . The fluid module asse the modular |
|
| 53:01 | the solid material and the modular of skeleton without the fluids in it, |
|
| 53:09 | call this the dry modulates that in application is actually a misnomer because the |
|
| 53:18 | isn't dry in the laboratory, it be dry, but in the earth |
|
| 53:22 | not dry. So I prefer to frame module asse or skeleton modules. |
|
| 53:30 | most papers refer to it as the modulates. So what gas mains equations |
|
| 53:37 | is they express the bulk modulates of saturated rock as a function of these |
|
| 53:48 | . And then of course you get velocities, you have to know the |
|
| 53:53 | modular. Um But if you have sheer module asse you could calculate the |
|
| 53:59 | module asse of the rock. Maybe had a brine saturated rock and I'm |
|
| 54:05 | add gas. So I calculate from equation. The change in the effect |
|
| 54:11 | module asse and the sheer modulates stays same and I use mass balance to |
|
| 54:18 | the change in density. So I calculate how velocity changes from an initial |
|
| 54:24 | Gas mains equations don't make the rock its components. It takes the rock |
|
| 54:32 | under one condition and tells you what velocities are gonna be when you're saturated |
|
| 54:38 | another condition. And there are a of assumptions in gas mains equations. |
|
| 54:45 | one thing, gas men's equations only uh perfectly well, not even |
|
| 54:53 | There are only supposed to be applicable chemically homogeneous rocks. So one |
|
| 55:02 | so a pure court sandstone. In , we use various tricks to take |
|
| 55:09 | account mixed little ology is with a of minerals and we'll talk about how |
|
| 55:17 | might do that. Uh They also the rock is Aissa tropic and of |
|
| 55:24 | everything is linear. We have small , This is a deviate oryx |
|
| 55:29 | As the wave passes through the it compresses and cheers the rock a |
|
| 55:35 | amount. And so uh the rock itself is an elastic medium. The |
|
| 55:46 | frame with fluids in it is what call a poor elastic medium. It's |
|
| 55:52 | perfectly elastic because it has fluid solid . So it has attenuation. We |
|
| 55:59 | treated as a visco elastic medium. , so how do we do fluid |
|
| 56:09 | of the density? Well, this our old friend, we have the |
|
| 56:14 | which is the poor volume divided by total volume. And we know how |
|
| 56:20 | density is related to porosity. And from the mass balance equation where we |
|
| 56:27 | these volume fraction of solid material times density of the solid material. And |
|
| 56:34 | log analysis, they call that the plus the volume fraction of of |
|
| 56:42 | which is the porosity times the density the fluid. Now if you have |
|
| 56:47 | mixture of fluids you use mass balance to calculate the density of the fluid |
|
| 56:54 | and if you have a mixture of again you have to do the same |
|
| 56:58 | , You have to use a volume average of the densities of the |
|
| 57:04 | Okay, that's the easy part. The hard part is gonna be when |
|
| 57:12 | uh add the fluid. So the thing we need to do is we |
|
| 57:16 | to know the module asse of the . Right, So we have the |
|
| 57:21 | among equations which give us the ma of the pure fluids. And if |
|
| 57:26 | have a fluid mixture, we use equation to calculate the module asse of |
|
| 57:32 | fluid mixture. And of course the of the fluid mixture again comes from |
|
| 57:37 | mass balance equation. Now Woods equation supposed to be applicable. If we |
|
| 57:45 | a homogeneous distribution of fluids um it a Royce bound, it is a |
|
| 57:54 | bound. So if we if we a different distribution of fluids uh say |
|
| 58:01 | pores have different saturation in them then would have something higher than the Royce |
|
| 58:09 | . And so the highest possible fluid , we could have would be a |
|
| 58:14 | bound of the fluid modules. And would be given by this equation. |
|
| 58:19 | there are situations where that seems to more applicable. I don't know if |
|
| 58:25 | get to talk about that, but our purposes we're assuming homogeneous saturation and |
|
| 58:31 | operating at near zero frequency. so now we're gonna assume a few |
|
| 58:42 | things. We have a rock We have a poor space filled with |
|
| 58:50 | and we want to combine these properties calculate the properties of the saturated |
|
| 58:56 | This is these are called gas mains there, it's sometimes called B. |
|
| 59:01 | . Gasman Theory because it's the low limit. In fact, zero frequency |
|
| 59:07 | of BeOS equations or was supposed to . It turns out very recently, |
|
| 59:13 | very own leon Thompson, who, the way, is the most cited |
|
| 59:19 | in our society journal Geophysics. So most sided geophysicist in exploration geophysics, |
|
| 59:27 | come out and he's proven that gas equations are in fact wrong. They're |
|
| 59:35 | the low frequency limit of the O equations. BeOS equations are |
|
| 59:40 | Gas mains equations have an error associated them. And these are the equations |
|
| 59:45 | been using and I'm going to show how to use these equations keep in |
|
| 59:50 | that one thing my students and I leon Thompson are working on our how |
|
| 59:56 | do fluid substitution correctly. So, mean, gas mains equations can't be |
|
| 60:03 | wrong because uh the industry would have that the predictions are bad, |
|
| 60:11 | So the results are in the right . And so they're close enough to |
|
| 60:17 | right answer that people didn't notice any problem with using them, but in |
|
| 60:25 | they're slightly wrong. And so uh are better ways to do fluid |
|
| 60:33 | but I think that's beyond the scope this course and by the way, |
|
| 60:36 | much harder to do correctly. So gonna stick with gas mains equations. |
|
| 60:44 | so some assumptions have to be The rock is ice a tropic and |
|
| 60:51 | . Uh the sheer module asses not by the fluid. So the skeleton |
|
| 60:57 | independent of the fluid. So the this is a purely mechanical effect. |
|
| 61:02 | are no chemical reactions between the fluids the solids. So and so the |
|
| 61:09 | material is chemically inner. Uh the fluid is firmly coupled to the |
|
| 61:17 | We have small stresses. So there's turbulence turbulence of the fluid as it |
|
| 61:22 | around. There's there's no there's no . You don't get open space. |
|
| 61:28 | fluid is is always filling the entire space. And uh probably the most |
|
| 61:37 | assumption is that the poor pressure is equipped vibrated throughout the rock. That |
|
| 61:45 | that every one of these pores, pore pressure is the same. And |
|
| 61:49 | could see that, that would not the case if the rocks, if |
|
| 61:54 | if the pores were not in communication each other. And and the rock |
|
| 62:00 | enough, that fluid can move freely the pores. Because obviously, if |
|
| 62:04 | have a very compressible pore, or have an in compressible spherical poor, |
|
| 62:10 | I apply a given stress to the , the fluid in the compressible pore |
|
| 62:16 | going to be more compressed, it's molecules are going to be pushed closer |
|
| 62:22 | and their fluid pressure is going to higher than the fluid in the spherical |
|
| 62:29 | . So that's an assumption the rock permissible enough that the fluid pressure equally |
|
| 62:37 | . And by the way there there's it may take time to equip vibrate |
|
| 62:42 | all the pores. So it means got to be a low frequency |
|
| 62:48 | If you are in very high there wouldn't be time for a quick |
|
| 62:53 | . So, lots of assumptions to at a wrong equation, but that's |
|
| 62:58 | we are. And so, uh way it works is given the bulk |
|
| 63:06 | and densities of the fluids and the modules and density of the solid |
|
| 63:13 | Remember, it's at least conceptually it's single solid material, we're gonna treat |
|
| 63:19 | like a pure mineralogy. And by way it's also wrong for that |
|
| 63:24 | Uh The way we make corrections for multiple minerals is not exactly right |
|
| 63:30 | So that's another degree of being Uh And we're also given the bulk |
|
| 63:37 | list and density of the rock at known saturation. And so what we're |
|
| 63:44 | gonna do is gonna change, we change the modulates of the fluid, |
|
| 63:48 | why might that happen? It could due to a temperature or pressure |
|
| 63:52 | or it could be due to a change, or it could be just |
|
| 63:58 | different fluids. So, um, know, a typical application would be |
|
| 64:04 | have a water sand And let me substitute and put southern gas, maybe |
|
| 64:12 | gas saturation into that water sand. does the p wave velocity of the |
|
| 64:19 | change? So, uh so that the problem. So, before we |
|
| 64:27 | get into dealing with the equations, time for our early break. So |
|
| 64:33 | reconvene will take approximately 10 minute We'll reconvene at 20 minutes after |
|
| 64:46 | Okay, let's go to gas men's . So this is it. And |
|
| 64:57 | I do have to warn you that notation changes throughout the course, because |
|
| 65:01 | took slides from various people, but really good for you to have to |
|
| 65:06 | to deal with different notations. I'm doing you a favor by being |
|
| 65:12 | and not making the notation uniform throughout class. Right, You're just gonna |
|
| 65:17 | to adjust every time you look in , you're gonna have to think about |
|
| 65:22 | the notation is. So this is men's equations expressed in terms of |
|
| 65:29 | So the velocity squared is equal to module is here divided by the |
|
| 65:37 | Right? So there's the density. what is the modulates of the |
|
| 65:43 | Well, it's K plus four thirds but mu doesn't change with the |
|
| 65:49 | So it's a constant there. The skeleton itself, you could think of |
|
| 65:55 | plus four thirds mu as being the of the rock frame. The rock |
|
| 66:02 | . The dry rock. So KB the dry rock bulk module asse. |
|
| 66:09 | is the dry rock steer modulates which the same irrespective of the fluid |
|
| 66:15 | So that doesn't change. So then this term this guy which shows the |
|
| 66:25 | of the fluid or calculates the effect the fluid. And so there are |
|
| 66:30 | important parameters. Here, one is dry rock module is divided by the |
|
| 66:38 | solid grain bulk module asse. So K dry over K solid. That's |
|
| 66:48 | that you need those parameters. You the porosity and you need the fluid |
|
| 66:54 | . So the change in p wave with the change in fluid module asse |
|
| 67:00 | all due to this guy. there's a little bit due to the |
|
| 67:05 | in density, but if all I'm is the fluid module asse, that's |
|
| 67:09 | it happens. So essentially it adds turn to the module asse of the |
|
| 67:15 | . And you could think of this changing the bulk modulates of the |
|
| 67:24 | Okay, so you're saying saying this different terminology, this is more typical |
|
| 67:33 | now? Instead of V P I pulled density from the other |
|
| 67:38 | So this is roe V p squared that's what's that? That's the plane |
|
| 67:43 | modulates to the rock. That's Alright, so this is M. |
|
| 67:48 | is K plus four thirds view for rock. Well, there's four thirds |
|
| 67:53 | and it doesn't matter what the fluid is. So K of the rock |
|
| 67:57 | equal to K Dry plus this term we saw before. It's got the |
|
| 68:04 | of K dry two K solid. got porosity in it and it's got |
|
| 68:11 | fluid watch. Allison it now. what is this? One? One |
|
| 68:26 | K. Dry over K of the . And you see it here, |
|
| 68:32 | minus K. Dry over the bulk of the solid. That's called the |
|
| 68:38 | O coefficient. And what that thing is the change in poor volume divided |
|
| 68:46 | the change in volume of Iraq. for the dry rock. And that's |
|
| 68:55 | to the porosity times the bulk modulates the dry rock divided by the bulk |
|
| 69:02 | of the pore space. So that's compressible the pore spaces which is one |
|
| 69:09 | K. Dry over K zero. you can express gas mons equation. |
|
| 69:15 | way the bulk modulates of the saturated is equal to K dry plus the |
|
| 69:23 | coefficient squared times M. Which is by this equation here? So this |
|
| 69:39 | , oh coefficient, when ferocity is , what is the B O coefficient |
|
| 69:45 | to be equal to? Well, porosity is zero uh K dry is |
|
| 69:52 | to k solid. Right? There's porosity, there's no poor space. |
|
| 69:58 | that's one. So the bl coefficient zero. What happens when porosity is |
|
| 70:06 | to 1? Well, when porosity equal to 1? Uh uh there |
|
| 70:14 | no skeleton module, asse soak a must be equal to zero. So |
|
| 70:21 | Bo coefficient is one. So the of the bl coefficient is 0-1 and |
|
| 70:30 | how it varies depends on the the K dr K matrix. Uh Now |
|
| 70:45 | zero, you could say is high , low consolidated uh material, uh |
|
| 70:53 | sediments would k dry would be very . So the B. O coefficient |
|
| 71:00 | be closer to one. Okay, now let's take a typical rock in |
|
| 71:09 | gulf of Mexico, a typical sandstone . And we start with the brine |
|
| 71:15 | velocity. We add gas from 0% , I mean 100% gas to 0% |
|
| 71:25 | here and we change the fluid module according to woods equation. And what |
|
| 71:33 | find is, you know, basically by Woods equation. Woods equation is |
|
| 71:38 | on off switch. So a compressible , the velocity is also an on |
|
| 71:44 | switch. A little bit of gas you the maximum change in velocity and |
|
| 71:50 | you get a rebound, it comes and that's because as you keep adding |
|
| 71:55 | , the density decreases. The module doesn't change much. So this is |
|
| 72:05 | same plot, but also showing what to the shear wave velocity. And |
|
| 72:10 | see the shear wave velocity is varying the density. So the shear wave |
|
| 72:15 | is increasing all along linearly. As add gas, p wave velocity drops |
|
| 72:22 | then it increases along with the shear velocity. So you can see out |
|
| 72:27 | , the V. P. V ratio becomes constant basically, you're canceling |
|
| 72:32 | the density effect. Okay, so an example of doing it. Uh |
|
| 72:46 | this fluid substitution on real rocks in earth. So you have a nice |
|
| 72:53 | here and here. Here is a sand, yellow is the percentage of |
|
| 72:59 | , gray is the percentage of courts . The percentage of water And uh |
|
| 73:07 | is the percentage of gas. you see there's more gas than water |
|
| 73:12 | . So we have a gas saturation maybe 70%. and so this these |
|
| 73:19 | the NC two values. Right? , uh the uh the density |
|
| 73:32 | the red curve Is the original measured in c. two. And the |
|
| 73:40 | curve is in this sand. Take the gas and make it all |
|
| 73:48 | And so that's the velocity you I noticed the effect on the shear |
|
| 73:54 | velocity is very small, but it in the other direction. The fluid |
|
| 74:02 | was only done here because this, water saturation is calculated to be all |
|
| 74:08 | . There was no gas down Alright, so the gas gas effect |
|
| 74:17 | often an on off switch light the velocity will decrease as you add |
|
| 74:24 | oil, but it will be a linear thing because it's module asses closer |
|
| 74:28 | the module asse of brian. If start dissolving gas and the light |
|
| 74:34 | it can start acting more like You could actually increase the velocity with |
|
| 74:40 | oils because they're modulates could be more more than the brine. That would |
|
| 74:45 | a very, very heavy oil and don't encounter those very often unless you're |
|
| 74:54 | the, you know, uh either highly bio degraded where you get a |
|
| 75:00 | mat, for example, it's practically or it could be uh in arctic |
|
| 75:06 | or antarctic areas where um the temperature low and the oil is almost |
|
| 75:13 | Then you could get velocity increases where have oil. Now, there are |
|
| 75:22 | different ways to express gas mains Uh This is the way he expressed |
|
| 75:29 | in his original paper, where the bulk module asse is equal to the |
|
| 75:39 | module asse times this ratio. And ratio has this factor que in here |
|
| 75:47 | Q depends on the fluid modulates the . The frame modular and also remember |
|
| 75:55 | sheer modules doesn't change. So this the way gasman wrote it in his |
|
| 76:00 | paper, this is a more conceptual to write gas mains equations And sometimes |
|
| 76:10 | helpful thinking of it this way it's helpful for computation because you're not solving |
|
| 76:16 | for case, sad you're solving for ratio here. But the symmetry of |
|
| 76:22 | one is nice. It's interesting. right, so uh You have the |
|
| 76:29 | for the saturated rock and K0 is solid rock is equal to that ratio |
|
| 76:36 | the dry rock plus that ratio for fluid. But there's this extra term |
|
| 76:45 | porosity here, of course, the ferocity you have, uh the more |
|
| 76:53 | want that fluid term to be Um We'll come back and we'll actually |
|
| 77:01 | this form later on, it's a convenient way of writing gas mains |
|
| 77:10 | Now, one of the parameters you to do fluid substitution. Well, |
|
| 77:16 | one way to do fluid substitution is solve for the dry modulates given the |
|
| 77:25 | of the saturated rock. So if had VPN B s with V P |
|
| 77:31 | p B. S in density. with roe V P squared, I |
|
| 77:35 | get K plus four thirds mu and roe V s squared I could get |
|
| 77:42 | . That gives me a K. the saturated rock, I can now |
|
| 77:49 | for the dry modulates and so I K. Now s is not |
|
| 77:56 | it's the saturated rock and I have , I have fluid module asse and |
|
| 78:02 | have the modulation of the solid So uh there we uh uh can |
|
| 78:11 | we have K. D. Now could change the fluids but to do |
|
| 78:15 | I need to have the shear wave . Okay so uh just taking you |
|
| 78:25 | some typical workflows for how we do . So I have K for the |
|
| 78:32 | rock. So that's the saturated rock equal to K. For the dry |
|
| 78:41 | plus one minus KD over K. squared divided by one minus porosity minus |
|
| 78:50 | over Ks divided by K. Solid ferocity divided by K fluid. And |
|
| 78:57 | have the sheer module I equal. I need to get each of these |
|
| 79:02 | . I need to get K I need to get get K. |
|
| 79:06 | . K. Matrix. Well Matrix I calculate from the composition if |
|
| 79:13 | pure courts, I know the uh module. List of courts. So |
|
| 79:20 | could I could look that up in in a handbook if it's a mixture |
|
| 79:25 | minerals. We use the bounding equations we take the Royce, void bounds |
|
| 79:31 | the different minerals. Typically we average that's called the hill average. We |
|
| 79:37 | the average of the Royce and void . So that gives me the matrix |
|
| 79:43 | asse, fluid modulates. I used Bachelor long equations porosity comes from log |
|
| 79:50 | . Uh K. D. Will have had to have solved for |
|
| 79:54 | other way. And so we could V. P. M. |
|
| 79:59 | S to do that but if we have B. S. What would |
|
| 80:02 | do? Well we could use trend and I'll show you how we do |
|
| 80:10 | . Um So we start with both of the 100% saturated rock. We |
|
| 80:20 | by, Well this is if we're with 100% saturated rock, we multiply |
|
| 80:29 | uh The density of 100% saturated The times V. P squared minus |
|
| 80:37 | thirds V. S squared. So gives me the bulk module asse of |
|
| 80:42 | 100% Brian Saturated Rock. And the modulates of the 100% brian saturated rock |
|
| 80:49 | the density times B. S Okay, now I'm going to calculate |
|
| 80:58 | dry frame module asse from the matrix asse using this expression here where these |
|
| 81:11 | the terms for those expressions? So I have an algebraic equation which |
|
| 81:18 | me to calculate the dry frame modules these values. Right? So I |
|
| 81:29 | the bulk modules of the 100% saturated . The bulk modules of solid, |
|
| 81:35 | could get X and Y. I plug plug X. And Y. |
|
| 81:38 | here. I get the dry frame . Now I'm ready to change the |
|
| 81:43 | module asse and do my fluid I had so to do fluid |
|
| 81:51 | I have two fluid substitute the density the way. Here's a four trip |
|
| 82:01 | um historical purposes. Here's a four subroutine to do this and it's like |
|
| 82:08 | lines of code. That's all it . So it's pretty easy to do |
|
| 82:12 | I start with 100% brian saturation. , so um yeah, with |
|
| 82:20 | with the uh dry frame module once I get this, then I |
|
| 82:26 | go back to here and I could my fluid substitution. I can see |
|
| 82:31 | the bulk modulates of the saturated rock with the bulk modulates of the |
|
| 82:40 | Now there's a complication in that. assuming that the fluid is homogeneous, |
|
| 82:50 | every pore has the same fluid same saturation of gas or oil. |
|
| 83:03 | This is an interesting way of plotting here is instead of velocity is |
|
| 83:11 | Right? And so where velocity where saw the rebound, do the |
|
| 83:15 | right. The velocity came back as add a gas. Of course the |
|
| 83:20 | continues to drop because now you're multiplying density for velocity, you're dividing by |
|
| 83:26 | square root of density. So it back, but now you're multiplying by |
|
| 83:31 | bigger number. So it goes down by the square of the density. |
|
| 83:37 | dividing, you're decreasing the density and so velocity comes up by the square |
|
| 83:45 | of density, but impedance goes down with density. You're multiplying by the |
|
| 83:52 | . So this is our fluid saturation . Uh Now, if you don't |
|
| 83:59 | a homogeneous distribution of fluids, you something called a patchy distribution and there |
|
| 84:08 | all kinds of variations on this. all there are many different ways that |
|
| 84:13 | fluid may not be uniformly distributed, if it happens to arrange itself in |
|
| 84:21 | certain way, you may wind up a more linear dependence on fluid |
|
| 84:32 | which brings us to the patchy saturation . And in many ways this is |
|
| 84:38 | of an upper limit on what the could be. And uh the reason |
|
| 84:45 | this is if the if I have mixture of materials with the same share |
|
| 84:53 | asse, then the plane wave modulates reciprocal of the plane wave module, |
|
| 85:01 | uh is equal to the volume weighted of the reciprocal of the different module |
|
| 85:07 | So in a way it's it's it's to a Royce bound for the different |
|
| 85:14 | . So, if I could have patch filled with gas, a patch |
|
| 85:17 | with oil patch filled with brian, sheer modulates is not supposed to be |
|
| 85:23 | , right? So therefore this equation exact. Now, of course, |
|
| 85:30 | begs the question. Why are you with different fluids? If if the |
|
| 85:35 | is exactly the same, Such that show module, this is the |
|
| 85:39 | Why do you have different fluids? , the patchy model doesn't necessarily reproduce |
|
| 85:46 | accurately the behavior, but it it of gives us an upper bound for |
|
| 85:52 | the module is. Could be So now let's take a rock and |
|
| 86:02 | uh substitute different fluids in the rock let's bury the pressure. So we're |
|
| 86:11 | the modulates of the rock, we're going to let the porosity change too |
|
| 86:16 | . So most of the dependence on here, this is a carbonate. |
|
| 86:21 | of the dependence on depth is due closing of low aspect ratio poor. |
|
| 86:27 | the effect on the total porosity isn't . And we have the water saturated |
|
| 86:34 | that might have come from laboratory measurements pressure was a proxy for depth. |
|
| 86:41 | we have a water saturated trend. put a very heavy oil in and |
|
| 86:46 | can see at low pressures in low shallow, there's a certain geothermal |
|
| 86:53 | assume the heavy oil is faster than water deeper. The heavy oil is |
|
| 87:00 | than the water because the temperature effect going to take over, it's |
|
| 87:05 | it's stronger on the heavy oil. is a dead oil. What is |
|
| 87:10 | dead oil? It's an oil where no gas in solution. Uh, |
|
| 87:17 | you don't keep the oil under if you release the pressure, all |
|
| 87:22 | gas will come out because you've dropped the bubble point. So that is |
|
| 87:28 | the dead oil. It's well It's not volatile. It doesn't have |
|
| 87:35 | bubbling out of it anymore. The is all gone. So this is |
|
| 87:40 | dead oil and it's more similar to . But again, as you get |
|
| 87:46 | , the difference gets greater because the of temperature is more, this is |
|
| 87:51 | light live oil. So the gas never allowed to come out of |
|
| 87:57 | it's velocities are even lower. And course gasses even lower. So if |
|
| 88:04 | didn't know the properties of the if you had to make a |
|
| 88:07 | you know, somewhere in between water gas, maybe halfway in between. |
|
| 88:13 | as you get to very high you're getting more and more like |
|
| 88:22 | Okay, Now, let's look at happens when we measure velocity versus saturation |
|
| 88:28 | the laboratory. And these are gas equations, which by the way, |
|
| 88:34 | told you were wrong, right, people thought they were right. And |
|
| 88:41 | we've seen is a big discrepancy in laboratory, especially at low gas |
|
| 88:48 | So, the dash line is what predicts the black line and the points |
|
| 88:54 | what are measured in the laboratory, a big difference and even a difference |
|
| 89:00 | the shear wave velocity. So, happening and a big part of what's |
|
| 89:09 | is the gas is not uniformly Also, remember, in the |
|
| 89:15 | gas mains equations are the low frequency . We have to take into account |
|
| 89:20 | fact that laboratory measurements are very, high frequency, they might be at |
|
| 89:25 | megahertz. So, uh we have do something better. Alright, |
|
| 89:34 | coming back to gas men's equation um this way, what happens as we |
|
| 89:45 | the pore fluid. Right? I as I changed the fluid module |
|
| 89:52 | say, I have two different fluid . I I could write this equation |
|
| 89:56 | , couldn't I? I could write for fluid modulates one which gives me |
|
| 90:02 | modulates one. And I could write for fluid module is two, which |
|
| 90:07 | me saturated module is to I could the equation twice and then I could |
|
| 90:16 | the equations from each other. And is what I get right. I |
|
| 90:24 | a change. This is this is . D. Over K zero |
|
| 90:33 | D. For fluid saturation one. this is the same quantity K. |
|
| 90:40 | it's not supposed to depend on the from saturation state to and fluid |
|
| 90:50 | So, you see, I canceled the dry frame modular snap. |
|
| 90:57 | isn't that interesting? Um But I've telling you all along that fluid substitution |
|
| 91:04 | on the dry frame module asse. I do fluid substitution right here, |
|
| 91:10 | could cancel out the dry frame So where is it? Where is |
|
| 91:18 | dry frame modular? Do you believe that the fluid? I've been telling |
|
| 91:34 | over and over again that the fluid is bigger when the dry frame module |
|
| 91:40 | small. Alright, haven't I been you that? Am I a |
|
| 91:45 | I just proved. Didn't I just that wrong? I don't see the |
|
| 91:50 | frame module is here. Doesn't this that the dry frame module is the |
|
| 91:56 | substitution doesn't depend on the dry frame . I think it Maybe inside the |
|
| 92:08 | . zero. Well it's not inside . Zero but it's inside K. |
|
| 92:13 | . And K. Uh K. . One and K. S |
|
| 92:16 | So the answer is it's not explicitly , but it's implicitly there. |
|
| 92:24 | It's implicitly in these module I so but I could do I I don't |
|
| 92:31 | to solve for the dry frame Right? I could I could do |
|
| 92:36 | substitution right here. Right. If have K. S. One and |
|
| 92:41 | F one, I could then solve K. S. two. |
|
| 92:47 | I change I changed the fluid So this is known. This is |
|
| 92:53 | . This is known. I could the new state. Yes. |
|
| 92:59 | So I don't explicitly have to calculate dry frame modules, which is |
|
| 93:07 | Okay, so previously showed you a , laboratory measurements where uh the |
|
| 93:17 | the goal of mine, we have velocity versus depth of the stolen mine |
|
| 93:22 | on laboratory measurements and equivalent pressures. I think I told you that laboratory |
|
| 93:28 | tend to overestimate the effect of pressure of damage to the core. |
|
| 93:38 | This is more typical. And these come from velocity versus depth. Friends |
|
| 93:45 | logs. So, uh, if look at velocity versus death from logs |
|
| 93:52 | in sand stones. Uh, this in the gulf coast. It doesn't |
|
| 93:57 | that curvature to it. It's a linear relationship. So, I could |
|
| 94:03 | fluid substitution on that guy. I put a heavy oil in and |
|
| 94:08 | very shallow. It might actually be . Uh, I put a light |
|
| 94:14 | oil in and shallow. It's kind halfway in between deep. It becomes |
|
| 94:19 | similar to gas And here we have gas effect there. Again, the |
|
| 94:26 | effect is much bigger, shallow than is deep. Okay, so here |
|
| 94:35 | some laboratory measurements. Um The dash is gas mains equation is the prediction |
|
| 94:43 | Gassman from the dry VPs. look at these observations and hypothesize the |
|
| 94:55 | for the for the observations by the , where you have two measurements at |
|
| 95:01 | same pressure. That's a history one measurement is pressuring up, the |
|
| 95:10 | measurement is pressuring back down. So showing you the effect of history. |
|
| 95:16 | on these measurements. Okay, now what's going on here with the saturated |
|
| 95:25 | not Well, just, just explain the velocities. Why is the velocity |
|
| 95:31 | what it is? I mean, kind of it matches the earlier one |
|
| 95:47 | we were looking at for the sandstone china similar. So it's just as |
|
| 95:53 | pressure increases, its more compressible at lower pressures and creases. That's that's |
|
| 96:03 | velocity. Look at your wave Do you see something funny about |
|
| 96:12 | I don't know it's switched. What's happened. What's happened is that's |
|
| 96:33 | weird, Dad is completely opposite with other one. So, what happened |
|
| 96:45 | , well, think of the equation the for shear wave velocity. We |
|
| 96:52 | . If the only thing that's changing density. The saturated rock should be |
|
| 96:58 | , but it's not just slower. faster. What does that mean? |
|
| 97:05 | means that the rigidity has increased for saturated rock. I've changed the rock |
|
| 97:14 | the effect is bigger than the history effect here. You see the history |
|
| 97:19 | effects. Right? So, probably mike battle was worried that history says |
|
| 97:26 | the explanation. That's not the This is because the rock has a |
|
| 97:34 | has a greater share modulates when when than when dry. Is that |
|
| 97:42 | Yeah, it's called frame hardening. gas means equations assume no chemical |
|
| 97:51 | but especially when you have clays, have the habit of swelling and interacting |
|
| 97:57 | fluids. So Claes can cause the to harden. Uh They could also |
|
| 98:07 | this frame to soften. Its it's complicated situation. Sometimes water hardens the |
|
| 98:14 | . Sometimes it softens the frame. that's why you shouldn't use the dry |
|
| 98:20 | skeleton. Uh Or you shouldn't use dry rock module. Is to predict |
|
| 98:26 | saturated rock module. Asse you should the inverted frame module asse from uh |
|
| 98:34 | all the equations measuring be PBS density for the frame module asse. That |
|
| 98:42 | the module is that should be used . The module is measured on the |
|
| 98:46 | rock. You want the module asse the rock frame in the presence of |
|
| 98:55 | poor fluids that are present in Two important lesson. Okay, now |
|
| 99:07 | a really good paper in geophysics that pointed out before TED Smith? It's |
|
| 99:12 | 2003. These were some slides I from him in 2006. And he |
|
| 99:19 | he works through uh the fluid substitution problem. And the reason we're going |
|
| 99:27 | all this is because I'm gonna ask to do this, I'm gonna ask |
|
| 99:30 | to code up all of these equations produce a result. So um first |
|
| 99:41 | you need V. P. And . S. V. S could |
|
| 99:45 | measured or it could come from one our V. P. B. |
|
| 99:48 | . Relationships that we know so Right? So we get the bulk |
|
| 99:54 | of the saturated rock under the C. Two conditions for using log |
|
| 100:01 | and log B. S. And using here, G. For sheer |
|
| 100:06 | . Usually we use mu he uses . So you calculate those next. |
|
| 100:13 | calculate the dry frame module asse. he uses this equation. I showed |
|
| 100:19 | an equivalent way to get there I had the X. And the |
|
| 100:23 | . And kind of simplified things. I was following a procedure outlined by |
|
| 100:31 | in his review paper. But his case star is the frame module |
|
| 100:39 | . I don't like to call it dry modulates the frame module asse. |
|
| 100:44 | , once you have the frame module you could calculate the saturated module is |
|
| 100:49 | new conditions. So you change the module asse. And uh Let's |
|
| 100:57 | I'm trying to look at his equation . Yeah, this K0 is his |
|
| 101:02 | module asse. And yeah, this it's this is another way of writing |
|
| 101:09 | mains equation. This is correct. um that's your new saturated modulates with |
|
| 101:20 | your new pore fluid is. Uh also have to do fluid substitution on |
|
| 101:26 | bulk density and then you calculate the velocities with the new saturated module asse |
|
| 101:33 | the new density. Okay, that's workflow, I'll take it through through |
|
| 101:43 | . I'll work the problem a little way. I'm saying, given uh |
|
| 101:49 | ferocity at 100% water saturation, Compute . P at water saturation of |
|
| 101:58 | So this is the equation I need solve, I need to know the |
|
| 102:01 | module is at 50%. The share is at 50% saturation and the density |
|
| 102:08 | 50% saturation. Okay, so I to go about getting these things. |
|
| 102:16 | , so uh first of all, either have measured B. S. |
|
| 102:22 | I have V. P. And trend curve. And I could get |
|
| 102:26 | And from that roe v A squared get the share modulates at 100%. |
|
| 102:34 | that gives me the share modular at . Um If I only have ferocity |
|
| 102:41 | I have to compute the density. I can use mass balance to do |
|
| 102:46 | . And so given the density and shear wave velocity, I get the |
|
| 102:50 | module is at 100% saturation. Uh I set that equal to the sheer |
|
| 102:56 | at 50% saturation. We're assuming we're c. two. We haven't dried |
|
| 103:02 | rock, we haven't changed the rock and still in the presence of the |
|
| 103:06 | fluids if it was water wet before water wet now. So I keep |
|
| 103:12 | share module is the same. I have two fluid fluid substitute the |
|
| 103:19 | too. So I use a new density. Right? So I used |
|
| 103:24 | water saturation and the densities of the , the density of the water. |
|
| 103:30 | I calculate the new uh the new of the 50% saturated rock. |
|
| 103:39 | now I need the bulk modules of saturation. Well, here I have |
|
| 103:44 | well known gas mains equations. Got dry module list. Um And the |
|
| 103:51 | modulates which I had to come get someplace, maybe one of my papers |
|
| 103:57 | a handbook, someplace the fluid modulates Battle and Mom. Um Well from |
|
| 104:04 | based on battle and Wong's equations for for the different fluids. Um So |
|
| 104:13 | can solve um we gave you the to solve explicitly for K. 50% |
|
| 104:20 | you had uh you know uh from . P. V. S. |
|
| 104:27 | 100%. I'm sorry to solve for . Dry if you had be PBS |
|
| 104:33 | density, you can solve for Dry if you're in a sandstone, |
|
| 104:38 | an easy relation that K dry is to the share module asse. It |
|
| 104:44 | coincidentally turns out that way. So could do it that way or you |
|
| 104:48 | be more precise about it and explicitly K dry using the equation that I |
|
| 104:55 | you. Okay then we have K and we have K oil and gas |
|
| 105:00 | the water from the bats, Lynn equations and we have water saturation. |
|
| 105:08 | so we calculate the new fluid module this is woods equation. Okay, |
|
| 105:14 | that's the prestige. So you will that in exercises but we're at the |
|
| 105:19 | of the hour again. So let's at 3:11. Okay, okay. |
|
| 105:32 | as I said, we have different , We have this approximation uh which |
|
| 105:39 | given by that equation. All you is brian sand velocity to calculate |
|
| 105:45 | sand. And we have the math approximation where you use em instead of |
|
| 105:52 | and you could get em from roe p squared. So that's nice. |
|
| 105:59 | we compared to the exact jasmine's equations different ferocity ease. And what we |
|
| 106:06 | is uh if we look at the For uh ferocity is greater than |
|
| 106:14 | Math cause error was bigger than ours it could approach 100 for very porous |
|
| 106:24 | . The results were similar For non rocks below 10 Moscow's approximation is better |
|
| 106:34 | my empirical equation. Uh but they're terrible. Okay. And fluid substitution |
|
| 106:42 | 10% ferocity is imprecise anyway because your error introduces a big error in your |
|
| 106:53 | . So, you know, I say my approximation is pretty good |
|
| 107:02 | we'll come back later and and we'll to look at the aero sensitivity of |
|
| 107:08 | men's equations. All right now, I said where where the fluid module |
|
| 107:14 | is very low, like a low . Uh your fluid substitution is an |
|
| 107:21 | off switch. And here dr Bassel battle and han in the newspaper, |
|
| 107:28 | plotting impedance versus saturation. P wave peter and shear wave and peters and |
|
| 107:34 | resulting poison's ratio. and uh here only 10% gas saturation, uh you've |
|
| 107:43 | all the change in velocity in impedance gonna get. And then after that |
|
| 107:48 | it's a pretty mild change. So again, on off switch, |
|
| 107:55 | but at high poor pressures, that becomes more gradual because the gas modular |
|
| 108:05 | much higher because of the higher poor . Okay, now, um we're |
|
| 108:16 | look at inferences that we could make gas men's equations and we could do |
|
| 108:25 | like cross plot frame module asse versus modular in a sandstone. So in |
|
| 108:34 | sandstone, um we know the poison's of the frame is about 0.1. |
|
| 108:41 | if we know the frame module we know the sheer modules. Remember |
|
| 108:45 | modular sequel, sheer module asse When poison's ratio is close to 0.1 or |
|
| 108:53 | module is approximately equal to share So uh I could just vary the |
|
| 108:59 | module asse and I could calculate the modules for a given fluid saturation four |
|
| 109:09 | of constant ferocity, that's the that's the other unknown. So I'm |
|
| 109:13 | a sandstone. So I know the bulk module asse. I'm good at |
|
| 109:20 | a range of ferocity ease and each is going to take on make a |
|
| 109:25 | curve and then I'm going to vary frame modulates at that ferocity. And |
|
| 109:30 | I'm going to calculate the satch, the saturated module is giving the fluid |
|
| 109:35 | asse. And this plot is really . And you could make all kinds |
|
| 109:41 | inferences from this. Uh For I could, you know, if |
|
| 109:47 | take take porosity zero then the saturated asses equal to 38. Right, |
|
| 109:56 | right. It's equal to the solid . So, whatever it was |
|
| 110:00 | uh that uh doesn't change, but I could theoretically At a very low |
|
| 110:12 | here. This curve is for 1% . I could theoretically produce a very |
|
| 110:19 | frame module asse if I had very flat cracks. So, a |
|
| 110:25 | like this, although not you won't that in practice. In theory, |
|
| 110:31 | curve is is physical. It's it's realizable, right? It doesn't it |
|
| 110:38 | happen for other reasons, natural but mathematically it doesn't violate any |
|
| 110:45 | Mathematically, it's legal to have that . Um And I can compute the |
|
| 110:54 | curve for 5%, porosity, 10% . And then look what happens is |
|
| 111:01 | get up above 20% porosity. These converge, This is 40% porosity and |
|
| 111:14 | going to get really, really wild go all the way to a ferocity |
|
| 111:19 | one. So I'm approaching one As I approach one, I would |
|
| 111:27 | this line, this is a lower on what the saturated modulates could be |
|
| 111:35 | a given frame modulates and we could some inferences here, we could |
|
| 111:45 | wow how if I get a if I have a saturated modulates up |
|
| 111:51 | and a frame module is down That could only be created with low |
|
| 111:57 | ratio pores. And it also tells that rocks naturally occurring rocks like in |
|
| 112:06 | gulf of Mexico porous rocks are gonna a very similar relationship between saturated modulates |
|
| 112:14 | frame modules. That's why we could away with an empirical equation between Vp |
|
| 112:22 | and vP gas. But this is get wilder, This is saturated module |
|
| 112:31 | versus freight module asse, I could this to VP VS. B. |
|
| 112:37 | . Right? Because remember I said sheer module asse is um is equal |
|
| 112:45 | the frame module us in a pure . So, for a pure |
|
| 112:51 | if I know the frame modulates, also know the sheer module list. |
|
| 112:55 | I know V. P. And . S. Given a density |
|
| 113:02 | Right? So now I could produce same kind of plot. So I |
|
| 113:08 | Vp VS. B. S. of saturated modules versus frame modules. |
|
| 113:14 | what happens here here is my 1% rock, this is predicting what |
|
| 113:24 | PBS relationships I should get. It's that where I have low porosity, |
|
| 113:30 | know, I have high velocities, should be here as I increase the |
|
| 113:36 | , the ferocity the velocities get And what I find is that I |
|
| 113:43 | to follow this lower bound here oddly . So we'll compare this to our |
|
| 113:51 | . P. B. S. for sand stones. But the point |
|
| 113:57 | , if I have a bride saturated with very low aspect ratio for |
|
| 114:01 | this tells me theoretically that I should above that V. P. |
|
| 114:06 | S trend. So a liquid liquid fractures would pull me above that |
|
| 114:13 | P. B. S trend. , so remember we had the Ramayana |
|
| 114:21 | equation, VP vs. V. . Equation and we showed that it |
|
| 114:27 | with our empirical relation. Um So are the dots And this is the |
|
| 114:36 | porosity Gassman limit. And they agree this tells me is that natural processes |
|
| 114:47 | trying to minimize Watson's ratio. Natural processes are always gonna push me |
|
| 114:53 | this lower bound unless something disrupts those like fractures. Right? So uh |
|
| 115:04 | the rock cooking the rock, having genetic transformations whatever is happening uh to |
|
| 115:12 | rock wherever you're at. You tend be near the lower bound with fractures |
|
| 115:19 | the the exception to the rule. this is a little bit of an |
|
| 115:32 | idea, but if you think about , suppose I was trying to find |
|
| 115:39 | in fractures. It was if I trying to find gas and fractures, |
|
| 115:45 | wouldn't want to be up here. , this has this for this to |
|
| 115:50 | . These have to be liquid filled . So gas and fractures would would |
|
| 115:55 | me on our gas line, it put me down here. So this |
|
| 115:59 | be a way of knowing what can't gas filled fractures. Okay. But |
|
| 116:12 | gets more complicated if we're trying to laboratory measurements, because laboratory measurements are |
|
| 116:24 | not um at the low frequency they're at hundreds of kilohertz or |
|
| 116:33 | And for that we have to use full B O theory. And so |
|
| 116:39 | the equation similar to gas men's but different. So, um, |
|
| 116:50 | different from gas mains equation? beta was our KD over K |
|
| 116:57 | Alright, so instead of one minus squared, you have one minus beta |
|
| 117:03 | this thing with this constant. And added a term in the numerator here |
|
| 117:12 | you actually added what is called an term with the density. I |
|
| 117:17 | Chesnokov likes to talk about density being dependent, it's not really the |
|
| 117:23 | it's the effect of the density on way of velocity is frequency dependent. |
|
| 117:30 | you get another term here and all these terms have ferocity over K K |
|
| 117:40 | the coupling factor between the poor fluid the frame. It's called the mass |
|
| 117:47 | factor. So if K is there's no coupling between the fluid and |
|
| 117:57 | frame and if K is infinity, infinite coupling the fluid in the frame |
|
| 118:03 | perfectly coupled. So what happens if said K to infinity? I get |
|
| 118:08 | mains equation. So, kind of . Alright, now we're going to |
|
| 118:23 | these predictions using these different equations to measurements. Remember I said, the |
|
| 118:30 | you get is gonna depend on the of gas in the pore space. |
|
| 118:40 | how we get gas, how we the gas in in the uh in |
|
| 118:46 | pore space matters, we could inject gas in or we could let the |
|
| 118:57 | in the rock drain out naturally. ? So we could inject Aaron or |
|
| 119:03 | could let the rock dry and let pockets form naturally. And as I |
|
| 119:16 | , when we measure velocities in the , we get a discrepancy from gas |
|
| 119:21 | equations. Uh there's a discrepancy for fully uh saturated rock as well. |
|
| 119:30 | you make this calculation from the dry , you calculate the saturated velocity. |
|
| 119:35 | difference is called non B. Dispersion. Um I'm sorry, it's |
|
| 119:44 | B. O. Dispersion. But there there are also huge differences |
|
| 119:50 | low saturation. So we'll have to about what's happening here now, accounting |
|
| 120:01 | the difference using the mass coupling factor , correct The velocities at 100% |
|
| 120:12 | but won't produce the observed curve, ? All of these are showing an |
|
| 120:19 | off switch, like gas mains but you could correct for the dispersion |
|
| 120:25 | 100% saturation by varying this mass coupling . So at least we could get |
|
| 120:31 | point right now, what's happening here has to do with the distribution of |
|
| 120:42 | , how gas is distributed in the . And if we have time later |
|
| 120:47 | the course, we may come back that and show how to calculate |
|
| 120:53 | But we're gonna uh we're not gonna about that now, I'm just pointing |
|
| 120:59 | that that difference exists. So here's example comparing velocities when we in when |
|
| 121:10 | push fluid into the rock, so increase the saturation by injecting fluid into |
|
| 121:18 | rock, or we decrease the water by letting the fluid drain out of |
|
| 121:25 | rock, letting the liquid drain out the rock. And you see two |
|
| 121:30 | different behaviors and that's attributed to different of gas and report space. |
|
| 121:42 | some other things come out of Beos frequency theory, and I expect you |
|
| 121:48 | memorize these equations for the final Actually, I'm only kidding, I |
|
| 121:54 | am showing the equations number one, show that they're complicated but to to |
|
| 122:01 | that there's a plus or minus sign . This is the velocity of the |
|
| 122:06 | wave at infinite frequency. There's a or minus sign, that means there |
|
| 122:15 | two p waves. So according to . O. Theory, we not |
|
| 122:22 | have a P wave and the shear , we have a fast P. |
|
| 122:27 | wave a share wave and a slow wave. And the slow P wave |
|
| 122:32 | slower than the share wave. We've been able to use that phenomenon |
|
| 122:40 | explain things like low frequency shadows under reservoirs, but just pointing out that |
|
| 122:49 | poor elastic wave propagation is not the as elastic wave propagation. So we |
|
| 122:57 | a fast P wave. This is versus porosity measured in the laboratory, |
|
| 123:03 | wave velocity and a slow P Right? This um this slow P |
|
| 123:11 | is what is called an evanescent The reason people don't talk about it |
|
| 123:17 | the reason people don't see it is it attenuate very rapidly. On the |
|
| 123:24 | hand, if it travels a very distance and converts back to p. |
|
| 123:29 | could produce events on your seismic section you won't be able to model with |
|
| 123:36 | P wave modeling. And these are we call low frequency shadows. |
|
| 123:45 | another caution. The frame module asse not the dry frame, You dry |
|
| 123:54 | frame, you change it. It the wedded frame module asse in the |
|
| 124:00 | of the N. C. To fluid. Alright, so I like |
|
| 124:04 | call it the skeleton module asse or the frame module asse. And in |
|
| 124:10 | mechanics they like to call it the module asse. So it's like a |
|
| 124:17 | . I'm squeezing the rock and the are free to escape. They squeeze |
|
| 124:23 | . The fluids come out. So the dreamed modular. Now, why |
|
| 124:33 | this important? Because as we saw that, in that case where the |
|
| 124:39 | wave velocity increased when I added uh fluids can interact chemically with the |
|
| 124:50 | minerals, particularly the clays at low . Uh This has been seen to |
|
| 124:59 | where you could produce silica gels. , if I have quartz grades, |
|
| 125:04 | at low pressure, I add It produces a silica gel on the |
|
| 125:10 | grain and causes the quartz grains to each other. So you could actually |
|
| 125:17 | the frame that way. Um On other hand, if you've ever built |
|
| 125:23 | on the beach, you could pile sand with a higher angle of |
|
| 125:29 | right? You can solidify the walls your sandcastle by wedding them. So |
|
| 125:35 | that case the capillary forces and the tension of the water is actually helping |
|
| 125:43 | the grains together. On the other , water can lubricate the graves. |
|
| 125:49 | I call that the banana peel but that hasn't caught on in the |
|
| 125:54 | literature. But think about, you , if you walk around Houston on |
|
| 125:59 | wet day, you really want to mud because you could go sliding, |
|
| 126:05 | ? So you can buy lubricating the , you can reduce the rigidity of |
|
| 126:10 | rock dramatically, or water can harden frame by causing plays to swell and |
|
| 126:19 | the other minerals more tightly. And of this is handled by gas men's |
|
| 126:25 | . Right. Gas mains equations are mechanical. Now this dry frame module |
|
| 126:40 | um back in uh my paper in the mud rock line paper I claimed |
|
| 126:48 | frame modular Sequels. The bulk module . Some years later. Z. |
|
| 126:53 | . Wang of battle and wang fain out with this uh empirical trend And |
|
| 127:01 | the share module is is .96 times frame modular. So that's pretty damn |
|
| 127:08 | . Right. Um This from a by Spencer showing that for different minerals |
|
| 127:16 | different uh different sediments. He's got relatively small range of lessons ratios. |
|
| 127:24 | For for the frames I um I'm keen on using uh laboratory measurements in |
|
| 127:36 | in brian saturated sentiments to sort out frame ma july. Um I'll explain |
|
| 127:47 | in a bit. Okay so let's a little bit more about the rock |
|
| 127:56 | properties. What controls the rock So here we see that uh as |
|
| 128:10 | increase the porosity, the frame module decreases the frame. Both modular and |
|
| 128:18 | frame share module is decrease. Um are measurements from Murphy again showing a |
|
| 128:27 | clear decrease and so various you could up with various empirical forms to fit |
|
| 128:35 | decrease of the frame modulates with These are a couple of popular forms |
|
| 128:46 | Creflo if have the bulk modulates And sheer module asse given by the ma |
|
| 128:56 | of the rural mineral Times. 1 the process he raised to some |
|
| 129:04 | And so they get a result. this critical porosity model looks like that |
|
| 129:11 | they're pretty similar for low porosity. rocks have different trends though. Uh |
|
| 129:27 | uh has this strand with a very intercept. So presumably this is not |
|
| 129:37 | , I think these were centered glass . Other laboratory measurements, a similar |
|
| 129:46 | as we come out to the 40% . Similar slope courts would be somewhere |
|
| 129:53 | here, but overall a more or linear increase with increasing ferocity. Uh |
|
| 130:04 | might not be so linear if you clays involved. Okay, so um |
|
| 130:21 | on if you try to use uh critical porosity um the question becomes, |
|
| 130:31 | what do you use after the critical ? So what what creep is trying |
|
| 130:37 | do? He's trying to add this here to kind of go towards Royce |
|
| 130:45 | . Right? Whereas the critical porosity model just goes to zero at whatever |
|
| 130:53 | porosity you choose. But you these rocks may have a different critical |
|
| 130:59 | than these rocks. Right? So fit these rocks properly, you may |
|
| 131:04 | fit these. And what about these here, you'd have to use a |
|
| 131:08 | critical porosity. So uh really none these empirical models work for all |
|
| 131:20 | Now we could do theoretical mathematical Uh These are not going to be |
|
| 131:32 | for predictive purposes but they're going to very useful for conceptual understanding of what's |
|
| 131:37 | on. And so you can uh the bulk module asse of the rock |
|
| 131:46 | inclusions being uh related to the bulk asse and share modulates of the materials |
|
| 132:00 | of the individual uh materials making things . But this requires explicitly specifying the |
|
| 132:13 | shape. So you need these factors which have the aspect ratio of the |
|
| 132:20 | in them. So you could but this kind of modeling, as we |
|
| 132:30 | last week, you could model uh example the dry frame module asse versus |
|
| 132:37 | . We just went directly predicted vP . V. S. But this |
|
| 132:43 | a step towards getting there. The ferocity versus dry frame modules. |
|
| 132:49 | you see you're getting these linear kinds trends which are similar to what we've |
|
| 132:56 | . A linear drop in the frame with ferocity. Um And um it |
|
| 133:04 | out that if you have used the tox ohs model with a frame |
|
| 133:09 | I mean an aspect ratio of Uh You get a trend that tends |
|
| 133:15 | agree with what we see with granular . Um This is what you would |
|
| 133:27 | if you had spherical pores. So velocities would be much higher. Now |
|
| 133:38 | this case uh you can add cracks uh to the rock, you could |
|
| 133:49 | I have spherical porosity and now I'm use custard toxins modeling and I'm gonna |
|
| 133:56 | cracks To the spherical porosity. So here we had an aspect ratio |
|
| 134:02 | .1, no spherical pores. All pores had an aspect ratio .1. |
|
| 134:08 | risk spherical pores. So there are hysterical spherical pores. And now we're |
|
| 134:15 | add cracks to that. And what see is a similar reduction in |
|
| 134:22 | But these cracks are much finer and can see how this affects the |
|
| 134:31 | P. V. S ratio. um what you're seeing here in the |
|
| 134:40 | rock is there isn't a big range V. P. B. |
|
| 134:43 | Ratios for the dry rock. In for the dry rock, the cracks |
|
| 134:51 | wind up giving you a lower P. B. S. Than |
|
| 134:54 | spherical for a student. Okay. the range is very small. All |
|
| 134:59 | these are pretty close to both, equal share modular In terms of the |
|
| 135:06 | v. P. B. ratio. The songs ratio is pretty |
|
| 135:10 | to .1 for all of these. that that noise gets to be too |
|
| 135:22 | for you, let me know Okay, good. Because I've got |
|
| 135:31 | working on a deck, I've got cutting down trees and now I have |
|
| 135:37 | lawnmower out there so it's driving me . Okay, now dispersion, I've |
|
| 135:49 | before that if we have attenuation, have dispersion. Dry rocks have very |
|
| 135:57 | attenuation. The attenuation in dry rock caused by solid solid friction. And |
|
| 136:06 | if if I look at wave propagation the moon for example. Attenuation is |
|
| 136:11 | low as soon as I saturate the attenuation increases dramatically because the movement |
|
| 136:18 | fluid and fluid. Solid friction. fact a partially saturated rock has the |
|
| 136:25 | attenuation. Because in a partially saturated the water is very free to move |
|
| 136:32 | compressing gas. So uh if if make laboratory missions as a function of |
|
| 136:43 | , the dry rock velocity isn't changing frequency whereas the these are body |
|
| 136:51 | So the in the water set traded you have high attenuation and the velocity |
|
| 136:58 | with frequency. Alright, so now gonna use the high frequency BBO equations |
|
| 137:10 | try to back out from the velocity what the frame module Ir I'm worried |
|
| 137:18 | if I use high frequency measurements to for K. D. The dispersion |
|
| 137:26 | going to give me the wrong dry modular. Yeah. To do this |
|
| 137:33 | have to know the mass coupling Right? So I'm gonna assume that |
|
| 137:42 | high frequency measurements the mass coupling factor very low The low frequency match. |
|
| 137:51 | I'm gonna set it to one at frequency measurements below frequency measurements. I'm |
|
| 137:59 | assume that gas means equations are So I'm gonna set the mass coupling |
|
| 138:05 | to infinity at that point. And gonna back out the frame module is |
|
| 138:12 | ways and I'm gonna cross plot. gonna do the same for the sheer |
|
| 138:21 | and I'm gonna cross plot. The module is for the sheer modules. |
|
| 138:26 | I do it for the dry rocks I get that trend for the same |
|
| 138:35 | . I do it and use gas equations and I don't get both modular |
|
| 138:42 | share modular. I get both modular greater than share modules on average. |
|
| 138:51 | the other hand, if I use mass coupling factor one, I'm back |
|
| 138:56 | bulk modulates equal share modules. So when we apply gas mons equations |
|
| 139:03 | high frequency measurements and we back out frame module asse we're introducing an apparent |
|
| 139:10 | which isn't real. I'm sorry, an apparent dispersion and apparent difference in |
|
| 139:25 | frame to share modulates ratio, which the difference in the frame worsens |
|
| 139:31 | That isn't real. It's misleading as result. Um your high frequency measurements |
|
| 139:37 | imply a higher poison's ratio for dry stones than you really have. |
|
| 139:49 | so uh you can invert gas mains to determine frame on july if you |
|
| 139:56 | VPN V. S and this will the poison's ratio if there is significant |
|
| 140:09 | . Now there are other things that change uh the frame module this and |
|
| 140:21 | one of the most important things is shape of the pores, which you |
|
| 140:32 | imagine would be strongly related to the content. So uh here We've got |
|
| 140:44 | corpse. These are the empirical relations were observed for sand stones. And |
|
| 140:53 | here we have 50% courts. Here have 0% courts. So, uh |
|
| 140:59 | have a higher ratio of both modules share modular. This is modeled using |
|
| 141:10 | , inclusion modeling. These are similar custom taxes. This is Okano Budiansky |
|
| 141:17 | , Right? The point is the courts, we get pretty much bulk |
|
| 141:24 | Sequels share modular. Um but we clay and that increases things. So |
|
| 141:30 | clay content is important. Similarly, know, kau sai plays muscovite. |
|
| 141:44 | all have higher frame persons. They have a higher mineral persons ratio than |
|
| 141:53 | . So, uh, a significant of any of these other things felt |
|
| 141:58 | far as calcite, micah's will cause sandstone. If I have a dirty |
|
| 142:06 | or anarcho six sandstone, it'll be higher frame poison's ratio. Uh, |
|
| 142:13 | low framed poison's ratio I've been talking um of about 60.1 with bulk modular |
|
| 142:21 | sheer modulates. This is for clean sand stones. Okay, so, |
|
| 142:31 | , how are we going to use fluid substitution while we could use it |
|
| 142:35 | do seismic modeling. So, for , this was something done. |
|
| 142:45 | around late 80's at the company I working and uh, here was the |
|
| 142:54 | V. P V. S ratio a gas sand. This was the |
|
| 143:01 | data. Uh so we're looking at amplitude variation with offset. So |
|
| 143:07 | this is the CDB gather and we're at these wave forms acquired at different |
|
| 143:14 | . And this is the elastic model was produced, the computer simulation that |
|
| 143:20 | produced using the predicted be PBS And if you look at the amplitude |
|
| 143:27 | with on this guy, you could at the, you could measure the |
|
| 143:33 | on the data, you could fit trend to the data, which is |
|
| 143:37 | red curve. And you could look the amplitudes from the simulated model and |
|
| 143:47 | see that they agree with the trend the data. So it's kind of |
|
| 143:53 | verification that the things we're doing aren't terribly wrong. Now. Here was |
|
| 144:00 | case which was interesting because it was oil stand, but it was a |
|
| 144:05 | oil sand and it was very Er So it's V. P. |
|
| 144:08 | . S ratio was higher than the shells, whereas the gas sand, |
|
| 144:13 | B. P. B. Was lower than the surrounding sea shells |
|
| 144:18 | , it's higher. And so rather having uh an amplitude increase with offset |
|
| 144:25 | the gas sand, uh These data a flat A. B. |
|
| 144:29 | Response didn't increase with offsetting and the model showed a similar result to uh |
|
| 144:38 | the data. Another complication that can is as we start producing a |
|
| 144:50 | So if we're looking at seismic data production has started the production can change |
|
| 145:01 | fluid properties. For example. Uh the case where you might have had |
|
| 145:09 | on oil and the pressure is the pressure comes down and drops you |
|
| 145:17 | the bubble point or the oil at case bubbles will come out of solution |
|
| 145:24 | the oil. You can see this has free gas in it. You're |
|
| 145:29 | have to use Woods equation. You're wind up with a very low module |
|
| 145:33 | more similar to the modulates of So here, as soon as you |
|
| 145:38 | that bubble point, you have a change in the impedance of the oil |
|
| 145:45 | rock, a quantum change. So could have a big change in the |
|
| 145:52 | , seismic response as a function of . So we call this a time |
|
| 145:57 | effect. Now, here was a of gas over a brian sand after |
|
| 146:08 | where the is presumed that gas came of solution in the brine. And |
|
| 146:16 | you're getting is a relatively flat variation amplitude with offset not uh an amplitude |
|
| 146:26 | with offset which is often what people . This was the original gas over |
|
| 146:35 | sand before production at least the synthetic of it. All right, |
|
| 146:41 | you can see here the the the V. P. B. |
|
| 146:45 | ratio is dropping in the brine leg gas is coming out of solution. |
|
| 146:50 | , I have to be very careful these things and that also affects if |
|
| 146:58 | use producing fields as analogs for seismic , it could cause you to get |
|
| 147:07 | trouble. So, for example, I have a productive field and there's |
|
| 147:14 | bright spot that the production is coming . Alright now I drill here, |
|
| 147:21 | get a dry hole. I drill , I get a dry hole. |
|
| 147:26 | of these had an amplitude anomaly like . So I go to this location |
|
| 147:32 | I look at the amplitude there and , I've got a little bit of |
|
| 147:36 | here. But compared to that, not this nice, coherent, beautiful |
|
| 147:43 | . I compare this is present day . These wells were on production long |
|
| 147:50 | the seismic data was acquired. Comparing amplitude to that amplitude is not appropriate |
|
| 147:59 | I've changed the fluid properties here by so it would tend to, you |
|
| 148:06 | , if I'm dropping the pressures and making uh the hydrocarbons more uh compressible |
|
| 148:17 | things are coming out of solution. free gas is coming out of |
|
| 148:21 | These amplitudes anomalies are stronger today than were before production. So, you |
|
| 148:30 | , comparing this to that isn't And in fact that was a productive |
|
| 148:39 | , I think, okay, I I showed this example before where we |
|
| 148:43 | gas in the shell. This was interesting case where we were looking at |
|
| 148:54 | near surfaced V. P. And . S. Measurements and we were |
|
| 149:00 | at this over a field and outside field. So the field is is |
|
| 149:11 | below us here. We're in the near surface, we have very low |
|
| 149:16 | wave velocities. Uh And these are . C. Two measurements using actually |
|
| 149:22 | shotgun to to uh create the And uh so we look at p |
|
| 149:30 | velocity versus shear wave velocity over uh the field. We have Lovie PVS |
|
| 149:39 | on the flank of the field. have high V. PBS ratios on |
|
| 149:43 | flank or off the flank outside the extent of the field. The measurements |
|
| 149:50 | making our between our empirical shale trend an empirical brian trend. Right? |
|
| 149:58 | we go over the field and we're suppress V. PBS rations. So |
|
| 150:05 | certainly suppress VP. So the claim that yeah we have micro seeping |
|
| 150:10 | It's lowering the V. P. . S. Ratios more like a |
|
| 150:14 | sand. Remember this is a mixture sands and shales but then something very |
|
| 150:23 | . It's not it's a reduction in . P. B. S |
|
| 150:26 | But you see that the share wave are much faster, right? So |
|
| 150:34 | is you know, seeping gas over field isn't gonna do that. What's |
|
| 150:40 | gonna cause your shear wave velocities to . Well in fact, what was |
|
| 150:46 | here was bacteria was eating the micro gas seeping gas and precipitating cement as |
|
| 150:58 | result of the bacterial activity. So where you had micro seeping gas, |
|
| 151:06 | rocks were more cemented. So be ratio was lower because of the gas |
|
| 151:13 | also uh the sheer sheer the rigidity higher because of the precipitated cement. |
|
| 151:25 | it's the top of the hour. we'll take a 10 minute break before |
|
| 151:30 | wrap up for the day and We'll you at 4:10. So in doing |
|
| 151:46 | substitution, some things to keep in . Question one. What are the |
|
| 151:56 | reading? What are you actually measuring those logs? A density log reads |
|
| 152:04 | a few inches into the formation. if you have a lot of |
|
| 152:12 | the density log has seen the density the invaded zone. So that may |
|
| 152:19 | different than the density of your Sonic logs read a foot or two |
|
| 152:26 | the formation. So they have better . But if you have a lot |
|
| 152:33 | invasion, uh the hydrocarbon effect you may be changed right Even with invasion |
|
| 152:42 | velocities, you still will get, will still have residual hydrocarbons in the |
|
| 152:48 | this invaded zone. So the, know, the velocities will still be |
|
| 152:55 | , but they won't be exactly the as the formation velocities. Uh another |
|
| 153:04 | for this and other reasons, it's better to substitute hydrocarbons into a brine |
|
| 153:12 | than to substitute brian into a hydrocarbon sand. And the brian saying the |
|
| 153:18 | of invasion are not going to be great on the sonic or the density |
|
| 153:24 | , but just in general, sonic tend to be more reliable in brian |
|
| 153:30 | if we're in a gas and we the gas in the drilling fluid, |
|
| 153:34 | attenuate the signal. Also, the of energy into the formation is |
|
| 153:40 | So, in gas sands, you to get a lot of cycle |
|
| 153:46 | you have attenuation in the formation, have poor coupling in the formation, |
|
| 153:51 | have attenuation in the drilling fluid. if the velocities are very low, |
|
| 153:56 | don't even measure the direct wave. mean, I mean, the refracted |
|
| 154:00 | , if you measure the direct way the fluid. So all kinds of |
|
| 154:05 | to be suspicious of velocities in the , sands, brian sands are probably |
|
| 154:11 | reliable. And so if one is to compare the brian sand result to |
|
| 154:18 | gas sand response, you're better off with the brian sand. We already |
|
| 154:25 | about the fact that the density log more sensitive to hold conditions washed |
|
| 154:31 | washed out zones, Rough boreholes, we talked about all of that caused |
|
| 154:37 | density logs to be really bad. sometimes we're better off using the sonic |
|
| 154:43 | to estimate the density than to actually the density log. Now, as |
|
| 154:49 | playing these scenarios of putting hydrocarbons into a brine sand, don't put |
|
| 154:56 | much if it's a Shelley Brian you can't couldn't have 90% gas |
|
| 155:02 | that's just not gonna happen. So in um Shelly rocks, Shelly |
|
| 155:10 | uh, make sure that you consider the residual water saturation would be. |
|
| 155:17 | of course, don't forget that the reliable sonic velocity you could read is |
|
| 155:24 | velocity of the drilling fluid? Uh if the actual formation velocity is less |
|
| 155:30 | that, as you might have in unconsolidated gas and the sonic log is |
|
| 155:35 | giving you the right velocity. so let's go back to doing some |
|
| 155:51 | . So the first one uh should fairly simple um except I'm not understanding |
|
| 156:04 | question. Oh okay, this is woods formula, calculate the fluid module |
|
| 156:14 | . We have to say fluid module . Okay, so this is a |
|
| 156:22 | exercise and we're starting you off easy just calculating um Woods equation. Use |
|
| 156:32 | this oil and a bride module is 3.5 giga pascal's and uh As water |
|
| 156:43 | varies from 0 to 1. See the module us fairies. So we |
|
| 156:55 | stop recording while you work on So what I'm gonna do, |
|
| 157:03 | so what I'm gonna do since this gonna take too long, we'll do |
|
| 157:07 | , we'll start it tomorrow. I'm go ahead and pull up another |
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| 157:15 | Just let me find it. Let's share. Uh There I go. |
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| 157:24 | and let me share where is There it is. Chair. |
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| 157:37 | are you seeing a word file? . Okay, so I think this |
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| 157:44 | gonna be good preparation for your final these these are the kinds of questions |
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| 157:50 | get it will all be short answer this multiple choice and true false. |
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| 157:56 | for interruption. So should I record now? Yeah, this way Stephanie |
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| 158:03 | review it. Okay so which of following is a hypothesis? A fine |
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| 158:12 | go more easily into suspension than coarse be as fine particles are added to |
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| 158:19 | course, sentiment ferocity is reduced. when gas replaces water in a porous |
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| 158:25 | shear wave velocity increases because of the attraction of the moon. The all |
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| 158:33 | the above. E. None of above. Would it be C. |
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| 158:43 | . Very good. Even though it ridiculous and wrong. It was very |
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| 158:49 | . You're using your brain. Um a hypothesis because it's an explanation right |
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| 158:56 | wrong of an observation. Good. . Which of the following is a |
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| 159:02 | theoretical upper bound a the Rammer Hunt equation be the critical porosity model. |
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| 159:10 | the Voigt average D all of the . E. None of the |
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| 159:22 | Um I have to go through my , think about think about the word |
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| 159:29 | theoretical as opposed to empirical see? A that's an empirical equation. It |
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| 159:47 | as a practical upper bound but it's the strict theoretical upper bound. What |
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| 159:55 | the widest bounds possible found possible. the low lowest bound possible? Oh |
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| 160:08 | just went over that. That's Well, okay. Yeah I mean |
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| 160:14 | was the low I'm sorry that was lowest bound on fluid substitution but if |
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| 160:23 | have to materials that I'm mixing what is the lowest the modules can |
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| 160:30 | . Well Okay, yeah you're zero but it may not be possible |
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| 160:36 | achieve. zero. What is the theoretical possible bound? Do you remember |
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| 160:43 | Royce void bounds? The Royce bound the reciprocal volume weighted average. That |
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| 160:50 | the lowest module issue could have and highest module issue could have theoretically is |
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| 160:58 | void average. That's the void So the answer is C. |
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| 161:08 | so three the Royce average computed using reciprocal volume weighted average of constituent plane |
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| 161:16 | , ma july A is a strict bound be greater than the plane wave |
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| 161:24 | is computing using Royce averages of bulk shear module. I see results in |
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| 161:31 | suspension of solid particles and fluid having rigidity in a wood like equation D |
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| 161:39 | of the above E. None of above. We just said A for |
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| 161:47 | one it's a Yeah, now it's that a suspension of solid particles uh |
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| 161:58 | , is the Royce bound. But you use uh you know that is |
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| 162:04 | a strict bound. So that that's we call the wood like equation |
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| 162:10 | four In poorly lit defied rocks with is below 30%. Which equation provides |
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| 162:18 | better prediction of velocity from ferocity. gardener sandstone equation be widely time average |
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| 162:27 | . See critical porosity model. I . I'm smart. I'm just bad |
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| 162:35 | the spot. Well, you haven't , I've just given you the kinds |
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| 162:42 | things that you're going to review. if you go back to your |
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| 162:46 | you'll find that the gardener equation is poorly lit ified rocks whereas widely time |
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| 162:54 | equation is for well it defied rocks the critical porosity model. Like the |
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| 163:00 | Gardner equation is a practical upper Mhm. Okay, true or false |
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| 163:09 | defoliation usually increases anisotropy feeling. This true. Yes. Okay. You |
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| 163:19 | one of the you know when I this class with you know this |
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| 163:22 | when I have 20 people, there's a curve. Right? So what |
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| 163:27 | I what do I do for a when there's one person in the |
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| 163:35 | The kinds of philosophical questions that I to deal with. Okay, |
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| 163:43 | So six. What needs to be to have a unique relationship between ferocity |
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| 163:49 | velocity? A pressure be poor see degree of with indication de |
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| 163:59 | Yes. Yeah. So you're not badly without studying. That's how good |
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| 164:06 | teacher I am. Which type of will have the greatest effect on seismic |
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| 164:14 | per unit volume of ferocity. A be effective C fracture. Mhm. |
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| 164:24 | it be buggy has the smallest effect size? Yeah. Because fractures are |
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| 164:35 | compressible. A few fractures. Lower velocity. A lot compared to normal |
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| 164:43 | . Okay, a true or A shell must be composed primarily of |
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| 164:51 | minerals which you'll remember from rocks and are fill a silicates true or false |
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| 165:01 | didn't hear your answer true false. took rocks and minerals 200 years |
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| 165:13 | So can be primarily courts. Right. They usually have a lot |
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| 165:21 | clay minerals but they don't have By definition a shell is a fine |
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| 165:30 | mud rock. Alright, true or . And an icy tropic rock cannot |
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| 165:38 | definition be homogeneous. Okay, that's . Okay. No it's not actually |
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| 165:47 | it or not. That's false. an anisotropy. Rock is anisotropy is |
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| 165:55 | variation of velocity with direction. But that could be the same. |
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| 166:02 | place. That variation of velocity could the same every place. So in |
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| 166:07 | ice tropic rock can be homogeneous at macro scale. At a micro |
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| 166:14 | No rock is homogeneous, right? you could be in poor you could |
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| 166:20 | ingrained. Right? So uh at you know, at the macroscopic way |
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| 166:30 | looking at at a rock the anisotropy it's the same every place. The |
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| 166:35 | is homogeneous. Okay, In the figure. Well, the figure is |
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| 166:42 | . All right, forget number I don't know what I did to |
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| 166:46 | figure. Okay, let's get rid that guy. Okay. 11. |
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| 166:55 | porosity of one has a void ratio 10 or infinity. Mhm. I'll |
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| 167:06 | you a hint avoid ratios, porosity by 1 - Porosity. Oh it |
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| 167:12 | be infinity. Okay. 12. is the grain density for Iraq? |
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| 167:18 | is 50% courts and 50% calcite. 2.65 to 2.87 C 2.71 D. |
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| 167:29 | of the above. So this requires know the grain densities for courts and |
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| 167:34 | . And these are numbers that Should remembered is two points Right? Because |
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| 167:44 | is 2.65. Well cal side is . So it can't, the answer |
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| 167:50 | be 2.87. It's got to be 2.65 and 2.71. So the answer |
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| 167:56 | none of the above. Yeah. . I could have like put two |
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| 167:59 | two together for that one. Okay Assume ice has a density of |
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| 168:07 | g per cc. What percentage of iceberg is exposed? 90% exposed. |
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| 168:18 | I was getting coffee. You only the tip of the iceberg and that's |
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| 168:26 | I was in my head. So don't know why. Okay. |
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| 168:32 | Which sphere pack has the lower specific area? A simple cubic. Be |
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| 168:40 | hexagonal. See exact journal close Oh that was cubic because lower specific |
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| 168:53 | and I think that one's cubic or , I'm like picturing all those things |
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| 169:01 | my head. Um It's not be think it's a no I don't |
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| 169:19 | You know what let's go back to place. Let's go find it. |
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| 169:29 | like looking through all my notes right . Trying to find open. It's |
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| 169:40 | a while lecture to. No that's . Class. Ah Okay. File |
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| 169:53 | should be able to find brows I find browse for some reason. |
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| 169:57 | there it is browse Where's porosity? it is. Unit two. |
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| 170:18 | This is like a Vulcan review and back bad memories. Right? Not |
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| 170:27 | all. Okay. We're getting Remember this guy? I am still |
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| 170:43 | at the test. I'm still looking the test. Okay. I have |
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| 170:48 | share this. Sorry, where is ? Oh God, hope that's |
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| 170:59 | Did you see the equation for a surface area? Well, I hear |
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| 171:21 | so which sphere pack has the high the lowest ferocity. We had simple |
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| 171:29 | , hexagonal or hexagonal close packed. you remember which of those as lowest |
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| 171:39 | . Simple cubic is the least exact exact clothes packed is the most |
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| 171:46 | . Right? So that must be lowest ferocity. So you have the |
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| 171:51 | . So which has the highest specific area. It would be the clothes |
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| 172:00 | . So it was a little bit to intuition, wasn't Yeah, I |
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| 172:05 | picturing just a big old cube. , I see. Yeah. |
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| 172:15 | Yeah. So these are spheres. just the way they're arranged. |
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| 172:22 | practice test. I need to re . What am I doing around |
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| 172:36 | Okay, we're back. So the lowest specific surface area weight. |
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| 172:46 | lowest specific surface area. One minus . The question was the lower So |
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| 172:52 | were right in the first place I wrong. The answers answers. Simple |
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| 172:59 | . I outsmarted myself. Okay. 15 as a sparkle grain increase increases |
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| 173:13 | size, the ratio of surface area volume A increases or B decreases, |
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| 173:23 | . Yes, there's a problem for . Wasn't okay, true or |
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| 173:32 | The sphere pack arrangement has a greater on specific area area than grain |
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| 173:40 | True. No. Remember grain It's it's three times one minus porosity |
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| 173:51 | our right. The grain size. I think we did this as an |
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| 173:58 | for different sphere packs and we found grain size was a dominating effect. |
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| 174:09 | , cause porosity uh you know, it's three times one minus porosity and |
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| 174:16 | only varies from 48% to 26%. ? But our can vary by orders |
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| 174:24 | magnitude. So, so, grain has a bigger effect. Okay, |
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| 174:30 | or false. A spherical particle has smaller surface area for a given volume |
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| 174:36 | an angular particle. That is Yes, Yes. The sphere has |
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| 174:50 | lowest surface area per uh per given than any other shape. I |
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| 174:59 | think about it. A flat plate angular. Right? So it's got |
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| 175:04 | high surface area for the volume. . Oh, for some reason the |
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| 175:10 | didn't didn't copy so let's forget about one. Okay, 19. Most |
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| 175:23 | reduction with increasing depth is usually accomplished a rearrangement of grains and compaction. |
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| 175:30 | segmentation sees dissolution, Yep. 20 increasing depth, which of the following |
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| 175:40 | generally occur. A decrease in point . Be increase of coordination. C |
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| 175:49 | . A flat or interlocking context. all of the above. E None |
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| 175:55 | the above. Mm When I say in point context, I should have |
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| 176:04 | decrease in the number of point I know C is right. Is |
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| 176:17 | right? Increase coordination. In other , you're contacting more and more grains |
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| 176:23 | you get buried? Yes. So I can see it's good. |
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| 176:29 | can see it's confusing without knowing where head was at. When I say |
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| 176:34 | in point contacts. That seems to contrary to increase of coordination. |
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| 176:40 | But I'm not talking about the number point contacts. Right? I didn't |
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| 176:48 | well, no, I wasn't talking the number of contacts. I was |
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| 176:53 | about the number of contacts that could classified as point context because what happens |
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| 176:59 | you bury Iraq, you deformed the and you start distorting the grains such |
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| 177:06 | they're no longer a point contacts. contact is going to be more compressible |
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| 177:13 | a flat contact, which is gonna uh less rigid than an interlocking |
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| 177:20 | Okay, next one ferocity and mud's increases with decreasing a pressure. Be |
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| 177:30 | size C ability to go into solution suspension. D All of the |
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| 177:37 | E. None of the above all the above. Yes, true or |
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| 177:50 | . Mont Marila night is a swelling that can have significant nonce Tokyo metric |
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| 177:56 | water incorporated into the crystal lattice. true true True false Sandstone has a |
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| 178:05 | porosity of about 15 false. That's . Yes. Remember we have the |
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| 178:16 | ferocity of 40% or simple cubic Okay. Um I think I've tortured |
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| 178:24 | enough for this afternoon. So let's it a day and uh yeah, |
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| 178:32 | know this will all be recorded so will be good review for your |
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| 178:37 | And also you get familiar with the of questions I asked. Alright, |
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| 178:44 | tomorrow morning we'll we'll write in early a.m. And we'll skip lunch again. |
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| 178:50 | we'll wrap up by four and we'll out the day doing fluid substitution in |
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| 178:58 | . So we're immediately gonna have to up. Okay, so see you |
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| 179:05 | the morning then. Alright, have good |
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