Hey Thom, I'm so glad that I didn't discourage you too much yesterday! I was sort of concerned that you might take it badly... Glad to see you took it constructively!
your warnings about the rigidity and usefulness of the inner wall construction are well taken and I will think this over and rectify this before moving forward with anything else.
If I might make a suggestion here: Don't build anything else yet! Hold off on building until you have a solid, sound, verified,cost-effective plan, completed. I know it's very disappointing to hold off for a couple of months when you seem to be so close to completing the place and being able to use it, but that's really what I would recommend. As I mentioned yesterday, I think your place CAN be great: it has the potential. But considering the mistakes so far, it will need careful design and careful construction to compensate, and to get things good. You were about to do some bad things, and I'm concerned you could be planning to do more bad things, so I really hope you take this suggestion to heart, and make sure that the design is done completely, in full detail, taking into account all of the aspects, verified for acoustics, verified for structure, verified for HVAC, verified for usability, verified for everything... and then, when it is completely designed, only then start building.
I've been through this process with several people over the years, some paying customers, some forum members, and it's always a tough call to stop when you have momentum and you think the end is in sight.... but you are actually not as far along as you think! There's still a lot to be done....
The reason for this as I see it is, that I have a tendency of taking on projects that are well beyond my capabilities at the time of starting.
So aren't you glad you found the forum!?
It's a good place to hang out your ideas, concepts, and thoughts, to see of they are feasible, and ask for advice. We'll try to keep you on track!
I don't think that's necessarily a bad thing, but it certainly comes with a range of risks, difficulties, and compromises.
It's not a bad thing at all! But when you run into things that are "well beyond my capabilities" as you put it, it's a good idea to ask!
He was aiming for NC-20, if I remember correctly, which came with a whole host of increasingly complex and expensive measures he advised me to take.
NC-20 is a typical goal for a good studio. Getting NC-20 is actually more about the HVAC system than the isolation system. Or perhaps "both in equal measures" would be a better way of putting it. To get NC-20, you need to design the HVAC system for that, along with the room. You might well be able to get NC-20 with the HVAC turned off, but there's not much point to that! You need to be able to use the room with the HVAC turned ON! HVAC design is an integral part of studio design: When I'm designing a studio, I often spend as much time on the HVAC as I do on the rest of the studio all together: HVAC is a big issue.
I tried to find a more reasonable compromise between versatility, high standards, affordability, and ease of construction with him many times, but he was rather unwilling to lower his requirements, and I found myself unable to properly communicate what I was actually aiming for. Most of this was obviously a matter of poor communication, and hence mostly my fault.
Communication is a two-way street: It's a pity that more effort didn't go into it from the other side, ... As a studio designer myself, I do appreciate that some clients can be ... ummm... "difficult" (!), but you don't sound like that type to me....
The primary purpose of this studio is mixed-source music production for video productions. This means, that I'll partly work with virtual instruments, electronic instruments (synths), and occasionally with session musicians for drums, horns, strings, and vocals in overdub.
Great! But that prompts a question; mixing for video and cine these days is often 5.1, 7.1 or even something more exotic. Do you plan to do that? Maybe not now, but at some point later? If you plan on ever doing multi-channel mixing, then the control room acoustics and overall design need to be done for that NOW! It's really tough to upgrade a dedicated 2.0 or 2.1 studio to 5.1. It basically involves ripping out all the treatment and starting over. Perhaps even needing to move the mix position and gear... It's perfectly fine to run a 2.0 or 2.1 system in a room designed for 5.1: no problem at all. But going the other way is a problem. So if there's any possibility at all that you might want 5.1 in the future, design the room for that now, even if you only use it for 2.1.
I don't intend to have the best studio far and wide,
Ahhh, but it COULD be!
The only real difference between a good studio and a great studio, is attention to detail in the design and tuning... You have seen what we achieved with Studio Three: But there's a back story there. Rod (the owner of Studio Three) first came to the forum wanting a little advice on how to soffit mount his speakers. Here on the forum, we pointed out several other things that were wrong with his initial design, and he decided to hire me to fix it. In fact, he just wanted me to design the soffits: that was the original brief. I named the project on my computer "front 2 meters", because that's all he wanted from me; a design for the two meters (six feet) at the front of the room, including the soffits and cloud. That's all. But as we got into it, that expanded to eventually include the entire control room, and then some other rooms too. At one point in our e-mail discussions, he commented to me that he didn't think his room could ever be useful "for A-listers" (top artists). I asked him: "why not?". I basically said something like: "If you don't think it can be great, then why are you investing all this money, and also hiring me? Do you really only want me to do just a mediocre job? Or do you want it to be really great, a place where A-listers would be happy to work?". That got him thinking, and he challenged me to give it my best shot, make it the best room I possibly could, put it "among the top 1% in the world". I have no way of proving that it really is among the top 1%, but it sure as hell is as good as I can get it! You can see that on the graphs: the response is flat, and can still be molded to fit any need.
Yours can be great too. I can see that. Not just good, but great.
The only thing in the way of making it word-class, is how much detail you put into the design, how carefully you build it, and how well you tune it. It probably won't get as flat as Studio Three, since that room is a lot bigger than yours, but it can still be well beyond a typical home studio.
Here's another thread you might be interested in (link below). It is in progress right now. A studio built buy one guy, from the ground up. I designed it a couple of years back, and it has been built quite. The live room is finished, and we are now just starting the process of tuning the control room. Today I posted the first results of the initial tuning, and you can see the "before" and "after" graphs there, from the acoustic devices that I designed last week, and that he has now built and installed. This is an on-going thing, and there will be more updates as we move forward with the build. I wanted you to see that, since his room is about the same size as yours, but based on a very different concept. However, due to the size similarities, you should be able to get similar results. Ir might be interesting for you to watch this thread, and get ideas for your own room design and treatment:
http://www.johnlsayers.com/phpBB2/viewt ... =2&t=21368 .
What I'm trying to say, is that you should not under-estimate the capabilities of that room: it can be really good. As good as most pro studios, for sure. Since this is a major investment for you, and obviously is your passion, and your future, to me it makes no sense to just say that "It will be sort of OK, but not fantastic". It CAN be fantastic, if you want it to be.
In terms of variable acoustics, I'll try to come up with some good solutions for that, as I think it's an important point. I intend to build movable baffles of different types, some highly absorptive, some highly reflective, some highly diffuse,
One of the rooms at Studio Three is what Rod and I call the "Varicustic room". It was originally intended to be a vocal booth / iso booth, but I suggested making it variable. Here's what we did:
Variable-acoustic-01--panels--construction--half-open-SML.jpg
Variable-acoustic-02--panels--construction--fully-open--SML-ENH.JPG
Variable-acoustic-03--partly-completed--SML-ENH.jpg
Variable-acoustic-04--room--completed--SML-ENH.jpg
Those are variable panels that you simply open or close, like a door. They swing over the central slotted wedge, modifying the decay times of the room in a controlled manner.
Here's the results, acoustically:
variable-acoustic-05--acoustic-rt60-plots-all-positions-t20.jpg
That was measured in a setup that would typically used for tracking an acoustic instrument, about a meter or so in front of the panels, so it's the overall room response that you are seeing. As you can see, as you swing the panels from fully opened to fully closed, the decay times in the LOW end go down, while in the high end they go up, with not much change in the mid range. In other words, it skews the response from being bass heavy and slightly "boomy" to being "bright" and "airy". You might want to consider doing something like that.
The environmental noise level outside the studio window sits at around 50dbA (60dbC) on average, and hardly ever reaches or exceeds 65dbA (75-80dBC) even during especially noise times. (both A and C weighting measured with slow impulse response) ... The current noise level in the studio with all doors firmly closed sits at around 32dBA (42dBC) in both rooms
Hmmmm.... so you have around 75 dBC outside, and around 40 dBC inside. That implies isolation of around 30 dB, which isn't much. And with 32 dBA / 42 dBC inside, you definitely are not getting NC-20! Probably more like NC-30. And you don't even have the HVAC turned on yet.... NC-30 is not going to be any use for Foley work.
Not trying to scare you! Just pointing out that there's a problem here: you are not getting what you should be getting. You should probably concentrate on investigating WHY you aren't getting the results you should be seeing.
My father has some serious reservations about drilling into the screed slab, because it contains the heating circuits.
There's a simple solution: thermal camera! Turn on the heating system, then take a thermal picture of the floor, and you'll see exactly where the heating pipes are, so you can avoid them:
thermal-camera-radiant-floor-IR image2.jpg
Simple! Fast, accurate, no problems. No drilled pipes!
You DO need to anchor the studs to the floor: Check your building code and local regulations: I'm pretty sure you'll find that it is a legal requirement. But even if it is NOT a legal requirement, you STILL need to do it, for a very simple reason: Your inner-leaf doors will be heavy, and as you open and close them there will be a large amount of stress and strain on the framing. Plus, there will be air pressure changes in the cavity as the doors open and close: You do NOT want the walls "walking" over the floor from that! Not to mention the vibrations from sound played at high levels, or instruments played at high levels... Your walls cannot just sit there without being anchored. If you don't anchor them, your doors will end up not closing properly, not sealing, not isolating....
The ceiling studs will sit on top of the inner shell construction as planned, but we would still prefer to use the resilient hangers I posted to secure the ceiling studs to the concrete ceiling, and several of the wall studs to the concrete walls for security,
There is absolutely no need for that, and it will trash your isolation. You CANNOT have any mechanical connections between the leaves of your rooms. Even on single nail or screw that connects them is enough to destroy the isolation.
Have you ever used a tuning fork?
tuning-fork-02--C-note-SML.jpg
How instruments were tuned before electronic tuners appeared... Tap it on the table, hold it up in the air, and you can faintly hear the tone. Tap it on the table, and hold the base of the fork on the table, and it is MUCH louder... because the solid connection transmits the vibration into the table, which then acts as a speaker. The size of the base stem is about the same size as a nail or screw....
That's illustrates perfect why there can be ZERO connections between the inner-leaf room and the outer-leaf.
Once that is complete, we'd evaluate if a second layer of drywall is needed to increase ...
Bad idea! That is called "building with no design", and is doomed to fail. It is also called "guessing", and you cannot successfully build a studio by guessing.... Instead, just CALCULATE! There are equations for predicting how an MSM wall will isolate. Just do the math, and design the studio to perform the way it needs to perform.
before filling in the spaces with rockwool and mounting a first layer of 15mm drywall.
Don't use drywall for the first layer: use either OSB or plywood. That gives the wall MUCH greater structural integrity, especially in sheer. Put one layer of OSB (or ply; whichever is cheaper where you live), then put a layer of drywall on top of that, optionally with Green Glue in between. But first design the wall so that the combined mass of those two, along with the depth of the air cavity, and the damping of the insulation, will be correct for your needs.
Does this sound like a workable approach, or do you still think this does more harm than good?
More harm than good.
One very well respected forum member, a renowned acoustician, used to have a signature that said; "Building a studio is 90% design, 10% construction". He is absolutely right! If you spend most of your time designing it, then the construction will be smooth, fast, and cheap, with a successful outcome. If you DON'T design it properly, construction will be problematic, slow, and expensive, with a very poor outcome. If you don't believe me, take a look at some of the build threads on the forum: Those that were designed carefully ALWAYS work out very, very well. Those that were "designed" by guesswork or built with no real design at all, always turn out badly. Or they never turn out at all...
Considering the placement of my control room window, I don't think that changing the orientation of the CR will do me much good.
You might be right. I'd need some time studying the actual SKP model to see if there are any possibilities, but from the photo, it looks like you are out of luck.
Would my current orientation be significantly worse than having the speakers firing down the longer dimension, considering that the room is already nearly square in footprint?
There would be a difference (20cm is 20cm!), but probably not life-or-death.
To be honest, I don't think he was very happy with me as a customer and I wasn't very happy with him as a consultant. I'm normally not a bad communicator, but the two of us seemed to be talking past one another, and I ended up trying to determine things on my own whenever I thought I could, with mixed results as it's becoming apparent.
Understood. Sometimes there's just no "connection" or "chemistry", and f that happens, it's better to pass on the project to someone else. I'm just completing the design for a mastering studio where that happened. The customer hired a very big name designed initially, but the design he delivered was nothing like what the customer needed. Communications issues: the designer wanted to do it one way, but the owner did NOT want it that way, for practical reasons: There was no way to actually build it on his property! There's nothing at all wrong with the design: it would have worked out well. Except that it could not be built in the space available. That's when the owner contacted me to take over, and re-do it completely, the way
HE wants it, not the way the
designer wanted it. So I fully understand! That one is currently under construction: I'll see if I can get permission from the owner to post some images.
Anyway, you made it to the forum, so you can now get the right advice, to do it the way you want it to be... but doe right!
Not by guesswork, but by design...
But to be clear, I don't wanna speak badly of the man at all, as he's clearly very good and experienced at what he does, but we seemed to be pulling in different directions.
Completely understood! That's very similar to the issue with the mastering studio I mentioned above: Big name designer, good reputation, many successful studios... but a lack of connection with the customer in this specific case. It happens.
Would it be conceivable to keep the orientation this way, and to increase the rear wall absorption substantially?
Possibly, but there's a lot of calculations that would need to be done to make sure. I would need to see the full layout and design intention, then spend some time working through it. But I'm rally tight on time right now! Several projects under way, and my paying customers get first priority. I'm sure you understand!
To be honest, I am surprised too. I showed him the plans before I handed them in for approval, and he didn't note any significant problems with it.
Curious...
I intend to build a stack of sandboxes with different materials that I can wheel into the room when I do have a project that requires Foley work.
You will need filters on your HVAC return registers! Foley work tends to put a lot of particulate stuff into the air, as you thump, beat, batter, clip, tear, shred, and mangle things. It's a good idea to filter that out, before it gets in to the HVAC ducts. Also, you will need to oversize your AHU, as there will be higher humidity in the room when you are playing with water, and you need to get that under control.
All of these things should have gone into the original design...
I guess I should have asked you sooner!
But you did find us in the end, and it's not too late: things can be fixed, and improved...
That stuff was by no means cheap, actually. It's called Pronouvo-Cork Type 1073 and costs an arm and a leg.
Interesting! You live and you learn.... I have never seen cork being used in that application before. It would not be allowed where I live: Chile is the earthquake capital of the world. If you have every been in a magnitude 7, or 8, or even 6 earthquake, you realize WHY things have to be anchored firmly. Things MOVE in a quake. But anyway, if you don't live in a seismic area, and that stuff is approved by your building code, then I guess it is OK....
The acoustic consultant said that the cork we put in between the foundation slabs may rot away in time as it gets wet from the groundwater, but that that would be nothing to worry about.
Ummm... So WHY did he put in there? Very strange.... Why not use an inert synthetic water-proof compound, that won't rot? Curious....
I did not consider the flanking potential of those strips, and neither did the acoustic consultant, as far as I'm aware. It was put in as a necessity, without really considering any alternative solutions...
There are several very good expansion joint compounds that are good both acoustically and also with water.
This part, I'm most bummed about. I feel like I could have found a significantly better solution for this with a little more preparation. ... The tubes carry only air from and to the rooms.
That's a problem. I would say that your HVAC is going to need a complete re-design. Sorry to tell you that in such blunt terms, but that's the way I see it.
What I'm seeing in the photos is ribbed 2 inch (50mm) pipe. Maybe a bit bigger, but I don't think so. The cross sectional area is small: therefore the air must move FAST (meters per second) in order to provide the correct flow rate (cubic meters per minute). Air that moves fast creates noise. Even worse, those are RIBBED pipes, meaning that the interior is a very rough surface, with bumps an valleys all over: That will create high turbulence, and high resistance to the flow of air. So you will fans that can move air at high speed, against high resistance, and they will also be noisy. The AHU will probably not be able to deal with that by itself: Even high static units usually don't go beyond about 0.8 in.water (about 200 Pa). So my guess is that you will need high static booster fans, in line.
The normal way of doing studio HVAC is with very large diameter ducts that move a large volume of air slowly, with low static pressure (low resistance). I normally use 6" ducts (150mm), or 8" ducts (200mm). The cross sectional area of a 50mm pipe is 1900mm2. Not very much. The cross sectional area of a 200mm duct is 31400 mm2, or nearly SEVENTEEN TIMES as much as one of your pipes. Therefore, air will have to travel seventeen time faster than normal through your pipes. And because air noise and turbulence rise with the SQUARE of the velocity (V^^2), there will be a LOT of noise. Air drag also rises with the square of the velocity, so there will be huge resistance to the flow of air.
To put all of this in perspective, current HVAC standards say that you should be circulating the room air through the HVAC system at the rate of about 6 "room changes per hour". In other words, you need to move the entire volume of air in the room, through those pipes, every ten minutes. For your live room, that is 7,86m x 5,15m x 3,31m x 6 = 803 cubic meters per hour, or 13.4 cubic meters per MINUTE. Every single minute you need to pump 13 cubic meters of air through those tiny little pipes. It's hard to be sure from the photos, but it looks like you have four pipes feeding the live room (and another four return pipes). So, assuming that those are 2" / 50mm pipes, the cross sectional area is 4 x 1900 = 7600 mm2 = 0.0076 m2. With a flow rate of 800 m3/hr, that implies a flow speed of 105,263 meters per hour (105 km/hr !!!), which is 1,754 meters per minute. The MAXIMUM flow velocity you want in a studio is about 90 meters per minute. o your flow speed will be twenty times the maximum allowed. This is not viable. Your silencer boxes will have to expand out to twenty times the cross sectional area, and keep that right up to the registers, and even then you would be running at the maximum rate: I like to aim for something more like 40 or 50 meters per minute, which is half of the maximum... so you'd need silencer boxes that expand to 40 times the cross section of your pipes...
To be very honest, I do not see this as being a viable, usable, valid approach. The flow speeds are just way too high. Unrealistically high. Unreasonably high. Even if you only go with half the recommended flow volume, it is still going ten times too fast. There is no way you are going to get NC-20 like this! There will just be too much air noise in the HVAC system.
I would strongly urge you to completely re-design the HVAC. You can use those pipes for running cables between the rooms, so they won't be wasted.
The technician who thought up the solution for the air supply with me ensured me that it'd be moving slow enough for it to be practically inaudible.
Air running through pipes at a hundred kilometers per hour is not slow! I'm wondering if he made a mistake in his calculations?
I'll see that I can determine these factors and improve on them before I move forward with anything else
I can't see how you can do that, to be honest. You would have to sloe the air down by 20 times, meaning that there would be way, way to little air circulation through the rooms. It will be stuff and unpleasant in there. The entire system needs a re-design. It is not feasible with those little pipes.
To give you an idea, here's a view of just ONE of the HVAC silencer boxes for Studio Three:
2014-Jun-14-Rear-HVAC-slotted-panel-device-03-ENH-SML.jpg
2014-Jun-12-Rear-HVAC-slotted-panel-device-01-ENH-SML.jpg
You can see the size of those things: That unit is fed by an 8" duct (31,000 mm2), and it then splits out into two separate paths, exiting though two registers, each measuring 8" by 12" (62,000 mm2 each side, total of 124,000 mm2). In other words, it slows the speed down by a factor of four, from 400 fpm to 100 fpm (121 meters per minute, to 30 meters per minute). It is dead silent! (That unit also incorporates an acoustic device in between the registers, for another purpose: ignore that).
That's what you need for your studio.
The building contractor signed off on it, so he can't be too worried.
Ummm... the CONTRACTOR signed off on it???? Nope. Just nope. It is the building INSPECTOR who has to sign off on it. When you got your building permit with the local authorities, they must have assigned an inspector to visit your construction site at various points in the build, inspector it to check that the contractor is doing it correctly, complying with the law, etc. He signs off, not the contractor! If the contractor is allowed to sign off on his own work, that's like allowing the bank teller to keep his own money, and count it himself, and sign off that it is all there, without anyone else checking!
Also, the contractor is not a structural engineer. They way things SHOULD work on a build like this, is that the architect hands the design to a structural engineer, who confirms that it can be built safely, and he signs off on that. The design the goes to the municipality, and if it it is all in order, they give you your permit. You then give the plans to the contractor, who builds it, but the architect and structural engineer still come in to check that things really are being done according to the plans, and the building inspector also checks at several stages, signing off the paperwork to show that the stage was approved... The contractor does not get to sign off ANYTHING! He just does the work, and it is signed off by someone else. If not, it's like putting the town drunk in charge of the beer factory....
How would I reasonably test for this? Pink noise generator at 80dB in the LR, and SPL meter in the CR?
Use REW. Set up full-range speakers in one room, and put the measurement mic first in the same room, then in the other room. Useh full spectrum sine sweeps.
A simpler way is to get together a loud rock band, with a good bunch of musicians, tell them to play like crazy in the LR. Measure in the same room, then measure in the other room, using your hand-held sound level meter.
Speaking of the soundlock, though. I do have this airgap between the concrete and cinderblock wall, and I haven't yet sealed it.
Where? Photos please. There should be no visible gaps.... there should be one door in the CR wall and another door in the LR wall. The gap between them can be covered in any of several ways, but the easiest is with OC-703 wrapped in black fabric, and press fitted into the gap.
Yes, there is a generous amount of a hemp-clay mixture underneath the foam. So far, I didn't have any moisture problems with either window, but that may be different in the long term. Of course, it was kind of a guess if it'll work or not...
That should be OK; but I prefer to use Silica gel: it is inert, and can adsorb a lot of moisture. If you ever replace those windows, I'd suggest switching to silica gel.
Did you calculate the amount correctly, according to the volume of air in the gap?
The plan is to place a kind of aluminium muffler plug in each of the pipes where they come into the studio rooms,
Sorry, but that won't work. Those little mufflers are for light machinery, not loud music in studios. Studio silencer boxes are HUGE. Here's an example:
BRAUS-ISO-silencer-box-in-place.SML-ENH.jpg
That's a very small silencer box, for a tiny vocal booth: It is being fed by a 6" duct (150mm). The box just fits between the outer-leaf joists, that are spaced 400mm OC. That's a studio for one of my customers in Australia. That's the type of silencer you need, except yours will need to be MUCH bigger. Here's the one for the Control Room in the same studio, under construction. This one is fed by TWO 6" ducts:
Silencer-Box-CR-Front.-01.jpg
Here's another, from the same studio (the thread I linked you to above, that we are busy tuning right now):
FRCAUS-Silencer-box-CR--20160503_160134-SML.jpg
That's what you will need. LARGE silencer boxes, properly designed for the job.
as well as a central HVAC noise attenuator box placed before the air distribution box to reduce the noise transmission from the AHU.
Nowhere near enough! You need one silencer box on each duct, at each point where it penetrates a leaf. I ave developed a proprietary design that allows combining some boxes into one unit, but they are still very large. The tiny little in-line mufflers just do not have anywhere near enough insertion loss to be useful.
I hope it won't be as much of a problem as I now fear,
It will! And more....
Sorry to be blunt, but that's reality...
The Wernig Q600 is the unit we plan to install.
The link seems to be dead. All I get is a message saying "Link Expired. Access denied!"
I knew that he charges for a phone call close to what I paid for the glass,
Wow! He must be one of the most expensive guys around! Most studio designers do not charge anywhere near that much!
He practically insisted on it. He proposed I use two layers of 4cm thick mats of compound rubber,
There's a problem here then. That's not how vibrations get into structures, and that's not how to stop them getting into your studio. Soil vibration is typically vertical, coming up from below. Not so much horizontal, coming on from the sides. Unless you also put those 4cm pads UNDER the complete foundation, there's not much point doing the sides alone.
Also, rubber is only good down to a certain frequency )depends on type and thickness: thin pads are only for very high frequencies, thick pads for lower). It is far more effective to use springs. What I would have done in your case, is to pour a normal foundation in the usual way for your area, build a concrete shell walls and roof, then float the rooms on properly floated isolation system, like this:
properly-floated-floor-01-SMALL.jpg
properly-floated-floor-spring02-SMALL2.jpg
Much simpler, works down to to very low frequencies, and probably less expensive than what you did.
I opted instead for 1.5cm thick compound rubber mats
There's a reason he specified 8cm of rubber... That is relate to the frequency of the vibration and therefore the isolation. By going with something that is only 19% of what he specified, the isolation frequency is now much, much higher, and the isolation is lower. Once again, since this is a tuned system, it is probably that you made things worse than having no rubber at all, since you are now likely on the amplification part of the curve for low frequency vibrations, such as tractors....
I suppose I don't need as much as my consultant recommended, but maybe more than I'm currently aiming at...
I will see to it! I'm not clear on the ceiling construction, though. 5m seems like quite a distance if I won't be suspending the ceiling studs at all from the concrete ceiling. Are the resilient hangers such a bad idea?
There's a limit to the amount of isolation you can get with hangers like those.
5m is not a large span. You an easily span that distance with typical studio ceiling loads, using normal sized joists. 2x8's, or maximum 2x10's would be all you need.
My father also has strong reservations about drilling into the floor slab, as it contains the underfloor heating circuits. There should be about 5cm of only concrete before hitting the heating circuits, but it's still risky drilling down there in case one of the tubes managed to float up enough to be accidentally punctured.
See above: rent or borrow a thermal camera, and you can locate the pipes very simply, and very accurately.
We're obviously going to remove the sylomer pads from the underside of the structure, so that the studwall sits directly on the slab
Yes, but your framing itself is too small to be usable for this. You need 2x4 or 2x6 studs. In metric, that's commonly 38mm x 89mm (2x4) or 38mm x 140mm (2x6). What you are using there is not able to structurally support the loads you will need to put on it.
but we would still prefer to hold it all in place using the mentioned resilient hangers. Would that make a bad situation worse or would it simply be less effective than it could be?
If you build it properly with the correct sized lumber (2x4 at least, = 38mm x 89mm), with OBS or plywood as the first layer of sheathing, then it is structurally very sound, perfectly capable of being self-supporting, and able to handle the loads a typical studio will place on it. There is no need to add vibration mounts or seismic snubbers. Studios around the world are built like this.
I'm getting an average of about dB (C-weighted, slow response) outside in the back area, with peaks of about dB (C-weighted, fast response) when cars drive past or a rooster crows. This is measured in the afternoon. in the Live Room, with all the doors closed, I'm measuring about dB (C-weighted, slow response)
??? The numbers are missing!
Well, after your advice, I am indeed considering going for a more affordable option than the ATCs. The original plan was to pair it all with a Genelec 5.1 system, including a 7050 BPM sub. Everything is back on the table right now, as I wanna make the most of your advice
Ahhh! So you are thinking 5.1 at some point! So, the studio control room needs to be completely re-designed to deal with that. 5.1 is a very different acoustic concept than 2.1.
OK, if you are doing music scoring for the big screen, then you will need a system that is capable of producing the same effect that you'd hear in a movie house, watching the movie. That's a little more complicated to set up than a typical studio!
One question: if you are doing audio for movies, are you required to comply with dolby, DTS THX, or some other standard? Do you need to have your studio certified? Some companies insist that all outsourced work must be done in certified studios. Is that the case with you? IF so, that's EXPENSIVE! Certification is not easy.... This is a big deal.... You have to buy only the speakers and equipment for that specific certification, and it's a complex, expensive process. Hopefully this is not the case with you! Hopefully, all you need is a normal 5.1 setup. Still complicated, but much, less so than a fully THX system...
If I decide to go ahead with the SCM45s, I'll certainly inquire about the remote amp option. I hadn't been aware that this was a possibility. But to be sure, what distance are you referring to? The distance from the remote amps to the speakers?
Right. You have to specify the cable length when you order, as they amp and cable kit come together. You can't make up the cables yourself: you have to use their cables, or your guarantee is void. So you have to measure the distance and order the correct cable kit.
Primarily for simplicity's sake. Perhaps I shouldn't be so timid, but I currently feel like I'm in over my head, so I'm trying to keep things simple.
Follow the thread above! We'll be soffit-mounting his speakers using my proprietary design. Similar to what I did in Studio Three. The same basic concept. You won't see all the "magic" that goes into the mount, as that's something that has taken me yers to develop, but you'll see the general overview, and the results...
That is good to know. So I suppose the general idea is to deflect early reflections to the rear of the room, where the LFs and some of the MFs can be absorbed by some generous trappings, would that be correct? What would you propose I use that can achieve that? Slat wall absorbers here instead of at the front would seem plausible to me (which isn't saying much)
Your entire control room should be based around one of the accepted design concepts: LEDE, RFZ, NER, CID, MR, etc. LEDE is dead, so forget that. CID is complicated, so forget that: I'd suggest RFZ, as in my opinion, that's the hands-down no-questions-asked best method. But it IS a method. With RFZ, the concept is to direct all first-order reflections away from the mix position, leaving a sphere of large radius around the engineer's head where there are no reflections at all: only direct sound. All of the reflections go to the back of the room, where they are absorbed, and diffused, then eventually return to the mix engineer as a low level reverberant field that dies away slowly and evenly at the correct rate for the room. The basic design criteria is that no reflections arrive within the first 20ms (the Haas time) of the direct sound, after which the diffuse field arrives at a level that is -20dB below the direct sound, and decays at the rate that is correct for the room dimensions.
Your design does not seem to be accomplishing that.
So I would need to know the spring coefficient of the sylomer pads (or rather he combined spring coefficient of the system), as well as its combined mass, to figure out at what frequency it resonates, if I understand it correctly. It's becoming painfully obvious how much work I still have to do
Yep! You would also need to know what the correct deflection is for that product: how much it needs to be compressed to actually "float", and what the useful range is. Then you'd need to calculate the load and surface area that you need in order to get that amount of deflection... If you over-compress the pad outside of its "floating" range then it "bottoms out", and flanks: no isolation. And if you
under-compress the pad outside of its "floating" range (not enough weight to make it float) then it "tops out", and flanks: no isolation. SO you have to get it right! The load must be within the range at all times...
I didn't comment on all of your remarks because I still need to process a whole range of them, and I do hope I'll be able to continue to pester you with any queries and misconceptions that may still arise along the way.
No problem at all! But I'd repeat my number one suggestion here: Stop building! Don't do anything more until the complete plan is in place, with every last detail worked out.
Thank you so much in the meantime,
- Stuart -
. There was some disagreement between the building contractor and the acoustic consultant. Ultimately, those dowels were the acoustician's idea, though, oddly enough.
And I'm afraid I have no idea how to find out either