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To many pumps!!!
So any significant damage to one area of the boat could wipe out all methods
of pumping any water overthe side or anywhere else? Sure thats a great plan? "Glenn Ashmore" wrote in message ... Having searched for hours for nonfunctioning pumps on deliveries I decided to put all my pumps on one centrally located platform under the salon sole. There are two fresh water pumps, one salt water wash down pump, one air conditioner cooling water pump, one fuel transfer pump, one Jabsco Sea Gulp bilge pump and a grey water pump. Only the waste pump, high pressure anchor sprayer and oil change pump are off the platform. Now I have to add a booster pump for the watermaker pump. Has anyone ever used the washdown pump as a watermaker boost pump? -- Glenn Ashmore I'm building a 45' cutter in strip/composite. Watch my progress (or lack there of) at: http://www.rutuonline.com Shameless Commercial Division: http://www.spade-anchor-us.com |
To many pumps!!!
Damage significant enough to wipe out the entire pump platform would
damage the hull so much that no pump could save the boat but I forgot to mention a 2000gph Rule forward, a 3700gph aft and an Edson manual under the cockpit. Oh yea, and then there is the 5300 gph 110V submersible with 50' of 2" discharge hose back in the lazerette for last ditch efforts. Like I said, to d**ned many pumps! James wrote: So any significant damage to one area of the boat could wipe out all methods of pumping any water overthe side or anywhere else? Sure thats a great plan? "Glenn Ashmore" wrote in message ... Having searched for hours for nonfunctioning pumps on deliveries I decided to put all my pumps on one centrally located platform under the salon sole. There are two fresh water pumps, one salt water wash down pump, one air conditioner cooling water pump, one fuel transfer pump, one Jabsco Sea Gulp bilge pump and a grey water pump. Only the waste pump, high pressure anchor sprayer and oil change pump are off the platform. Now I have to add a booster pump for the watermaker pump. Has anyone ever used the washdown pump as a watermaker boost pump? -- Glenn Ashmore I'm building a 45' cutter in strip/composite. Watch my progress (or lack there of) at: http://www.rutuonline.com Shameless Commercial Division: http://www.spade-anchor-us.com -- Glenn Ashmore I'm building a 45' cutter in strip/composite. Watch my progress (or lack there of) at: http://www.rutuonline.com Shameless Commercial Division: http://www.spade-anchor-us.com |
To many pumps!!!
On Fri, 08 Aug 2003 08:47:38 -0400, Glenn Ashmore
wrote: Damage significant enough to wipe out the entire pump platform would damage the hull so much that no pump could save the boat but I forgot to mention a 2000gph Rule forward, a 3700gph aft and an Edson manual under the cockpit. Oh yea, and then there is the 5300 gph 110V submersible with 50' of 2" discharge hose back in the lazerette for last ditch efforts. Like I said, to d**ned many pumps! Who was it that said there was no bilge pump quite as good as a scared man with a bucket? (You sure have a lot of pumps.) - Rick -- "Ignorant voracity -- a wingless vulture -- can soar only into the depths of ignominy." Patrick O'Brian |
To many pumps!!!
Glenn Ashmore wrote:
snip ... and a grey water pump. snip Glenn -- Can't help with your question, but I have one of my own. I read your web site, so I understand (I think) how you have your grey water pump plumbed, but not why. Minimize the throughhulls? Something else? dave |
To many pumps!!!
Dave Skolnick wrote: Can't help with your question, but I have one of my own. I read your web site, so I understand (I think) how you have your grey water pump plumbed, but not why. Minimize the throughhulls? Something else? Primarily to minimize through hulls and keep them out of the area forward of the keel where the most slamming can occur. Also, the galley arangement required that the sink be against the side where it may be below the waterline at a large angle of heel. That meant a sump and pump or religiously closing a throughhull every time. If the sump is going to be there for the sink it is logical to plumb everything else to it. Oh! Yea again. There is one more small booster pump in the forward head shower sump. -- Glenn Ashmore I'm building a 45' cutter in strip/composite. Watch my progress (or lack there of) at: http://www.rutuonline.com Shameless Commercial Division: http://www.spade-anchor-us.com |
To many pumps!!!
more time sailing less time pumping, you'll go blind.
"Glenn Ashmore" wrote in message ... Having searched for hours for nonfunctioning pumps on deliveries I decided to put all my pumps on one centrally located platform under the salon sole. There are two fresh water pumps, one salt water wash down pump, one air conditioner cooling water pump, one fuel transfer pump, one Jabsco Sea Gulp bilge pump and a grey water pump. Only the waste pump, high pressure anchor sprayer and oil change pump are off the platform. Now I have to add a booster pump for the watermaker pump. Has anyone ever used the washdown pump as a watermaker boost pump? -- Glenn Ashmore I'm building a 45' cutter in strip/composite. Watch my progress (or lack there of) at: http://www.rutuonline.com Shameless Commercial Division: http://www.spade-anchor-us.com |
To many pumps!!!
Glenn Ashmore wrote: ... Has anyone ever used the washdown pump as a watermaker boost pump? Jim Woodward wrote: As you certainly know, broadly there are two classes of pumps, high pressure / low volume and low pressure / high volume. I agree, although the distinction between positive displacement & nonPD is important for several reasons. Most booster pumps are non positive displacement so that they don't overpressurize the inlet side of the main pump casing. They can also supply positive flow over a wider pressure range, such as delivery to several subsystems. Another nice thing about non positive dispalacement pumps is that they can have flow through them when not running, and can readily be primed from either side. The former is good for water pressure, washdown and fire while the latter are used for bilge and sump applications. The best example of this difference is the Jabsco diaphragm pumps, where you can buy the same motor and frame driving different belt pulleys and diaphragms -- a single spare motor can back up both your freshwater and sump pumps.... Now I suspect the watermaker doesn't care much about pressure (there are so many variations today that I can't say for sure) and might even be upset if you had too much, but it does want a certain volume and minimum air. So, offhand, I'd suggest the AC cooling water pump rather than the washdown pump. Agreed, with the caveat that the AC cooling pump might be alternating current whereas Glenn might want to run his watermaker on 12V DC. But, you have a better way to make the choice -- look at the specs on the manufacturer recommended watermaker booster pump and then pick the pump you have that is closest. Too logical here. Aren't you even going to call anybody names?!? Fresh Breezes- Doug King |
To many pumps!!!
Caught oversimplifying. Two demerits. Doug is right, of course,
although in my defense I will point out that the Air Con pump is almost certainly centrifugal (and, hence, non-PD) while the washdown could be either, so my suggestion is OK. Of course, in your praise of non-PD pumps, you don't mention that they are unholy nuisances, prone to lose their prime at the slightest provocation -- I remember surfing in the Southern trades from the Galapagos to the Marquesas, a lot of air under the boat and the reefer going down every five minutes because its pump didn't like air. Changing course to pamper a pump isn't my idea of ideal. Fortunately the pump was happy to run dry, but I would have traded it for a diaphragm pump of sufficent capacity in a second. (Or why Fintry has pressurized seawater available in volume from any of three sea chests -- I love the conservatism of the Royal Navy, but that's another story). Rutuonline doesn't tell us which supply he's running the watermaker from, so you may be right there. As for, "Too logical here. Aren't you even going to call anybody names?!?", I am the voice of reason -- I don't ever call people names, even when they're flaming something-or-others (which, let there be no mistake, does not apply to Glenn or Doug). Jim Woodward www.mvfintry.com DSK wrote in message ... Glenn Ashmore wrote: ... Has anyone ever used the washdown pump as a watermaker boost pump? Jim Woodward wrote: As you certainly know, broadly there are two classes of pumps, high pressure / low volume and low pressure / high volume. I agree, although the distinction between positive displacement & nonPD is important for several reasons. Most booster pumps are non positive displacement so that they don't overpressurize the inlet side of the main pump casing. They can also supply positive flow over a wider pressure range, such as delivery to several subsystems. Another nice thing about non positive dispalacement pumps is that they can have flow through them when not running, and can readily be primed from either side. The former is good for water pressure, washdown and fire while the latter are used for bilge and sump applications. The best example of this difference is the Jabsco diaphragm pumps, where you can buy the same motor and frame driving different belt pulleys and diaphragms -- a single spare motor can back up both your freshwater and sump pumps.... Now I suspect the watermaker doesn't care much about pressure (there are so many variations today that I can't say for sure) and might even be upset if you had too much, but it does want a certain volume and minimum air. So, offhand, I'd suggest the AC cooling water pump rather than the washdown pump. Agreed, with the caveat that the AC cooling pump might be alternating current whereas Glenn might want to run his watermaker on 12V DC. But, you have a better way to make the choice -- look at the specs on the manufacturer recommended watermaker booster pump and then pick the pump you have that is closest. Too logical here. Aren't you even going to call anybody names?!? Fresh Breezes- Doug King |
To many pumps!!!
Now *THAT'S* what I call a prime throwaway line - or two....
I remember surfing .... Brian [envy, envy] Whatcott Altus OK On 13 Aug 2003 15:11:30 -0700, (Jim Woodward) wrote: Caught oversimplifying. Two demerits. /// -- I remember surfing in the Southern trades from the Galapagos to the Marquesas, a lot of air under the boat and the reefer going down every five minutes because its pump didn't like air. Changing course to pamper a pump isn't my idea of ideal. /// Jim Woodward www.mvfintry.com |
Fintry's sea chests
"Jim Woodward" wrote in message m...
SNIP (Or why Fintry has pressurized seawater available in volume from any of three sea chests -- I love the conservatism of the Royal Navy, but that's another story). Jim, I've been mulling over the merits of sea chests recently. Could you please tell me a little more about Fintry's sea chests. In particular, where are the openings in the hull, how large are the openings, and is there any clever shaping to the hull openings to minimise drag and/or increase water flow into them? I'm also interested to hear about any other aspects of the sea chest arangement that you think might be of interest. I think my design philosophy probably exhibits much of the "conservatism of the Royal Navy" so I'd love to know in more detail what they did. Thanks in advance, Julian. |
To many pumps!!!
This is in response to an e-mail from Julian. The return address on
his e-mail is , hence the reply here. ----- Original Message ----- From: "Julian" To: Sent: Thursday, August 14, 2003 10:08 AM Subject: Fintry's sea chests Jim, I've been mulling over the merits of sea chests recently. Could you please tell me a little more about Fintry's sea chests. In particular, where are the openings in the hull, how large are the openings, and is there any clever shaping to the hull openings to minimise drag and/or increase water flow into them? I'm also interested to hear about any other aspects of the sea chest arangement that you think might be of interest. I think my design philosophy probably exhibits much of the "conservatism of the Royal Navy" so I'd love to know in more detail what they did. Thanks in advance, Julian Julian: If you go to our web site, you'll find a piping diagram: http://www.mvfintry.com/pix/piping800.png and lines drawing: http://www.mvfintry.com/pix/flines800.png If you're interested, I can send you bigger versions (ie, more legible) of either -- just say how big is OK. The originals are in AutoCAD, if any of those formats are helpful. The sea chests are at frame 8 and 17 (of 45 total, 20" spacing), so they are well aft of midships, but they are also well down under the hull, where there is little deadrise. This is a disadvantage when she is in very shallow water or sitting in a mud berth. Her sister, Amazon Hope (see link on site), which is way up the Amazon in Peru, has recently been modified to avoid this problem. (The drawings at the bottom of http://www.mvfintry.com/details.htm all show frame locations). The chests are just steel boxes welded to the inside of the hull, with grating holes in the hull plating -- no special shaping at all. They're maybe a foot square and 6" high and have two valves mounted on the top for seawater intake and weed clearance (if you look at the piping layout, valves M19, M20, and M21 allow you to inject pressure seawater into a seachest with the intake valve closed to blast away anything that might clog the chest. Obviously, this trick works only if you have more than one seachest.) On the intake side, there's a large (although not particularly fine) strainer with a valve on either side to isolate it for cleaning. All the piping is galvanized steel, which requires attention from time to time, but has the advantage that it won't burn and sink the boat in case of an engine room fire. The fundamental advantage of a sea chest system is minimum holes in the hull. On a smaller scale than Fintry, when we bought our Swan 57, Swee****er, she had ten seawater intakes (engine, genset, refrigeration, 3 air conditioners, 2 heads, washdown, watermaker) and ten intake seacocks. If you started flooding, you'd have to close ten seacocks, several of which were very difficult to reach, in order to eliminate a bad hose as the cause of the flooding. As part of the preparation for our circumnav, we put in one 2" seacock, and manifolded everything to it. On top of the seacock was a tee, with the manifold connected to the side and a pipe plug in the top (think of the tee on its side with the straight through part vertical). By closing the sea cock, removing the pipe plug, screwing in a three foot length of pipe (long enough to be above waterline), and opening the seacock, we could push a rod down through the pipe, the tee, the seacock, and the hull and clean the intake. All of this requires some care to get it big enough and to make sure that centrifugal pumps have a steady upward path so that air will move up and out even if the pump loses its prime. On Fintry that's easy -- the engine room is twenty feet square and nine feet high and things like air con that use centrifugal pumps can be racked well above the seachest. On Swee****er, it was much harder, as everything was fitted into fairly small spaces. You'd like the intake to be in a high pressure area on the hull (see your naval architect) and I'd probably put a clamshell aft of it to help things along unless I were racing. The clamshell should be clear of the rod-through-the-hull trick if you use it. Jim Woodward www.mvfintry.com |
To many pumps!!!
Jim Woodward wrote:
.... in my defense I will point out that the Air Con pump is almost certainly centrifugal (and, hence, non-PD) while the washdown could be either, so my suggestion is OK. Righto Of course, in your praise of non-PD pumps, you don't mention that they are unholy nuisances, prone to lose their prime at the slightest provocation -- The times I've had this problem, it was tracable to a problem(s) with the system. It's not inherently the nature of centrifugal pumps. However a lot of pumps suffer from excessive casing clearance either due to wear or cheap manufacture; bad suction piping runs or sharing a suction with another system & thus having to fight for prime or being installed above the waterline or having air leaks in the suction (choose one or all the above). Having just repiped & remounted two pumps on our boat, and seen a lot of crummy installations on OPBs lately, it seems like an epidemic. But industry and the military don't have these problems often (and they pay more, too, hard as that is to believe). Jim Woodward wrote: This is in response to an e-mail from Julian. The return address on Julian: If you go to our web site, you'll find a piping diagram: http://www.mvfintry.com/pix/piping800.png and lines drawing: http://www.mvfintry.com/pix/flines800.png Thanks very much for your second post & links. I am considering installing sea chests on our boat and this is very thought-provoking, useful material. Fresh Breezes- Doug King |
Fintry's sea chests
Julian:
Since I couldn't reply to your e-mail, I posted a response to this in the original thread, "To Many Pumps"... Jim "Julian" wrote in message ... "Jim Woodward" wrote in message m... SNIP (Or why Fintry has pressurized seawater available in volume from any of three sea chests -- I love the conservatism of the Royal Navy, but that's another story). Jim, I've been mulling over the merits of sea chests recently. Could you please tell me a little more about Fintry's sea chests. In particular, where are the openings in the hull, how large are the openings, and is there any clever shaping to the hull openings to minimise drag and/or increase water flow into them? I'm also interested to hear about any other aspects of the sea chest arangement that you think might be of interest. I think my design philosophy probably exhibits much of the "conservatism of the Royal Navy" so I'd love to know in more detail what they did. Thanks in advance, Julian. |
To many pumps!!!
Jim Woodward wrote:
Take a look at http://www.mvfintry.com/pix/manifoldbilges800.jpg Every piece of pipe you see was custom welded and then galvanized after welding. It won't burn, won't burst, and won't have hose clamp failure. DUDE! Galvanized? I'm impressed. You obviously spent a lot of time & money working out a good engineering plant, did anybody suggest seamless SS piping just for laughs? It will eventually rust through, but yearly inspections deal with this -- rusting is obvious and slow. (We will, however, replace most of it outside of the engine room with schedule 80 PVC). Probably a smart move, although I've seen vibration cause trouble with PVC longevity, outside the engineroom it shouldn't be an issue. Whenever you get the chance, go aboard government and industrial boats and make notes -- you'll learn a lot about really designing for reliability and maintainability. Thanks, that's where I cut my chops starting an embarassingly long time ago. A trip to the Work Boat show in New Orleans (early December) can be eye-opening for someone whose only boating is on yachts. Thanks for the tip, I have some friends in N'awlins we love to visit. Fresh Breezes- Doug King |
To many pumps!!!
"Jim Woodward" wrote in message om...
This is in response to an e-mail from Julian. The return address on his e-mail is , hence the reply here. Jim, Thanks so much for taking the time to explain both Fintry's and your earlier Swan 57 sea chest set ups, and sorry about the email address, I forgot that I'd recently changed it on my newsreader. I have a few comments regarding your email below... If you go to our web site, you'll find a piping diagram: http://www.mvfintry.com/pix/piping800.png and lines drawing: http://www.mvfintry.com/pix/flines800.png If you're interested, I can send you bigger versions (ie, more legible) of either -- just say how big is OK. The originals are in AutoCAD, if any of those formats are helpful. The stuff on your website is perfectly legible thanks. The sea chests are at frame 8 and 17 (of 45 total, 20" spacing), so they are well aft of midships, but they are also well down under the hull, where there is little deadrise. This is a disadvantage when she is in very shallow water or sitting in a mud berth. Her sister, Amazon Hope (see link on site), which is way up the Amazon in Peru, has recently been modified to avoid this problem. (The drawings at the bottom of http://www.mvfintry.com/details.htm all show frame locations). The chests are just steel boxes welded to the inside of the hull, with grating holes in the hull plating -- no special shaping at all. They're maybe a foot square and 6" high and have two valves mounted on the top for seawater intake and weed clearance (if you look at the piping layout, valves M19, M20, and M21 allow you to inject pressure seawater into a seachest with the intake valve closed to blast away anything that might clog the chest. Obviously, this trick works only if you have more than one seachest.) There's no such thing as a new idea! I was considering a very similar mechanism of 2 sea chests and building in the facility to back-flush each sea chest if it became blocked. One thing that strikes me about the Fintry flushing arrangement however (if I have understood it correctly) is that, because it uses a seperate valve to inject water for clearing the seachest, it probably won't always clear a blockage in the mouth of the inlet valve (before the strainer) and might even make it worse. I was considering setting up each seachest with just one seacock leading to a strainer (like Fintry) but after the strainer then having a valve arrangement so that if the input becomes blocked the valves can be set to isolate the upstream water flow and allow water to be pumped out through the strainer and inlet to try to clear any obstruction that way. It seems to me that blasting water out through the inlet is the most effective way to clear any obstruction. If I do it this way then I don't really see the need for a sea chest as such and the simpler "sea chest" of your earlier Swan 57 would seem sufficient, provided that the necessary calculations are done to ensure that the inlet size and placement is sufficient to provide adequate flow for everything manifolded off it. On the intake side, there's a large (although not particularly fine) strainer with a valve on either side to isolate it for cleaning. All the piping is galvanized steel, which requires attention from time to time, but has the advantage that it won't burn and sink the boat in case of an engine room fire. The fundamental advantage of a sea chest system is minimum holes in the hull. On a smaller scale than Fintry, when we bought our Swan 57, Swee****er, she had ten seawater intakes (engine, genset, refrigeration, 3 air conditioners, 2 heads, washdown, watermaker) and ten intake seacocks. If you started flooding, you'd have to close ten seacocks, several of which were very difficult to reach, in order to eliminate a bad hose as the cause of the flooding. As part of the preparation for our circumnav, we put in one 2" seacock, and manifolded everything to it. On top of the seacock was a tee, with the manifold connected to the side and a pipe plug in the top (think of the tee on its side with the straight through part vertical). By closing the sea cock, removing the pipe plug, screwing in a three foot length of pipe (long enough to be above waterline), and opening the seacock, we could push a rod down through the pipe, the tee, the seacock, and the hull and clean the intake. That's a good idea. Actually, there is one other sea chest arrangement I have heard of that incorporates this, in a way it's like Fintry's seachest in that it's a foot share box welded (well, glassed, since it was fibreglass) to the hull, but instead of being 6 inches high like Fintry's, it was about 3 feet high so that it cleared the waterline, and the top was clear Lexan bolted on so that one could see any obstruction and unbolt an access panel to reach in (probably with a stick) to clear any obstruction. One drawback I see of a tall seachest like this is that it would compromise the effectiveness of using a back-blast of seawater from the other sea chest to clear an obstruction. Using my philosophy of good engineering (carefully select everyone else's good ideas and blend them together to create the perfect result) my thinking right now is to fit 2 sea chests with each "sea chest" being in fact a simple large through-hull like your Swan 57, with your rather clever T arrangement and removable rodding-pipe as an emergency backup, but with appropriate valves upstream of the strainer to enable back-flushing through the inlet as the preferred method of clearing any blockage. Does anyone see any significant problem or improvement for the above? - Julian |
To many pumps!!!
Just so there's no mistake here -- the galvanizing, etc. was done by
the builders to the Royal Navy spec thirty years ago. We're just working within the framework (or should I say "maze" or maybe "rat's nest") that we inherited. See the web site for more details. You mentioned stainless -- do you have any thoughts about it? My general feeling is "worried" when I think about stainless and hot running salt water, or even cold stagnant salt water. I suspect that the galvanized mild steel will last longer and fail more slowly (it begins to weep), but I'm not a metallurgist..... And, yes, PVC, even Scd 80, has its problems. We'll use it only for bilge and freshwater suctions, not seawater, and not in the engine room. Jim Woodward www.mvfintry.com DSK wrote in message ... Jim Woodward wrote: Take a look at http://www.mvfintry.com/pix/manifoldbilges800.jpg Every piece of pipe you see was custom welded and then galvanized after welding. It won't burn, won't burst, and won't have hose clamp failure. DUDE! Galvanized? I'm impressed. You obviously spent a lot of time & money working out a good engineering plant, did anybody suggest seamless SS piping just for laughs? It will eventually rust through, but yearly inspections deal with this -- rusting is obvious and slow. (We will, however, replace most of it outside of the engine room with schedule 80 PVC). Probably a smart move, although I've seen vibration cause trouble with PVC longevity, outside the engineroom it shouldn't be an issue. Whenever you get the chance, go aboard government and industrial boats and make notes -- you'll learn a lot about really designing for reliability and maintainability. Thanks, that's where I cut my chops starting an embarassingly long time ago. A trip to the Work Boat show in New Orleans (early December) can be eye-opening for someone whose only boating is on yachts. Thanks for the tip, I have some friends in N'awlins we love to visit. Fresh Breezes- Doug King |
To many pumps!!!
"Jim Woodward" wrote in message om...
SNIP You mentioned stainless -- do you have any thoughts about it? My general feeling is "worried" when I think about stainless and hot running salt water, or even cold stagnant salt water. I suspect that the galvanized mild steel will last longer and fail more slowly (it begins to weep), but I'm not a metallurgist..... Do you ever visit www.metalboatsociety.com? They have a set of discussion forums and, since the emphasis is on metal, tend to discuss such issues. In case you've not visited, it isn't at all obvious (at least to me) as to how to go to the discussion forums. The way I get there is to click on the "Search" link on the homepage and then click on the "Metal Boat Society Forum Index" to get to the forum index. - Julian. |
To many pumps!!!
"Julian" wrote in message ...
SNIP There's no such thing as a new idea! I was considering a very similar mechanism of 2 sea chests and building in the facility to back-flush each sea chest if it became blocked. One thing that strikes me about the Fintry flushing arrangement however (if I have understood it correctly) is that, because it uses a seperate valve to inject water for clearing the seachest, it probably won't always clear a blockage in the mouth of the inlet valve (before the strainer) and might even make it worse. I was considering setting up each seachest with just one seacock leading to a strainer (like Fintry) but after the strainer then having a valve arrangement so that if the input becomes blocked the valves can be set to isolate the upstream water flow and allow water to be pumped out through the strainer and inlet to try to clear any obstruction that way. It seems to me that blasting water out through the inlet is the most effective way to clear any obstruction. Your concern is quite correct, but I think your solution just exchanges one problem for another. Your proposal tees the blast line to the inlet line outboard of the shutoff in the inlet. There is still a section of the inlet line between the tee and the inlet valve that can't be blasted. To some extent your concern is over an improbable event -- the grating in the hull plating has much smaller holes than the inlet line, so almost all of the time you'd be clearing either a plastic bag from the grating or mud from the chest. If I do it this way then I don't really see the need for a sea chest as such and the simpler "sea chest" of your earlier Swan 57 would seem sufficient, provided that the necessary calculations are done to ensure that the inlet size and placement is sufficient to provide adequate flow for everything manifolded off it. The advantage of the chest is that the first strainer is the small holes in the hull plating, so plastic bags don't get inside at all. SNIP That's a good idea. Actually, there is one other sea chest arrangement I have heard of that incorporates this, in a way it's like Fintry's seachest in that it's a foot share box welded (well, glassed, since it was fibreglass) to the hull, but instead of being 6 inches high like Fintry's, it was about 3 feet high so that it cleared the waterline, and the top was clear Lexan bolted on so that one could see any obstruction and unbolt an access panel to reach in (probably with a stick) to clear any obstruction. One drawback I see of a tall seachest like this is that it would compromise the effectiveness of using a back-blast of seawater from the other sea chest to clear an obstruction. Well, yes, you'd use the stick rather than blast. An advantage with this system is that you could use it as the manifold, putting a seacock on each pipe leading off it. While that means that you'd have to close all the seacocks to stop broken-hose-flooding, at least they'd all be in one maintainable and accessible place, rather than scattered around the boat. You've also got to find space for and construct a mission critical box three feet high. Using my philosophy of good engineering (carefully select everyone else's good ideas and blend them together to create the perfect result) my thinking right now is to fit 2 sea chests with each "sea chest" being in fact a simple large through-hull like your Swan 57, with your rather clever T arrangement and removable rodding-pipe as an emergency backup, but with appropriate valves upstream of the strainer to enable back-flushing through the inlet as the preferred method of clearing any blockage. If you have the space, looks good, although it violates KISS. I'd pick one or the other clearing method. I should add, that in our circumnav, roughly 33,000 miles, we never had an obstruction in the intake -- grass in the strainer that required cleaning eventually, yes, but a complete obstruction, no. Thus planning two different methods of clearing two intakes seems overkill to me. One further thing to consider. On Swee****er we located the graywater and blackwater discharges to port of the keel. (We used Lectra San, but a voyaging boat must be able to pump it overboard.) The one intake described above was to starboard. You don't want to be pumping your own waste back aboard -- there were places (Cairns, for example) where we were moored bow and stern in a reversing current, so half the time the current was moving from stern to bow. At least in places like that, I'd like the intake and discharges to be on oppostive sides of the boat. Jim Woodward www.mvfintry.com |
To many pumps!!!
Jim Woodward wrote:
Just so there's no mistake here -- the galvanizing, etc. was done by the builders to the Royal Navy spec thirty years ago. We're just working within the framework (or should I say "maze" or maybe "rat's nest") that we inherited. It's kinda fun though. Isn't it amazing how you start out with a huge amount of space for absolutely everything, and then you find that "everything" takes up more space than you thought? Having all valves labelled is crucial. See the web site for more details. It's a great web site but many of the pictures have 'google' stamps instead of a picture. You mentioned stainless -- do you have any thoughts about it? Yep, it's way too friggin expensive and the electroformed pipe (rolled & welded instead of seamless) is almost always fails along the joint. IMHO galvanised mild or hi-carbon steel is much better even if neglected. My general feeling is "worried" when I think about stainless and hot running salt water, or even cold stagnant salt water. I suspect that the galvanized mild steel will last longer and fail more slowly (it begins to weep), but I'm not a metallurgist..... Also, you can spray on that "cold galvanise" rust inhibitor and do pretty well. Usually corrosion is worst along joints & flanges. For places where you really want minimum corrosion and have money to burn, monel is the way to go. The boat looks really great, it's a huge project and the vessel has marvelous possibilities. We are finding our 36 footer to be plenty enough work, though! Fresh Breezes- Doug King |
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