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Thrust vectoring
"JAXAshby" wrote in message
... an object placed on the "suction side" of a propeller will there is no force in natural called "suction". Everyone with even one semester in physics knows that. how many semesters did you say you had, jeffies? There may not be a force called "suction" but I did not use the word in that context. "Suction Side" is a commonly used engineering term, used in the context of both propellers and compressors. If you had the even most basic knowledge of refrigeration (you claimed family in the business) you would know that. You've just demonstrated that you're a complete fraud, jaxie. But we all knew that. |
Thrust vectoring
Subject: Thrust vectoring
From: (JAXAshby) Jaxass, your comment has nothing to do with what he's been discussing. It is, however, very basic knowledge, which I'm surprised you know...... it can also be applied to moving ahead, but that's probably too much "input" for you for one day. Shen schlackoff, you were told to never post in English. Adults are posting and they use big words like "docking" and such. Huh? What does that have to do with what he is saying .... "back up" is not being discussed. Shen careful. you *must* be moving through the water for a rudder to be effective when trying to back up. Thanks. One of the things I tend to talk about is the potential advantage of using rudders when twisting (swivel) as it tends to help when you work into how you need to set your rudders to "walk". o |
Thrust vectoring
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Thrust vectoring
t can
also be applied to moving ahead, no, it can not. water *pushed* over a rudder can cause a rudder to turn a boat, while water "pulled" over a rudder can not. |
Thrust vectoring
wayne, you are out of your league.
*push* is required under the laws of physics. If you can't see that, just take Feynman's word for it. It is a fact of physics that you can NOT control using rudder by *pulling* water over it. you MUST push. =================== Absolutely not true. If there is water moving past the rudder, regardless of direction or cause, it can be used to create a directed thrust simply by angling the rudder away from the flow direction. The confusion arises because the prop in forward pushes a large flow across the rudder, whereas the prop in reverse pulls only a relatively small amount of water across the rudder. Small, but not zero. You don't need a degree in physics to understand this, just a little common sense. Richard Feynman would no doubt find the discussion amusing however. |
Thrust vectoring
Thanks ....comments interspersed:
Rod McInnis wrote: With this in mind, for those with twin screw boats, if I told you that rudders were important tools of boat handling, but not to be considered for steering, rather for "thrust vectoring", when maneuvering around a dock, etc., when kicking an engine ahead, both positive and negative ...... would you understand what I was saying? No, I would think that most people would be more confused. Why? To begin with, I would start by pointing out that there is a big difference between how an inboard reacts and how I/Os or outboards react. There is also a big difference between what I call "large rudder" and "small rudder" boats. Sorry, I should have made it more specific that I was just talking about "inboards" not IO's or outboards. On inboards, there can be "large rudder" as well as "small rudder" boats (generally they tend toward "small" but it's "not written in stone"). It's also interesting that few talk about type of rudder when talking about it's "size" (can also be read as "power"). A typical sail boat has a "large rudder" which becomes effective, in either forward or reverse, as soon as the boat is making way. A typical power boat has a "small rudder" which either needs a significant amount of boat speed or to have the prop pushing water past it. These rudders are generally ineffective in reverse. see above The basic concept of twin engine inboards is that you consider the rudder to only be a factor when the engine is in forward. Ignore it for the engine in reverse. Interesting comment that I think a few have made. To check on myself, I went back to my original post to see if I'd indicated anywhere that I was applying this "thrust vectoring" to astern "kicks" ... I wasn't, and in fact specifically stated "when kicking an engine ahead", so I don't know where your last two sentences are coming from. Hmmmm I see something ... "both positive and negative", refers to rudder angle when doing, say, a twist or walk. otn |
Thrust vectoring
On Thu, 25 Mar 2004 02:07:31 GMT, otnmbrd
wrote: For years, on occasion, I've have been involved with teaching someone boat handling, using single and/or twin screw inboards.....if I told you that rudders were important tools of boat handling, but not to be considered for steering, rather for "thrust vectoring", when maneuvering around a dock, etc., when kicking an engine ahead, both positive and negative ...... would you understand what I was saying? otn Probably not, judging by one or two of the responses here. Perhaps it would be easier for you to demonstrate the effect of sucking a fluid past a board placed in the forward stream line. Take a hand vacuum (I used a Bissett) and close to the suction nozzle, place a sheet of paper parallel to the air flow into the nozzle. Place the edge quite close to the nozzle's side. You will see the paper move sidewards towards the airflow into the vacuum if the flow speed is unequal on each side of the paper. Bernouilli of course. The effect is quite small, but readily visible. Faster flow leads to lower pressure, of course. Extending the demo to the rudder placed behind the propellor spinning in reverse to show the small side force on the rudder should then be easier to communicate, I'd think. Brian Whatcott |
Thrust vectoring
You're absolutely wrong about this jaxie. Feynman would think you're a complete
fool for invoking his "sprinkler paradox" in this case. The boat is not turned directly by the propeller, it is turned because a water flow is pressing against the rudder. "Push" and "pull" are irrelevant, and the water flow could even come from a current, or the wash from another boat. For a variety of reasons, the affect is far more powerful in foreword, but it is still there in reverse. USSailing, and Boat/US both describe this on their websites. http://www.videos.sailingcourse.com/...pring_line.htm http://www.boatus.com/seaworthy/swlines.asp And the Coast Guard http://www.uscg.mil/hq/g-o/cgaux/Pub...crew/ch10d.pdf "JAXAshby" wrote in message ... wayne, you are out of your league. *push* is required under the laws of physics. If you can't see that, just take Feynman's word for it. It is a fact of physics that you can NOT control using rudder by *pulling* water over it. you MUST push. =================== Absolutely not true. If there is water moving past the rudder, regardless of direction or cause, it can be used to create a directed thrust simply by angling the rudder away from the flow direction. The confusion arises because the prop in forward pushes a large flow across the rudder, whereas the prop in reverse pulls only a relatively small amount of water across the rudder. Small, but not zero. You don't need a degree in physics to understand this, just a little common sense. Richard Feynman would no doubt find the discussion amusing however. |
Thrust vectoring
Thanks. G Wasn't really interested in how you reacted to others
responses, only in how YOU reacted. As for the rest, you seem to have also grabbed onto the "reverse" aspect, which is NOT what I was discussing at all. I repeat, "When kicking an engine ahead" Thrust vectoring does not apply when going astern, unless G you have Flanking Rudders.... which is another story entirely. otn Brian Whatcott wrote: Probably not, judging by one or two of the responses here. Perhaps it would be easier for you to demonstrate the effect of sucking a fluid past a board placed in the forward stream line. Take a hand vacuum (I used a Bissett) and close to the suction nozzle, place a sheet of paper parallel to the air flow into the nozzle. Place the edge quite close to the nozzle's side. You will see the paper move sidewards towards the airflow into the vacuum if the flow speed is unequal on each side of the paper. Bernouilli of course. The effect is quite small, but readily visible. Faster flow leads to lower pressure, of course. Extending the demo to the rudder placed behind the propellor spinning in reverse to show the small side force on the rudder should then be easier to communicate, I'd think. Brian Whatcott |
Thrust vectoring
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