instablaster

+Rehuel Galzote This is not an engine. This is a hydraulic pump. Blue indicates low oil pressure coming from oil tank, and the red indicates high pressure oil going to cylinders or hydraulic motors.

mekanizmalar Oh oh haha I'm really sorry. I've been looking through ur engine videos I mistakenly thought this thing is engine since there's an engine that looks like this.

Shalom! So if I want to repower my machine with electric motor, should I replace the pump as well since it has a minimum idle rotation in its design? Or would it be okay to have stop and go rotation from the electric motor? Thank You! Shalom!

Hi Cristian, The ends of the cylinders are connected to crescent shaped channels on the green disk shown at right. When the pistons move to the right during compression, the oil is forced out from the red crescent. When the piston move to the left, the oils is sucked in from the blue crescent.

mekanizmalar Yes I understand that. I don't understand how you compress the fluid between the 2 crescent channels. There is a portion where the cylinder is not connected to either one but the piston is still compressing the fluid. That will not happen (the compression in a fixed volume chamber).

Cristian Armaselu First, As you can see from video, the gab between the two crescent is as wide as the cylinder width. So transition is in split second. The second is that at the upper and the bottom section where transition occur, the rate of change of the piston stroke is zero, therefore piston literary do not make any compression in there, The third is that there is not such a thing as incompressible fluid. When the oil is compressed, no matter how small, there is always some compression. Combined effect of these three cases make it work.

I am sorry but I don't understand your confusion. Distance between shaft axis to pistons axis for alt the pistons are the same no matter what the swash plate angle is. Maybe I am missing something in the question but I don't know what. Swash plate angle deviation from 90 degrees is not that much, maybe +/-15 or 20. Do not forget also that pistons are moving inside a cylinder block, which makes axis distances from shaft axis to pistons axis constant. Swash plate is circular.

I understand how you mean, it is simply just compensated by doing the swash plate a little bigger to accommodate the smaller diameter. There are other designs where this will not be necessary.

Phon no send me

Utilizo Adobe Flash para el desarrollo de mis animaciones.

+Dileep Kumar Thank you for your nice comment. I learned something new from you, meaning of abbreviation TQ, tq for that.

+Metin Simsek Thank you for your comment. I know that I should use odd numbers, but six plunger made animation much easier.

I am sure that it leaks. However, there must be a hole in the body where swash-plate located. This hole drains excess oil to the reservoir of the hydraulic unit.

Thanks, I am happy that it helped.

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+David Flemming Thank you for your support.

Thank you.

+toyuko aka When swash plate has more angle, there will be more oil flow, but not necessary high pressure. During this time hydraulic motor, or a hydraulic piston is operating in the green region shown in the animation. When motor or piston encounter an obstacle, the pressure will spike and during that time swash plate should be brought to vertical position to prevent further pressure rise. When swash plate is in perpendicular position, the oil flow becomes zero, but pressure inside the pipe still be high. Leakage in the system gradually reduce the pressure, but as long as the obstacle prevent piston to move, small deviation of swash plate will maintain high pressure in the system. In short the animation shows what I described in here. I also suggest to you to watch following animation about ram pump. kzbin.info/www/bejne/l4a3m4mlq9V-rKM Notice that when there is flow, low pressure produced in the exit causes valve to close. But when the valve closed, there is no flow discharge from the system, and pressure spikes. In short no flow does not mean there is no pressure.

i think you are wrong, no oil flow, the pistons don't take compression, so that the pump doesn't produce pressure. the pressure in the suction and discharge pipe are the same.

I'm not sure I'm following this quite right, but it does seem to me that oil is consumed by the pump under negative pressure (so you get oil plus vacuum), which is the play it needs to provide absolute compression beyond the intake stroke. This lets all output stroke run as variable points leading up to absolute compression of the oil. Whenever there is a stroke to push oil out, it can't begin with absolute pressure on all strokes, otherwise the sum of pistons would overload and lock in position or blow a seal. Mechanically there are many ways to accomplish this task, but this one appears fairly efficient. I just wish he'd done a 3d animation showing the inlet and outlet stroke positions matched with flow regulation points.

Thanks.

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