I'm interested in the nature of the instability you have found when using proportional valves to lower a load. Can you tell us more? You might be discounting them unnecessarily.
There are lots of hydraulic machines that use gravity alone to lower a load: vehicle tail lifts, tipper trucks, fork lift trucks, hydraulic elevators (think shopping mall), engine hoists, trolley jacks etc. The trick is to identify exactly what you are looking for in the system and choose suitable components and control strategies.
Here’s a few pointers:
• Presumably you want the circuit to be leak-free – or can you tolerate the lifted load creeping down over a matter of several minutes/hours?
• Do you want the load to come down at some nominally fixed speed, an absolutely constant speed or do you want to be able to vary the speed as you go?
• Do you need any acceleration/deceleration control or is simple “lower”/ “stop” sufficient?
• Are there massive variations in the working temperature of the fluid?
If you have a reasonably fixed load, a fairly consistent operating temperature and you want to lower at a nominally fixed rate, then a simple orifice and a solenoid operated poppet valve (leak free) will suffice. Or the poppet valve could be manually operated (via a knob, lever, handle, linkage or cable). Or both … it is common on scissor lifts for the normal lowering function to be solenoid operated and the emergency lowering function (from ground level) to be operated by a cable release attached to the manual override on the solenoid valve. The beauty of the orifice approach is that it is simple and relatively insensitive to small changes in load (the speed will go up in proportion to the square root of the load: the load has to quadruple for the speed to double).
If you want a [sort of] fixed speed with varying fluid temperatures then make sure that there is little pressure drop in your pipework and valve (be generous with the sizes) and that your orifice is the “sharp edge” type.
If you want a fixed speed under significantly varying loads then you will need a type of pressure compensated flow control valve. Some of these are specially constructed for load lowering – look for SB and SQ valves from Hawe as an example of this.
Be careful when using an ordinary pressure compensated flow control valve in a lowering circuit. Explanation: when you close your solenoid valve the flow control valve’s hydrostat will open fully. Then when you next open the solenoid valve the hydrostat has to move back to the “correct” position from the starting point of “wide open”. In the few milliseconds it takes to reach the correct position the hydrostat will be too far open – the flow will initially be too high and then re-establish the right value. You will feel this as a “jump” when you start to lower, it might be of no significance but it makes it difficult to set the position accurately if you ever have to stop before reaching the bottom. It is possible to arrange for external closing of the hydrostat to remove the jump but it is hard to incorporate such a technique without spoiling the leak-free nature of the circuit.
If you want variable control of the lowering speed from some remote position then an electrically adjustable proportional valve combined with a solenoid operated poppet valve might be the way. (The poppet valve is only needed if you want the circuit to be leak free because a proportional throttle valve is unlikely to be so.)
There are lots of proportional valves that will do what you want. Some have built in pressure compensation (check out Wandfluh) and some, if force controlled (non-feedback type) rather than stroke controlled (feedback type), will allow the flow forces to modulate the opening of the throttle and this gives a rough pressure compensation effect. I’m wondering now if your previous [bad] experience of proportional valves in load lowering circuits was because you were using a stroke controlled valve with a very high pressure differential.
DOL
