DE2237713A1 - CONTINUOUSLY OPERATING PRESSURE MEDIUM CONVERTER - Google Patents

Description

Continuously operating pressure medium converter, preferably piston converter The innovation relates to a pressure medium converter for converting a gas pressure into a liquid pressure using a sealed against both media spaces Piston that generates a liquid pressure as a result of the gas pressure on the primary side.

Pressure fluid converters are often used to have a relatively low To convert air or gas pressure into a liquid pressure. For the print implementation DiS4erential pistons are mostly used, with one piston area of applied to the gas pressure and the resulting force generates a Plüssigkeits -pressure, the two pressure chambers are sealed against each other.

These pressure medium converters are preferably used when the working medium compressed air is already present in a control system and 1. Its low energy density is a disadvantage e.g.

if large actuating forces are required with a small installation volume, or 2. Defined speeds for motion sequences are to be implemented, which is hardly possible due to the compressibility of gaseous media, on the other hand can be easily achieved with liquid pressure media.

In the case of the known pressure medium converters, there are terms of their usability Limitations.

These pressure medium converters are only available in connection with a working cylinder usable whose stroke volume must be smaller than that of the pressure medium converter.

With the return stroke of the working cylinder, this must be the pressure medium converter removed oil can be pushed back into the latter.

Since leakage losses occur on the pressure medium converter or on the working cylinder, the hydraulic fluid must always be brought to its full volume by refilling will.

this severely restricts its use in the case of leaky systems.

The pressure medium converter according to the invention does not have these disadvantages on.

Its properties correspond to those of a pump unit like this is used in hydraulics.

The main characteristics are as follows.

1. The pressure center oil converter can provide a continuous flow of oil, so that it can be used to supply several working cylinders or hydraulic motors at the same time can be used with different oil requirements.

2. The pressure medium converter is filled up during the return stroke from one Reservoir; this enables the working cylinder to displace the pressure fluid to promote in the reservoir, where at the same time a defection of the eventual air contained in the hydraulic fluid takes place.

3. The lift control is designed as a sequence control, the control 'takes place Via the control bores 1.5, 1.6, 2.5, 2.6 which are connected to the pistons 1.0, 2.0 with the Pressure chambers 1.9, 2.9 are connected, the pressure pulse valves 1.3,1.4,2.3,2.4 with When pressure is applied, they control the directional control valves 1.2, 2.2 with a pressure pulse . The control bores on the cylinder make safe control easy reached, limit switches and cam valves are omitted.

Pistons 1.0, 2.0 are pushed back using small pressure cylinders 3.1, 3.2 which are constantly pressurized, thereby reducing the air consumption significantly reduced compared to known pressure medium converters.

4. An energy consumption. of the pressure medium converter is only for the duration given the withdrawal of hydraulic fluid, although the latter is constantly on the predetermined Pressure is held.

In the known pump units, this advantage can only be achieved with one relatively high effort can be realized; e.g. by using a pump with changeable Stroke volume, which is equipped with a constant pressure regulator.

The pressure medium converter according to the invention consists of at least two cylinders that are used as pressure medium converters.

They are operated alternately by an independent valve control in such a way that when switching over there is always an overlap of the two pistons.

This prevents an interruption in the flow rate. Of the The return stroke takes place via the pressure cylinders 3.1, 3.2, which are constantly subjected to air pressure will.

Operating mode By opening the button 6.0, the flow is over the pressure reducer 5.0 compressed air through the valve 1.2 into the cylinder space 1.9 of the piston 1.0; this starts moving, causing the hydraulic fluid to flow through the differential piston 1.1 is pressed into the pressure line P via the check valve 1.7.

When the piston 1.0 passes over the control bore, the air pulse valve is activated 2.3 pressurized, this controls valve 2.2 by means of an air pulse and pressurizes the piston 2.0 with compressed air, causing the piston to settle 2.0 in motion and presses the hydraulic fluid over the differential piston 2.1 through the check valve 2.7 into the pressure line P when driving over the control bore 1.5 the air pulse valve 1.3 is pressurized, controlled by an air pulse the valve 1.2 to, this vents the piston 1.0 which through the piston 3.1 is pushed back. The piston 1.1 sucks in hydraulic fluid via the suction valve 1.8 from the reservoir 4.0. When driving over the control bore 1.6 by the piston 2.0, the air pulse valve 1.4 is pressurized, controlled by an air pulse the valve 1.2 to pass, this acts on the piston 1.0 with pressure, this presses via the differential piston 1.1 and the check valve 1.7 the hydraulic fluid in the pressure line P.

When the piston 1.0 passes over the control bore 2.6, the The air pulse valve 2.4 is pressurized, which controls by means of an air pulse switch valve 2.2 to venting, piston 2.0 is vented.

The piston 2.0 is pushed back by the piston 3.2, the Piston 2.1 sucks in hydraulic fluid from the reservoir via the suction valve 2.8.

As long as pressure oil is removed from the pressure medium converter, repeat this movement abla, uf.

Claims (3)

Claim Pressure medium converter for converting a gas pressure into a liquid pressure using a piston that is sealed off from the two edien rooms and, as a result of the gas pressure on the primary side generates a liquid pressure, characterized in that that at least two pistons are pressurized with gas and one forcibly Stroke control ensures that at least one of the two pistons has the hydraulic fluid maintains the pressure specified by the gas pressure. 2. Pressure medium converter according to claim 1, characterized in that for stroke control, the cylinder chambers 1.9, 2.9 have control bores through the stroke movement of the pistons 1.0, 2.0 either with the pressure chambers 1.9, 2.9 or with the ventilated rooms 1.10, 2.10 are connected to generate a pressure pulse by which the impulse valves .3,1-.4, 2.3,2.4 are each actuated. 3. Pressure medium converter, characterized in that by applying of the cylinder chamber 3.0 a constant restoring force on the piston 3.1,3.2 on the Pistons 1.0 and 2.0 act.