CS240360B1 - Connection for hydraulic circuit protection against overloading - Google Patents

Abstract

The circuit for protecting hydraulic circuits against overload consists of a dynamic check valve (1), to which a safety valve (2) is connected in parallel. The circuit according to the invention prevents oil leakage from the damaged part and at the same time prevents an impermissible increase in pressure in the working branch of the hydraulic motor after the dynamic check valve is closed. When the circuit according to the invention is connected in parallel in all working branches of the hydraulic motor or motors, these ensure the closure of all working branches. The circuit according to the invention can be used where it is necessary to prevent uncontrolled movement of the device in the event of a distribution failure and also the leakage of the working medium into the environment.

Description

The invention solves the problem of protection of working branches of hydraulic motors against overloading in the function of a dynamic check valve in the case of failure of tightness of the hydraulic circuit.

In the event of a leak in the hydraulic circuit ^{1 of the} hydraulic circuit, the known hydraulic return valves close the working branches of the hydraulic motors, and the pressure in these branches increases due to the dynamic effects of inertia masses connected to the hydraulic motor. In the case of co-operation of several dynamic check valves, damage to the hydraulic motor branches can occur by the fact that one of the cooperating dynamic check valves does not close.

This drawback removes the circuit according to the invention wherein a safety relief valve is connected in parallel to the dynamic check valve. By utilizing the circuit according to the invention, an unacceptable pressure build-up in the working branches of the hydraulic motor is prevented and thereby damaged. In the case of parallel cooperation of several circuits according to the invention in the working branches of the hydraulic motors, these ensure the closing of all working branches of the hydraulic motors.

In FIG. 1 is a functional diagram of a circuit according to the invention in a single hydraulic circuit as one example of a possible incorporation into a fluid system. A dynamic check valve 1 is connected to the lower inlet 16 of the hydraulic motor 17 with a load 18 by means of the upper inlet-outlet space 9, which via its lower inlet-outlet space 10 is connected via a control element 13 to the outlet 14 of the generator 12 or via a waste branch 15 to a tank 11 A safety valve 2 is connected to the upper inlet / outlet space 9 of the dynamic check valve 1 and is connected via its outlet 21 to the lower inlet / outlet space 10 of the dynamic check valve 1.

In FIG. 2 is a cross-sectional view of a possible design of the circuit. The dynamic check valve with the upper inlet / outlet space 9 and the lower inlet / outlet space 10 is formed by the valve housing 3, the spring 4, the closing body 5 and the spacer element 6. The safety valve is formed by the closing body 5, valve plug 7 and spring element 8.

In the event of a failure of the hydraulic circuit between the lower I / O space 10 and the control element 13 in the circuit of FIG. 1, at the point of damage to the hydraulic circuit, the working fluid starts to leak from the circuit. The flow rate of fluid escaping from the hydraulic circuit through the damaged inlet is increased by the gravitational effects of the load 18 until it reaches the value at which the dynamic return valve 1 closes. Upon closing of the dynamic check valve 1 by the inertia forces of the load 18, the pressure in the lower inlet 16 of the hydraulic motor 17 rises up to the value set on the safety valve 2. After reaching this value, the safety valve 2 opens. By decreasing the kinetic energy of the load 18, the pressure in the lower inlet 16 is reduced. After the pressure drops below the value set on the safety valve 2, it is closed and the device according to the invention prevents further movement of the hydraulic motor 17.

As the flow increases in the direction from the upper inlet / outlet space 9 to the lower inlet / outlet space 10 in the valve housing 3 around the closure body 5 of FIG. 2 above the nominal value, the force from the pressure drop on the closure body 5 exceeds the spring force 4, thereby closing the closure body 5 to close the valve sleeve 3. After increasing the pressure in the upper inlet / outlet space 9 for arbitrary reasons to a value which by force acts on the valve plug 7 Overcoming the force of the resilient element 8, the valve plug 7 moves the valve plug 7 in the direction of pressure in the closure body 5, thereby allowing the working fluid to flow through the closure body 5 into the lower inlet / outlet space 10 of the valve housing 3.

After the pressure drop in the upper inlet / outlet space 9, its force effect on the valve plug 7 is overcome by the resilient element 8, whereby the valve plug 7 closes the flow through the shut-off body 5 in the direction away from the upper inlet / outlet compartment 9. to the lower inlet / outlet space 10 of the valve body 3.

The circuit according to the invention is intended for use in the hydraulic circuits of working machines and equipment in which, in the event of a failure of the hydraulic circuit, hydraulic oil leaks and thereby uncontrollable movement of the respective part of the machine or device controlled by the hydraulic motor or multiple hydraulic motors.

The wiring according to the invention can also be used in pneumatic circuits and wherever it is necessary to prevent uncontrolled movement of parts of the device in the event of a failure of the distribution system and also leakage of the working medium into the environment.

Claims (2)

240360 OBJECT A connection for protecting hydraulic circuits from overload consisting of a dynamic bad valve and a safety valve, characterized in that for the dynamic INVENTION the valve (1) is parallel, the safety valve (2j) connected. 2. Connection according to claim 1, characterized in that the relief valve (2) is part of a dynamic valve (1). 2 sheets of X drawings ·