RU207413U1 - HYDRAULIC STAND FOR STRENGTH TESTS - Google Patents

Abstract

The utility model relates to hydraulic systems of actuators, namely, to the hydraulic block of the hydraulic cylinder of the test bench for static and repeated-static strength tests of products. The technical result of the proposed utility model is to ensure reliable protection of the process of static strength testing of products with stepwise loading of the test product from the application to the test product of forces exceeding the maximum established for this test, which may occur in the event of failure of one of the hydraulic unit units, with providing protection from the human factor. The technical result is achieved in a hydraulic strength test stand unit containing a discharge line designed to connect to the pump of the pumping station and a drain line designed to connect to the oil tank of the pumping station, a proportional valve, the input of which is connected to the discharge line, the first output of which is connected to the discharge line , the second outlet is connected to the supply and drain line of the piston cavity of the power hydraulic cylinder, designed to apply a load to the test product, the third is connected to the supply and drain line of the rod cavity of the hydraulic cylinder, there is a load limiter containing safety spring valves installed on the supply and drain lines of the piston and the rod chambers of the hydraulic cylinder, a proportional pressure reducing valve with built-in electronics is installed in the discharge line between the pumping station and the proportional valve, the input of which is connected by the discharge line to the pumping station, the first output is related to the proportion with an onal distributor, the second outlet is connected to the drain line to the oil tank of the pumping station, there is a bypass line between the supply and drain line of the piston cavity of the hydraulic cylinder and the supply and drain line of the rod cavity of the hydraulic cylinder, in which a safety valve of the piston cavity of the hydraulic cylinder is installed on the side of the piston cavity of the hydraulic cylinder, and on the side of the rod end there is a safety valve of the rod end of the hydraulic cylinder, the bypass line between the safety valve of the piston end of the hydraulic cylinder and the safety valve of the rod end of the hydraulic cylinder is connected to the drain line, there is an electronic control unit connected to a proportional valve, a proportional reduction valve with built-in electronics and made with the ability to connect to the sensor for measuring the force developed by the hydraulic cylinder. 1 ill.

Description

The utility model relates to hydraulic systems of actuators, namely, to the hydraulic block of the hydraulic cylinder of the test bench for static and repeated-static strength tests of products.

An analogue is known - a hydraulic unit of a strength test stand - RU2644443, 12.12.2016, containing a discharge line designed to be connected to a pump and a drain line designed to connect to an oil tank, a proportional valve, the input of which is connected to the discharge line, the first output is connected to the discharge line , the second outlet is connected to the supply line to the piston cavity of the hydraulic cylinder, the third is connected to the supply line to the rod cavity of the hydraulic cylinder, there is a safety valve installed between the supply line to the piston cavity of the hydraulic cylinder and the supply line to the rod cavity of the hydraulic cylinder.

The disadvantage of the analogue is the low degree of protection of the tested product from destruction in the event of failure of the hydraulic unit. For example, if a proportional valve fails, the pressure in one of the cavities of the hydraulic cylinder may exceed the allowable value and a force will be transferred to the test product, which will destroy it. And this is not planned by the test method, since the ultimate deformations of the product are first determined at lower loads, therefore, the loading is carried out stepwise. In addition, an abrupt application of a load has an impact property, and in this case the nature of the test ceases to be static. When the user notices excessive force from the control devices, he manually opens the safety valve, which is designed as an emergency pressure relief valve, to prevent excessive force from being transmitted to the product under test. The manual mode is unreliable, this explains the low degree of protection of the tested product from destruction.

A known analogue is a hydraulic unit of a strength test stand - RU2305264, 07.07.2005, adopted as a prototype, containing a discharge line designed to be connected to a pump and a drain line designed to be connected to an oil tank, a proportional valve, the input of which is connected to the discharge line, the first the outlet is connected to the drain line, the second outlet is connected to the supply line to the piston cavity of the hydraulic cylinder, the third is connected to the supply line to the rod cavity of the hydraulic cylinder, there is a load limiter containing safety spring valves installed on the supply lines to the piston cavity of the hydraulic cylinder and supply to the rod cavity of the hydraulic cylinder ...

Due to the presence of a load limiter containing safety spring valves, the prototype has an advantage over the previous analogue, which consists in automatic protection against overload of the tested product in the event of failure of the hydraulic block units.

The disadvantage of the prototype is the low degree of protection of the test item from destruction during the implementation of step loading of the test item due to the low degree of automation of the device. In static tests, in most cases, loading is carried out stepwise from 10 to 100% of the required force, with a step of 10-20% at each stage. At each stage, a given force is maintained. To carry out such loading using the prototype device, it is necessary to manually reconfigure the load limiter for the ultimate force each time for each loading stage. The fact that the setting is carried out manually introduces a human factor and reduces the reliability of protection.

The technical result of the proposed utility model is to ensure reliable protection of the process of static strength testing of products with stepwise loading of the test product from the application to the test product of forces exceeding the maximum established for this test, which may occur in the event of failure of one of the hydraulic unit units, with providing protection from the human factor.

The technical result is achieved in a block of a hydraulic strength test stand, which contains a discharge line designed to be connected to the pump of the pumping station and a drain line designed to connect to the oil tank of the pumping station, a proportional valve, the input of which is connected to the discharge line, the first output of which is connected to the discharge line , the second outlet is connected to the supply and drain line of the piston cavity of the power hydraulic cylinder, designed to apply a load to the test product, the third is connected to the supply and drain line of the rod cavity of the hydraulic cylinder, there is a load limiter containing safety spring valves installed on the supply and drain lines of the piston and the rod chambers of the hydraulic cylinder, a proportional pressure reducing valve with built-in electronics is installed in the discharge line between the pumping station and the proportional valve, the input of which is connected by the discharge line to the pumping station, the first output is related to the proportion with an onal distributor, the second outlet is connected to the drain line to the oil tank of the pumping station, there is a bypass line between the supply and drain line of the piston cavity of the hydraulic cylinder and the supply and drain line of the rod cavity of the hydraulic cylinder, in which a safety valve of the piston cavity of the hydraulic cylinder is installed on the side of the piston cavity of the hydraulic cylinder, and on the side of the rod end there is a safety valve of the rod end of the hydraulic cylinder, the bypass line between the safety valve of the piston end of the hydraulic cylinder and the safety valve of the rod end of the hydraulic cylinder is connected to the drain line, there is an electronic control unit connected to a proportional valve, a proportional reduction valve with built-in electronics and made with the ability to connect to the sensor for measuring the force developed by the hydraulic cylinder.

Figure 1 shows a block diagram of a hydraulic strength test stand.

The hydraulic unit of the strength test stand contains a discharge line 1, as shown in Fig. 1, intended for connection with the pump of the pumping station 2 and a drain line 3, intended for connection with the oil tank of the pumping station 2, a proportional valve 4, the input 5 of which is connected to the discharge line 1, the first outlet 6 of which is connected to the drain line 3, the second outlet 7 is connected to the supply and drain line 8 of the piston cavity 9 of the hydraulic power cylinder 10, designed to apply a load to the tested product, the third 11 is connected to the supply and drain line 12 of the rod cavity 13 of the hydraulic cylinder 10, there is a load limiter containing safety spring valves 14, 15 installed on the supply and drain lines 8, 12 of the piston 9 and rod 13 cavities of the hydraulic cylinder 10, in the discharge line 1 between the pumping station 2 and the proportional valve 4 there is a proportional pressure reducing valve 16 with built-in electronics, input 17 of which is connected by a discharge line 1 with pumping station 2, the first outlet 18 is connected to the proportional valve 4, the second outlet 19 is connected to the drain line 3 to the oil tank of the pumping station 2, there is a bypass line 20 between the supply line and drain 8 of the piston cavity 9 of the power hydraulic cylinder 10 and the supply line and drain 12 of the rod cavity 13 of the hydraulic cylinder 10, in which a safety valve 14 of the piston cavity of the hydraulic cylinder 10 is installed on the side of the piston cavity 9 of the power hydraulic cylinder 10, and a safety valve 15 of the rod cavity of the hydraulic cylinder 10 is installed on the side of the rod cavity 13, the bypass line 20 between the safety valve 14 of the piston the cavity of the hydraulic cylinder 10 and the safety valve 15 of the rod cavity of the hydraulic cylinder 10 is connected to the drain line 3, there is an electronic control unit 21 connected to the proportional valve 4, the proportional pressure reducing valve 16 with built-in electronics and made with the possibility of connecting to the sensor 22 for measuring the developed hydraulic cylinder ndrom 10 efforts.

Let us consider an example of a specific implementation of a hydraulic strength test stand unit. The hydraulic unit is used as part of a test bench for static strength testing of an aircraft wing. The block is made in the form of a base on which the proportional valve 4, the safety valve 14 of the piston cavity of the hydraulic cylinder 10, the safety valve 15 of the rod cavity of the hydraulic cylinder 10, the proportional pressure reducing valve 16 with built-in electronics are fixed with clamps, which are connected by pipelines according to the diagram shown in Fig. 1. Also on the base is an electronic control unit 21, which is connected by wired interfaces with a proportional valve 4, a proportional pressure reducing valve 16 with built-in electronics. Proportional valve 4 is designed to change the directions of the flow of the working fluid from the pump of the pumping station 2 to the piston or rod cavity of the hydraulic cylinder 10 and the value of the flow rate of the working fluid is proportional to the input signal. The safety valves 14, 15 are made in the form of direct-acting spring-loaded safety valves. In these, the force to close the valve is generated by compression of the coil spring. The compression ratio of the spring is adjusted with the adjusting screw. The spring force is transmitted through the spindle to the disc. The disk seals the nozzle as long as the spring force is greater than the force generated by the pressure of the working fluid at the valve inlet. They are designed to limit the maximum force developed by the hydraulic cylinder 10. They are preset to the maximum force that they plan to use for a particular test. The proportional pressure reducing valve 16 is a proportional electronically controlled pressure reducing valve with an integrated electronic control unit. It is used to reduce the outlet pressure in the event of an increase in flow through the valve.

Let us consider an example of the operation of a hydraulic strength test stand unit. The hydraulic cylinder is installed 10 with an emphasis on the floor with an emphasis on the rod against the product being tested - an aircraft wing. A force sensor 22 in the form of a strain gauge is installed between the hydraulic cylinder rod 10 and the wing. The hydraulic cylinder 10 provides a much greater maximum force than the force required to break the product being tested for strength. When the proportional valve 4 fails, its spool is displaced, at which the working fluid begins to be supplied into the piston cavity or the rod cavity of the hydraulic cylinder 10 with a multiple of the maximum flow rate, as a result of which the force of the hydraulic cylinder 10 may exceed the limit for this test process. However, the presence of the safety valve 14 of the piston cavity of the hydraulic cylinder 10 and the safety valve 15 of the rod cavity of the hydraulic cylinder 10 excludes such a situation. In this case, the safety valve 14 or 15 of the branch in which the pressure was exceeded opens and releases the working fluid, preventing overpressure.

In a static test, the loading of the test item is carried out stepwise from 10 to 100% with a step of 20%. At each stage, a given force is maintained. The magnitude of the force is controlled by the control unit 21 according to signals from the force sensor 22. The force of the hydraulic cylinder 10 at each current stage of loading is controlled by the proportional valve 4 by supplying it with a signal from the control unit 21 according to the program embedded in the control unit. The pressure limitation by the proportional reducing valve 16 is carried out by supplying it with a signal from the control unit 21, while the limit force is automatically changed during the transition from one loading stage to another according to the program of the control unit 21. In this case, if the proportional valve 4 fails, similarly to that described above situation, the proportional pressure reducing valve 16 releases excess working fluid into the pumping station, preventing the force on the hydraulic cylinder from exceeding the limit for this stage of loading. The advantage of such control over manual control is that such adjustment takes much less time, which guarantees protection against a sharp excess of the force set for the stage and does not depend on the human factor. There can be several tens of loading stages, therefore it is very difficult to carry out such control manually.

In another embodiment, the hydraulic unit is used as part of a test bench for a linear actuator used to drive robotic platforms of mobility, for example, a Gew-Stewart platform with six degrees of freedom.

The types of emergency situations from which protection is provided can be as follows:

- failure of the control system, in this case protection is provided by mechanical valves 14, 15;

- the proportional valve 4 does not respond to signals and is fully opened, in this case protection is provided by the operation of the proportional pressure reducing valve 16, as described above;

- failure of the signal from the force sensor 22, the occurrence of interference, in this case, protection against excess loads at a given stage is provided by the operation of the proportional pressure reducing valve 16.

Duplication of protective equipment ensures that the product under test is protected against overloading during the test process.

Claims (1)

A hydraulic unit of a strength test stand containing a discharge line designed to be connected to the pump of the pumping station and a discharge line designed to be connected to the oil tank of the pumping station, a proportional valve, the input of which is connected to the discharge line, the first output of which is connected to the discharge line, the second output is connected with the supply and drain line of the piston cavity of the power hydraulic cylinder, designed to apply a load to the tested product, the third is connected to the supply and drain line of the rod cavity of the hydraulic cylinder, there is a load limiter containing safety spring valves installed on the supply and drain lines of the piston and rod cavities of the hydraulic cylinder, characterized in that a proportional pressure reducing valve with built-in electronics is installed in the discharge line between the pumping station and the proportional valve, the input of which is connected by the discharge line to the pumping station, the first output is connected to the proportional distribution a divider, the second outlet is connected to the drain line into the oil tank of the pumping station, there is a bypass line between the supply and drain line of the piston cavity of the hydraulic cylinder and the supply and drain line of the rod cavity of the hydraulic cylinder, in which a safety valve of the piston cavity of the hydraulic cylinder is installed on the side of the piston cavity of the hydraulic cylinder, and on the side of the rod end, there is a safety valve of the rod end of the hydraulic cylinder, the bypass line between the safety valve of the piston end of the hydraulic cylinder and the safety valve of the rod end of the hydraulic cylinder is connected to the drain line, there is an electronic control unit connected to a proportional valve, a proportional reduction valve with built-in electronics and made with the ability connection with the sensor for measuring the force developed by the hydraulic cylinder.

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