RU86309U1 - STAND FOR TESTING SPRING POWER SPRINGS - Google Patents

Abstract

A stand for testing the power parameters of springs, comprising a hydraulic cylinder, on the rod of which a pressure device is fixed; a base for installing a spring, a pump station, a control unit and a linear displacement sensor, a directional valve connected to the pump station through a safety valve, characterized in that it also includes a transport container for the springs and the manipulator for testing, the hydraulic cylinder, pressure device and the base for installing the springs is mounted on a frame equipped with a rotary axis, mounted on the base of the stand, and the transport container for incoming to the test springs is made in the form of it in the direction of the container manipulator with the possibility of placing the springs in it in a horizontal position, the manipulator comprising a traverse placed on the frame, a carriage mounted on the traverse, and a spring gripping mechanism connected to the carriage, and the carriage and the spring gripping mechanism are provided with drives.

Description

The utility model relates to test equipment, namely, to test benches for the power parameters of compression springs and can be used, in particular, for testing spring springs for railway suspension.

A known bench for dynamic testing of compression springs, comprising a base, a pneumatic acceleration-brake device, comprising a cylinder, front and rear flanged, a piston located in the center, equipped with a rod and dividing the cylinder cavity into a piston and shock chambers connected to each other, a piston return device in the initial position, concentrically located relative to the piston receiver, connected to the compressed air line. The rear flange of the cylinder is made in the form of a shut-off valve with a pneumatic membrane-spring actuator, the spool and the membrane of which are respectively the bottom of the piston chamber and receiver. And the rod and piston chambers are constantly communicated with each other through a throttle hole made in the piston, and the rod chamber is also in communication with the atmosphere through a throttle hole made in the front flange of the cylinder, on which a sealed container is fixed with the possibility of filling with lubricating fluid, in the cavity of which is aligned with the rod of the piston, a guide rod is mounted cantilever on which the test spring is placed with emphasis on the end of the piston rod, and the free end of the guide rod is inserted into about the axis of the piston rod a hole whose residual depth is not less than the working stroke of the tested spring (RF patent No. 2138794, class G01M 17/04. Publ. 09/27/1999).

However, the known device does not allow testing of springs used in spring suspension of railway transport.

A device for monitoring the elastic and linear characteristics of springs, containing a power receiving pad, a loading mechanism in the form of an electromechanical gearbox with a linearly moving loading plate, a loading drive drive motor, a linear displacement transducer, a strain gauge force transducer and a recording-converting unit, an amplifier, an interface and a frequency converter rotation of the drive motor of the loading mechanism. In this case, the linear displacement transducer is made incremental, the amplifier is instrumental, and the recording-converting unit is in the form of a single-chip microcontroller. Moreover, the amplifier is located in the housing of the strain gauge force transducer, and the interface and speed converter, electrically connected to the drive motor of the loading mechanism, are connected to the output of a single-chip microcontroller (utility model patent No. 41517, class G01L 1/04. Publish. October 27, 2004 .).

But in this device, the spring is installed in a vertical position, which increases the complexity of the work of loading / unloading, i.e. reduces labor productivity.

Closest to what is proposed in its technical essence is a bench for testing the power parameters of springs, containing a hydraulic cylinder, the rod of which is fixed to a pressure device, a base for installing a spring, a hydraulic circuit for controlling the operation of the hydraulic cylinder, a pump station, a control unit and a linear displacement sensor connected to the output by the first input of the control unit. The hydraulic control circuit for the operation of the hydraulic cylinder contains a control valve connected to the pumping station through a safety valve, a hydraulic valve with a check valve, a hydraulic valve, the first and second pressure sensors. The pressing device is made in the form of lower and upper plates installed with a gap relative to each other, to which the inputs of linear displacement sensors and the reference point of spring deformation are connected. In this case, the outputs of the first and second pressure sensors and the spring deformation reference sensor are connected respectively to the second, third and fourth inputs of the control unit, the first output of which is connected to the control valve, and the second, third and fourth outputs are connected by step electric drives to the control inputs of the safety valve, respectively , a hydraulic throttle and a hydraulic valve (certificate for utility model No. 35435, class G01M 17/04. Publ. 10.01.2004).

However, in this device, loading / unloading spring springs suspension is laborious, which reduces labor productivity.

The task to which the claimed utility model is directed is to reduce the complexity of the work of loading / unloading the spring for testing, increasing productivity and improving working conditions.

The technical result consists in simplifying the installation of a spring for testing.

The problem is solved in that in the stand for testing the power parameters of the springs, containing a hydraulic cylinder, on the rod of which a push device is fixed; a base for installing a spring, a pump station, a control unit, a linear displacement sensor, a directional valve connected to the pump station through a safety valve, a transport container for incoming springs and a manipulator are also introduced. In this case, the hydraulic cylinder, the pressure device and the base for installing the spring are fixed on the frame, equipped with a rotary axis, mounted on the base of the stand. And the transport packaging for incoming springs for testing is made in the form of a tank inclined towards the manipulator with the possibility of placing springs in it in a horizontal position. Moreover, the manipulator comprises a traverse placed on the frame, a carriage mounted on the traverse, and a spring gripping mechanism connected to the carriage, and the carriage and the spring gripping mechanism are provided with drives.

Fixing the hydraulic cylinder, the pressure device and the base for installing the spring on the frame, equipped with a rotary axis and mounted on the base of the stand, allows the frame to occupy a horizontal position, providing ease of installation of the spring in the working area of the stand.

The introduction of transport containers for the springs arriving for testing, made in the form of a tank inclined towards the manipulator with the possibility of placing the springs in it in a horizontal position, allows the springs to be moved to the manipulator under the influence of gravity without the use of auxiliary mechanisms.

A manipulator containing a traverse placed on the frame, a carriage mounted on the traverse, and a spring gripping mechanism associated with the carriage, serves to move the spring from the transport container to the working area of the stand.

The supply of the carriage and the mechanism for capturing the spring drives increases the level of automation of the stand.

Figure 1 shows a stand for testing the power parameters of the springs, top view. Figure 2 shows a side view of the stand.

The test bench for the power parameters of the springs contains a transport container 1, a manipulator consisting of a traverse 2, a frame 3, a carriage 4 and a gripping mechanism 5 of a spring 6, a hydraulic cylinder 7, a pressing device 8, mounted on a rod 9 of the hydraulic cylinder 7, a base 10 for installing a spring 6 , pump station 11, control unit 12, linear displacement sensor 13, force measuring device 14, valve 15, connected to the pump station 11 through a safety valve 16. Hydraulic cylinder 7, pressure device 8 and the base 10 for installing the spring 6 times placed on the frame 17, equipped with a rotary axis 18, mounted on the base 19 of the stand. And the carriage 4 and the gripping mechanism 5 of the spring 6 are equipped with drives (not shown).

The stand works as follows.

The springs 6 are loaded into a transport container 1, which, under the action of gravity, moves to the manipulator. The gripping mechanism 5 clamps and raises the spring 6. The carriage 4, mounted on the traverse 2, placed on the frame 3, moves the spring 6 into the working area of the stand. In this case, the frame 17, equipped with a rotary axis 18, mounted on the base 19 of the stand, occupies a horizontal position. The gripping mechanism 5 lowers the spring 6 into the target of the frame 17. And the hydraulic cylinder 7, through the pressure device 8 located on the rod 9, presses the spring 6 to the base 10. After that, the gripping mechanism 5 releases the spring 6 and leaves the working area of the stand.

Next, the frame 17 rotates around the axis 18 and occupies a vertical position. The hydraulic cylinder 7 releases the spring 6 from pre-tensioning, while the load measuring device 14 registers a zero value on the control unit 12. Spring 6 is ready for testing.

Next, the hydraulic cylinder 7 through the pressure device 8 twice compresses the spring 6 with a test load. At the same time, the moment of zeroing the load on the load measuring device 14 serves as a command for the control unit 12 to register the position of the linear displacement sensor 13, i.e. spring size 6 in the free state. The magnitude of the maximum load created by the hydraulic cylinder 7 on the spring 6 is limited by the operation of the safety valve 16.

The hydraulic cylinder 7 through the pressure device 8 again compresses the spring 6 with a test load, after which its size in the free state is again determined. The difference in the recorded values of the height of the spring 6 after the first and second compression and determines its shrinkage.

The second step in testing the spring 6 is to determine the deflection boom. To do this, a command is sent to the hydraulic cylinder 7 from the control unit 12, and the hydraulic cylinder 7 compresses the spring 6 through the pressure device 8 located on the stem 9. When the specified load is monitored by the force measuring device 14, the hydraulic cylinder 7 stops, and the linear displacement sensor 13 determines the height spring 6, which is recorded in the control unit 12. After which the hydraulic cylinder 7 releases the spring 6 from the external load, and the control unit 12 analyzes the received information from the load measuring device 14 and the sensor 13. The linear motion spring 6 is considered to have passed the test if its parameters meet the requirements of the design documentation.

Next, the hydraulic cylinder 7 through the pressing device 8 again compresses the spring 6, after which the frame 17 together with the spring 6 rotates around the axis 18 and again occupies a horizontal position. The carriage 4 of the manipulator, moving along the traverse 2, enters the working area of the stand. The gripping mechanism 5 is lowered and clamping the spring 6, and the hydraulic cylinder 7 releases the spring 6. Then the gripping mechanism 5 lifts the spring 6. Next, the spring 6 is placed in the discharge zone using the carriage 4 of the manipulator. Spring test completed.

The claimed stand for testing the power parameters of the springs reduces the complexity of the work of loading / unloading the spring on the stand, increases productivity and improves working conditions.

Claims (1)

A stand for testing the power parameters of springs, comprising a hydraulic cylinder, on the rod of which a pressure device is fixed; a base for installing a spring, a pump station, a control unit and a linear displacement sensor, a directional valve connected to the pump station through a safety valve, characterized in that it also includes a transport container for the springs and the manipulator for testing, the hydraulic cylinder, pressure device and the base for installing the springs is mounted on a frame equipped with a rotary axis, mounted on the base of the stand, and the transport container for incoming to the test springs is made in the form of it in the direction of the container manipulator with the possibility of placing the springs in it in a horizontal position, the manipulator comprising a traverse placed on the frame, a carriage mounted on the traverse, and a spring gripping mechanism connected to the carriage, and the carriage and the spring gripping mechanism are provided with drives.