RU113361U1 - STAND OF DETERMINATION OF CHARACTERISTICS OF SPRINGS OF THE ROLLING STOCK TROLLEY (OPTIONS) - Google Patents

Abstract

1. A stand for determining the characteristics of the springs of a rolling stock bogie (at full compression), containing a mechanism for forced compression of springs using a power cylinder, on the rod of which a pressure plate is fixed, a base for installing a spring, a force measuring device based on a corresponding sensor, a linear displacement sensor, a block control unit and a power supply unit, characterized in that when the stand is turned on, the control unit implements a time delay, during which the protective screen moves. ! 2. The stand according to claim 1, characterized in that a measuring ruler with a pointer connected to the rod is used as a linear displacement sensor, and a pressure gauge is used as a force-measuring device sensor. ! 3. A stand for determining the characteristics of the springs of a rolling stock bogie (at full compression), containing a mechanism for forced compression of the springs using a power cylinder, on the rod of which a pressure plate is fixed, a base for installing a spring, a force measuring device based on a corresponding sensor, a linear displacement sensor, electronic a control unit and a power supply unit, characterized in that, in addition to the time delay for the screen, the control unit additionally contains a stress calculation mechanism based on the force characteristic of the spring, so that during the tests it does not exceed the stress corresponding to the yield point of the material, while for their visualization the stand has the corresponding screens, and uses the keyboard on the panel to enter additional data. ! 4. A stand according to claim 3, characterized in that in case of failure to achieve

Description

The utility model for the proposed stand relates to test equipment. The device is designed to measure the characteristics of compression springs during the production or repair of bogies of a freight car, as well as other products incorporating compression springs.

Different types of bogies are used on rolling stock and, therefore, their spring suspension springs may differ. And all of them are checked for compliance with the established parameters. Because the installation of spring suspension springs from a cart of one type in the carts of another disrupts the normal operation of spring suspension - the friction damper, worsened operation, increased dynamic load on the wagon. And this leads to a breakdown of the spring kit and, as a consequence, to the destruction of the structural elements of the car and the track’s upper structure, reduces the safety of movement.

According to the definitions from the Standard Methods for Testing Springs (ST SSFZhT TsT-TsV-TsL 084-2000, M, p. 3), the maximum (test) load corresponds to the compression of the spring until the coils are completely in contact or to a voltage corresponding to the yield strength of the material. To fulfill this condition, static tests of the trolley springs are performed by appropriate loading to the maximum compression ratio of the coil of the spring. At the same time, the magnitude of the stress corresponding to the yield strength of the material can be achieved before the coils are completely compressed. Therefore, a number of appropriate devices have been created for monitoring the characteristics of the springs.

Thus, a stand is known that contains a bed rigidly attached to a horizontal surface, on which a guide with teeth is fixedly mounted. A carriage moves along the guide, on one end of which there is a long stand with horizontal support in the upper part, on the other end of the carriage - a short stand on which is placed a sensor for measuring the pitch of turns of a compression screw spring (US Pat. No. 2388996, G01B 21/00, dated March 31, 2009). A gear is fixed on the shaft of the latter, engaged with the teeth of the guide, and a rod is vertically mounted on the horizontal support of the long strut of the carriage, the lower end acting on the sensor for measuring the diameter and the arrow of the deflection of the tested compression screw spring, attached to the long carriage strut. The upper end of the rod is rigidly connected to the fork, while a spring is placed between the horizontal support and the fork. An axis with a roller placed on it is installed inside the fork, a stream is made on the rim of the latter, which includes the wire of the first turn of the compression screw spring, the longitudinal axis of which is parallel to the guide. Moreover, a compression screw spring is placed between two disks, one of which is rigidly mounted on the shaft of the geared motor, and the other is mounted with the possibility of rotation relative to the screw passing through the nut fixed to the upper edge of the bed. Another disk is also mounted with the possibility of longitudinal movement along with the screw. There are sensors for measuring the diameter, the arrow of the deflection and the pitch of the coil of the spring are connected to the microprocessor control system. The device is intended only for measuring the geometric parameters of the springs, but is not prepared for measuring the power characteristics. Therefore, it is not intended to reject springs that are inappropriate for the type of truck due to their highly specialized purpose.

A known bench for testing the power parameters of springs, the design of which solves the problem of simplifying the installation of a spring for testing (US Pat. RU No. 86308, G01M 17/04, 04/22/2009) and which is selected as the closest for the first modification of the claimed group. The stand contains 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 control valve connected to the pump station through a safety valve. In this case, the hydraulic cylinder, the pressure device and the base for installing the spring are fixed on a portal frame made with a rotary axis, mounted on the base of the stand. This proposal, although designed for use in rolling stock, has an unstable design. And, in addition, it is unsafe during testing - it does not protect personnel, for example, when the spring under test breaks before being compressed into turns. In addition, the disadvantage of this machine is the definition of a limited number of spring parameters. It is not intended to reject springs that are inappropriate for the type of cart.

A device is known for testing and automatic rejection of springs, selected as the closest solution, containing measuring presses with different load ranges, mechanisms: feeding under the measuring press, moving the springs inside the device, sorting the measured springs into suitable and unfit, unloading the springs from the device (pat . RU No. 2349394, B07C 5/34, dated 30.10.2007). The device is controlled by an electronic measuring unit. This device has many functions, but because of its size it is inconvenient when used as a simple device to determine the characteristics of the springs of a wagon or locomotive when it is fully compressed. At the same time, it does not determine the stress corresponding to the yield strength of the material, since it is not included in the test program. In addition, measures to protect personnel during spring tests, for example, when a test specimen breaks to a maximum load compressed into turns, are not described. Therefore, there remains a need for further modernization of such stands, starting from the simplest device.

A device is proposed for the operational control of spring parameters, for example, when assembling a spring set of rolling stock trolleys.

The task to which the claimed group of models is aimed is to increase safety during testing, expand the technical capabilities of the bench, and, in addition, expand the range of measured springs, automate the process of measuring and selecting springs according to the type of carts or for different types of devices containing similar parameters springs.

The technical result is achieved by the fact that in the stand for determining the characteristics of the springs of the rolling stock carriage under full compression, which contains a mechanism for forced compression of the springs using a power cylinder, on the rod of which a pressure plate is fixed, a base for installing the spring, a force measuring device based on an appropriate sensor, a linear displacement sensor , control unit and power supply, a protective mechanism is additionally laid down, for which when the stand is turned on, the control unit realizes a temporary delay LCD during which the protective screen is moved.

Also in the stand as a linear displacement sensor, a measuring ruler with a pointer connected to the rod is used, and a pressure gauge as a sensor of a force measuring device. At the same time, the range of validity springs for each type of trolley is marked on the line.

The essence of the second aspect of the claimed group of models lies in the fact that in the stand for determining the characteristics of the springs of the rolling stock trolley under full compression, containing a mechanism for the forced compression of the springs using a power cylinder, on the rod of which a pressure plate is fixed, a base for installing the spring, a load measuring device based on the corresponding sensor, the linear displacement sensor, the control unit and the power supply, is additionally incorporated on the basis of the removed power characteristics, the voltage calculation mechanism so that during the tests not to exceed the voltage corresponding to the yield strength of the material, while for their visualization the stand has appropriate screens, and for entering additional data uses the keyboard on the control unit panel.

In addition, if stresses corresponding to the yield strength of the material are not achieved, a command to end the full compression process is sent to the turns after the rate of change of the spring compression ΔL from the applied force does not change by a predetermined value, for example, ΔL / ΔF≥k.

The technical result is also achieved by the fact that a device for determining the correspondence of springs to a certain type of carriage of a wagon or locomotive, comprising a mechanism for forcing the springs by means of a power cylinder, a force measuring device based on a force sensor that controls the compression force of the spring and its height under load and having several measurement channels, associated with a range of test loads; the control and monitoring unit and the power supply unit further comprises a measurement channel for analyzing the parameters corresponding to the type of carriage, and that is selected in the control unit by means of a corresponding switch, and information on the design characteristics of the springs corresponding to the type of carriage is digitally recorded in the memory of the control unit which in the indicated block compares information on the parameters of the measured springs with those stored in memory; on the basis of which a decision is made on the conformity or rejection of the springs, which is displayed on the indicator device and the display of the control unit.

As an example of a specific implementation, figures 1, 2 and 3 schematically depict a stand with a protective screen. Figure 2 shows a variant of the structural design of the stand with additional nodes. Figure 3 shows a variant of the design of the stand with the determination of the correspondence of the springs to a specific type of carriage of a wagon or locomotive

In the presentation of the first option, the stand has a pneumatics control unit 1, a power unit 2, as well as a power supply unit (shown schematically in figure 1). The power unit 2 in the form of a cylinder 3 is located on the stops 4 on the base 5. The test spring 6 is installed on the base between the supports supporting the cylinder under the pressure plate 7. A movable protective shield is attached to the base 9. It is driven using an auxiliary cylinder (shown in the pneumatic diagram like 10). As an embodiment, the figure shows the case when the linear displacement sensor 11 is attached to the pressure plate, and the pointer on the cylinder body. The opposite version is also possible: a pointer on the plate, and a linear displacement sensor on the body. Control of spring contact by the pressure plate is made on the basis of a separate part (a mechanical indicator such as a flag) located on the plate.

Since special attention is given to the height of the spring in a fully compressed state, an appropriate interval is applied to the linear displacement sensor, falling into which the spring is recognized as usable.

The pneumatic part includes a pressure control device (pressure gauge) 12, a three-way valve 13, a gearbox 14, a filter 15 and a control valve 16 for the cylinder 10, designed to put the screen in working condition during testing.

In the second embodiment, the stand of FIG. 2 has a control and monitoring unit or an electronic measuring unit 1, a power unit 2, and a power supply unit (not shown). In addition, displays 17 are shown on the panel panel showing the characteristics of the spring and a keyboard 18 for entering the spring parameters into the microcontroller of the stand. The spring data may also come from a central computer (not shown) through an appropriate interface. The presence of measuring sensors allows you to quickly perform measurements, including in automatic mode. The protective screen is not shown.

In a block view, the stand of FIG. 3 has a control unit 1, a power unit 2, and a power supply unit (not shown). In addition, indicators 19 are located on the block panel, showing whether the spring characteristics correspond to a given type of trolley. The type of cart is selected by the corresponding position of the switch 20.

In the power unit, power pneumatic or hydraulic cylinders or a drive through a step screw from a hydraulic or electric motor are used to create a load.

When using pneumatics, air is supplied to the power cylinders using manually operated pneumatic valves (first option) or an electronic measuring unit with electropneumatic valves. This block is a block controller, a central control computer with transducers of displacement, force, and actuating sensors.

Information about the design parameters of the springs is recorded in the microprocessor memory in digital form or recorded. Information about the power characteristics of the tested springs from the sensors is digitally supplied to the electronic measuring unit or is built separately at the end of the tests based on the previously obtained calibration. In this case, in the electronic measuring unit, the specified characteristics of the springs are compared with the characteristics of the tested springs.

According to the first aspect of the claimed group of models, the stand works as follows.

The spring is installed under the plate of the power unit and it is put into operation. In this case, compression begins to be performed after a certain period of time, during which the actuator of the protective screen covers the area with the tested spring from the person controlling the stand. In this case, the screen can only be retracted with the piston of the cylinder. The process is controlled by a linear displacement transducer, for which, for example, a measuring ruler with a pointer connected to the rod 11 is used, and a pressure gauge 12 as a force measuring device gauge. The force applied to the spring is judged by the pressure / force calibration dependence.

According to the second aspect of the claimed group of models, the test bench operates using an electronic control unit, which additionally incorporates a stress calculation mechanism based on the removed spring force characteristics, so that during testing it does not exceed the stress corresponding to the yield strength of the material, while for visualization the test bench has appropriate screens 17, and to enter additional data uses the keyboard 18 on the front panel. The operator first enters the necessary data to calculate the stresses of a particular spring. Then the service person starts the device by pressing the appropriate button. In this case, at first, the protective screen overlaps the working area. The test process is fully automated based on available measuring sensors and actuators. In the test process, in the case of failure to reach the stresses corresponding to the yield strength of the material, the command to end the full compression process is sent to the turns after the rate of change of the spring compression ΔL from the applied force F does not change by a predetermined value.

According to the third aspect of the claimed group of models, the stand works as follows

At startup, to determine the type of springs, the operator must enter (select) the type of truck of the freight car for which the spring kit is assembled, and install the springs in the device one by one. That is, step 1 - select the type of trolley. In addition, it may be necessary to establish a rejection interval if it is not programmed. That is, preliminarily lay down the upper and lower values for the measured characteristics of the springs.

For example, the corresponding switch 20 selects the position: spring for spring suspension of freight cars of the cart 18-100 or 18-578.

Next, the next step - 2 sets the spring in the receiving cup and starts the stand in operation. Step 3 is performed: the operator presses the START button - at the same time, the device closes the protective screen, determines the type of spring. Then the spring is compressed by a cylinder (pneumatic in our case) with a test load corresponding to this type of spring for the indicated type of trolley.

Note that the device automatically determines the type of spring (external or internal). During the loading of the spring, the device determines the stiffness and height of the spring and, depending on the values obtained, indicates the conformity of the spring to the type of trolley. In the algorithm of the stand, for example, the following situations are considered:

a) if the spring under the test load has a height greater than the maximum allowable (rejection size) - due to increased rigidity or the spring is fully compressed (it has sat down on the coils), then the spring is rejected.

b) if the spring under the test load has a height less than required - due to reduced stiffness or free height H ₀ - for example, a spring from a spring set of another type of trolley, then the spring is also rejected.

c) if the spring has parameters set by the operator for the specified type of trolley, then the spring is allowed to be installed in the spring set of the trolley.

When the specified load value is reached, the spring compression stops and its reduction begins. After the load is completely removed from the spring, the device unlocks the screen and starts the process of its removal to the initial state.

The GREEN lamp will turn on on the control unit if the spring parameters correspond to the selected type of trolley and the spring height H ₃ under the test load does not exceed the set upper and lower values, or RED if the parameters exceed the lower level and the spring is rejected. In addition, for wedge-shaped springs, those from suitable ones that are not rejected by the upper value are used. Then the spring is removed from the test site.

It is forbidden to install rejected springs in the spring set of the cart. It is clear that there may be other combinations of the proposed stand options. Currently, design documentation has been developed for the claimed group of models, and prototypes of the test bench options for testing the springs of a railway carriage are being manufactured. The results of preliminary tests of one of the bench options showed compliance with the stated requirements.

Claims (5)

1. A stand for determining the characteristics of the springs of the rolling stock carriage (with full compression), comprising a mechanism for forcing the springs by means of a power cylinder, the rod of which is fixed to the pressure plate, the base for installing the spring, a force measuring device based on the corresponding sensor, linear displacement sensor, block control unit and power supply, characterized in that when the stand is turned on by the control unit, a time delay is realized during which the protective screen is moved. 2. The stand according to claim 1, characterized in that a measuring ruler with a pointer connected to the rod is used as a linear displacement sensor, and a pressure gauge is used as a sensor of a force measuring device. 3. A stand for determining the characteristics of the springs of the rolling stock carriage (under full compression), comprising a mechanism for forcing the springs to be compressed by means of a power cylinder, on the rod of which a pressure plate is fixed, a base for installing the spring, a force measuring device based on an appropriate sensor, linear displacement sensor, electronic a control unit and a power supply, characterized in that in addition to the time delay for the screen, the control unit is additionally incorporated on the basis of the removable power characteristics of the spring stress calculation mechanism, so that during the tests not to exceed the stress corresponding to the yield strength of the material, while for their visualization, the stand has appropriate screens, and uses the keyboard on the panel to enter additional data. 4. The stand according to claim 3, characterized in that in case of failure to achieve stresses corresponding to the yield strength of the material, a command to end the full compression process is sent to the turns after the rate of change of the compression value of the spring ΔL from the applied force F does not change by a predetermined value . 5. A stand for determining the characteristics of the springs of a rolling stock carriage, comprising a mechanism for forced compression of the springs using a power cylinder, a force measuring device with appropriate sensors that controls the compression force of the spring and the height of the spring under load, having several measurement channels associated with the range of test loads; an electronic measuring unit (control and monitoring unit) and a power supply unit, characterized in that, in addition to the time delay, the screen additionally has a channel for measuring parameters, including sensors for determining the type of spring (internal or external) corresponding to the type of trolley in the control unit is selected by means of a corresponding switch, for which purpose information on the design characteristics of the springs corresponding to the type of bogies is recorded in the memory of the control unit, on the basis of which the trial value is set loads for setting the maximum allowable deformation of the spring, while the force measuring device additionally controls the height of the springs under the action of the test load or the height of the spring when fully compressed to the turns, and in this block the information about the parameters of the measured springs is stored with those stored in the memory, the height of the springs under the action of the test load or the height of the spring with full compression to the turns; on the basis of which a decision is made on the conformity or rejection of the springs, which is displayed on the indicator device and display.