RU84481U1 - STAND FOR TESTS OF HYDRAULIC JACKS OF STARTING COMPLEXES UNDER NATURAL LOADING CONDITIONS - Google Patents

Abstract

1. A test bench for launch jacks of launch complexes under full-scale loading conditions, comprising a power frame with means for creating a loading force on the hydraulic jack to be tested, while fastening nodes of the supports of the tested hydraulic jack are fixed on the power frame, characterized in that as a means of creating a loading force on the hydraulic jack to be tested using a loading hydraulic jack, and the power frame is made in the form of a frame mounted horizontally on the supports and including transverse traverses and longitudinal b flanges, in the middle part of which brackets are vertically fixed, the free ends of which are connected by an axis on which the lever is rotatably fixed at one end, on the other end of which are nodes for fastening the rod supports of the loading and tested hydraulic jacks, and fastening nodes for their rear supports mounted on different transverse traverses and are located in one horizontal plane, while the distance from the axis of rotation of the lever to the axis of rotation of the mount of the rod support of the test hydraulic jack This is equal to the distance from the axis of rotation of the support truss to the axis of rotation of the attachment site of the rod support of the hydraulic jack in natural conditions. ! 2. The stand according to claim 1, characterized in that the lever is rigidly connected to the axis, the ends of which are mounted in bearing assemblies at the ends of the brackets. ! 3. The stand according to claim 1, characterized in that it is equipped with a second loading hydraulic jack, the attachment points of the supports of which are mounted on the transverse traverse and the lever, while the second loading hydraulic jack is placed in the same plane as the first loading hydraulic jack, their axis

Description

The utility model relates to testing equipment, in particular, to test benches for power hydropneumatic equipment under natural loading conditions, intended for use on launch rocket complexes, and can be used in testing hydraulic jacks of various sizes.

The launch complex includes support trusses, an upper cable mast and a service mast. During preparation for the start, these elements are transferred from the initial state (inclined) to the working (vertical) by turning around their axis of rotation due to the forces created by hydraulic jacks. The maximum efforts created by the hydraulic jacks of the supporting farms and the service mast of the launch complex reach about 45 tf with the stroke of its plunger relative to the lower support of the hydraulic jack of about 1 m.

To determine the operability of such hydraulic equipment, including the newly developed one, it is necessary to conduct bench tests under full-scale loading conditions.

A well-known test bench for jacks of launch complexes under full-scale loading conditions, containing a power frame with means to create a loading force on the tested hydraulic jack, while the support frame of the supports of the tested hydraulic jack is fixed on the power frame (see Stand CM336. Set of drawings No. CM336. SB00.VO, - M., KBOM, 1972.-27 p).

The dimensions of the well-known stand are: height - 6 900 mm, plan dimensions 9 500 mm (maximum) × 4,200 mm. A well-known stand with such dimensions allows testing a certain range and sizes of hydraulic jacks of launch complexes under conditions close to full-scale.

In Fig.1 shows a General view of the test bench for hydraulic jacks of the launch complex, and in Fig.2 - view And the stand in Fig.1.

In the well-known test bench, the main element providing the loading force to the hydraulic jack under test (shown in broken lines in the drawing) is the rocker 1 with unequal shoulders, mounted in the bearing assemblies 2 on the vertical columns 3. The test bench allows two jacks to be tested simultaneously 4. To ensure hydraulic jack tests 4 on the beam 1, the fastening nodes of the upper supports 5 of the hydraulic jacks 4 are fixed, and the fastening nodes of their lower supports 6 are fixed on the supports 7 mounted on the base of the stand.

To test the hydraulic jacks 4, sets of weights 8 and 9 (loading means) are installed at different ends of the rocker arm 1, providing the specified inertial and momentary loading characteristics of the hydraulic jack 4. At the lower end of the rocker arm 1, a stop 10 is mounted, which interacts with the lock 11, which secures the rocker 1 in cocked position.

Tests of hydraulic jacks 4 are carried out as follows.

In the initial state, the rocker 1 is in a vertical position with technological hydraulic jacks connected to its upper 5 supports, the lower supports 6 of which are installed on the base of the stand. In this case, the stop 10 interacts with the lock 11, and the beam 1 is fixed in the cocked position. After that, the technological hydraulic jacks are dismantled, and the tested hydraulic jacks are installed in their place 4. The hydraulic system of the stand (not conventionally shown in the drawing) is attached to the fittings of the working and rod cavities of the hydraulic jacks 4, after which the rods of the tested hydraulic jacks 4 are extended to the stop in the attachment points of the upper supports 5 fixed on the beam 1.

After opening the lock 11, the rocker 1 is released and under the influence of the static moment created by the set of loads 8 and 9, loads the rods of the tested hydraulic jacks 4 through the upper supports 5, while the working cavities of the hydraulic jacks 4 are opened for draining the working fluid, and the rod ones for suction. Under the influence of the static moment created by the set of loads 8 and 9, the rocker 1 rotates clockwise, moving the rods of the tested hydraulic jacks 4.

After moving the rods of the tested hydraulic jacks 4 to their lowest position, the working fluid is supplied under pressure, and the rod cavities are opened to drain the working fluid, and the beam 1 under the influence of the tested hydraulic jacks 4 is turned counterclockwise to the extreme upper position of the rods of the tested hydraulic jacks 4 .

Next, the loading cycle is repeated. Tests of hydraulic jacks are carried out up to 50 working cycles of loading.

The disadvantages of the known test bench for power jacks of the launch complex are as follows:

1. Since the well-known stand has certain dimensions (it was created for testing hydraulic jacks that create a force of 20 tf), which in general determines the creation in a certain range of predetermined forces on the equipment under test, while maintaining the strength of the stand structure and its elements, it does not allow testing again created samples of hydraulic jacks of high power - 45 tf.

2. In addition, another drawback of the known stand is that it is a large structure with the following dimensions: height 6900 mm, plan dimensions 9500 mm × 4200 mm, and weight (with interchangeable processing equipment) of more than 65 tf. This generally complicates its maintenance and operation. To test new hydraulic jacks of different sizes, it is necessary to produce additional elements that ensure the mounting of the equipment under test on the stand. This leads to additional material costs and increases the testing time of hydraulic equipment.

The technical problem solved by the utility model is to create a stand for testing hydraulic jacks in a wide range of preset loading forces, simplifying the design of the stand and simplifying its maintenance and operation.

This problem is solved in that in the well-known test bench for jacks of launch complexes under natural loading conditions, containing a power frame with means for creating a loading force on the tested hydraulic jack, while the support frame of the supports of the tested hydraulic jack is fixed on the power frame, according to the utility model as a means of creating loading forces on the tested hydraulic jack use a loading hydraulic jack, and the power frame is made in the form of a frame mounted horizontally on supports and on yawing transverse traverses and longitudinal beams, in the middle part of which brackets are vertically fixed, the free ends of which are connected by an axis, on which the lever is rotatably fixed at one end, the nodes for fastening the rod supports of the loading and tested hydraulic jacks are fixed on the opposite ends, and the attachment points of their rear supports are mounted on different transverse traverses and are located in the same horizontal plane, while the distance from the axis of rotation of the lever to the axis of rotation of the mount I of the rod support of the hydraulic jack under test is equal to the distance from the axis of rotation of the support truss to the axis of rotation of the mount of the rod support of the hydraulic jack in natural conditions.

In addition, the lever is rigidly connected to the axis, the ends of which are mounted in bearing assemblies at the ends of the brackets.

The stand can be equipped with a second loading hydraulic jack, the support attachment points of which are fixed on the transverse traverse and the lever, while the second loading hydraulic jack is placed in the same plane with the first loading hydraulic jack, their axes are parallel and they are located symmetrically with respect to the axis of the tested hydraulic jack.

Moreover, the brackets on the longitudinal beams can be installed vertically down or vertically upward relative to the power frame.

Figure 3 shows a top view of the test bench for jacks of the launch complex under natural loading conditions, and figure 4. - section AA of the stand in figure 3.

The stand contains a power frame 1, mounted horizontally on the vertical supports, uprights 2. Frame 1 is made of 2 reinforced longitudinal beams 3 and 4, the ends of which are connected by reinforced transverse traverses 5 and 6. In the middle of the longitudinal beams 3 and 4 are fixed vertically down brackets 7, the free ends of which are connected by an axis 8. The axis 8 is mounted in brackets 7 in the bearing units for rotation. On the axis 8, a lever 9 is installed with nodes fixed in its upper part on different sides for mounting the front (stock) bearings 10 and 11 of two loading 12 and one hydraulic jacks 13 tested, respectively. The hydraulic jacks 12 are placed in the same plane, their axes are parallel and they are located symmetrically with respect to the hydraulic jack being tested 13. The distance from the axis of rotation of the lever 9 to the axis of rotation of the mount of the rod support 11 of the hydraulic jack 12 to be tested is equal to the distance from the axis of rotation of the support truss to the axis of rotation of the mount rod support hydraulic jack in natural conditions. The rear bearings 14 and 15 of the hydraulic jacks 12 and 13 are fixed to the attachment points mounted on the transverse crossbars 5 and 6, respectively. In this case, the axes of the rear supports 14 and 15 of the hydraulic jacks 12 and 13 are placed in one horizontal plane. The tilt angles of the rear support 15 and the front support (rod) 11 of the tested hydraulic cylinder 13 at the initial moment are equal to the corresponding tilt angles of the hydraulic jack supports on the launch complex in the initial position.

The equality of the distance from the axis of rotation of the lever to the axis of rotation of the mount assembly of the rod support of the hydraulic jack under test to the distance from the axis of rotation of the support farm to the axis of rotation of the mount of the rod support of the hydraulic jack under natural conditions provides kinematically in-kind loading of the test product on the bench during the entire test.

The loading hydraulic jacks are selected with characteristics that ensure the creation of the working force of the tested hydraulic jack up to 80 tf, and the stroke of their rods and the distance of their upper (rod supports) on the lever should provide the required stroke of the rod of the tested hydraulic jack.

The hydraulic system of the stand (not shown conditionally in the drawing) includes: a container with a working fluid, a high-pressure source - a gear type volumetric pump, a filter, shut-off and control valves, manometers and a piping system.

In the stand design, two loading hydraulic jacks 12 are used, which provides testing of hydraulic jacks 13 in a wide range of loading forces, which are regulated by a predetermined program for changing the flow cross sections in the pressure relief lines of the working fluid from the working cavities of the loading hydraulic jacks.

Dimensions of the stand: length 6080 mm, width 1510 mm, height 1340 mm; weight (without hydraulic system) 4.1 tf.

Taking into account such dimensions of the stand, and, in particular, height (1.34 m), its maintenance and operation is simplified. The absence of a multi-ton beam with loads used to load the hydraulic cylinder under test with specified forces, and the use of hydraulic jacks as a loading device increases the reliability of the proposed stand in a wide range of loading forces.

Testing the hydraulic jack on the proposed stand is as follows.

The initial position of the individual elements and nodes of the stand. The test jack 13 is mounted on a stand and fixed in the attachment points of the front (rod) and rear supports 11 and 15, respectively. The rods of the loading hydraulic jacks 12 are extended, the rod of the tested hydraulic jack 13 is in the extreme position (fully placed in the cylinder).

From the hydraulic system of the bench, the pressure in the working cavity of the tested hydraulic jack 13 is adjusted to the value specified in the Technical conditions for testing by adjusting the hydraulic resistance of its drain line. Then opens the control valves on the highway, connecting the working cavity of the loading hydraulic jacks 12 with a tank with a working fluid. When this occurs, the working stroke of the tested hydraulic jack 13, accompanied by the rotation of the rod head in the support 11. The pressure in the working cavity of the tested hydraulic jack 13 is regulated by the fittings in accordance with the specified law of change in the movement of the rod.

In the test process, the rod cavity of the test 13 and the loading 12 hydraulic jacks are connected to the tank with the working fluid.

When the rod reaches the tested hydraulic jack 13 extreme extended position, the pressure in its working cavity is stopped, and then the working fluid from it is discharged into a container with the working fluid. At the same time, the working fluid under the necessary pressure is supplied to the working cavities of the loading jacks 12, the rods of the loading hydraulic jacks 12 are extended, moving the elements and nodes of the test bench and the hydraulic jack 13 being tested to their initial position.

The described loading cycle is repeated in accordance with the requirements of the Technical conditions for testing.

Thus, the use of a utility model ensures loading conditions during the testing of hydraulic jacks that correspond to full-scale conditions in a wide range of loading forces.

Protection of the test and test equipment during the loading process is ensured by the fact that the maximum extension of the rod of the tested hydraulic jack is limited by the stroke of the rods of the loading hydraulic jacks, and the maximum pressure in the working cavity of the tested hydraulic jack is limited by a safety valve located on the discharge line of the hydraulic system.

Using the utility model will allow testing hydraulic jacks in a wide range of specified values of the loading forces. In addition, the design of the stand, its maintenance and operation is simplified.

Claims (5)

1. A test bench for launch jacks of launch complexes under full-scale loading conditions, comprising a power frame with means for creating a loading force on the hydraulic jack to be tested, while fastening nodes of the supports of the tested hydraulic jack are fixed on the power frame, characterized in that as a means of creating a loading force on the hydraulic jack to be tested using a loading hydraulic jack, and the power frame is made in the form of a frame mounted horizontally on the supports and including transverse traverses and longitudinal b flanges, in the middle part of which brackets are vertically fixed, the free ends of which are connected by an axis on which the lever is rotatably fixed at one end, on the other end of which are nodes for fastening the rod supports of the loading and tested hydraulic jacks, and fastening nodes for their rear supports mounted on different transverse traverses and are located in one horizontal plane, while the distance from the axis of rotation of the lever to the axis of rotation of the mount of the rod support of the test hydraulic jack This is equal to the distance from the axis of rotation of the support truss to the axis of rotation of the attachment site of the rod support of the hydraulic jack in natural conditions. 2. The stand according to claim 1, characterized in that the lever is rigidly connected to the axis, the ends of which are mounted in bearing assemblies at the ends of the brackets. 3. The stand according to claim 1, characterized in that it is equipped with a second loading hydraulic jack, the attachment points of the supports of which are mounted on the transverse traverse and the lever, while the second loading hydraulic jack is placed in the same plane as the first loading hydraulic jack, their axes are parallel and they are symmetrically located relative to the axis of the test jack. 4. The stand according to claim 1, characterized in that the brackets on the longitudinal beams are installed vertically downward relative to the power frame. 5. The stand according to claim 1, characterized in that the brackets on the longitudinal beams are installed vertically upward relative to the power frame.