RU222222U1 - Stand for testing rubber-metal joints - Google Patents

Abstract

The utility model relates to the field of mechanical engineering, namely to stands for testing rubber-metal hinges. A stand for testing rubber-metal hinges, containing a frame consisting of a base with an electric motor installed on it, which, by means of a belt drive, rotates a crank mechanism, a connecting rod connected to the crank mechanism, what is new is that a load mechanism consisting of prismatic supports for the test sample, a system of levers, brackets and axes that transmit radial load to the tested rubber-metal hinge from suspensions with weights, as well as a pulse counter that records the number of rotation cycles of the rubber-metal hinge inside the bushing under the influence of radial load, and wear sensors that record the maximum wear of the rubber parts of the rubber-metal hinge. An increase in the reliability of the stand design is achieved by simplifying the design of the mechanism that creates a load on the rubber-metal joint being tested. 1 ill.

Description

The utility model relates to mechanical engineering (special military equipment), namely to stands for testing mechanical engineering products, in particular to test stands intended for testing rubber-metal hinges (RMH).

The previously developed stand IL-203-4 is known, which was designed to test the quality of manufacturing of rubber-metal bushings (RMB) by testing them for cyclicity in the mode of simultaneous twisting of rubber rings under the influence of radial load. The objects of control were bushings, as well as other rubber-metal pins, bushings and hinges with up to 7 rubber rings.

The IL-203-4 stand consists of a frame with a base, a fixing and rotation mechanism for installation controlled by the RMV, a loading mechanism, an electric drive, a crank mechanism, and a device for counting cycles. The loading mechanism of the stand consists of a rod system with load springs. The support of the mechanism was the frame body. The load on the controlled RMV was transmitted through rods from springs and was regulated using a special screw device. The crank mechanism is located in the upper part of the stand and is designed to transmit reciprocating influence on the fixing and turning mechanism. The testing process takes place in the following way. The controlled RMV is pressed (using a special device) into the mounting sleeve of the stand. Next, the RMV, pressed into the mounting sleeve, was installed in the body of the rotation mechanism and secured with the help of covers. The load mechanism rods were attached to a bushing with a pressed RMV symmetrically relative to the vertical axis of the bushing, and the bolts of the rod clamping device were tightened. Next, the stand’s automatic launcher was turned on.

The disadvantage of this stand design is the limited functionality due to constant monitoring of the elastic characteristics of the load springs. According to the stand's passport, the load springs had to be periodically removed from the stand and their elastic parameters monitored on a special tensile testing machine, then installed back, which complicated the maintenance of the stand as a whole. In addition, the use of tension devices was carried out by manual adjustment, which required significant effort, which made the operation of the stand inconvenient.

A bench for testing elastomeric bearings (RU 2767596 C1, IPC G01M 13/04 (2006.01), published on March 17, 2022) was chosen as a prototype, since the mentioned elastomeric bearing can serve as an analogue of the rubber-metal hinge being tested. This stand contains a frame with an installed hydraulic cylinder, an electric motor, a crank mechanism and measuring instruments. A three-arm lever is hingedly mounted on the frame of the stand, to which a connecting rod connected to a crank is attached through a hinge. The shanks of the flat rods are attached to the lever bearing using crosses, which are secured to the bearing under test using a rocker arm. The radial load on the test sample is applied using a hydraulic cylinder, which is connected to the force sensor through an articulated rod.

The disadvantage of this design is the method of setting the load in the form of a working hydraulic cylinder. The load from the hydraulic cylinder requires a separate hydraulic station, which complicates the design of the stand as a whole, takes up additional space, requires the consumption of additional electricity and complicates the maintenance of the stand as a whole. In addition, the operation of a hydroelectric power station has a limited time and a certain service life.

The technical result is to increase the reliability of the stand design by simplifying the design of the mechanism that creates a load on the rubber-metal joint being tested.

Declared technical result is achieved due to the fact that the stand for testing rubber-metal hinges contains a simplified design of the loading mechanism, consisting of prismatic supports (for fastening the test sample), a system of levers, brackets and axes that transmit radial load to the tested rubber-metal hinge from suspensions with weights. The simplified design of the loading mechanism has a significantly longer service life of the structural elements, which ensures a longer test time without maintenance of the stand as a whole, thereby increasing the reliability of the stand design.

Analysis of distinctive features showed the following:

- the presence in the stand of a loading mechanism consisting of prismatic supports (for fastening the test sample), a system of levers, brackets and axes that transmit radial load to the rubber-metal hinge being tested from suspensions with weights, provides a longer service life of the stand’s structural elements, which provides more a long test period without maintenance of the stand as a whole, thereby increasing the reliability of the stand design.

- the presence in the stand of a pulse counter recording the number of rotation cycles of the rubber-metal joint inside the bushing under the influence of radial load, wear sensors recording the maximum wear-out of the rubber part of the rubber-metal joint ensures a more reliable design of the measurement system than digital control systems and measurement of loading cycles, thereby increasing the reliability of the design stand.

The essence of the utility model is illustrated by drawings, where:

in fig. 1 – stand for testing rubber-metal joints, side view.

The stand for testing rubber-metal hinges contains a frame 1, consisting of a base 2, which is a welded structure made of sheets and channels, which serves to install all the main components and parts on it. An electric motor 3 is fixed to the base 2 of the frame 1, which, by means of a belt drive 4, rotates the crank mechanism 5. A connecting rod 6 connections with the crank mechanism 5. A load mechanism consisting of a system of levers 7, brackets and axles 9, suspensions with weights 10. A support for the levers 7 is a housing with radial ball bearings. The load on the test RMSH is transmitted from suspensions with loads 10 through systems of levers 7 installed on prismatic supports 8, bracket knives and rods. The rods are equipped with a bushing with an RMS pressed into it. When installing the rubber-metal hinge in the prismatic supports 8, the system of levers 7 with suspensions with weights 10 is lifted using a hydraulic jack. The stand also contains a device for measuring the total number of cycles of the test RMSH in the form of a pulse counter 11, a device for automatically turning off the stand consists of two wear sensors 12, which are mounted on the central sheet of the enclosing structure of the loads of the loading mechanism.

The stand for testing rubber-metal hinges works as follows.

At the ends of the lever system 7 of the stand, hangers with weights 10 are installed and secured to the previously extended jack support until they come into contact with the lower surface of the lever system 7 of the stand, which should take a horizontal position. Weights are installed on the suspensions with weights 10, so that the lever systems 7 of the stand rest against the jack support and are at the same time in a horizontal position. The presence and reliability of visible grounding of the stand, the integrity of the protective casings of the stand, and the absence of foreign objects that impede normal operation and pose a threat to human safety are checked.

The rubber-metal joint being tested is pressed (using a special device) into the installation sleeve of the stand. Next, the hinge under test, pressed into the bushing, is installed in the body of the prismatic supports 8 and secured with the help of covers. The vertical rods of the loading mechanism are mounted on a bushing with a pressed rubber-metal hinge symmetrically relative to the vertical axis of the bushing, and the bolts of the rod clamping device are tightened.

The jack is lowered, and it is necessary to leave a gap between the stop of the jack and the lever system 7, ensuring that the lever system 7 sags freely.

The wear sensors 12 are pre-adjusted so that the moment of operation of the pins of the automatic shutdown device for any of the wear sensors 12 corresponds to the level of permissible wear of the rubber-metal hinge.

The START control button is pressed, and the electric motor 3 of the stand is turned on, which, by means of a belt drive 4, rotates the crank mechanism 5 and connecting rod 6. During operation, the following parameters are monitored: wear of the rubber-metal joint under test - according to wear sensor 12, the number of cycles of its loading - according to the counter impulses 11.

At the end of the test work, when the rubber-metal hinge is worn to a given size, the electric motor 3 is automatically switched off when the pins of the automatic shutdown device of any of the wear sensor 12 are triggered. Based on the readings of the pulse counter 11, the number of loading cycles of the rubber-metal hinge is determined. The number of loading cycles of the rubber-metal hinge must correspond to the standard parameters.

Thus, the stand is a more reliable design, allowing for longer test times without stand maintenance.

Claims (1)

A stand for testing rubber-metal hinges, containing a frame consisting of a base with an electric motor installed on it, which, by means of a belt drive, rotates a crank mechanism, a connecting rod connected to the crank mechanism, characterized in that a load mechanism consisting of prismatic supports is installed on the stand for the test sample, a system of levers, brackets and axes that transmit radial load to the tested rubber-metal joint from suspensions with weights, as well as a pulse counter that records the number of rotation cycles of the rubber-metal hinge inside the bushing under the influence of radial load, and wear sensors that record the maximum wear of the rubber part rubber-metal hinge.