RU2170919C1 - Device for measurement of contact deformation - Google Patents

Abstract

FIELD: measurement technology; measurement and recording of contact deformation and tightness of parts which are brought in contact. SUBSTANCE: proposed device has housing made in form of hermetic chamber. Joint simulator consisting of two parts is fitted in wall of housing. Tube with rod-type pusher is tightly fitted in hole of first part. Tightly fitted on tube is flexible member connecting the tube with housing and rod-type pusher motion sensor. Second part of joint simulator is provided with tangential motion sensor. Surface of contact plane of second part of joint simulator is flat. Bearing is mounted for creating loading force of joint simulator and pin engageable with surface of its second part is located along its axis. EFFECT: extended functional capabilities of device and its universality. 1 dwg

Description

 The invention relates to measuring technique, namely to means for measuring and recording contact deformations and tightness of contacting samples, and can be applied in laboratory studies of the contact characteristics of tribosystems and sealing compounds close to actual operating conditions.

 A device for measuring contact deformations is known, comprising a housing made in the form of a sealed chamber with an opening in one of the walls, a joint simulator mounted on this wall and made of two parts, the first of which has a central hole coaxial to the wall opening, a tube installed in the holes are hermetically sealed and the end of which is mounted coaxially in the openings of the body wall and the first part of the simulator, other than its end and both parts of the simulator form a cavity, a finger to create a loading force on the joint simulator, a rod pusher placed in the tube, an elastic element sealed on the tube, made in the form of a rigid bellows and connecting the tube to the housing, a rod pusher displacement sensor, made in the form of a hollow sealed housing mounted on the free end of the tube with a sensing element fixed to it, registering a device associated with a sensing element, a pressure source and a locking member (a. S. USSR N 1375959, G 01 M 3/08, 1988 - prototype).

 The disadvantage of this device is that it does not allow to study the tightness of the joint in the presence of shear tangential loads present in real operating conditions, and due to the presence of a cavity and a hole for an abutment in the second part of the simulator, the volumetric deformation of both parts of the joint simulator is included in the overall balance of deformations, which reduces the accuracy of measuring contact deformations, and the hole for the stop in the second part of the joint simulator increases gas leakage, which reduces the accuracy of the tightness measurement.

 The objective of the invention is to increase the accuracy of measuring contact deformations and tightness of the joint, expanding the functionality by bringing the laboratory conditions of the study closer to the real ones during operation of the joints due to the possibility of measuring the tangential stiffness of the joint and investigating the dependence of tightness on the tangential stiffness of the joint while reducing the volumetric deformation of the test samples and reducing incidental gas leaks.

 This problem is solved in that in a device for measuring contact deformations, comprising a housing made in the form of a sealed chamber with an opening in one of the walls, a joint simulator mounted on this wall and made of two parts, the first of which has a central hole, coaxial to the hole walls, a tube installed in the holes hermetically and the end of which is installed coaxially in the holes of the wall of the housing and the first part of the simulator, and its end and both parts of the simulator form a cavity, a finger to create a load Iliya on the junction simulator, a rod pusher placed in the tube, an elastic element sealed on the tube, made in the form of a rigid bellows and connecting the tube to the housing, the rod pusher displacement sensor, made in the form of a hollow sealed housing mounted on the free end of the tube and mounted on a sensitive element, a recording device connected with a sensitive element, a pressure source and a shut-off element - the second part of the joint simulator is solid and connected to the pusher loading device, the second part of the joint simulator is equipped with a tangential displacement sensor located on the first part of the joint simulator, and the surface of the second part of the joint simulator in the contact plane is made flat, and the finger is mounted on an axis in the bearing interacting with the surface of the second part of the joint simulator.

 The device is equipped with a pusher of the loading device, which transfers the shear load to the second part of the simulator to create contact strains in the joint in the tangential direction.

 A finger that generates normal compressive force on the joint simulator is mounted in the bearing to allow simultaneous impact of normal and tangential loads on the joint simulator with a decrease in the finger resistance to the shear load due to the application of rolling friction.

 The second part of the simulator is made continuous, without a channel for stopping the pusher, to reduce the resistance of the finger in the bearing during its movement by eliminating the holes on the surface of the second part of the simulator and to reduce gas leaks through it.

 The second part of the simulator is equipped with a sensor located on the first part of the joint simulator for measuring the tangential displacements of the second part of the joint simulator relative to the first.

 The surface of the second part of the joint simulator in the joint area is made flat to reduce volumetric deformations of the parts of the joint simulator, since the parts of the joint simulator are contacted over a larger area in the plane of their contact, unlike the prototype, where the contact of both parts of the simulator does not cause the entire surface when exposed to normal load crushing and embedding of these parts into each other, especially with different hardness of materials of parts of the joint simulator, which prevents the influence of the tangential load due to the greater captivity parts and reduces the accuracy of the measurements.

 Thus, the proposed differences ensure the achievement of a new technical effect - the approximation of laboratory research conditions to the real ones during operation of the joints due to the possibility of measuring the tangential stiffness of the joint and studying the dependence of tightness on the tangential stiffness while reducing the volumetric deformation of the test samples and reducing side gas leaks.

 A device for measuring contact deformations (see drawing) contains a housing made in the form of a sealed chamber 1, the tightness of which is ensured by a gasket 2. A hole 4 is made in the wall 3 of the chamber 1. The joint simulator is made of the first 5 and second 6 parts. The first part 5 of the joint simulator is hermetically installed in the hole 4 of the wall 3 by means of a gasket 7. In the first 5 part of the joint simulator, a hole 8 is made coaxially to the hole 4 of the wall 3. A tube 9 with an end provided with an end face 10 is coaxially installed in the hole 8 of the first part 5 of the joint simulator and the holes 4 of the wall 3, and the end face 10 forms a cavity 11 between the first part 5 and the flat surface of the second part 6 of the joint simulator. The free end of the tube 9 is placed in the cavity of the sealed chamber 1. The elastic element 12 is made in the form of a rigid bellows soldered into the cover 13, which is sealed by means of gaskets 14 on the nut 15. The elastic element 12 is mounted on the free end of the tube 9 with a sealed installation of the first part 5 of the joint simulator in the hole 4 of the wall 3 due to the compression forces of the bellows. The rod pusher 16 is made with a flat and mounted in the tube 9 with the possibility of reciprocating movement, and the flat 17 of the rod pusher 16 and the inner surface of the tube 9 is formed channel 17. The hollow body of the sensor 18 movements of the rod pusher 16 is made in the form of an elastic bellows 19, equipped with a cover 20 which, by means of a gasket 21, is hermetically fixed on the nut 15. The sealed cavity 22, thus formed, is communicated through the channel 17 with the cavity 11. The nut 15 by means of the sleeve 23 and the gasket 14 is hermetically installed on the tube 9 by means of a threaded connection 24. In the cavity 22, a sensing element 25 is rigidly mounted tightly connected to the recording device 26. The rod pusher 16 is placed in the cavity 22 of the housing of the displacement sensor 18 with the possibility of interaction with the sensing element 25, and the nut 28 and the spring 29, fixed on the nut 15, ensures the balance of the pusher 16. The second part 6 of the joint simulator is fixed in the pusher 30 by means of a bolt 31 with a nut 32. A loading device (not shown) is provided with a pusher 30 s the ability to create a shear force in a given direction to the second part 6 of the joint simulator. The fitting 33 and the locking element 34, equipped with a cover 35, a valve 36, provides a message to the cavity of the sealed chamber 1 through the channel 38, as well as the cavity 11 through the channel 39 and the hole 40 in the tube 9 with a pressure source (not shown) and with the atmosphere. The finger 41 of the press (not shown) through the bearing 43 mounted on the axis 42 creates a compressive force on the second part 6 of the joint simulator. On the first part 5 of the joint simulator, a sensor 44 of tangential displacements of the second part 6 of the joint simulator is installed. The sensor 44 is connected to a recording device 26.

 The device operates as follows. When assembling the device, the first part 5 of the joint simulator is hermetically sealed using a gasket 7 in the wall 3 of the chamber 1 so that the end of the pusher protrudes above the contact surface of this part of the simulator. Install the second part 6 of the simulator on it, which comes into contact with the rod pusher 16 and causes it to move by a certain amount, fixed by the recording device 26 and taken as the reference point. The cavity of the device chamber 1 and the cavity 11 are connected to the atmosphere by means of a fitting 33 and a locking member 32, and atmospheric pressure is established in them and in the cavity 22 of the housing of the sensor 18 for displacement of the rod follower 16. The sensor 44 is installed on the first part 5 with a touch with the second part 6 of the joint simulator, the initial reading is recorded by the recording device 26. The bearing 43 creates the necessary load on the joint simulator, and the joint is deformed in the normal direction, causing the rod follower 16 to move, which is sensitive an element 25 associated with the recording device 26. Create a shear load in the tangential direction by means of the pusher 30, while the joint is deformed in the normal and tang ntsialnom direction as the fixed sensor element 25 and the sensor 44, respectively associated with the recording device 26. This ensures measurement of contact deformation joint in the mutually perpendicular directions: the normal and tangential upon application of compressive and shear loads. The installation of the sensor 44 on the first part of the joint simulator 5 and the execution of the second part 6 with a flat contacting surface eliminates the error caused by volumetric deformation of the contacting parts of the joint simulator under the influence of loads on them.

 To measure the tightness during static application of loads create excessive pressure in the cavity 22 of the sealed displacement sensor 18 and in the sealed chamber 1 of the device. If there is a leak at the junction of parts 5 and 6 of the simulator, the differential pressure in the chamber 1 of the device and in the cavity 22 of the sensor 18 provides movement of the sensing element 25 relative to the stationary rod follower 16, proportional to the gas leak for a given period of time and recorded by the recording device 26.

 To measure the tightness in dynamic mode, a load of a certain amplitude, controlled by the sensor 44, which varies in direction and magnitude, is applied to the second part 6 of the joint simulator by means of a clip 30 for a given period of time. For a given period of time, the movement of the sensing element 25 is recorded by the device 26 and a value proportional to gas leakage through the test joint, contact deformation and wear of the contacting surfaces of the first 5 and second 6 parts of the joint simulator is determined. Create, by rotating the screw 34, in the cavities 22 and 11 atmospheric pressure and record the movement of the rod pusher 16 relative to the sensing element 25 by the recording device 26 and determine the value proportional to the leakage of the joint. The normal load is removed and the value of the residual contact deformation of the joint is determined by the amount of displacement of the rod follower fixed by the sensing element 25 connected to the device 26. The reading of the recording device 26 is compared with the initial value before the normal load is applied and a value proportional to wear in the mating zone of the first 5 and second 6 parts simulator interface. So carry out a study of the dependence of tightness and wear of the test samples on the applied normal and tangential loads.

 The proposed device for measuring contact deformations, the tightness of the joint and its wear allows a comprehensive study of tribosystems and sealing equipment on one device, providing improved accuracy compared to calculation methods and allowing us to investigate contact stiffness, the actual contact area and the dependence of tightness on contact stiffness in the test samples in conditions of complex stress-strain state and due to this increase the reliability of tribosystems and sealing fishing.

 In addition, the measurement of wear at a variable load allows you to diagnose a complex stress-strain state on the contact spots and on the basis of these data to determine the nature of friction processes in tribosystems or sealing units, which extends the functionality of the device.

Claims (1)

 1. A device for measuring contact deformations, comprising a housing made in the form of a sealed chamber with an opening in one of the walls, a joint simulator mounted on this wall and made of two parts, the first of which has a central hole coaxial with the wall opening, a tube, installed in the openings of the body wall and the first part of the simulator, and its end and both parts of the simulator form a cavity, a finger to create a loading force on the joint simulator, a rod pusher placed in the tube, an elastic element, ger metically mounted on the tube, made in the form of a rigid bellows and connecting the tube to the housing, a rod pusher displacement sensor, made in the form of a hollow sealed housing mounted on the free end of the tube with a sensing element fixed to it, a recording device connected to the sensing element, a pressure source and a locking member, characterized in that the second part of the joint simulator is solid and connected to the pusher of the loading device, the second part of the joint simulator is provided with tchikom tangential displacements placed on the first part of the simulator interface, wherein the surface of the second part of the simulator interface in the plane of the contact is flat, and the finger is mounted on an axle in a bearing interacting with a surface of the second part of the simulator interface.