SU868465A2 - Device for thermal shock testing of articles - Google Patents

Description

The invention relates to testing equipment, in particular to devices for testing products for thermal shock. g

A device for testing ^e- products for thermal shock containing heating elements, a bath with a refrigerant and a mechanism for moving a test sample from heating elements to a bath with a refrigerant fl].

The disadvantage of this device is the low accuracy of the tests.

By main auto No. 700820, there is known a device for testing products under thermal shock, comprising a heat chamber 15 and a cold chamber separating their heat-insulating wall with an opening, a container for accommodating products installed in the wall opening with the possibility of movement, a mechanism for moving the container, and a sealing system made in in the form of heat-insulating plugs mounted on opposite ends of the container, the thickness of which is equal to * 5 the thickness of the insulating wall [2].

The disadvantage of the device is the narrow functionality that does not allow creating additional 30 mechanical loads on the product during its heating and cooling.

The purpose of the invention is the expansion of functionality by creating additional mechanical loads on the product.

This goal is achieved by the fact that through holes are made in the wall of one of the chambers and in the plug located on the side of this chamber, and the device is equipped with a vibro-shock mechanism located outside the chamber and a reciprocating drive of the vibro-shock mechanism and a rod placed in these holes. one end installed on the container, and the vibration-shock mechanism interacts with the other end of the rod.

The drawing shows a diagram of the device.

The device comprises a heat chamber 1 and a cold chamber 2 formed by a thermally insulating wall 3 separating them with an opening 4, side walls 5 and 6, and upper and lower walls 7 and 8. In the opening 4, a container 9 is mounted for movement to accommodate test items 10. The system sealing the chambers 1 and 2 is made in the form of heat-insulating plugs 11 and 12, mounted on opposite ends of the container 9 and having a thickness equal to the thickness of the thermally insulating wall 3. In wall 5 or b one IE cameras 1 or 2, as well as in the plug 11 or 12, hosted from the side of this chamber (in the drawing, chamber 2 and tube 12; through holes 13 and 14 are made. Through tube 13 of tube 12 and into hole 14 in chamber wall 8, a pipe 15 is inserted connected to the core 16 of the electrodynamic vibro-shock mechanism 17, which is mounted on a platform 18 connected to a reciprocating drive 19 through a helical shaft 20 interacting via bevel gears 21 and 22 with an electric motor 23. Inside the tube 15, a rod 24 is placed, one end of which is connected to the coil 25 of the vibroshock mechanism, and the other end to a gripper 26 for mounting the test products 10.

The device operates as follows.

The test product 10 is fixed in the gripper 26 and placed in the container 9, which is installed in the middle position relative to the insulating wall -3, the heat-insulating plugs 11 and 12 protect the product 10 from heat and cold from chambers 1 and 2. Chamber 1 is heated, and chamber 2 cooled to predetermined temperatures. Turn on the motor 23 of the actuator 19 reciprocating movement ^ result. whereby the screw shaft 20 moves the container 9 into the heat chamber 1, where the product is heated, and at this moment the hole 4 is blocked by a heat-insulating plug 12, which prevents heat exchange between the chambers 1 and 2. When the product is heated to a predetermined temperature, the container 9 is moved to the cold chamber 2, and the plug 11 overlaps the opening 4. Thus exposing the product 10 to cyclic influence of positive and negative temperatures, it is simultaneously affected by vibration and shock loads created by the vibro-shock mechanism 1 7, which are created by transmitting powerful pulses of electric current through the coil 25 located in the electromagnetic field created by the core 16. When the container 9 is cycled from the chamber 1 to the chamber 2, the vibro-shock mechanism 17 is moved with it using the reciprocating drive 19 continuously acting on the product with 10 vibro-shock loads.

The device allows you to test products for thermal shock with simultaneous exposure to mechanical vibro-shock loads.

Claims (2)

(54) DEVICE FOR TESTING PRODUCTS The invention relates to a test technique, in particular, to devices for testing products for a thermal shock. A device for testing thermal shock products is known, which contains heating elements, a coolant bath and a mechanism for moving the test specimen from heating elements to a coolant bath. The disadvantage of the device is the low test accuracy. According to the main auth. No. 700820, a device for testing thermal shock products is known, comprising a heat chamber and a cold chamber, a thermal and eolating wall separating them with an opening, a container for placing products installed in a stackable opening, a container transfer mechanism, and a sealing system made thermally insulated plugs attached to opposite endosos of the container, the thickness of which is equal to the thickness of the thermally insulated wall 3. The drawback of the device is its narrow functionality, not allow to create an additional ON THERMAL SOUND mechanical loads on the product during its heating and cooling. The purpose of the invention is to expand the functionality by creating additional mechanical loads on the product. This goal is achieved by the fact that through the wall of one of the chambers and in the traffic jam placed on the side of this chamber, through holes are made, and the device is equipped with a vibro-impact mechanism placed outside the chamber and the reciprocating movement of the vibro-impact mechanism and rod located in these holes .and installed at one end in the container, and the vibro-impact mechanism interacts with the other end of the rod. The drawing shows a diagram of the device. The device contains a heat chamber 1 and a cold chamber 2 formed by a thermal insulation wall 3 separating them with an opening 4, side walls 5 and 6 and upper and lower walls 7 and 8. In the opening 4 the container 9 is mounted for moving the tested products 10 The sealing system Kcinep 1 and 2 is made in the form of thermal insulating plugs 11 and 12 mounted on opposite ends of the container 9 and having a thickness equal to the thickness of the thermal insulating wall 3. In the wall 5 or 6 of one of the chambers 1 or 2, as well as in the plug 11 or 12, posted from the side of this chamber (in the drawing, chamber 2 and plug 12; through holes 13 and 14 are made. A tube 15 is connected to the hole 13 of the plug 12 and the hole 15 connected to the core 16 of the electrodynamic vibro-impact mechanism 17, which is installed on platform 1b coupled to a reciprocating drive 19 through a screw shaft 20, interacting via bevel gears 21 and 22 with an electric motor 23. Inside tube 15 a rod 24 is stretched, one end of which is connected to the coil 25 of the vibro-impact mechanism and the otheran end with a gripper 26 for fastening the test articles 10. The device operates as follows. The test article lU is secured in the gripper 26 and placed in container 9, which is installed in an average position relative to the heat insulating wall -3, the thermal insulation plugs 11 and 12 protect the product 10 from heat and cold from chambers i, and 2. Camera 1 is heated, and the chamber 2 is cooled to the set temperature. The electromotor 23 of the actuator 19 is switched back and forward, as a result of which the screw shaft 20 moves the container 9 into the heat chamber 1, where the product heats up, and at this moment the hole 4 is crossed with a thermal insulation plug 12 preventing heat exchange between the chambers 1 and 2. when the product is heated to a predetermined temperature, the container 9 is moved to the cold chamber 2, and about 11 it closes the opening 4. In this way, the product 10 is cycled to positive and negative temperatures, simultaneously operate by vibration and shock loads created by the vibro-impact mechanism 17, which are created by passing powerful pulses of electric current through the coil 25 in the electromagnetic field created by the core 16. When the container 9 is cyclically moved from chamber 1 to chamber 2, the vibro-impact mechanism 17 moves together with it by means of the actuator 19 reciprocating movement, continuously impacting the product 10 by vibro-impact loads. The device allows for the testing of products for thermal shock with simultaneous exposure to mechanical vibro-impact loads. The invention The device for testing products for thermal shock on av.st. 700820, characterized in that in order to expand the functionality by creating additional mechanical loads on the product, through holes in the wall of one of the chambers and in the stopper placed on the side of this chamber, and the device is equipped with a vibro-impact mechanism placed outside the chamber and the translational movement of the vibro-impact mechanism and the rod located in the said holes and installed at one end in the container, and the vibro-impact mechanism interacts with the other end of the rod. Sources of information taken into account in the examination 1. Pisarenko GS, Rudenko V.N. Third chenko G.N. and others. The strength of materials at high temperatures. Kiev, Naukova Dumka, 1U66, p.550, fig.446. 2. USSR author's certificate number 700820, cl. G 01 N 3/60, 1977 (prototype) ..