RU130704U1 - STAND FOR RESEARCH OF THREADED COMPOUNDS FOR VIBRATION PULSE - Google Patents

Abstract

A stand for studying threaded joints for vibro-impulse action, comprising a base plate on which elastic tubular elements are placed filled with a working fluid, a movable mass mounted on elastic tubular elements, a plunger connected to cavities of elastic tubular elements, a power system and a hydrostatic device connected to cavities of elastic tubular elements and a power system, characterized in that it further comprises an electric motor with an eccentric on the shaft, which interacts with a lunge, and the movable mass is the attachment point of the tested threaded connection and consists of a movable plate, which is directly mounted on the elastic tubular elements, and an upper plate with a central hole for the threaded bolt; the plates of the attachment site are rigidly interconnected with the help of racks, while on the base plate an additional flange is rigidly fixed through the body, made with a central hole for the bolt and side holes through which the posts of the attachment site are passed with a gap; in addition, the stand is equipped with a strain gauge, which is designed to control the tightening force of the threaded connection and glued to the bolt of the threaded connection, and strain gauges for registering variable loads in the threaded connection, which are glued to the posts of the mount, in addition, the hydrostatic device is designed as a hydraulic accumulator with a controllable check valve.

Description

The utility model relates to test equipment, and more particularly, to equipment for creating variable loads by vibro-pulse hydraulic action, and can be used to study critical threaded joints experiencing variable loads in the aerospace, engineering, automotive and power engineering industries.

From the prior art, a stand for the study of bolted joints with controlled tightening is known (lab. Work in the discipline "Technological equipment of public catering enterprises", http://www.spbitrbetitop.narod/ru/l/lab.files/top41.2.swf) . The stand comprises a base plate on which a threaded connection fastening unit is mounted, and means for controlling the tightening force in the form of a dynamometer spring and indicator. The specified stand allows you to determine the tightening torque of the bolted connection and to evaluate the coefficient of friction in the thread and on the end of the nut with a single static loading. However, threaded joints in real conditions in most cases are subject to repeated vibration loads, and using a well-known stand it is impossible to create conditions that would allow testing threaded joints for dynamic variable loads.

One of the common causes of bolted joint damage is a reduction in the pre-tightening of the joint under dynamic loads. (Birger I.A., Iosilevich GB. Threaded and flange connections. - M.: Mechanical Engineering, - 1990 - 351 p.)

Known loading of samples with a variable load using weights on vibrating stands (Maksak V.I., Tskhai E.B. Study of the effect of multi-cycle loading of a threaded joint on radial deformation of a nut under static loading. -Electronic scientific journal "Investigated in Russia" .- 2009. - No. 118. - P.153 8-1544. - http // zhumal. Ape.relarn.ru/articles/2009/118.pdf.) The BC-68 vibrostand specified in the article is mass-produced and contains two imbalances that are due to changes masses of imbalances and the angle between them create table vibration.

The disadvantages of the VS-68 vibrostand are a small variable load and its energy consumption, because Testing of samples lasts up to 10 million cycles and above.

Widely known are hydraulic and electro-hydraulic vibrators described in the book of Baranov V.N. and Zakharov Yu.E. Electro-hydraulic and hydraulic vibration mechanisms.-M., Mechanical Engineering, 1977. - P.276-279.

The subject table of the described electro-hydraulic vibrating stands is rigidly connected to the piston rod of the hydraulic cylinder, which is controlled by a multi-edge spool. The piston feedback with the spool is carried out by an electromechanical converter. Based on this scheme in MVTU im. N.E.Bauman developed many electro-hydraulic vibrating stands for testing with a load of up to 200 kgf in the frequency range from 0-150 Hz.

Compared with the VS-68 vibration stand, hydraulic vibrators are favorably distinguished by increased specific power, small dimensions, reduced noise level, the ability to change the amplitude and frequency of vibrations. At the same time. they differ

structural complexity and require high precision performance of hydraulic elements.

Closest to the claimed utility model in terms of technical nature and the nature of the impact on the test object is a vibratory pulse source (patent for the invention No. 2244954, publ. 20.05.2008), designed to impact on the soil surface in

geophysics.

The specified device selected for the prototype contains a base plate, a movable mass placed on elastic tubular shells using clamps. The upper and lower elastic tubular shells are connected by their cavities to a hydrostatic generator, in turn, connected to a medium pressure source and a power system. The lower and upper elastic tubular shells are hydraulically connected to a plunger valve controlled by an electromagnet through a lock and a spring.

According to the prototype, a base plate with a moving mass, elastic tubular shells and clamps is installed on the surface of the soil. Working fluid from a medium pressure source is supplied to the elastic tubular shells. The power system is turned on, which drives the shaft of the hydrostatic generator. The latter excites an alternating volume in the upper and lower elastic tubular shells, while the latter changes the pressure relative to the average pressure in the system. The plunger spool is held in place by the lock in the middle position. Vibration source operates in a vibration mode.

At a fixed point in time, when the moving mass is in the upper position determined by the displacement sensor, a signal is sent from the control device to the electromagnet, which releases the plunger spool through the spring and the lock. In this case, the movable mass squeezes the working fluid from the lower cavity of the tubular shell into the plunger valve, which, shifting, squeezes the same volume of the working fluid into the upper cavity of the elastic tubular shell. The moving mass excites a pulse on the base plate. Then the whole cycle is repeated again.

The device according to the prototype provides an effective vibroimpulse effect (variable loads) on the soil by creating a shock action of the moving mass on the base plate and deformation of the elastic shells. However, this device is not suitable for multi-cycle testing of threaded connections.

The objective of the utility model is to use the advantages of the principle of the prototype to create a vibration pulse, simplify the device and provide tests with an increase in the variable load on the threaded connection

The technical result aimed at solving the problem is to create a multi-cycle variable axial load on the turns of the threaded joint caused by the deformation of the elastic element and to reduce the test time in comparison with the known devices.

The task and the technical result is achieved as follows.

Like the device of the prototype, the inventive stand for the study of threaded connections contains a base plate on which elastic tubular elements are placed, filled with a working fluid, a movable mass mounted on elastic tubular elements, a plunger associated with cavities of elastic tubular elements, a power system and a hydrostatic device connected to the cavities of the elastic tubular elements and the power system.

Unlike the prototype, the stand additionally contains an electric motor with an eccentric on the shaft with which the plunger interacts. The fastening unit of the tested threaded connection serves as a moving mass and consists of a movable plate directly mounted on elastic tubular elements, and an upper plate with a hole for a threaded bolt. The movable and upper plates of the attachment unit are rigidly interconnected by struts. The difference is that in addition to the base plate, a flange is made rigidly, through the housing, made with a central hole for the bolt and side holes through which the struts of the attachment node are passed with a gap. In addition, the stand according to the claimed utility model is equipped with strain gauges that are designed to control the variable forces of the threaded connection and are glued to the posts of the mount, and a strain gauge that serves to control the tightening force and glued to the bolt of the threaded connection.

As a hydrostatic device in the claimed invention, a hydraulic accumulator with a controlled check valve is used.

Unlike the prototype, the utility model does not contain upper elastic tubular shells, a displacement sensor, a latch, and an electromagnet, which simplifies the design of the stand.

Figure 1 shows a stand for the study of threaded connections, figure 2 is a diagram of the axial forces of the threaded connection during testing.

The stand for the study of threaded joints consists of an upper plate 1, a movable plate 3, connected by struts 2, which are the attachment point of the tested threaded connection. Samples of the threaded connection - nut 4 and bolt 5 are loaded with an axial tightening force using a flange 6, which has a force circuit with the base plate 7 through the housing 8. The whole system of the upper plate 1, racks 2 and the movable plate 3 is placed on the elastic tubular elements 9, the cavity which is filled with working fluid. The tightening torque of the threaded connection is carried out by tightening the nut 4, which is maintained at a predetermined level by the power supply system 12, the hydraulic accumulator 15 and is controlled by the strain gauge 13. The vibrational load of the threaded connection is carried out by a plunger pair 10 in combination with an eccentric 11 on the motor shaft. The additional pulsating force created by the deformation of the elastic tubular element 9 is controlled by strain gauges 14 glued to the posts 3 ..

The stand for the study of threaded joints works as follows. A threaded connection is established between the flange 6 and the upper plate 1 and tightened with a nut 4, for which the flange 6 is disconnected from the housing 8, and the movable plate 3 is disconnected from the posts 2 by unscrewing the screws 17. After installing the bolt 5, passed through the flange 6 and the upper plate 1 nut 4 is screwed onto it. Racks 2 are passed through flange 6, after which the movable plate 3 is attached to them. The assembled assembly is inserted and fastened in the housing 8. In this case, the movable plate 3 must lie on the elastic tubular elements 9. The cavities of the elastic tubular elements cops 9 are filled with working fluid from the power supply system 12 and are compressed by 15-20 percent of the outer diameter of the elastic tubular elements 9 by tightening the nut 4. The plunger pair extrudes the working fluid into the cavity of the elastic tubular elements 9, lifting the upper plate 1 through the posts 2 and the movable plate 3, creating a load on the threaded connection. Under the action of the elastic forces of the threaded connection, the upper plate 1, the struts 2 and the movable plate 3, the threaded connection is unloaded, displacing part of the working fluid into the hydraulic system. The threaded joint is loaded to the tightening force. Then the engine with the eccentric 11 is turned on and the plunger 10 displaces the fluid into the hydraulic system and the cavity of the elastic tubular elements 9, which, when filled, lift the movable plate 3, thereby creating additional force on the threaded connection (nut 4 and bolt 5).

To compensate for the volume of the working fluid associated with its leakage in the places of sealing of the elastic tubular elements, and to maintain the tightening force of the threaded connection, a hydraulic accumulator 15 with controllable check valves 16 is used.

The change in axial load is shown in Fig.2.

By changing the frequency of rotation of the electric motor, the magnitude of the eccentricity and the diameter of the plunger, it is possible to change the test parameters of the threaded connection, bringing them closer to the load parameters of real threaded connections.

Calculations show that using a high pressure sleeve with an inner diameter of 16 mm and an outer diameter of 29 mm with a metal braid and a length of 200 mm with a lateral deformation of 20% of the outer diameter as an elastic tubular element, the contact area with the movable plate 3 is 18 cm ² (9 mm × 200 mm). At an operating pressure of 180 kg / cm ^{2, the} generated force will be 3240 kgf, which is greater than the required force for testing the Ml 2 thread.

An experiment performed using a sample with an M12 × 1.5 thread showed high efficiency of the proposed device instead of the BC-68 mechanical vibration stand, reducing noise and power consumption. In addition, using the proposed utility model instead of a mechanical vibrating stand, it is easy to obtain the necessary variable axial load to simulate the operation of a real threaded joint. Using high-pressure hoses (elastic tubular elements) of various lengths and diameters of the plunger, the necessary variable loads can be selected when testing samples in a wide range of nominal diameters.

The introduction of the proposed utility model will increase the magnitude of variable loads and reduce energy costs for the study of threaded joints.

Claims (1)

A stand for studying threaded joints for vibro-impulse action, comprising a base plate on which elastic tubular elements are placed filled with a working fluid, a movable mass mounted on elastic tubular elements, a plunger connected to cavities of elastic tubular elements, a power system and a hydrostatic device connected to cavities of elastic tubular elements and a power system, characterized in that it further comprises an electric motor with an eccentric on the shaft, which interacts with a lunge, and the movable mass is the attachment point of the tested threaded connection and consists of a movable plate, which is directly mounted on the elastic tubular elements, and an upper plate with a central hole for the threaded bolt; the plates of the fastener are rigidly interconnected with the help of racks, while on the base plate an additional flange is rigidly fixed through the body, made with a central hole for the bolt and side holes through which the racks of the fastener are passed with a gap; in addition, the stand is equipped with a strain gauge, which is designed to control the tightening force of the threaded connection and glued to the bolt of the threaded connection, and strain gauges for registering variable loads in the threaded connection, which are glued to the posts of the mount, in addition, the hydrostatic device is designed as a hydraulic accumulator with a controllable check valve.

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