RU170345U1 - DEVICE FOR MEASURING ELECTRIC RESISTANCE OF GRAPHITE CONTACTS - Google Patents

Abstract

The utility model relates to electrical engineering, in particular, can be used for incoming control of the electrical resistance of contacts made of carbon-based composite materials used in electromagnetic relays of railway automation. The objective of the proposed technical solution for a device for measuring the electrical resistance of graphite contacts is to increase the reliability of electromagnetic relays of the first class of reliability types NM, NMSh and REL. In the process of solving this problem, a technical result is achieved, which consists in providing the same conditions for clamping contact elements on the graphite contacts under study during their control and increasing the accuracy of measuring electrical resistance. The technical result is achieved by a device for measuring the electrical resistance of graphite contacts, characterized in that it includes a microohmmeter, a frame having three side walls, an upper, a middle shelf and a base, with a casing of pins with a pin attached to it, and an upper conductive point tip placed in the pins. , which serves to close the electrical circuit on the upper surface of the graphite contact, stage, for installing and fixing the graphite contact, with the lower current heater located in the table case ovodnym point tip serving for the electric circuit on the lower surface of the graphite contact, multi-link linkage mechanism serves to move in opposite directions of the upper and lower current conducting lugs point.

Description

The utility model relates to electrical engineering, in particular, can be used for incoming control of the electrical resistance of contacts made of carbon-based composite materials used in electromagnetic relays of railway automation.

A device for measuring the transition resistance of contacts, containing the power section of the circuit from a series-connected DC source and an ammeter and a measuring section of the circuit, consisting of a voltmeter, connected by contact springs to the contact terminals of the contacts of the product, characterized in that it is additionally introduced a current stabilizer and a switch, and the current stabilizer is connected in series to the current source, and the power and measuring sections of the circuit are connected to the terminals products through the switch and contact springs, while each of the springs has a separate connection to the power and measuring sections of the circuit. Patent for utility model (RU 39715 Application: 2004108731/22, 03.24.2004 G01R 27/08) The disadvantages of this device is that the device does not allow to determine the contact resistance.

The transient resistance of the relay contacts according to the specifications must comply with the following values:

- NMSh type relays for closing (front) no more than 0.25 Ohm, for opening (rear) no more than 0.03 Ohm,

- type H relays for closing (front) no more than 0.3 Ohm, for opening (rear) no more than 0.03 Ohm,

- 2C relay no more than 0.15 Ohm.

According to the value of electrical resistance, contacts refer to products having low resistance. Known devices for measuring low resistances, based on the use of the method of ammeter and voltmeter. (Pisarevsky E.A. Electrical Measurements and Instruments. Energy. 1970, p. 325). When measuring small resistances, additional errors arise due to the influence of the transition resistance at the connection points. To avoid this, the so-called Four wire connection method. Two pairs of wires are used: one pair of wires is supplied to the measured object and a given current is supplied, and the other pair is used to measure the voltage on the object, which is proportional to the current strength and the resistance of the object. The wires are connected to the terminals of the measured two-terminal device so that each of the current probes does not directly touch the voltage probe corresponding to it, and it turns out that the transition resistances at the contact points are not included in the measuring circuit. The use of two pairs of probes, current and potential, is the main technique for eliminating the influence of the resistances of the connecting wires and the transition resistances on the result of measurements of low resistances. This method is implemented by the IKS-15 microohmmeter.

The objective of the proposed technical solution for a device for measuring the electrical resistance of graphite contacts is to increase the reliability of electromagnetic relays of the first class of reliability types NM, NMSh and REL.

In the process of solving this problem, a technical result is achieved, which consists in providing the same conditions for clamping contact elements on the graphite contacts under study during their control and increasing the accuracy of measuring electrical resistance.

The technical result is achieved by a device for measuring the electrical resistance of graphite contacts, characterized in that it includes a microohmmeter, a frame having three side walls, an upper, middle shelf and a base, with a casing of pins with a pin attached to it, and an upper conductive point tip placed in the pins. , which serves to close the electrical circuit on the upper surface of the graphite contact, stage, for installing and fixing the graphite contact, with the lower current heater located in the table case ovodnym point tip serving for the electric circuit on the lower surface of the graphite contact, multi-link linkage mechanism serves to move in opposite directions of the upper and lower current conducting lugs point. In addition, the casing of the pintles is mounted on the upper shelf of the frame, made in the form of a flange, inside of which the pintle is placed, made in the form of a sleeve, the insulating cup of the upper conductive rod with the conductive point tip is located inside the pintle, the pinole is closed by a non-conductive fixed sleeve through which the rod passes, there is a compression spring between the insulating cup and the non-conductive fixed sleeve inside the pin, the upper conductive rod has a detachable fixed connection with the insulating glass and a movable connection with a non-conductive fixed sleeve, the upper conductive rod is isolated from the housing using an insulating cup and a non-conductive fixed sleeve, and a conductive point tip using a heat shrink tube, the pin is kinematically connected movably with a lever mechanism, the upper conductive rod passes through a non-conductive, fixed sleeve conductive point tip passes through the bottom of the insulating cup and pins, graphite contact, at the time of measurement about resistance, pressed to the table using pins, a conductive point tip, at the time of measuring electrical resistance, pressed to the upper surface of the graphite contact, using a spring installed inside the pins, the pressing force is 2.5-3.0 N, the casing is fixed on the middle shelf of the frame, made in the form of a flange, an insulating cup of the lower conductive rod with a conductive point tip is located inside the case, between the insulating cup and the inner surface of the table there are compression springs ment, moving the insulating glass rod and a clamping nut is limited, the lower current conducting rod isolated from table body via the movable insulating nozzle. the rod is kinematically movably connected to the lever mechanism, the graphite contact is fixed on the table using a cap mounted on the table case, the conductive point tip is pressed to the bottom surface of the graphite contact at the moment of electrical resistance measurement, using the lever mechanism rocker, the lever mechanism consists of the leading link, made in the form of a double-sided crank with a given angle of rotation, two connecting rods, and the upper connecting rod is kinematically connected with the double-sided thought fixed on the upper shelf, the free end of which is made in the form of a plug and kinematically connected to the pinole, the lower connecting rod is kinematically connected to a two-way rocker mounted on the middle shelf, the free end of which is made in the form of a plug and kinematically connected to the conductive rod, the link link the mechanism is made in the form of a shaft, mounted on two side walls of the frame, a double-sided crank is fixed on the shaft, at one end of the shaft, on the outside of the side wall of the frame, a handle for it is fixed about rotation, the upper and lower bilateral rocker arms are made in the form of flat springs, the elasticity of the upper rocker plate allows the pin to be pressed against the contact with a force of 20-25 N, and the elasticity of the lower rocker plate allows the conductive point tip of the lower contact surface to be pressed with a force of 1.5-2 , 0 N, resistance measurement is carried out with an IKS-5 Microohmmeter, while the current probes are connected one to the pins, and the second to the table, the potential voltage probes are connected one to the lower and the second to the upper conductive rods with conductive point tips.

The technical result, which consists in providing the same conditions for clamping the probes on the studied graphite contacts during their control, is achieved by the fact that the proposed device for a given angle of rotation of the crank allows you to get close in value of the pressure of the electrodes to the graphite contact. This mode of operation of the device is maintained during its long-term operation. The stability and uniformity of the positioning conditions of graphite contacts allows us to exclude from the obtained resistance results the influence of factors other than the internal electrical resistance of the contact, which improves the accuracy of measuring electrical resistance.

The proposed device for measuring the electrical resistance of the contacts of a carbon-based composite material is illustrated by drawings, where:

- in FIG. 1 - presents the housing of the device;

- in FIG. 2 - pinol assembly;

- in FIG. 3 - table assembly;

- in FIG. 4 - a device for measuring electrical resistance (shown lever mechanism).

A device for measuring electrical resistance contains a microohmmeter (not shown in FIG.), A housing 1 having three side walls 1.1, 1.2, 1.3, an upper 1.4, an average 1.5 shelves and a base 1.6. On the upper shelf 1.4, it is fixed by the casing 2 of the quill 3 and placed in the quill 3 by the upper conductive point tip 3.1. On the middle shelf 1.5 of the frame 1, a stage 4 is fixed with a lower conductive point tip 4.1 located in the case of the stage 4. On two side walls 1.1 and 1.3 and the upper flange 1.4 and the middle flange 1.5, a multi-link lever mechanism 5 is fixed. The casing 2 of the quill 3 is made in the form of a flange, the quill 3 made in the form of a sleeve is placed inside the flange. An insulating cup 3.2 of the upper conductive rod 3.3 with a conductive point tip 3.1 is located inside the pin 3, the pin 3 is closed by a non-conductive fixed sleeve 3.4, through which the rod 3.3 passes, between the insulating glass 3.2 and a non-conductive fixed sleeve 3.4 there is a compression spring 3.5. The upper conductive rod 3.3 has a detachable fixed connection with an insulating sleeve 3.2 and a movable connection with a non-conductive fixed sleeve 3.4. The conductive point tip 3.1 is insulated with a heat shrink tube (not shown in FIG.). The pin 3 is kinematically connected movably with the linkage 5. The casing of the table 4 is made in the form of a flange 4.1, the insulating cup 4.2 of the lower conductive rod 4.3 with the conductive point tip 4.4 is located inside, between the insulating cup 4.2 and the inner surface of the table 4 there are compression springs 4.5, the movement of the insulating cup and stem is limited by a clamping nut. The lower conductive rod 4.3 is kinematically movably connected to the linkage 5. The fixation of the graphite contact 4.6 on stage 4 is made using a cap 4.7 mounted on the table body. The lever mechanism 5 consists of a leading link 5.1, made in the form of a two-sided crank with a given angle of rotation, two connecting rods 5.2 and 5.3. The upper connecting rod 5.2 is kinematically connected with the two-way rocker 5.4, mounted on the upper shelf 1.4. The free end of the rocker arm 5.4 is made in the form of a fork and kinematically connected to the pinole 3, the lower connecting rod 5.3 is kinematically connected to the double-sided rocker arm 5.5, mounted on the middle shelf 1.5. The free end of the rocker arm 5.4 is made in the form of a plug and is kinematically connected to the lower conductive rod 4.3. The leading link 5.1 of the lever mechanism 5 is made in the form of a shaft, the shaft is mounted on two side walls of the housing 1.1 and 1.3, a double-sided crank 5.1 is fixed on the shaft, a handle 5.6 is fixed for turning it from the outer side of the side wall 1.3 of frame 1.

The proposed device operates as follows. The graphite contact is mounted on the table, centered by a cap. The resistance measurement is carried out with an IKS-5 Microohmmeter, while the current probes are connected one to the pins, and the second to the stage, the potential voltage probes are connected one to the bottom, and the second to the upper conductive rods with conductive point tips. After the device is ready for measurements, the crank of the lever mechanism is manually rotated, the pin presses the graphite contact to the surface of the table, and the point conductive tips come into contact with the upper and lower surfaces of the graphite contact. Measurement of electrical resistance. The graphite contact, at the time of measuring the electrical resistance, is pressed to the table using pinoli 3 with a force of 20-25 N. The upper conductive point tip 3.1, at the time of measuring the electrical resistance, is pressed to the surface of the graphite contact with a force of 2.5-3.0 N , the lower conductive point tip 4.4, at the time of measuring the electrical resistance, is pressed to the surface of the graphite contact with a force of 1.5-2.0 N.

A prototype was made, which is being tested at the Kamyshlovsky Electromechanical Plant.

Claims (17)

1. A device for measuring the electrical resistance of graphite contacts, characterized in that it includes a microohmmeter, a housing having three side walls, an upper, a middle shelf and a base, with a casing with pins attached to it, and an upper conductive point tip placed in the pins, serving to close the electrical circuit on the upper surface of the graphite contact, stage, for installing and fixing the graphite contact, with a lower conductive point tip located in the table case, A puddle of an electric circuit on the lower surface of the graphite contact, multi-link linkage mechanism serves to move in opposite directions of the upper and lower current conducting lugs point. 2. The device according to p. 1, characterized in that the casing is mounted on the upper shelf of the casing, made in the form of a flange, inside of which is placed a pin made in the form of a sleeve, an insulating glass of the upper conductive rod with a conductive point tip is located inside the pin, the pin is closed a non-conductive fixed sleeve through which the rod passes, a compression spring is located inside the quill between the insulating cup and a non-conductive fixed sleeve. 3. The device according to p. 2, characterized in that the upper conductive rod has a detachable fixed connection with an insulating cup and a movable connection with a non-conductive fixed sleeve. 4. The device according to claim 2, characterized in that the upper conductive rod is isolated from the housing using an insulating cup and a non-conductive fixed sleeve, and a conductive point tip using a heat shrink tube. 5. The device according to p. 1, characterized in that the pin is kinematically movably connected to the lever mechanism. 6. The device according to p. 2, characterized in that the upper conductive rod passes through a non-conductive fixed sleeve, and the conductive point tip passes through the bottom of the insulating cup and pins. 7. The device according to p. 1, characterized in that the graphite contact, at the time of measuring the electrical resistance, is pressed to the table with pins. 8. The device according to p. 2, characterized in that the conductive point tip, at the time of measuring the electrical resistance, is pressed against the upper surface of the graphite contact with a spring installed inside the pin, the pressing force is 2.5-3.0 N. 9. The device according to p. 1, characterized in that the casing of the table is mounted on the middle shelf of the casing, made in the form of a flange, inside the casing there is an insulating cup of the lower conductive rod with a conductive point tip, compression springs are located between the insulating cup and the inner surface of the table, moving the insulating cup and stem are limited by a clamping nut. 10. The device according to p. 9, characterized in that the lower conductive rod is isolated from the table body using a movable insulating cup. 11. The device according to p. 9, characterized in that the rod is kinematically movably connected to the lever mechanism. 12. The device according to p. 9, characterized in that the fixation of the graphite contact on the table is made using a cap mounted on the table. 13. The device according to p. 9, characterized in that the conductive point tip, at the time of measuring the electrical resistance, is pressed against the lower surface of the graphite contact using the rocker lever mechanism. 14. The device according to p. 1, characterized in that the linkage mechanism consists of a drive link made in the form of a double-sided crank with a given angle of rotation, two connecting rods, and the upper connecting rod kinematically connected with a two-way rocker mounted on the upper shelf, the free end of which is made in the form of a plug and kinematically connected to the pinole, the lower connecting rod is kinematically connected to a two-way rocker mounted on the middle shelf, the free end of which is made in the form of a plug and kinematically connected to the conductor with a flat stock. 15. The device according to p. 14, characterized in that the drive link of the linkage is made in the form of a shaft, is mounted on two side walls of the frame, a double-sided crank is fixed to the shaft, at one end of the shaft, on the outside of the side wall of the housing, a handle is fixed for it rotation. 16. The device according to p. 14, characterized in that the upper and lower two-way rocker arms are made in the form of flat springs, the elasticity of the upper rocker plate allows the pin to be pressed against the contact with a force of 20-25 N, and the elasticity of the lower rocker plate allows the conductive point tip of the lower contact surfaces with a force of 1.5-2.0 N. 17. The device according to p. 1, characterized in that the resistance measurement is carried out with an IKS-5 Microohmmeter, while the current probes are connected one to the pin, and the second to the table, the potential voltage probes are connected one to the lower and the second to the upper conductive rods with conductive point tips.

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