SU1647465A1 - Device for measuring electrization of dielectrics in vacuum and in cases - Google Patents

Abstract

The invention relates to electrical measuring equipment and is intended to measure the contact electrification of dielectrics under vacuum and gas conditions. The purpose of the invention is to expand the functionality of the device while improving the measurement accuracy. The device contains a rod 1, a housing 3, a crank mechanism 4, a connecting rod 5 and hinges 6, 7, electrode 17, a Farade cylinder 29, an electrometer 31, a test magnetic circuit, a magnetic relay 36 and part 37. with a spring 9, piston 10, mz (nitro p, vt bodies 11. pushbutton switch p 12 1yy, f d switch 13, il 14, prodlych, cut 15 in the wall of the rod 1, cantilever lug 16, high impedance insulator .8 with rod 19, cup 20, springs 21, plugs 22, electromagnetic stochs 23 with a working movable element 24 causes 25, electro unit 26, software electronic time relay 27, multi-contact relay 28. hard line 30, insulator 2 of screen 33 with a removable cover 34, holes 38 in the Farad cylinder 29. Executive relay 39 and program time relay 40 allow strict control and unification of the testing process samples when implementing an arbitrary version of the device operation program. 2 ill. No

Description

The invention relates to electrical engineering and is intended for measuring contact electrification of dielectrics in vacuum and gas.

The aim of the invention is to increase the accuracy of measurement and expand the functionality of the device.

In FIG. 1 and 2 schematically show a device.

The device consists of a hollow core 10 1. The length of which significantly exceeds its diameter. The rod 1 with the possibility of reciprocating motion is mounted in a cylindrical guide 2, which is fixedly attached to the body 3 of the device. The rod 1 is connected to the crank mechanism 4 by means of a complex connecting rod 5 and hinges 6 and 7.

The composite connecting rod 5 is equipped with a clamping unit 20 dynamometer, including a cylindrical, narrowed in the lower part of the glass 8 with a spring 9, which is rigidly attached to the upper part of the complex connecting rod 5, and a piston 10, which is connected with the lower part of the connecting rod 5 using a threaded connection Moreover, the piston 10 with its lower part freely enters the inner part of the cup 8, and the upper one is adjacent to its walls, forming a sliding surface of 30 NII.

The crank mechanism 4 is driven by an electric motor (not shown) and is equipped with a magnetic starter 11 and a push-button switch 12 Start, which 35 is outside the sealing space. The magnetic starter 11 is electrically connected to the limit switch 13 Stop mounted on the housing 3 of the device, while its control body 40 - rod 14 fixes the On position when the rod 1 is at bottom dead center.

The wall of the rod 1 has a longitudinal cutout 15 in the form of a narrow slit, into which the free end is inserted by a cantilevered protrusion 16, approximately 2/3 of the inner diameter of the rod 1, fixedly mounted on the guide body 2.

An autonomous unit is installed in the inner part of the rod 1 — a detachment accelerator, the group of elements of which includes a spherical electrode 17, coupled through a high-resistance insulator 18 to the rod 19, which is rigidly attached to the bottom of the stack — 55 to 20, located in the inner part of the rod 1 In the inner part of the cup 20, a spring 21 is placed, the upper part of which abuts against the bottom of the cup 20 (from the inside), and the bottom - into the plug 22, which has openings in the central part and is fastened in the shaft 1 by means of a threaded connection.

An electromagnetic stopper 23 is installed in the area of the cup 20 and on the outside of the rod 1, the working movable element 24 of which rests against the cylindrical part of the cup 20 through the holes in the wall of the rod under the action of the spring 25. The electromagnet 26 (the electromagnet 26 and the stopper 23 generally constitute a linear electromagnetic traction relay, the elements of which are spaced motionless in space) is mounted on the housing 3 of the device, and at such a height along a parallel vertical axis that the axis of the element 24 and the electromagnet 26 coincided when the rod 1 is in the bottom dead wheelbarrow (Fig. 1). The electromagnet 26 is electrically connected to the output of a software-electronic electronic time switch 27, the starting moment of which (fixing the start time of the exposure, i.e., contacting the electrode 17 with the sample 35) is synchronized with the moment of operation of the limit switch 13 and the drive of the electric motor (more precisely, the operation of the magnetic starter 11). The output of the time relay 27 is equipped with a multi-contact switching relay 28. A feature of the relay 28 is that it operates in a pulsed mode, i.e. when the starting control signal from the output of the time relay 27 is received at its input terminals, the executive relay is activated for a time of 2-3 s.

Opposite the bottom of the rod 1, a Faraday 29 cylinder is installed on the device’s body, which is electrically connected via a hard line 30 to the electrometer 31. The Faraday 29 cylinder is fixed by means of an insulator 32 to the bottom of the screen 33, which is equipped with a removable cover 34. The test sample 35 is mounted concentrically on the bottom of the Faraday cup 29 (mount not shown).

The minimum distance from the inner flat part of the Faraday cup 29 to the working lower part of the electrode 17 (its lower point) is determined with the sample 35 laid. In this case, the rod 1 is at the bottom dead center, the rod 19 is maximally extended from the inner part of the rod 1 (spring 21 is maximally compressed ), and the lower point of the electrode 17 only contacts the surface of the sample 35. Under these conditions, the spring 9 of the clamping unit is minimally compressed, i.e. the piston 10 in the inner part of the cup 8 is in its lowest position, which is achieved by adjusting the position of the piston 10 on the body of the lower part of the connecting rod 5 using a threaded connection.

On the outer side of the cylindrical wall of the cover 34 of the outer screen of the Faraday 29 cylinder, an electromagnetic relay 36 with a retractable contact is fixed. The actuating element 37 of the electromagnetic relay 36 is located at the horizontal center axis of the electrode 17 when it is at bottom dead center (Fig. 2B). The actuating element of the electromagnetic relay 36 is located concentrically with respect to the hole 38 made in the cylindrical wall of the Faraday cup 29.

The input terminals of the electromagnetic relay 36 are connected to the executive relay 39 (delay relay), which is controlled by a software time relay 40, the starting timing of which is synchronized with the moment of operation of the limit switch 13 and the moment of actuating the electric motor, more precisely the operation of the magnetic starter 11.

A feature of the actuating relay 39 is that it operates in a pulsed mode, i.e. when a start control signal is received at its input terminals from the time relay 40, the executive relay 39 remains in operation for a longer time, determined by a duration of several seconds, i.e. works with a delay.

The device operates as follows.

In the initial position (Fig. 2a), the rod 1 is at bottom dead center, the bottom point of the electrode 17 is at the greatest distance from the surface of the sample 35, since under the action of the spring 21, the rod 19 is maximally carried into the inner part of the rod 1, while the working part of the movable element 24 only rests on the outer cylindrical part of the glass 20, while not fixing its spatial position.

When pressed for 1-2 seconds with the push-button switch 12 Start (Fig. 1), which is located outside a vacuum or gas-filled enclosed space, the magnetic starter 11 is activated, an electric motor (not shown) starts to work and the crank pair (crank 4, connecting rod 5) is brought into action (starts to rotate clockwise).

The duration of pressing the switch 12 for a time of 1-2 s is determined by the inertia of the mechanical system, leading the rod 1 in the reciprocating motion. At the indicated time interval, the limit switch 13 is triggered (Fig. 26), since its control rod 14 is shifted along the arrow Νι. As a result, the contacts of the limit switch 13 are closed.

Under conditions that determine the movement of the rod 1 (Fig. 26) upward along the arrow Μι, the upper flat part of the cup 20 reaches the level of the cantilever protrusion 16, which is rigidly fixed to the device’s body, the spring 21 begins to compress and the rod 19, and therefore the electrode 17 extends out. When the rod 1 is near the top dead center (Fig. 26), and the upper part of the glass falls below the horizontal level of the element 24 of the electromagnetic stopper 23, the spatial position of the glass 20 is fixed under the action of the spring 25 (Fig. 1).

With further rotation of the crank 4 (Fig. 2c) at a time when the rod 1 is close to the bottom dead center, the working surface of the electrode 17 is brought into contact with the surface of the test sample 35. When the rod 1 reaches the bottom dead point (Fig. 2d), the force compression of the spring 9 of the clamping dynamometer unit (Fig. 1) determines the magnitude of the working pressure at the point of contact of the surfaces of the electrode 17 and the sample 35. The value of this pressure is pre-set by selecting the elasticity of the spring 9.

At the time when the rod 1 is at the bottom dead center (Fig. 2d), the limit switch 13 Stop is activated (its contacts open), i.e. its control - the rod 14 moves in the direction of arrow N2, since its movement is not impeded by the side of the cylindrical part of the rod 1. Therefore, the magnetic starter 11 is de-energized and the electric motor driving the system stops.

At the same time, starting magnetic block of the starter (Fig. 1) to the input terminals of the software time relay 27 and relay 40 start-up electrical signals are received, as a result of which time relays 27 and 40 are brought to the initial states of the time reference. The exposure time of both software time relays is pre-set on the time scale of the time relay so that the actuating relay 39, which actuates the electromagnetic relay 36, the controlled time relay 40 is activated earlier (exposure end) than the time relay 27.

A feature of relay 39 is that it operates in a delay mode, i.e. when a start control signal is received at its input terminals (from the time relay 40), the executive relay 39 is activated for a time of several seconds. For example, if the contact time of the electrode 17 with the sample 35 is set using the software time switch 27 (exposure time) for 3 minutes, then the shutter speed relay 40 is set to 2 min 30 s. This period also includes the operating time and relay 39 (delay time).

Thus, due to the sequence of these switching operations, the free end of the actuating element 37, controlled by the electromagnet of the relay 36, reaches the body of the electrode 17 and is in contact with it for several seconds (5 s is recommended), which is sufficient to redistribute the electric charge in the region of the double electric layer (in the contact metal-dielectric pair), as well as the redistribution of electric charge in the conductive parts as a whole.

After the exposure time has elapsed (the exposure time of the software relay 27), i.e. when the multi-contact actuating relay 28, installed at the output of the time relay 27, is triggered, two processes occur in the system.

In the first process, a power control pulse is applied to the input of the electromagnetic relay 26 (duration 1-2 s), as a result of which the stopper 23 is activated (its working element 24 moves along the arrow M ₂ (Fig. 2e). As a result, the spatial position of the glass 20 in the inner part of the rod 1 ceases to be fixed and it immediately rises upward under the action of the spring 21, entraining the rod 19 and, consequently, the electrode 17. As a result, the act of tearing off the working surface of the electrode 17 from the surface Sample 35.

The clamping unit (group of elements 8 10) in this case takes its initial position (Fig. 2e). As a result, the double electric layer in the contact area of the electrode 17 - sample 35 is destroyed, and since the electrode 17 is removed from the Faraday 29 cylinder (the work of moving is performed), its mirror charge is of the opposite sign and is recorded by the recorder of the electrometer 31.

In the second process, during the operation cycle of the electromagnetic relay 26, normally open Start contacts are closed, which is identical to the direct drive of the device manually. This is due to the operation of the multi-contact actuating relay 28 when using its autonomous normally open contact pair (not shown).

Due to the completion of these commutations, the magnetic starter 11 is triggered a second time, the actuator motor is rotated and the rod 1 starts to move towards the top dead center (Fig. 2e), and then returns to its original state (Fig. 2a).

Subsequent pressing of the start switch 12 allows the required number of times to repeat the act of tearing off the working surface of the electrode 17 from the surface of the sample 35. This operation can be automated by introducing a software device that controls the action of the Start button 12.

The advantage of the proposed device in comparison with the well-known is to expand the functionality while improving the accuracy of the measurements. This is achieved by implementing an asymmetric temporal sample testing program. First of all, it is possible to select the exposure time, i.e. contact time of the measuring electrode with the sample. This makes it possible to slowly lower the measuring electrode to the surface of the sample, which avoids sudden shifts and shocks (impacts), and therefore eliminates the risk of its destruction.

Fast, almost instantaneous detachment of the measuring electrode from the surface! First of all, the sample virtually eliminates the occurrence of the process of neutralizing the electric charge in the surface region of contact between the two phases of the substance. This is especially true for testing samples with a fleecy structure.

The use of the device also allows you to coordinate the exposure time with the moment and duration of the removal of electric charge to the ground before the act of separation. Thus, it becomes possible to strictly control and unify the process of testing samples when implementing an arbitrary version of the program of functioning of the device.

Claims (1)

Claim A device for measuring the electrification of dielectrics in vacuum and in gases, containing a holder of the test sample mounted on the base of the device’s body in the form of a shielded Faraday cup electrically connected to an electrometer, exciting static electricity, an electrode located above the sample on a rod coupled to a mechanical drive back - progressive movement, as well as switching block, the first output of which is connected via a time relay to an electromechanical actuator, whose element in the form of a contact rod is grounded and touches the exciting electrode in its 15 lowest position, characterized in that, in order to increase the accuracy and expand the functionality of the device, it additionally contains a detachment accelerator installed inside the hollow rod, the active element which, on the one hand, is connected to the exciting electrode via a rod through an insulator, and, on the other hand, is connected to the base of the rod through a hole through which a rod passes through a spring, while opposite to the top of the active element of the detachment accelerator in the direction of its vertical axis, a cantilever protrusion is fixedly fixed to the device body, which 10 with its loose end enters through the groove into the inner part of the hollow rod, an electromechanical stopper is installed on the body of the hollow rod to fix the active element through the hole the detachment accelerator in the lower position, the electromechanical stopper electromagnet is connected to the comm unit · a software time switch, and the surface excites electrode, inverted: to the studied sample, named tor form.