RU2335850C1 - Method of isolating channels of contact electrical communication and device of contact electrical communication to this effect - Google Patents

Abstract

FIELD: electrical engineering.

SUBSTANCE: electrical communication devices for launched bodies is used in transmission of metering information to recording hardware from pickups incorporated with the onboard equipment of launched shell dummies furnished with metering systems. The method of contact electrical communication channels isolation consists in that the current collector preset-length conductors, isolated one from the other, are arranged in the contact zone in the amount equal to the number of the electrical communication channels. The contact zone of the conducting elements is limited and a non-stationary mechanical contact is maintained between the conducting elements of the current collector and the conducting elements of the appropriate channel of the electrified unit electric circuit. The conducting elements of the current collector are spatially enclosed around the contact zone alternating in compliance with the channels numbers and are arranged in the plane with the direction of lines in it not aligned with the electrified unit travel trajectory. The conducting elements of the current collector of the appropriate channel number are interconnected by the communication line wires. The electrified unit is moved inside the current collector and, during this motion, the non-stationary mechanical contact is effected in the area limited by the conducting elements sizes.

EFFECT: higher reliability.

5 cl, 2 dwg

Description

The invention relates to the field of technology for providing transmission to the receiving node of an electrical signal from an electrified node in motion. A current collector is a device for removing electric current from a contact element during the movement of an electrified assembly (Polytechnical Dictionary. / Editorial: A.Yu. Ishlinsky (Ch. P 50 ed.) And others. - 3rd ed., Revised and additional . - M .: Soviet Encyclopedia, 1989. - P.536). The continuity of the operation of the electrical communication channel is ensured by this method of maintaining the sliding contact of the contact element of the moving unit with the current collector.

Contact electric communication devices with a moving body are used to transmit measurement information from sensors placed, for example, on rods thrown using pallets, to recording equipment (Impact dynamics. Transl. From English / Zukas J., Nicolae T., Swift X, F., et al. - Mir, 1985 .-- 296 p., Ill., Pp. 130 ... 132, Fig. 3.14 ... 3.17). In the specified device, when measuring, a method of separation of electric communication channels is implemented, in which a current collector in the form of a node with an appropriate number of channels is attached to the target by the number of electrically isolated elements made in the form of a tip and connected to recording equipment. Before the collision, fixed tips penetrated the metal contact plates located on the front end of the plastic tray and connected to strain gauges mounted on the rod. When throwing the rod fixed in a plastic pallet onto the current collector, the tip and the plate close the electric circuit and form the number of electrical communication channels corresponding to the number of elements with the tip. With rod throwing speeds of up to 1 km / s realized in a series of tests, the contact electrical connection of the sensors with the recording equipment existed for a time during which the sump moved approximately 100 mm.

A device for studying cutting processes is known (copyright certificate SU 1038080, B23B 25/06, 02/18/82, in which a sensor (accelerometer) is installed at the end of the processed sample. In this case, one of the output contacts of the sensor is electrically connected to a metal contact pin mounted on the said end face of the sample and electrically isolated from the housing, and the second to the housing of the sample. The sample is moved relative to the cutters by accelerating it in the barrel, equipped with cutters and a current collector fixed on the muzzle of the barrel. The current collector electrically isolated from the barrel is made in the form of a frame of insulating material with a copper foil fixed in it, folded in several layers. At the moment of contact with the foil, the electric circuit is closed. The resulting channel of contact electrical communication with the sensor located in the sample processed by the cutters, operates during the time of the contact of the cutters with the sample.

There is also a known method of testing with continuous registration of the parameters of the final ballistics of the missile bodies and the contact communication device that implements it (decision to grant a patent for an invention dated September 22, 2006 according to application No. 2005124568/28 (027637) dated August 02, 2005). In the known contact communication device, the current collector is a node that is fixed in front of the barrier, electrically connected to the wire of the electrical communication channel. The element of the device (conductor) during the operation of the device makes contact with the current collector. The contact area is a certain rectilinear contact zone on the surface of the current collector in the form of a straight line of limited width lying in a plane drawn through the trajectory of movement of the missile body. The minimum removal of the surface of the current collector facing the conductor from the said path is selected from the condition of preventing contact with the missile body. In the general case of motion when moving a missile body along the current collector, movement around the axis of symmetry (axis of rotation) of the missile body can also be realized. In this case, the contact area is realized on the surface of the current collector in the form of a certain helical line. The parameters of this line and the location on the surface of the current collector are not predetermined. The parameters depend on the speed of movement of the missile body, the geometric shape and linear dimensions of the current collector and conductor of a known contact communication device. The known method of testing provides for the possibility of organizing in the device of contact communication, at least two channels of electrical communication. The method includes an operation, namely, before throwing the body, its position in the throwing device is oriented in accordance with the location of the electrically-mounted current collector elements isolated from one another and fixed to the obstacle.

Known methods for separating contact electrical communication channels and current collectors do not, however, provide the technical task of maintaining continuous electrical communication with deep penetration of the missile bodies having the required weight and size characteristics into the barrier. Contact electrical communication, based on the use of metal contact plates fixed in a plastic pallet, modifying the mass and size characteristics of the missile bodies, has a significant impact on the course and result of the interaction of the missile body with the obstacle. This excludes the use of well-known solutions when conducting tests of throwing bodies with specified characteristics to determine the parameters of their final ballistics (parameters of the action of throwing bodies over an obstacle) both in the conditions of field tests and in the conditions of bench tests in the laboratory. The thrown body during functioning can make spatial (not rectilinear) movement or movement around an axis. Often implemented for bodies stabilized by rotation, is the option of rotation around the axis of symmetry. In known solutions, including a method of dividing the channels of contact electrical communication, significant is the uncertainty of the contact area of the elements of the contact device with the current collector. This reduces the reliability of maintaining multi-channel contact electrical communication in cases of tests of throwing bodies that implement difficult initial conditions for the interaction of bodies with obstacles: an inclined barrier, the presence of an angle of attack or nutation. This excludes or limits the possibility of implementing reliable multichannel communication for the most real and practicable cases of indirect motion of a missile body in the period of final ballistics. Basically, the time period for maintaining the closure mode of contact metal plates on the current collector in known solutions is determined not by the time of the final ballistics of the studied missile body, but by the absolute values of the geometric dimensions of the contact electrical communication devices in the longitudinal direction (spokes, knots with a tip). Therefore, an increase in throwing speed leads to a proportional decrease in this period.

The present invention is directed to maintaining multichannel electrical contact with a propelled body, including one rotating around an axis of symmetry, in the process of breaking through an obstacle and when a body penetrates an obstacle. Increases due to the provision of multichannel communication and the acquisition of data on the history of changes in the parameters of the process, the effectiveness of tests of throwing bodies for impact with the measurement of loads acting on bodies from the side of the obstacle, or other kinematic or power characteristics of the final ballistics of the body in the obstacle in cases that are realized during testing spatial movement of the body when it penetrates the barrier or when the barrier is broken. The reliability of obtaining the result is also ensured if it is necessary to register the penetration parameters from the beginning of the process to the complete stop of the body or the destruction of the barrier or body, since the required number of tests is reduced to obtain the necessary data about the implemented process or the materials used.

These results are achieved due to the fact that when implementing the method of separation of electric communication channels in the area of the contact of a given length, electrically isolated conductive elements of the current collector are installed in an amount equal to the number of electric communication channels, they limit the contact area of the conductive elements of the electrified assembly with the conductive elements of the current collector while the conductive elements of the current collector close spatially around the zone of realization and contact, alternate between each other in accordance with the channel numbers, set in a plane, the direction of the lines in which does not coincide with the direction of movement of the electrified node, the conductive elements of the current collector of the corresponding channel number are electrically connected to each other, carry out the movement of the electrified node inside the current collector, and when electrified node inside the current collector carry out non-stationary mechanical contact in the region limited by the size of the conductive elements of the current collector the receiver in the direction of movement of the electrified site, electrically isolated from one another the conductive elements of the electrical circuit of the electrified site in the area of contact in the direction that does not coincide with the lines in the plane of installation of the elements of the current collector.

The indicated results when implementing the method are achieved by using a contact electric communication device, including a current collector, electrically connected to the wire of the electric communication channel, and a conductor installed in the insulator, designed to limit the contact area and electrically connected to the corresponding communication channel in the electric circuit of the electrified node, while the current collector in the device is made in the form of a node consisting of at least two electrically insulated nnyh from each other and spatially closed elements mounted in a plane direction in which the lines does not coincide with the direction of movement of the electrified node, wherein the alternating elements corresponding to each channel are connected together with a corresponding channel of each wire telecommunications line.

The current collector in the device can be made in the form of a truncated cone, composed of ring-shaped electrically isolated elements from one another.

The elements of the current collector can be installed in a plane orthogonal to the direction of movement of the electrified site.

The elements of the current collector can be installed with the same step in the direction of movement of the electrified assembly, and contact area restriction elements are formed on the conductor, while the step of performing these elements on the conductor must coincide with the installation step of the elements of the current collector.

The invention is illustrated in the drawings, where

figure 1 shows the moment of operation of the contact electrical communication device when implementing the method of separation of channels of electrical contact;

figure 2 shows an embodiment of a contact electrical communication device.

The method of separation of contact electric communication channels consists in the fact that in the contact realization zone of a given length L, as shown in FIG. 1, the conductive elements of the current collector 1 are electrically isolated from one another in an amount equal to the number of electric communication channels, they provide a limitation of the contact area of the installed in the insulator 2 of the conductive elements 3 of the electrified node 4 with the conductive elements of the current collector 1 and during movement carry out non-stationary mechanical contact of the conductive elements of the current collector 1 with conductive elements 3 electrically isolated from one another of the corresponding channel of the electric circuit 6 of the electrified assembly. The conductive elements of the current collector 1 are closed spatially around the zone of contact, alternate with each other in accordance with the channel numbers and set in a plane, the direction of the lines in which does not coincide with the direction of movement V of the electrified node 4. The conductive elements of the current collector 1 of the corresponding channel number are electrically connected to each other by wires 5 communication lines of electric communication channels with a receiving unit. The electrified assembly 4 is moved inside the current collector, and when the electrified assembly moves inside the current collector, unsteady mechanical contact is made in the region l limited by the dimensions of the conductive elements of the current collector 1 along the path V of the electrified assembly, electrically isolated from one another in the insulator 2 of the conductive elements 3 of the electric circuit 6 electrified site 4 in the area of the contact L in the direction that does not coincide with the lines in the plane of the wire dyaschih elements 1 susceptor. An embodiment of a current collector in a contact electric communication device, shown in FIG. 2, is proposed to increase the efficiency of the device in testing the operation of throwing bodies equipped with measuring systems (electrified nodes) in difficult initial conditions for their interaction with targets 8. To one of the conductive elements 3 is connected a sensor, for example, an accelerometer 9, the sensitive axis of which is directed along the axis of the electrified assembly, and to another, an accelerometer 10, the sensitive axis of which, for example detecting orthogonal axis electrified node. The axial and lateral forces arising during the operation of the electrified assembly along the barrier at an angle to it will be recorded on separate channels of the electric communication line.

In a device for implementing the inventive method (see figure 2), the current collector can also be made in the form of a knot tapering in the direction of throwing the body, for example, a horn-shaped shape made up of conductive elements of the current collector 1 made of electrically conductive material, electrically isolated from one another made of dielectric elements 7, while alternating conductive elements of the current collector 1 through one are connected together with the corresponding wire 5 of the channel of the electric communication line. The horn-like shape of the current-receiving unit contributes to the reliability of maintaining contact between the elements 1 and 3 of the device in the final phase of the investigated processes. The installation of the conductive elements 1 of the current collector in a plane orthogonal to the path of movement of the electrified site, provides the ability to conduct conductive elements in a simple geometric form.

A possible embodiment of such a current-receiving unit may also be a truncated cone made of electrical insulating material, in the inner surface of which concentric electrically conductive elements of the current collector are mounted. The strength characteristics of the material of the dielectric elements 7 are selected as close as possible to the characteristics of the material from which the conductive elements of the current collector 1 are made. Observance of this condition creates the conditions for shockless, smoother contacting of the elements of the device during its operation. This, in turn, eliminates the possibility of creating conditions for shorting one of the conductive element 3 of the conductive elements of the current collector belonging to different channels. Materials, dimensions of the contacting elements and the shape of the current collector are selected in preliminary tests for a given speed range. In tests using accelerometry to record the parameters of the process of final (terminal) ballistics, the initial recorded parameter is the history of changes in the values of deceleration (negative acceleration) of the electrified site over the process time. The tests showed that in the absence of contact between elements 1 and 3 on any of the electrical communication channels of the device, the deceleration value is maintained at a constant level until the next change in value when contact is resumed. In the case of occurrence of mechanical, and consequently, electrical contacts between the conductive elements 1 belonging to different channels of the device’s electrical connection, an oscillatory process is observed in the electric circuit to reduce the charge accumulated by the large-scale capacity of the charge with a frequency determined by the parameters of the formed oscillatory circuit. To improve the reliability of obtaining registration with the absence of faults and contact breaks, the embodiment of the conductive elements 3 shown in FIG. 2 is used. For the presented embodiment with two electric communication channels, the conductive elements of the current collector 1, electrically connected to the wire 5 of one of the channels of the electric communication line, are installed with the same step b along the path of the electrified assembly, and elements of the contact area 11 are formed on the conductor 3, while the execution step elements 11 on the conductor 3 coincides with step b of the installation of conductive elements 1. Elements 11 are offset in space with respect to one another in the direction of the path of the per room electrified site 4, partially depicted in figure 2 by a dashed line. The magnitude of the offset and the magnitude of the step is determined by the number of channels of electrical communication. For the variant of figure 2 with two channels of electrical communication and the same dimensions of the elements 1 in the direction of the path of movement of the electrified node 4, the step value b is equal to twice the sum of the sizes of one conductive element 1 and one electrically insulating element 7. The offset value, respectively, is equal to half the step size b. The use of the current collector assembly in tests of throwing bodies increases the test efficiency when complicating the initial conditions for meeting bodies with obstacles by improving the conditions for contacting device elements, increasing the reliability of obtaining the result and reducing the number of experiments needed to obtain the required data on the change in the values of the parameters of the final ballistics in the process under study .

Claims (5)

1. The method of separation of channels of contact electrical communication for electrical connection of the electrical circuit of a moving electrified site with a receiving site, characterized in that the conductive elements of the current collector are installed electrically isolated from one another in an area equal to the number of channels of electrical connection, electrically isolated from one another, and the regions are limited contact electrically isolated conductors of an electrified assembly with conductive elements When moving an electrified assembly inside the current collector, non-stationary mechanical contact is made between the conductive elements of the current collector and the conductors of the corresponding channel of the electric circuit of the electrified assembly electrically isolated from each other in the region limited by the size of the conductive elements of the current collector along the path of the electrified assembly, while the conductive elements of the current collector are spatially closed elements closing spatial around the area of contact implementation, and is set in planes in the direction of the lines does not coincide with the path of movement of the electrified node. 2. A contact electrical communication device for electrically connecting an electrical circuit of a moving electrified assembly to a receiving assembly, including a current collector electrically connected to an electric communication channel wire and installed in the insulator, at least one conductor configured to limit the contact area and electrically connected to the corresponding communication channel in the electrical circuit of the electrified node, while the current collector is made in the form of a node consisting of at least of two electrically isolated from one another and spatially closed conductive elements installed in planes, the direction of the lines in which does not coincide with the trajectory of the electrified node, and the conductive elements of the current collector are made alternating, corresponding to each channel of electrical communication, and connected to the corresponding wire of each channel of the line electrical connection. 3. The device according to claim 2, characterized in that the current collector is made of a horn-shaped shape and is composed of annular, electrically conductive elements isolated from one another. 4. The device according to claim 2, characterized in that the conductive elements of the current collector are installed in planes orthogonal to the trajectory of the electrified site. 5. The device according to claim 2, characterized in that the conductive elements of the current collector are installed in increments along the path of movement of the electrified assembly, the elements installed on the conductor are configured to limit the contact area, and the step of installing these elements on the conductor is determined by the number of communication channels and matches with the installation step of the conductive elements of the current collector, and the contact limiting elements installed on the conductors of different channels are shifted one relative to the other in the direction of the path moving the electrified node.

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