RU176196U1 - ELECTROMAGNET - Google Patents

Abstract

The utility model relates to the technique of converting electrical energy into mechanical energy and can be used in electrical engineering to create discrete control drives — gates, gate valves, valves, etc., operating as part of objects that have a local on-board power supply system, are saturated with electronic control devices and have long period of operation with long periods of storage. The electromagnet contains a housing, a coil located in it, a retractable anchor, a rod, a sleeve and a return mechanism, the sleeve being installed along the axis of the coil, and a retractable anchor located inside the coil with the possibility of moving along its axis and connected to the rod and return mechanism installed in the sleeve , two groups of diodes, a cover, a pusher, an annular stop, a cylindrical nut with a flange, a flywheel and a locking mechanism, while the diodes in the groups are connected in parallel, the first group of diodes is connected in parallel with the coil, the second group of diodes is connected in series with the coil and counter to the first group of diodes, the cover is mounted on the opposite end of the housing, the pusher is mounted in the cover with the possibility of its longitudinal movement and has a thread on its part protruding beyond the cover, the ring stop is mounted on the cover so that the flange a cylindrical nut is located between the cover and the annular stop, and the inner surface of the cylindrical nut with a flange and the threaded surface of the pusher form a helical pair, and the cylindrical nut a flange rigidly connected to the flywheel, on which the locking mechanism. The return mechanism of the retractor armature is made in the form of a cylindrical spring mounted on the rod between the sleeve and the retractor armature. The locking mechanism includes a lever, an axis and a spring-loaded stop, while the lever is mounted on an axis connected to the flywheel and mates with a stop mounted to move in the hole of the cylindrical nut with a flange, and the lid has a blind hole in diameter of the stop. The technical result is the elimination of electromagnetic interference in the wiring network during switching of the electromagnet coil and the possibility of forced (mechanical) movement of the armature with the rod to increase the reliability of operation of the electromagnet.

Description

The utility model relates to techniques for converting electrical energy into mechanical energy and can be used in electrical engineering to create discrete control drives — gates, gate valves, valves, etc., operating as part of objects that have a local on-board power supply system, are saturated with electronic control devices and have a long period of operation with long periods of storage, including at low temperatures, in unheated rooms, under a canopy or tarpaulin, at which x provide a periodic (eg, semi-annual or annual) maintenance. Such objects may include modern, equipped with electronic devices, seasonal vessels, as well as tracked and wheeled vehicles.

Currently, a large number of actuators with electromagnets are known.

The electromagnet is known according to the USSR author's certificate for invention No. 1614040 (application 4625224 with priority dated November 30, 1988), IPC Н01F 7/16, publ. 12/15/1990

The electromagnet contains a core on which the control coil is located, and a movable armature. A through hole is made in the core in which the armature is moved. When voltage is applied to the control coil, the electromagnetic force generated by the magnetic flux of the coil draws the anchor into the core hole. The disadvantage of the described device is the occurrence of a voltage pulse at the terminals of the coil when the control voltage is removed, which can disable the coil when it is insufficient due to the difficult operating conditions of the electric strength, and also lead to damage to various electronic devices of the object due to the occurrence of reverse polarity pulses in the object wiring, amplitude which can significantly - 2-3 times - exceed the rated voltage of the electrical system. In addition, products of corrosion and wear of the armature and core, as well as grease thickened as a result of long-term storage or exposure to low temperatures, located in the gap between the inner surface of the core and the armature, increase friction during operation of the device and can lead to jamming of the armature in the core, which will lead to the failure of the device when you try to use it after prolonged storage, or when you turn on the product at low temperatures. The specified set of disadvantages does not allow the use of the device in question as a part of objects saturated with electronic control devices, used and subjected to long-term storage in difficult conditions, including when exposed to low temperatures.

The electromagnet has a similar drawback for working in the product under conditions of high environmental pressure according to the RF patent for invention No. 2381583 (application 2008127603 with priority dated 07.07.2008), IPC H01F 7/06, publ. 02/10/2010

The device comprises a housing with a spring-loaded anchor, a coil, a casing and coil lead-out wires installed therein. The anchor of the electromagnet is rigidly connected to the rod passing through the through central hole of the housing between the rod and the housing. The stem head is supported by a spring, a compressed nut, while the stem head, spring and nut are placed in the open end cavity of the housing. In the device in question, no measures were taken to suppress the impulse voltages arising from the switching of the electromagnet coil, while it is possible to jam the armature and rod due to thickening of the lubricant and clogging of the gap between the body and the rod due to long-term storage and exposure to low temperatures. The device does not provide measures for the forced movement of the armature with the rod during the maintenance of the product and when it starts after storage.

Closest to the claimed device is an electromagnet according to the patent of the Russian Federation for utility model No. 102 (application 93035886 with priority dated July 12, 1993), IPC H01F 7/16, publ. 10/25/1994 g. (Prototype).

The electromagnet contains a magnetic casing, a passage flange, a coil, a retractor anchor, a rod moving in supports located with a gap, while the rod is rigidly connected to the anchor. For reliable operation of the device, the gap between the supports is filled with grease. In the device under consideration, when the electromagnet coil is switched over, pulsed voltages occur, while it is possible to jam the armature and rod in the supports due to thickening of the lubricant due to long-term storage and exposure to low temperatures, as well as clogging of the gap between the rod and supports by the particles of the developed material. The device does not provide for the forced movement of the armature with the rod during maintenance of the product and when it starts after storage.

These shortcomings are the cause of the unreliability of the device.

The objective of the utility model is to ensure reliable operation of the electromagnet during its operation and after long-term storage as part of objects saturated with electronic control devices that are used and subjected to long-term storage in difficult conditions, including when exposed to low temperatures.

The problem is solved due to the fact that the electromagnet contains a housing, a coil located in it, a retractable anchor, a rod, a sleeve and a return mechanism, while the sleeve is installed in the housing along the axis of the coil, and the retractable anchor is located inside the coil with the possibility of its movement along its axis and is connected with a rod and a return mechanism installed in the sleeve, it has two groups of diodes, a cover, a pusher, an annular stop, a cylindrical nut with a flange, a flywheel and a locking mechanism, while the diodes in the groups are connected in parallel, the first PP diodes are connected parallel to the coil, the second group of diodes is connected in series with the coil and counter to the first group of diodes, the cover is mounted on the opposite end of the housing (magnetic circuit), the pusher is mounted in the cover with the possibility of longitudinal movement and has a thread on it protruding beyond the cover parts, an annular stop is mounted on the cover so that the flange of the cylindrical nut is located between the cover and the annular stop, with the inner surface of the cylindrical nut with the flange and zbovaya follower surface form a screw pair and a cylindrical nut with a flange rigidly connected to the flywheel, on which the locking mechanism.

The return mechanism of the retractor armature can be made in the form of a cylindrical spring mounted on the rod between the sleeve and the retractor armature.

The locking mechanism may include a lever, an axis and a spring-loaded stop, while the lever is mounted on an axis connected to the flywheel and mates with a stop mounted to move in the hole of the cylindrical nut with a flange, and the lid has a blind hole in diameter of the stop.

The proposed design eliminates the occurrence of electromagnetic interference in the wiring network during switching of the electromagnet coil and allows for forced (mechanical) movement of the armature with the rod, which significantly increases the reliability of operation of the device. Forced movement of the armature with the rod can be carried out periodically during operation or when it is first turned on after a long break.

The design of the device is shown in the drawing.

The electromagnet contains a housing 1, a coil 2 located therein, a retractor anchor 3, a rod 4, a sleeve 5 and a return mechanism 6, while the sleeve 5 is mounted in the housing 1 along the axis of the coil 2, and the retractor anchor 3 is located inside the coil 2 with the possibility of its movement along its axis and connected to the rod 4 installed in the sleeve 5 and the return mechanism 6. In addition, there are two groups of diodes 7 and 8, a cover 9, a pusher 10, an annular stop 11, a cylindrical nut with a flange 12, a flywheel 13 and a locking mechanism 14 moreover, the diodes in groups 7 and 8 are connected in parallel t Thus, their conclusions of the same name are combined. The first group of diodes 7 is connected parallel to the coil 2, the second group of diodes 8 is connected in series with the coil 2 and counter to the first group of diodes 7. The cover 9 is mounted on the opposite sleeve 5 of the end face of the housing 1, the pusher 10 is installed in the cover 9 with the possibility of its longitudinal movement and has a thread on its part protruding beyond the cover 9, an annular stop 11 is mounted on the cover 9 so that the flange of the cylindrical nut 12 is located between the cover 9 and the annular stop 11, and the inner surface of the cylindrical nut with a flange 12 and the threaded surface of the pusher 10 form a screw pair, and a cylindrical nut with a flange 12 is rigidly connected to the flywheel 13, on which the locking mechanism is mounted 14. In the electromagnet, the return mechanism 6 is made in the form of a cylindrical spring 17, which is mounted on the rod 4. B in turn, the rod 4 is placed between the sleeve 5 and the retractable armature 3. The locking mechanism 14 of the flywheel 13 may have an arbitrary design. In the device, the locking mechanism 14 consists of a lever 15, an axis 16 and a stop 18 spring-loaded by a cylindrical spring 17. The lever 15 is mounted on an axis 16 connected to the flywheel 13 and mates with a stop 18 that can be moved in the hole of the cylindrical nut with a flange 12, and in the cover 9 there is a blind hole 19 along the diameter of the stop 18.

The electromagnet operates as follows.

When voltage is applied to the coil of coil 2, a magnetic flux is created, under the influence of which the armature 3 is drawn into the coil 2 and gives the rod 4 translational motion. The rod end 4 protruding from the sleeve 5, when moving, drives the actuator coupled to the rod 4. The actuator is not shown in the figure and may be any valve, diaphragm, electrical contacts, etc. When the current supply to the coil 2 is stopped under the action of the return mechanism 6 in the form of a cylindrical spring 17 working in compression, the retractor armature 3 and the associated rod 4 return to their original position, which leads to the return to the initial position of the actuator connected to the rod 4 . In this case, the self-induction voltage appears at the terminals of the coil 2. If a positive potential arises on the first terminal 20 of coil 2 with respect to the second terminal 21, then the diodes of the assembly 7 open and a current pulse passes through them, as a result of which the pulse interference does not enter the on-board network. If a negative potential arises at the first terminal 20 of the coil 2 with respect to the second terminal 21, the diodes of the assembly 8 prevent its penetration into the onboard network.

During routine maintenance of the electromagnet or before its first switching on after long-term storage, manual “scrolling” of the device is performed. To do this, press the end of the lever 15 protruding beyond the flywheel 13 in the direction of arrow A. At the same time, the lever 15 rotates on the axis 16 and presses the stop 18 with its upper end in the figure, the end of which leaves the blind hole 19. After that, rotate the flywheel 13, while the cylindrical nut associated with it with the flange 12 also rotates. The threaded part of the cylindrical nut with the flange 12 acts on the screw part of the pusher 10, ensuring its axial movement. In this case, the axial movement of the cylindrical nut with the flange 12 is impossible, because its flange is located between the cover 9 and the annular stop 11. The pusher 10 acts on the spring-loaded anchor 3, which moves together with the rod 4. Rotating the flywheel 13 in the clockwise and counterclockwise directions, the armature 3 and the rod 4 are axially swung. A significant reduction in effort on the flywheel 13 when it is rotated indicates that the armature 3 and the rod 4 can freely, without jamming, move in the axial direction and the device is ready for operation. This ensures that the electromagnet is reliably triggered when voltage is applied to the coil 2. After this, the flywheel 13 is turned into a position that pushes the pusher 10 into the cylindrical nut with the flange 12 and the stop 18 enters the blind hole 19, while the end of the stop 18 is subjected to a cylindrical spring 17 enters the hole 19 and the flywheel 13 is locked.

When implementing an electromagnet, the following technical solutions can be used. The housing 1, the retractable anchor 3, the sleeve 5, the cover 9, the pusher 10, the ring stop 11 and the flywheel 13 are made of structural steel using turning operations. Coil 2 is wound on the frame with a copper wire of the PEL, LDPE, etc. grade, followed by impregnation with varnishes FL-98, ML-92, GF-95. The rod 4 and a cylindrical nut with a flange 12 to reduce their friction with the mating parts are made of bronze also using turning operations. The return mechanism 6 can be made in the form of a cylindrical spring mounted on the rod between the sleeve 5 and the retractor arm 3. For diode groups 7 and 8, silicon diodes are selected. The specific brand of diodes is determined based on the voltage and current in the circuit of the electromagnet. When implementing the device, good results were obtained using silicon diodes D237I. In the given specific embodiment of the inventive electromagnet, the locking mechanism 14 of the flywheel 13 includes a lever 15, an axis 16 and a stop 18 spring-loaded with a cylindrical spring 17, while the lever 15 is mounted on an axis 16 connected to the flywheel 13 and mated with a stop 18 mounted to move in the hole of a cylindrical nut with a flange 12, and in the cover 9 there is a blind hole 19 along the diameter of the stop 18.

The pilot operation of the electromagnet as part of military equipment, including during its long-term storage in unheated rooms and under a canopy, confirmed the reliability of the device during operation and during the preparation of products for use after removing the equipment from long-term storage.

Thus, the proposed design of the electromagnet eliminates the occurrence of electromagnetic interference in the wiring network during switching of the electromagnet coil and allows for forced (mechanical) movement of the armature with the rod, which significantly increases the reliability of operation of the device. Forced movement of the armature with the rod can be carried out periodically during operation or when it is first turned on after a long break.

Claims (3)

1. An electromagnet comprising a housing, a coil located therein, a retractor armature, a rod, a hub and a return mechanism, the hub being mounted in the housing along the axis of the coil, and a retractable armature located inside the coil with the possibility of its movement along its axis and connected to the sleeve with a rod and a return mechanism, characterized in that it additionally contains two groups of diodes, a cover, a pusher, an annular stop, a cylindrical nut with a flange, a flywheel and a locking mechanism, while the diodes in the groups are connected in parallel, the first PP diodes are connected parallel to the coil, the second group of diodes is connected in series with the coil and counter to the first group of diodes, the cover is mounted on the opposite end of the housing, the pusher is mounted in the cover with the possibility of its longitudinal movement and has a thread on its protruding ring part the stop is mounted on the cover in such a way that the flange of the cylindrical nut is located between the cover and the annular stop, with the inner surface of the cylindrical nut with the flange and the threaded surface st pusher form a screw pair and a cylindrical nut with a flange rigidly connected to the flywheel, on which the locking mechanism. 2. The electromagnet under item 1, characterized in that the return mechanism of the retractor armature is made in the form of a cylindrical spring mounted on a rod between the sleeve and the retractor armature. 3. The electromagnet according to claim 1, characterized in that the locking mechanism includes a lever, an axis and a spring-loaded stop, the lever being mounted on an axis connected to the flywheel and mating with a stop mounted to move a cylindrical nut with a flange in the hole, and there is a blind hole in the cover along the diameter of the stop.

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