CN212113342U - Energy-saving bistable permanent magnet holding electromagnet - Google Patents

Abstract

The utility model discloses an energy-saving bistable permanent magnet keeping electromagnet, which comprises two fixed ferromagnetic poles and a disc-shaped permanent magnet; the two fixed ferromagnetic poles are coaxially fixed by a cylinder, both ends of which are respectively fixed with a cover plate, and the center of the cover plate is respectively provided with a guide hole which is coaxial with the cylinder; one guide shaft passes through the center of the permanent magnet and is fixed with the permanent magnet, two fixed ferromagnetic poles are arranged on two sides of the permanent magnet, and the guide shaft can freely slide between the guide holes of the two cover plates and output power; the two fixed ferromagnetic poles are wound with electromagnetic coils, pulse current is supplied to the coils, the fixed ferromagnetic poles generate magnetism and polarity change, and the permanent magnet can move from one fixed ferromagnetic pole to the other fixed ferromagnetic pole; after the current is reversed, the permanent magnet moves in the opposite direction and is attracted to the original fixed ferromagnetic pole; after the power is cut off, the permanent magnet keeps the adsorption position unchanged. The utility model discloses simple structure, the circular telegram time is extremely short, can keep suction after the outage, has greatly practiced thrift the electric energy and has reduced and generate heat.

Description

Energy-saving bistable permanent magnet holding electromagnet

Technical Field

The utility model belongs to the technical field of the electro-magnet, concretely relates to energy-saving bistable formula permanent magnetism keeps electro-magnet.

Background

Electromagnets are common driving elements in industrial production and daily life. Such as miniature relays, ac contactors, dc contactors, solenoid valves, electromagnetic locks, etc., all use electromagnets as driving elements. The electromagnet is reliable in operation and simple in structure, but has the following defects: (1) energy consumption: the driving electromagnet of one contactor is a small few watts, a large few hundred watts or more, and a plurality of contactors are arranged below one train carriage; in a factory workshop, the contactors in the whole row work, and the energy consumption of the contactors cannot be ignored. After the contactor, the relay and the electromagnetic valve act in place, the electromagnet is still electrified to keep the attraction force until the elements reset. Generally, when an electric appliance works on duty, the electromagnet is electrified all the time. (2) Heat generation: the large number of electric appliances in the low-pressure cabin under the motor vehicle compartment are in operation, so that the temperature in the compartment is high, the environmental temperature standard of the electric appliances has to be improved, and people are forced to select better and more expensive insulating materials and other materials, the price is increased, and the risk is increased. Some chemical valves do not allow the electromagnet to work at high temperature, so that the amount of copper wires is increased. (3) The loss is large: the electromagnet acts by means of magnetic force, power is cut off when the electromagnet is reset, the magnetic force disappears, a reset spring needs to be additionally arranged to ensure that the actuating mechanism is reliably reset, the electromagnet needs to additionally overcome the elastic force when the electromagnet is powered on, and loss is increased.

Disclosure of Invention

To the weak point among the prior art, the utility model provides an energy-saving bistable formula permanent magnetism keeps electro-magnet.

In order to achieve the above purpose, the utility model discloses technical scheme as follows:

an energy-saving bistable permanent magnet holding electromagnet comprises two fixed ferromagnetic poles and a permanent magnet, wherein the two fixed ferromagnetic poles are coaxially fixed by a cylinder, cover plates are fixed at two ends of the cylinder, and a guide hole is formed in the center of each cover plate and is coaxial with the cylinder; a guide shaft penetrates through the center of the permanent magnet and is fixed with the permanent magnet; the guide shaft passes through guide holes of cover plates at two ends of the cylinder and can freely slide and output power; the two fixed ferromagnetic poles are arranged at the two sides of the permanent magnet, the center of the two fixed ferromagnetic poles is provided with a hole, and a guide shaft fixed with the center of the permanent magnet penetrates through the hole; the two fixed ferromagnetic poles are respectively wound with electromagnetic coils, pulse current is supplied to the two electromagnetic coils, and the fixed ferromagnetic poles generate magnetism and polarity change, so that the permanent magnet moves from one fixed ferromagnetic pole to the other fixed ferromagnetic pole; continuously adsorbing the magnetic material on the next fixed ferromagnetic pole after power failure; when the current is reversed, the reverse movement process is generated and is absorbed on the previous fixed ferromagnetic pole.

The permanent magnet is disc-shaped.

The guide shaft adopts a nonmagnetic guide rod, and the guide rod moves along with the permanent magnet and is transmitted to a mechanism needing to act.

Has the advantages that: the utility model adopts the permanent magnet as the action element and is provided with the pulse electromagnetic coil; the permanent magnet is driven to move by instant electrification and moves from one stable position to another position, and the movement direction of the permanent magnet can be changed by changing the direction of the pulse current; after the power failure, the position after the action is kept unchanged by the attraction of the permanent magnet. No matter how long the holding time is after the action, the power is only switched on within one second, thereby greatly saving the electric energy and reducing the heat generation.

Drawings

Fig. 1 is a schematic structural view of the present invention;

fig. 2 is a schematic diagram of the permanent magnet of the present invention after moving to another fixed ferromagnetic pole.

Detailed Description

The present invention is described below with reference to specific examples. It will be understood by those skilled in the art that these examples are for illustrative purposes only and are not intended to limit the scope of the present invention in any way.

An energy-saving bistable permanent magnet keeper electromagnet, as shown in figure 1, comprises a disc-shaped permanent magnet 1 and two fixed ferromagnetic poles 2a, 2b, wherein the two fixed ferromagnetic poles 2a, 2b are coaxially fixed by a cylinder 5, cover plates 6 are fixed at two ends of the cylinder 5, the two fixed ferromagnetic poles 2a, 2b are respectively fixed with the cover plates 6 at two sides through three screws, and a central guide hole of the cover plate is coaxial with the cylinder 5; a guide shaft 3 penetrates through the center of the permanent magnet 1 and is fixed with the permanent magnet 1; the guide shaft 3 penetrates through guide holes of cover plates at two ends of the cylinder 5, can freely slide and outputs power; the two fixed ferromagnetic poles 2a and 2b are arranged at two sides of the permanent magnet, and the guide shaft 3 passes through the center of the permanent magnet and is not contacted with the two fixed ferromagnetic poles 2a and 2 b; the two fixed ferromagnetic poles 2a and 2b are respectively wound with electromagnetic coils, pulse current is supplied to the two electromagnetic coils 4a and 4b, the fixed ferromagnetic poles 2a and 2b generate magnetism and polarity change, and therefore the permanent magnet moves from one fixed ferromagnetic pole to the other fixed ferromagnetic pole; continuously adsorbing the magnetic material on the next fixed ferromagnetic pole after power failure; when the current is reversed, the reverse movement process is generated and is absorbed on the previous fixed ferromagnetic pole. Because the coil is electrified instantaneously, the number of turns and the resistance of the coil can be small, the diameter of the lead can be very small, and the coil cannot be burnt even if the resistance of the coil is several times smaller than that of a conventional electromagnet with the same attraction.

The guide shaft 3 adopts a nonmagnetic guide rod, the guide rod is fixedly connected with the permanent magnet 1, and the guide rod moves along with the permanent magnet and transmits power to a mechanism needing to act; the guide rod is also a guide piece, so that the permanent magnet can only move along the axis of the central holes of the two cover plates and cannot touch other parts.

The basic principle of the utility model is that: in operation, as shown in fig. 1, the permanent magnet attracts a right fixed ferromagnetic pole 2b, and an electromagnetic coil 4b is wound around the fixed ferromagnetic pole 2 b. When commutation is required, a pulse current is passed through the two electromagnetic coils 4a, 4b to cause the magnetic poles to change polarity: the right fixed ferromagnetic pole 2b is S pole and generates repulsion to the S pole of the permanent magnet 1, the left fixed ferromagnetic pole 2a is S pole and generates attraction to the N pole of the permanent magnet 1, and under the push-pull action, the permanent magnet 1 rapidly changes position and flies to the left fixed ferromagnetic pole 2a and firmly attracts; after the current is cut off, the permanent magnet 1 is still attracted to the back fixed ferromagnetic pole 2a and is not changed; even if the shock is applied to a certain vibration, the shock-proof rubber sheet will not be separated, and the state after the movement is shown in figure 2. In the same way, the current is reversed to generate a magnetic field with the polarity opposite to that of the permanent magnet 1, so that the permanent magnet 1 is separated from the fixed ferromagnetic pole 2a due to the repulsion of like poles; the opposite right fixed ferromagnetic pole 2b generates attraction magnetism to generate a reverse motion process, and the reset state of the attracted fixed ferromagnetic pole 2b is shown in fig. 1. The guide shaft 3 fixedly connected with the permanent magnet 1 also reciprocates linearly, and the guide shaft 3 transmits power to a mechanism needing to act.

Based on the utility model discloses a pulse drive circuit of research and development uses same permanent magnetism to keep electro-magnet and same drive circuit, can realize that the alternating current-direct current power is general, the general pulse electromagnet of high low-voltage to it is direct general with original traditional electro-magnet. This allows mass production and use of common pulse drive elements.

Claims (2)

1. An energy-saving bistable permanent magnet holding electromagnet is characterized in that: the permanent magnet generator comprises two fixed ferromagnetic poles and a disc-shaped permanent magnet, wherein the two fixed ferromagnetic poles are coaxially fixed by a cylinder with cover plates fixed at two ends, and a guide hole coaxial with the cylinder is formed in the center of each cover plate; a guide shaft penetrates through the center of the permanent magnet and is fixed with the permanent magnet; the guide shaft penetrates through the guide holes of the cover plates at the two ends of the cylinder, can freely slide and output power; two fixed ferromagnetic poles are arranged at two sides of the permanent magnet, and the center of the ferromagnetic pole is provided with a hole which can be penetrated by a guide shaft; the two fixed ferromagnetic poles are respectively wound with electromagnetic coils, pulse current is supplied to the two electromagnetic coils, the fixed ferromagnetic poles generate magnetism and polarity change, and the permanent magnet moves from one fixed ferromagnetic pole to the other fixed ferromagnetic pole by magnetic force; after the power is cut off, the permanent magnet is continuously adsorbed on the next fixed magnetic pole; when the current is reversed, the reverse movement process is generated and is absorbed on the previous fixed ferromagnetic pole.

2. An energy saving bistable permanent magnet keeper as claimed in claim 1 wherein said guide shaft is a nonmagnetic guide rod which moves with the permanent magnet and transfers power to the mechanism to be actuated.

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