KR19990060988A - Solenoid with sliding contact - Google Patents

Abstract

The present invention relates to a solenoid designed to allow a movable member moving by a magnetic field of an electromagnet to slide a fixed contact on a moving passage. By installing the first and second fixed contacts 40 and 41 at the front and rear ends of the cylindrical moving passage 50 integrally formed with the movable member 30, the movable member 30 opens the moving passage 50. Sliding and selectively coupled to the first fixed contact 40 or the second fixed contact (41).

Therefore, the present invention has the advantage that the solenoid can be easily used in compact electric devices or facilities by miniaturizing and reducing the weight.

Description

Solenoid with sliding contact

The present invention relates to a solenoid having a sliding contact, and more particularly, to a solenoid designed to allow a movable member moving by a magnetic field of an electromagnet to slide a fixed contact on a moving passage.

A solenoid is an electronic device that converts electrical energy into mechanical movement. It is composed of an electromagnet (a spiral coil wound around a hollow core) through a movable rod made of iron or steel at the center. When a current is passed through the coil, the result is a magnetic field that is attracted by a rod to move it. When the current stops, the rod is returned to its original position by a spring or other mechanism.

An example of the configuration of such a known solenoid is well shown in FIG. 1. An electromagnet 4 is formed in the case 2 of the nonmagnetic material, and the movable member 3 which is attracted by the magnetic force of the electromagnet 4 is coupled to the cylindrical passage 5 of the nonmagnetic case 2. The movable member 3 is a magnetic material that is attracted when a magnetic field is generated in the electromagnet and returns when the magnetic force is cut off. In addition, a micro switch SW2 is formed at the end of the movable member 3. The micro switch SW2 is composed of an NC fixed contact, a NO fixed contact, and a movable contact. The movable contact is coupled to the movable member 3 so that the movable member 3 is attracted to the NO fixed contact at the NC fixed contact. It slides. Similarly, when the movable member 3 is returned, the movable contact of the micro switch SW2 slides from the NO fixed contact to the NC fixed contact.

One side of the NC fixed contact is connected to a battery power supply BAT for supplying current to the coil of the electromagnet 4 and a solenoid operation switch SW1 is connected to the battery BAT in series. In addition, an operation indicator L1 is installed in parallel with the power line including the battery power BAT. One end of the electromagnet 4 coil is connected to the other side of the NC fixed contact, and the other end of the electromagnet coil is connected to the battery power source BAT.

In addition, one side of the NO fixed contact is connected to the battery power supply and the other side is connected to the current limiting resistor LR1 and the contact electronic relay coil K1. The current limiting resistor LR1 and the contact electronic relay K1 are connected in parallel with each other. The contact A of the contact electronic relay is connected in series with the operation indicator L1. The contact A of the electronic relay is a contact that operates when the relay coil is excited and is closed, and returns to open when the relay coil is demagnetized.

In addition, the freewheeling diodes D1 and D2 are connected in opposite directions to the power supply in parallel between both ends of the electromagnet coil 4 and the electromagnetic relay coil K1 to turn on and off the inductive load. Prevent the presence or absence of contact.

Therefore, when the solenoid operation switch SW1 is closed, the battery power BAT is transferred from one side of the NC fixed contact to the other side of the NC fixed contact, so that power is applied to the electromagnet coil. When power is applied to the electromagnet 4, a magnetic field is generated to attract the movable member 3, which is a magnetic body, and the movable contact coupled to the movable member 3 is coupled to the NO fixed contact. Therefore, the battery BAT power is transferred from one side of the NO fixed contact to the other through the movable contact and applied to the contact electronic relay K1 and the current limiting resistor LR1.

In addition, when power is applied to the electronic relay K1, the relay coil is excited to close the contact point A, which is interlocked with the coil, and the operation indicator L1 is turned on to display the operation state of the solenoid to the outside. On the other hand, the current of the battery BAT power applied to the current limiting resistor LR1 is changed to a small current by the resistance and is applied to the coil of the electromagnet 4, and a small magnetic force is generated in the electromagnet, resulting in the contact holding force of the movable member 3 Is kept.

As described above, the conventional solenoid has a problem in that the solenoid cannot be used in a dense electric apparatus or equipment because the solenoid has to be provided with a separate space for the micro switch in the inner space of the case.

Therefore, the present invention was devised to solve the above problems of the prior art, and an object of the present invention is to miniaturize and lighten the solenoid without changing the electrical characteristics of the solenoid.

In order to achieve the above object, the present invention constitutes a piston type of the movable member 30 sucked by the magnetic field of the electromagnet 20, and the cylindrical movable passage 50 integrally formed with the movable member 30. By installing the first and second fixed contacts 40 and 41 at the front and the rear ends, the movable member 30 slides the moving passage 50, so that the first fixed contact 40 or the second fixed contact 41 is located. And optionally). Here, the movable member 30 is not only attracted by the magnetic force of the electromagnet as a conductive magnetic material, but also coupled with the conductive fixed contacts 40 and 41 to conduct electricity.

Other objects and advantages of the invention will be described below and will be appreciated by the practice of the invention. Furthermore, the objects and advantages of the present invention can be realized by means and combinations indicated in the appended claims.

1 shows an internal structure and a connection circuit diagram of a conventional solenoid.

Figure 2 shows the internal structure and the connection circuit diagram for the solenoid of the present invention.

Explanation of symbols for the main parts of the drawings

10: solenoid body 20: electromagnet

30: movable member 40: first fixed contact

41: second fixed contact point 50: movement path

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In FIG. 2, an electromagnet 20 is positioned at the center of the non-magnetic solenoid body 10 and a cylindrical passage (cylindrical) is formed on one side of the body 10. The cylindrical moving passage 50 is coupled to the piston-type movable member 30, the movable member 30 is made of a conductive magnetic material that can be affected by magnetic force as well as conduct electricity.

In addition, a ring-shaped or engraved fixed contact is formed at both ends of the moving passage 50. The fixed contact near the electromagnet 20 is called the second fixed contact 41 and the opposite side of the first fixed contact 40. This is called. Here, the sculpture refers to the fragment formed of the conductor is formed in a shape recessed at a predetermined position of the moving passage (50).

The first fixed contact 40 is coupled to the electromagnet 20 via the NC terminal and the NO terminal of the electronic relay K1, and the second fixed contact 41 is the electronic relay coil K1 and the current limiting resistor LR1. It is coupled to the electromagnet 20 via). The current limiting resistor LR1 and the electronic relay coil K1 are connected in parallel with each other. In addition, an operation indicator L1 is connected to the NO terminal of the electronic relay K1 in series. The movable terminal is connected to the NC terminal in the state in which the electronic relay coil K1 is elemental, but is connected to the NO terminal when excited.

In addition, the movable member 30 is connected to the battery power source BAT via the solenoid operation switch SW1.

Therefore, when the solenoid operation switch SW1 is closed, the battery power BAT is applied to the electromagnet 20 via the movable member 30 via the first fixed contact 40 and the NC terminal of the electronic relay K1. . When power is applied to the electromagnet 20, magnetic force is generated to attract the movable member 30, which is a magnetic body, and the movable member 30 moves toward the electromagnet 20 to be coupled to the second fixed contact 41.

Therefore, the current passing through the movable member 30 is applied to the current limiting resistor LR1 and the electronic relay coil K1 through the second fixed contact 41. When power is applied to the electronic relay K1, the relay coil is excited and the movable terminal linked with the coil is moved from the NC terminal to be connected to the NO terminal.

In this way, when the movable terminal is connected to the NO terminal, the operation indicator L1 is turned on to indicate that the solenoid is operating externally. On the other hand, the current of the battery BAT power applied to the current limiting resistor LR1 is changed to a small current by the resistance and is applied to the coil of the electromagnet 4, and a small magnetic force is generated in the electromagnet, resulting in the contact holding force of the movable member 3 Is kept.

The present invention is not limited to the above-described embodiments, and various modifications and variations are made by those skilled in the art to which the present invention pertains without departing from the spirit and scope of the appended claims. Of course it is possible.

As described above, the present invention has an advantage that the solenoid can be made compact and lightweight so that it can be easily used even in dense electric devices or facilities.

Claims (4)

The movable member 30 which is attracted by the magnetic field of the electromagnet 20 is formed in a piston shape, and the first and the first ends of the conductive material are respectively formed at the front and rear ends of the cylindrical moving passage 50 integrally formed with the movable member 30. And second movable contacts 40 and 41 to allow the movable member 30 to slide the moving passage 50 to be selectively coupled to the first fixed contact 40 or the second fixed contact 41. A solenoid having sliding contacts. The method of claim 1, The movable member (30) is a solenoid having a sliding contact, characterized in that it is not only attracted by the magnetic force of the electromagnet as a conductive magnetic material, but also conducts electricity in combination with the conductive fixed contact. The method of claim 2, Solenoid having a sliding contact, characterized in that the cylindrical moving passage 50 is a non-magnetic insulator. The method according to claim 2 or 3, The first and second fixed contact point (40 and 41) is a solenoid having a sliding contact, characterized in that installed in the form of any one of the ring-shaped or sculpture on the cylindrical moving passage (50).