KR200209360Y1 - Radio frequency switch - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

RF (Radio Frequency) Switch

2. The technical problem the invention is trying to solve

The present invention can reduce the power consumption and heat generation, increase the reliability of vibration environment, reduce the chattering time, and easily share parts with latching switch. In providing.

3. Solution Solution

The present invention provides a housing, a fixed plate installed on an upper side of the housing, a first and second solenoids provided with a predetermined distance to the fixed plate to generate an electromagnetic force during power supply, and between the first and second solenoids. A permanent magnet installed at a lower side of the permanent magnet and a lower side of the first and second solenoids, the both ends of which are selectively contacted with the solenoid, a first leaf spring mounted on the lower surface of the seesaw, and First and second press pins which are axially movable from both ends of the first leaf spring and selectively pressed by the first leaf spring, and contact plates and contact plates provided at one end of each of the press pins. 12. An RF switch comprising an RF connector that is selectively contacted by a second switch, the RF switch comprising: Biases in the center between the solenoid to one side by a predetermined distance is the RF switch, one to maintain the constant contact of the seesaw installed to provide.

4. Important uses of the devise

It can be used as an RF switch of a high frequency transmission system requiring fast switching and light weight.

Description

RF Switch {RADIO FREQUENCY SWITCH}

The present invention relates to a radio frequency (RF) switch used in a high frequency transmission system, and more particularly to a fail-safe switch that can be used as a fail-safe switch by improving the latching switch.

In general, there are two kinds of radio frequency (RF) switches used in the microwave transmission system, a failsafe type switch and a latching type switch.

The fail-safe switch is a switch that maintains a normally NC contact while power is not applied, and maintains a normally open contact while power is applied, and a latching switch is only switched. It is a switch to maintain the contact by supplying pulse power.

Figure 1a and 1b is a configuration diagram showing a conventional fail-safe switch, as shown in the housing 10, the power supply terminal (10a, 10c) mounted on the upper end of the housing 10, and the housing A PCB assembly 20 installed inside the 10 and having a simple control circuit, and a solenoid 30 installed below the PCB assembly 20 to generate electromagnetic force when the power is supplied, and the solenoid 30 ) Is installed in the hollow so as to be movable in a hollow, and is moved by the press pole 31 of the metal material which moves downward by the electromagnetic force of the solenoid 302 and the press pole 31 according to the movement of the press pole 31. Seesaw 40 made of a metal that rotates about the coaxial 40a, a failsafe spring 50 provided on a spring support 50a to elastically support the other end of the seesaw 40, and the seesaw 40 The bottom of both ends of the) A first spring for elastically supporting the first press pin 60 and the second press pin 60 ', which are selectively pressed according to the rotation operation, and the first press pin 60 and the second press pin 60'. 70 and the second spring 70 ′ and attached to end portions of the first press pin 70 and the second press pin 70 ′ and are provided with an RF connector, that is, the common terminal 80 and the first terminal 81. Or a first contact plate 90 and a second contact plate 90 'electrically connecting the common terminal 80 and the second terminal 82 to each other.

Hereinafter, the operation of the conventional fail-safe switch described above will be described with reference to FIGS. 1A and 1B.

First, in the initial state, the second contact plate 90 ′ is in contact with the common terminal 80 and the second terminal 82. That is, the second press 60 'is pressed by pressing the other side (right side in the drawing) of the seesaw 40 by the elastic force of the fail-safe spring 50, which causes the second contact plate 90' to be a common terminal. It contacts the 80 and the 2nd terminal 82, and maintains NC (Normally Contact) contact.

In this state, when power is applied through the power supply terminals 10a and 10c, power is applied to the solenoid 30 through the PCB assembly 20 in which a simple control circuit for interfacing with the solenoid 30 is embedded. As a result, the solenoid 30 generates an electromagnetic force to push the press pole 31 downward.

The downwardly moved press pole 31 is rotated by pressing one side (left side in the drawing) of the seesaw 40, thereby pressing the first press pin 60, the first contact plate 90 is the RF connector Is connected to the common terminal 80 and the first terminal 81 to perform a normally open (NO) contact.

In such a state, when the power supplied to the solenoid 30 is cut off, the solenoid 30 does not generate an electromagnetic force, so that the fail-safe spring 50, which was compressed at the NO contact point, has the other side ( Right) to move the press pole 31 to its original position, and simultaneously push the second press pin 60 'to move the second contact plate 90' back to the common terminal 80 and the second connecting terminal. It contacts with (82) (NC contact), and maintains an initial state.

In this state, when the power is not applied, the common terminal 80 and the second connection terminal 82 always maintain the NC contact by the force of the fail-safe spring 50, and when the power is applied, the common terminal 80 and the 1 The connecting terminal 81 maintains the NO contact by the electromagnetic force generated by the solenoid 30.

In conclusion, the conventional fail-safe switch maintains the NC contact state by using the elastic force of the spring in the initial state when the power is not applied, but when the power is applied, the electromagnetic force is generated in the solenoid and is converted to the NO contact. It is implemented by returning to the initial contact state (NC contact state) by the elastic force of.

2A and 2B are diagrams illustrating a conventional latching switch. As shown therein, a housing 30, a power supply terminal 30a to 30c mounted on an upper end of the housing 30, and the housing ( 30 is installed inside the PCB assembly 31 having a simple control circuit, a magnet plate 32 attached to the lower side of the PCB assembly 31 at a predetermined distance, and the bottom surface of the magnet plate 32. First and second solenoids 33 and 33 'installed at both sides to generate electromagnetic force when the power is supplied, and fixed iron plates 34 fixed to ends of the first and second solenoids 33 and 33'. (34 '), the permanent magnet (35) provided between the first second solenoids (33, 33'), and the rotational shaft by the electromagnetic force of the first and second solenoids (33, 33 ') A seesaw 36 made of a metal material which is operated in a seesaw operation with reference to 36a), and is provided below both ends of the seesaw 36, and is provided by the seesaw 36. First and second press pins 37 and 37 'pressed against each other, and first and second springs 38 and 38' elastically supporting the first and second press pins 37 and 37 '. And an RF connector, that is, the common terminal 39 and the first connection terminal 40 or the common terminal 39 and the second connection, are attached to ends of the first and second press pins 37 and 37 '. It consists of first and second contact plates 42 and 42 ′ which electrically connect the terminals 41.

Hereinafter, the operation of the conventional latching switch as described above will be described with reference to FIGS. 2A and 2B.

First, the seesaw 36 is magnetized by the permanent magnet 35 so that both ends generate magnetic force of the S pole. In addition, the first and second solenoids 33 and 33 'are also magnetized so that the first and second fixed iron plates 34 and 34' at both ends generate magnetic poles of N poles.

At this time, the initial seesaw 36 assumes that one side (left side) is in contact with the first fixed iron plate 34 of the first solenoid 33.

In this state, the pulsed power is supplied through the power supply terminals 30a and 30c so that the S pole is generated in the first fixed iron plate 34 positioned below the first solenoid 33.

Then, since both ends of the seesaw 36 are also magnetized to the S pole, one side (left) of the seesaw 36 is pushed downward due to mutual repulsive force with respect to the same pole, so that the first press pin 37 One spring 38 is pushed downward while compressing. When the first press pin 37 is pushed, the first contact plate 42 attached to one end thereof contacts the common terminal 39 and the first connection terminal 40.

As described above, when one side (left) of the seesaw 36 is rotated downward, the other side (right) is moved upward to contact the second fixed iron plate 34 ′ of the second solenoid 33 ′.

At this time, since the other side (right side) of the seesaw 36 is magnetized to the S pole and the second fixed iron plate 34 'is magnetized to the N pole, an attractive force acts on the first solenoid 33. It maintains contact status even if power is not supplied.

Meanwhile, in order to reverse the seesaw rotation operation, the S pole is applied to the second fixed iron plate 34 'positioned below the second solenoid 36' by supplying power through the power input terminals 30b and 30c. To occur.

The subsequent operation is the same as the previously described operation. That is, the repulsive force acts on the other side of the second solenoid 33 'and the seesaw 36 so that the other side (right) of the seesaw 36 is pushed downward. As a result, the second press pin 37 ′ is pushed back so that the second contact plate 42 ′ contacts the common terminal 39 and the second terminal 41.

At this time, one side (left side) of the seesaw 36 is moved upward to touch the fixed iron plate 34 of the first solenoid 33, the attraction force to each other to continue to maintain the contact state.

As described above, the conventional fail-safe switch has to be continuously supplied with power in order to maintain the connection state between the common terminal and the first terminal, which leads to high power consumption and high heat generation rate, which may adversely affect other components. There was a problem.

In addition, there is a problem that the size of the product becomes larger and heavier because the number of windings of the solenoid must be increased in order to reduce the power consumption in accordance with the trend to save power.

In addition, if the seesaw and the press pole are made of a metal material and the contact operation of the seesaw and the press pole is repeatedly performed, the contact surface of the seesaw is formed. As a result, the dimensional change as much as being dug is caused by the contact plate connected to the press pin being pressed so small that the contact anxiety and the non-contact occur, thereby reducing the reliability of the switch.

In addition, since the force of the fail-safe spring and the voltage provided to the solenoid are proportional to each other, if the force of the fail-safe spring is increased to increase the force of maintaining the NC contact, the force of the fail-safe spring can be overcome at the NO contact point. As the electromagnetic force of the solenoid must be counted, the driving voltage increases and the current consumption increases. Therefore, in consideration of the required voltage and current of the user, the elastic force of the spring cannot be sufficiently hardened, so that the force for maintaining the NC contact becomes weak and thus there is a weak problem in the vibration environment.

In addition, when the contact plate is in contact with the RF connector, the chattering time is prolonged due to the influence of the failsafe spring, which is not suitable for a high frequency system requiring a fast switching operation.

Conventional fail-safe switch and latching switch has a problem that the cost reduction or productivity increase is not made because the parts are not shared with each other.

Accordingly, the present invention has been devised to solve the above problems, and in the RF switch, the magnet is moved by a predetermined distance to an arbitrary solenoid side and disposed by a magnetized seesaw and solenoid without fail-safe spring It is an object of the present invention to provide an RF switch that can serve as a fail-safe switch.

1A is a configuration diagram showing a state in which power is not applied in a conventional fail-safe switch;

1B is a configuration diagram showing a state in which power is applied in a conventional fail-safe switch;

2A is a configuration diagram showing a state in which a NO contact is maintained in a conventional latching switch.

2B is an operation explanatory diagram showing a state in which an NC contact is maintained in a conventional latching switch.

Figure 3a is a block diagram showing a state in which power is not applied to the fail-safe switch according to an embodiment of the present invention.

Figure 3b is a block diagram showing a state in which power is applied to the fail-safe switch according to an embodiment of the present invention.

Figure 4 is a block diagram showing a fail-safe switch according to another embodiment of the present invention.

* Explanation of symbols for main parts of the drawings

140, 141: first and second solenoid 150: permanent magnet

160: seesaw 170, 240: first and second leaf spring

180, 181: first and second press pins 200: common terminal

210: first connection terminal 220: second connection terminal

230, 231: first and second contact plates

The RF switch for achieving the object of the present invention, the housing, a fixed plate installed on the upper side of the housing, and the fixed plate is installed with a predetermined distance to the first and second solenoid to generate an electromagnetic force during power supply And a seesaw provided between the permanent magnet provided between the first and second solenoids, the lower side of the first and second solenoids so that both ends thereof selectively contact the solenoid, and the bottom surface of the seesaw. First and second press pins mounted to the first and second press pins which are axially moved from both ends of the first leaf spring and selectively pressed by the first leaf spring, and the press pins, respectively. RF switch comprising a contact plate installed at one end of the RF connector and an RF connector selectively contacted by the contact plate In, by installing biased to one side by a predetermined distance from the center of the permanent magnet between the two solenoid is configured to maintain constant contact of the seesaw.

The two solenoids are configured to generate magnetic forces of different polarities when the power is applied.

It is configured to install a second leaf spring on one side of the seesaw.

The second leaf spring is made of a nonmagnetic material.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention; 3A and 3B are exemplary views of one embodiment of the present invention, as shown therein, the housing 100; A power supply terminal (100a) (100b) mounted on an upper end of the housing (100); A PCB assembly (110) installed inside the housing (100) and having both ends fixed to first and second supports (120a) (120b) and having a simple control circuit therein; A fixing plate 130 installed at a lower side of the PCB assembly 110 and having both ends fixed to the first and second supports 120a and 120b, respectively; First and second solenoids 140 and 141 installed at the fixed plate 130 at a predetermined distance to generate an electromagnetic force during power supply; First and second fixed iron plates 140 'and 141' attached to the lower side of the first and second solenoids 140 and 141; A permanent magnet (150) installed between the first and second solenoids (140) (141) and slightly biased toward the second solenoid (141); A metal seesaw 160 installed between the lower sides of the first and second solenoids 140 and 141 to perform a seesaw operation around the pivot shaft 161; A first leaf spring (170) mounted on a lower surface of the seesaw (160) to rotate together with the seesaw (160); First and second press pins 180 which are installed to be movable in the axial direction from both ends of the first leaf spring 170 and selectively pressed by the contact according to the seesaw operation of the first leaf spring 170. 181; First and second springs (195) (196) for elastically supporting the first and second press pins (180, 181); Attached to end portions of the first and second press pins 180 and 181, an RF connector, that is, the common terminal 200 and the first connection terminal 210 or the common terminal 200 and the second connection terminal 220. And first and second contact plates 230, 231 selectively contacting.

In the present embodiment, the permanent magnet 150 is preferably located at a distance moved by 1/6 to 1/8 of the distance between the center axis of the seesaw and the solenoid.

Hereinafter, the operation of the fail-safe switch according to the present invention will be described with reference to FIGS. 3A and 3B.

First, the seesaw 160 is magnetized by the permanent magnet 150 so that both ends thereof have an S polarity. The first and second fixed iron plates 140 ′ and 141 ′ attached to the lower sides of the first and second solenoids 140 and 141 are magnetized to the N pole.

As such, when the power is not applied to the first and second solenoids 140 and 141, as shown in FIG. 3A, the permanent magnet 150 is more than the first solenoid 140 than the second solenoid 141. Since it is located closer to the side, the magnetic force of one side (right side of the drawing) of the seesaw 160 is stronger by the principle that the asymmetry of the magnetic force, that is, the strength of the magnetic force is inversely proportional to the square of the distance between the magnetic bodies. That is, since the attraction force between one side (right side in the drawing) and the second solenoid 141 of the seesaw 160 is stronger than the attraction force between the other side (left side in the drawing) and the first solenoid 140 of the seesaw 160 One side (right side in the drawing) of the 160 is in contact with the second solenoid 141 and the other side (left side in the drawing) of the seesaw 160 is rotated downward.

The first leaf spring 170 which is rotated together with the seesaw 160 pushes the first press pin 180 to move downward. Therefore, the first contact plate 230 installed at the end of the first press pin 180 is in contact with the common terminal 200 which is the RF connector and the first connection terminal 210 (NC contact).

Meanwhile, in the state as shown in FIG. 3A, power is applied to the first and second solenoids 140 and 141 to generate a magnetic pole of the S pole in the first solenoid 140 and to the second solenoid 141. Let N-pole magnetic force be generated. Then, the attraction force acts on the fixed iron plate 140 'of the first solenoid 140 and the other side (left) of the seesaw 160, and the fixed iron plate 141' of the second solenoid 141 and the seesaw 160 One side (right) is the repulsive force is actuated the seesaw 160 is rotated clockwise around the axis (161).

Accordingly, the first leaf spring 170 installed on the bottom surface of the seesaw 160 is also rotated together to press the second press pin 231 to move downward, and thus is installed at the end of the second press pin 181. The second contact plate 231 is in contact with the common terminal 200, which is an RF connector, and the second connection terminal 220 (NO contact).

On the other hand, when the power is cut off from the two solenoids 140 and 141 in the state as shown in FIG. 3b, the restoring force of the second spring 196 that has been contracted and the magnetization of the first and second fixed iron plates 140 'and 141' are reduced. By the change of the polarity, the seesaw 160 rotates counterclockwise again to maintain the state of FIG. 3A until power is applied again.

In this case, when the supplied power is cut off, the magnetic force on one side (right) is stronger than the magnetic force on the other side (left) of the seesaw 160, so that the return to the state as shown in FIG. Can be kept stable.

On the other hand, Figure 4 is a block diagram showing another embodiment of the RF switch according to the present invention, the second leaf spring 240 made of a non-magnetic material on the other side (left) of the seesaw 160 in contact with the first solenoid 140 If you installed by adding It is maintained in the NO contact by applying power in the embodiment of the present invention described above, the first fixed iron plate 140 'portion of the first solenoid 140 when the power is cut off is completely left without losing magnetic This is to prevent the case where the switch to the NC contact is delayed.

That is, the second plate spring 240 of the nonmagnetic material is installed on the other side (left side) of the seesaw 160 so as to be less affected by the remaining magnetic force so that the switch to the NC contact can be made quickly.

In conclusion, the fail-safe switch according to the present invention moves the permanent magnet from the center between the two solenoids to one side and maintains the NC contact state without the fail-safe spring by using an asymmetric magnetic force. By generating different magnetic forces, it converts to the NO contact point, and when the power is cut off again, it returns to the first contact state (NC contact point).

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge.

As described above, the RF switch according to the present invention is to maintain the NC contact state by the asymmetrical force of the magnetic force, supplying power to both solenoids to generate magnetic force of different polarity to the seesaw by the force of the magnetic force Because of the rotation, the switching operation can be performed at a lower voltage than the conventional one, and thus the heat generation rate is reduced.

And because it can act as a fail-safe switch without fail-safe spring, it reduces the chattering time, resists vibration environment, and improves the reliability of the contact state.

In addition, since parts common with the latching switch are easy, there is an effect of improving productivity.

Claims (5)

A housing, a fixed plate installed on an upper side of the housing, a first and second solenoids provided with a predetermined distance to the fixed plate and generating electromagnetic force during power supply, and installed between the first and second solenoids. A seesaw provided between the permanent magnet and a lower side of the first and second solenoids so that both ends thereof selectively contact the solenoid, a first leaf spring mounted on the bottom surface of the seesaw, and the first plate First and second press pins which are axially movable below both ends of the spring and selectively pressed by the first leaf spring, and selectively by the contact plate and the contact plate provided at one end of each of the press pins. In the RF switch comprising an RF connector in contact with, The permanent magnet is installed to be biased to one side by a predetermined distance from the center between the two solenoids to maintain a constant contact state of the seesaw. The method of claim 1, The two solenoids RF switch that generates magnetic force of different polarity when power is applied. The method of claim 1, RF switch is provided with a second leaf spring on one side of the seesaw The method of claim 3, wherein The second leaf spring is a non-magnetic RF switch. The method of claim 1, The permanent magnet is And an RF switch located at a distance moved by 1/6 to 1/8 of the distance between the central axis of the seesaw and the solenoid.