JPS63168929A - Switch mechanism employing lead switch - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to a switch mechanism using a reed switch.

[Conventional technology]

Conventionally, reed switches operate only when a predetermined magnetic force is applied, so when providing a holding circuit function, it is necessary to add a complex electric circuit such as a self-holding circuit using an electromagnetic relay or a flip-flop circuit. In addition, a special reed switch is used to provide a reed switch with a contact operation and a contact b operation.

[Problem that the invention seeks to solve]

According to conventional reed switches, as mentioned above, when using a reed switch to function as a holding circuit, a complicated electric circuit must be added, making the circuit complex and increasing costs. Another problem is that the type of reed switch must be changed in order to achieve a contact operation and a contact b operation with one reed switch.

In addition, since the sensitivity to magnetic force is not high, there is a problem that it does not respond to weak magnetic force.

[Means for solving problems]

The present invention was made in view of the above problems, and in a switch mechanism configured to switch a reed switch by the magnetic force of a magnet, one fixed magnet is provided on one side of the reed switch, and one fixed magnet is provided on the other side of the reed switch. two opposing rotating magnets are disposed within each other's magnetic fields, and means for rotationally driving the rotating magnets is provided, and the rotational driving means rotates the same polarities of the two rotating magnets in the same direction. , the reed switch is turned [ON] by the combined magnetic field of the fixed magnet and the two rotating magnets, and the same poles of the two rotating magnets are directed to the opposite direction by the rotation driving means. Therefore, a measure was taken to configure the reed switch to be turned OFF by a composite magnetic field of a fixed magnet and two rotating magnets.

[Effect]

In the switch mechanism using a reed switch according to the present invention, in the switch mechanism configured to switch the reed switch by the magnetic force of a magnet, one fixed magnet is provided in one example of the reed switch, and two fixed magnets are provided on the other side of the reed switch. arranging opposing rotating magnets so as to be located within each other's magnetic fields, providing means for rotationally driving the rotating magnets, and directing the same poles of the two rotating magnets in the same direction by the rotational driving means, The reed switch is switched to [○N] by the combined magnetic field of the fixed magnet and the two rotating magnets, and the same poles of the two rotating magnets are directed in the opposite direction to the direction and fixed by the rotation driving means. The reed switch (O
Since the structure is configured to switch to FFI, when the rotation driving means is not in operation, the two rotating magnets influence each other so that the same poles face in the same direction, and this state is stably maintained. At this time, for example, if the magnetic fields of the two rotating magnets and the magnetic fields of the stationary magnet cancel each other out at the sharp point, the reed switch will not be moved and will be stably maintained in the (OFF) state.

When the rotation drive means acts on the switch mechanism of the reed switch in the stable holding state to rotate one of the rotating magnets, the other rotating magnet located within the magnetic field of the rotating magnet is also rotated.

When the rotation driving means further acts to rotate the rotating magnet by 90 degrees or more and then stops acting, the two rotating magnets influence each other again so that the same poles point in the same direction. Since the direction is opposite to the above, the directions of the magnetic lines of force of the fixed magnet and the two rotating magnets match, and the reed switch is moved [ON].
and maintain that state stably.

Further, when the switch mechanism using the reed switch according to the present invention is operated by an external magnet, the two rotating magnets relay the magnetic field of the external magnet and transmit it to the reed switch.

〔Example〕

Below, the principle of a switch mechanism using a reed switch according to the present invention will be explained based on FIGS. 1, 2, and 3.

In FIGS. 1, 2, and 3, two rotating magnets are rotatably provided, and the N pole of a fixed magnet 1, for example, is fixed facing a reed switch 2. Among the rotating magnets, the one closer to the reed switch 2 is used as a switching magnet 3, and the other one is used as a holding and stabilizing magnet 4.

Here, when the operating magnet 5, which is an external magnet serving as a rotational drive means, is not close to each other, that is, when the operating magnet 5 is stable, the different poles of the two magnets always face each other. Switching magnet 3 is fixed magnet 1 and reed switch 2
Since the switching magnet 3 is installed slightly offset from the extension line of the reed switch 2, one of the magnetic poles of the switching magnet 3 is close to the reed switch 2 when the switching magnet 3 is stable as described above. For example, the N pole of the switching magnet 3 is connected to the reed switch 2.
If it is close to , the N-pole magnetic line of force of the fixed magnet 1 and the N-pole magnetic line of force of the switching magnet 3 repel within the reed switch 2, and the reed switch 2 turns OFF. For example, if the S pole of the switching magnet 3 is close to the reed switch 2, the lines of magnetic force of the fixed magnet l and the switching magnet 3 within the reed switch 2
The directions of the magnetic lines of force match and the reed switch 2 is turned on.
becomes.

The above-mentioned state of the reed switch 2 is stably maintained against external disturbances by attracting the different polarities of the switching magnet 3 and the holding and stabilizing magnet 4 to each other.

When the reed switch 2 is in the C0FF) state (Fig. 1), when the N pole of the operation magnet 5, which has a sufficiently strong magnetic force compared to the three magnets, approaches from the holding and stabilizing magnet 4 side, the switching magnet 3 is in a stable state. The S pole of the holding and stabilizing magnet 4 is attracted to the N pole of the operating magnet 5, and is rotated according to the movement of the operating magnet 5. When the operating magnet 5 approaches the switching magnet 3, (
(Fig. 2), since the N poles of the operation magnet 5 and the switching magnet 3 both face the direction of the reed switch 2, the reed switch 2 is moved against the magnetic force of the fixed magnet 1 (Fig. 2).
N). After that, when the operating magnet 5 passes near the switching magnet 3 (FIG. 3), the switching magnet 3 is rotated by 906 degrees or more, so when the operating magnet 5 leaves, the switching magnet 3 and the holding and stabilizing magnet 4 are separated. is rotated 180 degrees from the stable state shown in Figure 2, and the S pole of the switching magnet 3 is closer to the reed switch 2, so
Inside the reed switch 2, the directions of the magnetic lines of force of the fixed magnet 1 and the lines of magnetic force of the switching magnet 3 match, and the reed switch 2 is turned [ON], and this state is maintained. At this time, the reed switch 2 operates as an a-contact switch.

Continuing from this state, when the operating magnet 5 approaches from the switching magnet 3 side and passes near the holding and stabilizing magnet 4, the reed switch 2 changes from (ON) to (
OFF), and when the operating magnet 5 is removed, that state is maintained.

Next, when the reed switch 2 is [ON] and in a stable holding state, when the S pole of the operating magnet 5 approaches from the holding stable magnet 4 side, the switching magnet 3 and the holding stable magnet 4 move the operating magnet 5. When the operating magnet 5 passes near the switching magnet 3, the switching magnet 3
and the holding and stabilizing magnet 4 is 180 degrees from the holding stable state.
Since the N pole of the switching magnet 3 approaches the reed switch 2, the reed switch 2 is turned OFF.
), and that state is maintained.

At this time, the reed switch 2 operates as a b contact switch.

When in a stable holding state, the different polarities of the switching magnet 3 and the stabilizing holding magnet 4 attract each other, making it stable and less susceptible to external disturbances such as vibrations, making it difficult to malfunction.

Further, even when the magnetic force from the operating magnet 5 is weak, the switching magnet 3 and the holding and stabilizing magnet 4 relay the magnetic force of the operating magnet 5, so the sensitivity of the switch mechanism using the reed switch is good.

Furthermore, the reed switch 2 can also be operated by mechanically rotating the holding and stabilizing magnet 4 with an operating lever serving as a rotational drive means, so even without the operating magnet 5, the reed switch mechanism can be used as a limit switch. Applicable to

Further, by adjusting the installation interval between the switching magnet 3 and the holding and stabilizing magnet 4, the sensitivity of the switch mechanism using the reed switch can be adjusted.

Next, an embodiment in which a switch mechanism using a reed switch according to the present invention is applied to a liquid level switch will be described based on FIG. 4.

A liquid level switch 6 using a switch mechanism using a reed switch according to the present invention is fixed to the outer surface of a tank 7 made of a non-magnetic material, and includes a built-in magnet 8 for operating the liquid level switch 6 using the reed switch. A float 9 is floating on the liquid level on the inner surface of the tank 7.

The liquid level switch 6 using a reed switch is composed of a fixed magnet 1, a reed switch 2, a switching magnet 3, and a holding and stabilizing magnet 4. The N pole of the fixed magnet 1 faces the reed switch 2, and is used for operating the float 9. The north pole of the magnet 8 is set to face the liquid level switch 6 using a reed switch.

When the liquid level is at the Ll level, the reed switch 2 is turned ON due to the influence of the operating magnet 8 of the float 9, and when the liquid level rises above the Ll level (L2), the reed switch 2 is turned ON. The liquid level is maintained as it is, and the full water indicator light 11 of the liquid level display device 10 is turned on.

Next, when the liquid level falls and passes the level Ll (L3), the reed switch 2 is turned OFF, and the full water indicator light 11 of the liquid level display device 10 is turned off.

When the liquid level rises again and passes the level of Ll (L2)
, the reed switch 2 is turned on (ON), and the full water indicator light 11 of the liquid level display device 10 is lit again.

In addition, when the liquid level is sufficiently higher or lower than the Ll level, the operating magnet 8 is separated, so the switching magnet 3 and the holding and stabilizing magnet 4 attract each other and are stabilized in the current state. Therefore, the contacts of the reed switch 2 are not affected by slight vibrations and operate stably.

In addition, since the liquid level switch 6 using a reed switch according to the present invention is highly sensitive, the magnetic force from the operating magnet 8 may weaken due to deterioration of the operating magnet 8, or the magnetic force from the operating magnet 8 may be attenuated due to the thickness or material of the tank 7. The liquid level switch 6 operates stably even if the liquid level switch 6 changes.

Furthermore, since a reed switch is used, maintenance is easy and it can be used safely even in hazardous atmospheres such as flammable gases.

〔effect〕

The switch mechanism using a reed switch according to the present invention can hold a contact without an electric circuit such as a relay, and can function as an A contact or a B contact with the same switch. The mechanism has a simple structure and can be made at low cost.

In addition, when the switch mechanism using the reed switch according to the present invention is operated by an external magnet, the two rotating magnets relay the magnetic field of the external magnet and transmit it to the reed switch, so that the magnetic force is highly sensitive. , the operation is stable even when the magnetic force from the external magnet is weak.

Furthermore, the reed switch mechanism according to the present invention stabilizes the operation of the reed switch through the mutual influence of the switching magnet and the stabilizing holding magnet, thereby preventing malfunctions.

[Brief explanation of the drawing]

FIGS. 1, 2, and 3 are explanatory diagrams of a switch mechanism using a reed switch according to the present invention, and FIG. 4 shows an example of a liquid level switch using the switch mechanism using a reed switch according to the present invention. It is an explanatory diagram. 1...Fixed magnet, 2...Reed switch, 3
... Switching magnet, 4... Holding and stabilizing magnet, 5.8... Operation magnet, 7... Tank.

Claims (5)

[Claims] (1) In a switch mechanism configured to switch a reed switch by the magnetic force of a magnet, one fixed magnet is provided on one side of the reed switch, and two opposing rotating magnets are connected to each other on the other side of the reed switch. The rotating magnet is positioned within a magnetic field of The reed switch is turned [ON] by the combined magnetic field of the magnet, and the rotary drive means directs the same poles of the two rotating magnets in the opposite direction to the fixed magnet and the two rotating magnets.
A switch machine groove using a reed switch configured to turn the reed switch [OFF] by the combined magnetic field of two rotating magnets. (2) The fixed magnet is provided at one end of the reed switch in the axial direction of the lead wire of the reed switch, and the rotating magnet is slightly offset in the axial direction of the lead wire at the other end. A switch mechanism using a reed switch according to claim 1, wherein one of the rotating magnets is provided, and the other rotating magnet is provided opposite to the rotating magnet. (3) The fixed magnet is provided at one end of the reed switch at a position at a predetermined distance in the axial direction of the lead wire of the reed switch, and the fixed magnet is provided at a position at a predetermined distance in the axial direction of the lead wire at the other end. A switch mechanism using a Lee switch according to claim 1, wherein one of the rotating magnets is provided at a distance slightly shorter than the above distance, and the other rotating magnet is provided opposite to the rotating magnet. (4) A switch mechanism using a reed switch according to claim (1), wherein the rotational drive means is an operating magnet that acts on the rotational magnet. (5) A switch mechanism using a reed switch according to claim (1), wherein the rotation driving means is an operating lever that acts on the rotating magnet.