JP5982266B2 - Solenoid device - Google Patents

Description

  The present invention relates to a solenoid device having a plurality of electromagnetic coils and a plurality of plungers.

  2. Description of the Related Art Conventionally, a solenoid device having an electromagnetic coil that generates a magnetic flux when energized, a plurality of plungers, and a fixed core made of a soft magnetic material is known (see Patent Document 1 below).

  This solenoid device is configured to generate a magnetic force by energizing an electromagnetic coil and attract a plunger to a fixed core. A spring member is arranged between the plunger and the fixed core. When energization of the electromagnetic coil is stopped, the magnetic force is reduced, and the plunger is separated from the fixed core by the elastic force of the spring member. In this way, the plunger is moved back and forth. The solenoid device is used, for example, to open and close a switch and open and close a valve by an advance / retreat operation of a plunger.

  The solenoid device has two modes of use: a mode in which each plunger is individually sucked into the fixed core in a predetermined order (individual suction mode) and a mode in which a plurality of plungers are simultaneously sucked into the fixed core (simultaneous suction mode). Some have The individual suction mode is used, for example, when inspecting whether or not a switch that has been turned off is welded by sequentially turning on the individual switches and checking whether or not a current flows through the circuit. In addition, the simultaneous suction mode is used, for example, when power is supplied to an electrical device through a switch by simultaneously turning on a plurality of switches.

  In order to be able to execute these two use modes, the solenoid device includes a plurality of electromagnetic coils. And each plunger is arrange | positioned in the center of each electromagnetic coil. In the individual suction mode, each plunger is sucked separately by energizing each electromagnetic coil individually in a predetermined order. In the simultaneous suction mode, each plunger is simultaneously sucked by simultaneously energizing a plurality of electromagnetic coils.

JP 2005-222871 A

  However, the solenoid device has a problem in that the power consumption of the electromagnetic coil is large because it is necessary to energize a plurality of electromagnetic coils simultaneously in the simultaneous suction mode.

  The present invention has been made in view of such a background, and can individually attract individual plungers to a fixed core, and can reduce power consumption of an electromagnetic coil when simultaneously attracting a plurality of plungers. A solenoid device is to be provided.

One aspect of the present invention includes a first electromagnetic coil and a second electromagnetic coil that generate magnetic flux when energized,
A first plunger that moves forward and backward with energization of the first electromagnetic coil;
A second plunger that moves forward and backward with energization of the second electromagnetic coil;
A first fixed core disposed at a position facing the first plunger in the advancing and retracting direction of the first plunger;
A second fixed core disposed at a position facing the second plunger in the advancing and retracting direction of the second plunger;
A first connecting yoke for connecting the first plunger and the second plunger;
A second connecting yoke for connecting the first plunger and the second fixed core ;
A first magnetic circuit constituting yoke through which the magnetic flux of the first electromagnetic coil flows,
The first magnetic circuit constituting yoke and the second connecting yoke are separated from each other on the side where the first fixed core is provided in the forward / backward direction,
The end of the second connecting yoke opposite to the side connected to the second fixed core is close to the first plunger,
In a state where only the first electromagnetic coil among the two electromagnetic coils of the first electromagnetic coil and the second electromagnetic coil is energized, the magnetic flux of the first electromagnetic coil is changed to the first magnetic circuit constituting yoke and the first plunger. And magnetic force generated by flowing through a first magnetic circuit including the first fixed core, the first plunger is attracted to the first fixed core without attracting the second plunger to the second fixed core,
When only the second electromagnetic coil of the two electromagnetic coils is energized from both non-energized states in which energization of the two electromagnetic coils is stopped, the magnetic flux of the second electromagnetic coil is changed to the second plunger. And the magnetic force generated by flowing through the second magnetic circuit including the second fixed core, the second plunger is attracted to the second fixed core without attracting the first plunger to the first fixed core,
In both energized states in which both the two electromagnetic coils are energized, the first plunger is moved by the magnetic force generated by the magnetic flux of the two electromagnetic coils flowing through the first magnetic circuit and the second magnetic circuit. thereby sucked into the first fixed core, the second plunger is attracted to the second fixed core, part of the magnetic flux of the second electromagnetic coil, the first connecting yoke and the first plunger and the second connection A third magnetic circuit including a yoke, the second fixed core, and the second plunger, and not including the first magnetic circuit constituting yoke ;
When the energization to the first electromagnetic coil is stopped while the energization to the second electromagnetic coil is maintained from the both energized states, the magnetic flux of the second electromagnetic coil is changed to the second magnetic circuit and the third magnetic coil. A structure in which the first plunger is held in a suction position that is a position sucked by the first fixed core while the second plunger is sucked by the second fixed core by a magnetic force generated by flowing through the circuit. The solenoid device is characterized in that (Claim 1).

  The solenoid device is configured such that the magnetic flux of the second electromagnetic coil flows through the third magnetic circuit when the two energized states are set. When the energization to the first electromagnetic coil is stopped while the energization to the second electromagnetic coil is maintained from both the energized states, the magnetic flux of the second electromagnetic coil is changed to the second magnetic circuit and the third magnetic circuit. The first plunger is held at the suction position while the second plunger is attracted to the second fixed core by the magnetic force generated by flowing through the first and second cores. Therefore, even if it does not energize the 1st electromagnetic coil, two plungers can be attracted simultaneously only by energizing the 2nd electromagnetic coil. Therefore, the power consumption of the electromagnetic coil can be reduced.

  In the solenoid device, when only the first electromagnetic coil of the two electromagnetic coils is energized, only the first plunger of the two plungers is attracted to the fixed core (first fixed core). Further, when only the second electromagnetic coil of the two electromagnetic coils is energized from both the non-energized states, the magnetic flux of the second electromagnetic coil does not flow through the third magnetic circuit, and the second plunger of the two plungers. Only the fixed core (second fixed core) is sucked. Therefore, the first plunger and the second plunger can be separately sucked by the fixed core.

  As described above, according to the present invention, there is provided a solenoid device capable of individually attracting individual plungers to a fixed core and reducing the power consumption of an electromagnetic coil when simultaneously attracting a plurality of plungers. can do.

Sectional drawing of the electromagnetic relay using the solenoid apparatus in Example 1. FIG. The figure for demonstrating the operation | movement order of the electromagnetic relay in Example 1. FIG. The figure following FIG. The figure following FIG. The figure following FIG. The example of the circuit using the electromagnetic relay in Example 1. FIG. 1 is a perspective view of a solenoid device in Embodiment 1. FIG. The perspective view of the solenoid apparatus in Example 2. FIG. Sectional drawing of the electromagnetic relay in Example 3. FIG. Sectional drawing of the electromagnetic relay in the state which energized two electromagnetic coils in Example 3. FIG. Sectional drawing of the electromagnetic relay using the solenoid apparatus in Example 4. FIG. The figure for demonstrating the operation | movement order of the electromagnetic relay in Example 4. FIG. The figure following FIG. The figure following FIG. The figure following FIG. The figure following FIG. The figure following FIG. The example of the circuit using the electromagnetic relay in Example 4. FIG. FIG. 9 is a perspective view of a solenoid device according to a fifth embodiment.

  The solenoid device can be used for an electromagnetic relay, for example. For example, two switches can be provided in the electromagnetic relay, one switch can be opened and closed by a first plunger, and the other switch can be opened and closed by a second plunger.

The first plunger includes a plunger main body portion and a contact / separation portion magnetically connected to the plunger main body portion. In the suction position, the contact / separation portion is the first connection yoke or the second connection yoke. In the non-suction position in which the distance between the first plunger and the first plunger is not attracted by the first plunger when the first plunger is not attracted to the first yoke by approaching the coupling yoke, the distance between them is relatively narrow. It is preferable that these spaces are spaced apart from the connecting yoke so as to be wider than the suction position.
In this case, when both energized states are established, the first plunger is sucked to the suction position, and the contact / separation portion approaches the first connection yoke or the second connection yoke. Therefore, the magnetic resistance between them becomes small, and the magnetic flux of the second electromagnetic coil easily flows. That is, the magnetic flux of the second electromagnetic coil easily flows through the third magnetic circuit. Therefore, when the energization of the first electromagnetic coil is stopped while the energization of the second electromagnetic coil is maintained after the two energized states are maintained, the first plunger is moved to the attraction position by the magnetic force generated by the magnetic flux flowing through the third magnetic circuit. Can be easily held.
Further, when both the non-energized states are set, the first plunger moves to the non-suction position, and the contact / separation portion is separated from the first connection yoke or the second connection yoke. Therefore, the magnetic resistance between them increases. Therefore, when switching from both of the non-energized states to a state where only the second electromagnetic coil of the two electromagnetic coils is energized, it becomes difficult for the magnetic flux to flow in the third magnetic circuit without attracting the first plunger. Only the second plunger can be sucked into the second fixed core.
The term “magnetically coupled” means that the contact / separation part and the plunger are connected in a state where magnetic flux can flow between them. For example, the contact / separation part and the plunger are integrally formed of a soft magnetic material, or they are formed as separate parts and fixed while the contact / separation part is in contact with the plunger. Can be “magnetically coupled” to the plunger body.

The contact / separation portion has a diameter larger than that of the plunger main body portion, and the first connection yoke or the second connection yoke is formed with a through hole through which the plunger main body portion is inserted, and the first plunger It is preferable that the contact / separation part is configured to come into contact with the peripheral part of the through-hole when moved to the suction position (claim 3).
In this case, when the first plunger moves to the suction position, the contact / separation part can be brought into contact with the entire periphery of the through hole, and the contact between the contact / separation part and the first connection yoke or the second connection yoke can be achieved. The area can be increased. Therefore, when the magnetic flux of the second electromagnetic coil flows to the third magnetic circuit, a strong magnetic force is generated in the contact / separation portion, and the first plunger can be reliably held at the suction position.

Preferably, a predetermined gap is formed between the inner peripheral surface of the through hole and the plunger main body.
In this case, since the gap is formed, it is difficult for the magnetic flux to pass from the inner peripheral surface of the through hole to the plunger main body when the both energized states are made. Therefore, the magnetic flux of the third magnetic circuit can easily flow to the contact / separation part, and the contact / separation part can be attracted by a strong magnetic force. Moreover, if it is set as the said structure, it can suppress that a plunger main-body part is strongly attracted | sucked to the internal peripheral surface of a through-hole by magnetic force. Therefore, it is possible to smoothly advance and retract the first plunger.

Also, a third electromagnetic coil that generates a magnetic flux when energized, a third plunger that advances and retreats when the third electromagnetic coil is energized, and a position that faces the third plunger in the advancing and retreating direction of the third plunger. And a third plunger yoke through which the magnetic flux of the third electromagnetic coil passes and the third plunger is slidably contacted, and the third plunger is the first electromagnetic coil or the second electromagnetic coil. The first plunger and the second plunger are not affected by the magnetic flux generated by energizing the coil, but only affected by the magnetic flux generated by energizing the third electromagnetic coil. The third plunger yoke is configured to be integrated with the first connection yoke or the second connection yoke so as not to move back and forth under the influence of the magnetic flux of the electromagnetic coil. Preferred (claim 5).
In this case, since the third plunger yoke is integrated with the first connection yoke or the second connection yoke, the number of parts can be reduced. Therefore, the manufacturing cost of the solenoid device can be reduced.

Example 1
Examples of the solenoid device will be described with reference to FIGS. As shown in FIG. 1, the solenoid device 1 of the present example includes a first electromagnetic coil 2a, a second electromagnetic coil 2b, a first plunger 3a, a second plunger 3b, a first fixed core 5a, and a second fixed coil. The core 5b, the 1st connection yoke 41, and the 2nd connection yoke 42 are provided. As shown in FIGS. 2 and 3, the first electromagnetic coil 2a and the second electromagnetic coil 2b generate a magnetic flux Φ by energization. As shown in FIG. 2, the first plunger 3a advances and retreats with energization of the first electromagnetic coil 2a. Further, as shown in FIG. 3, the second plunger 3b advances and retreats with energization to the second electromagnetic coil 2b. The first fixed core 5a is disposed at a position facing the first plunger 3a in the advancing / retreating direction (Z direction) of the first plunger 3a. The second fixed core 5b is disposed at a position facing the second plunger 3b in the advancing / retreating direction (Z direction) of the second plunger 3b. The first connection yoke 41 connects the first plunger 3a and the second plunger 3b. The second connection yoke 42 connects the first plunger and the second fixed core 5b.

  As shown in FIG. 2, in a state where only the first electromagnetic coil 2a is energized (first energized state) among the two electromagnetic coils 2 (2a, 2b) of the first electromagnetic coil 2a and the second electromagnetic coil 2b, the first The first plunger 3a is attracted to the first fixed core 5a without attracting the second plunger 3b to the second fixed core 5b by the magnetic force generated by the magnetic flux Φ of the electromagnetic coil 2a flowing through the first magnetic circuit C1. The first magnetic circuit C1 is a magnetic circuit including the first plunger 3a and the first fixed core 5a.

  In addition, from the non-energized state (see FIG. 1) in which the energization of the two electromagnetic coils 2a and 2b is stopped, only the second electromagnetic coil 2b is energized (the second electromagnetic coil 2b). In the energized state (see FIG. 3), the second plunger 3a is not attracted to the first fixed core 5a by the magnetic force generated by the magnetic flux Φ of the second electromagnetic coil 2b flowing through the second magnetic circuit C2. The plunger 3b is sucked into the second fixed core 5b. The second magnetic circuit C2 is a magnetic circuit including a second plunger 3b and a second fixed core 5b.

  As shown in FIG. 4, in both energized states where both of the two electromagnetic coils 2a and 2b are energized, the magnetic flux Φ of the two electromagnetic coils 2a and 2b flows through the first magnetic circuit C1 and the second magnetic circuit C2. The first plunger 3a is attracted to the first fixed core 5a and the second plunger 3b is attracted to the second fixed core 5b due to the magnetic force generated by. Further, a part of the magnetic flux Φ of the second electromagnetic coil 2b flows through the third magnetic circuit including the first connecting yoke 41, the first plunger 3a, the second connecting yoke 42, the second fixed core 5b, and the second plunger 3b. .

  When the energization to the first electromagnetic coil 2a is stopped while maintaining the energization to the second electromagnetic coil 2b from both the energized states as shown in FIG. 5, the magnetic flux Φ of the second electromagnetic coil 2b is changed to the second magnetism. The position where the first plunger 3a is attracted to the first fixed core 5a while the second plunger 3b is attracted to the second fixed core 5b by the magnetic force generated by flowing through the circuit C2 and the third magnetic circuit C3. It is configured to be held in the suction position.

  The solenoid device 1 of this example is used for an electromagnetic relay 10. In the electromagnetic relay 10, two switches 19 (19a, 19b) are formed. As shown in FIG. 1, each switch 19 includes a fixed contact 13, a movable contact 14, a metal fixed contact support 15 that supports the fixed contact 13, and a metal movable contact support that supports the movable contact 14. Part 16. A contact-side spring member 12 is attached to the movable contact support portion 16. The contact-side spring member 12 presses the movable contact support portion 16 toward the fixed contact support portion 15 side.

  A core-side spring member 11 is provided between the plunger 3 and the fixed core 5. The core-side spring member 11 presses the plunger 3 toward the movable contact support portion 16 side.

  As shown in FIG. 2, when the first plunger 3 a is attracted to the first fixed core 5 a, the movable contact support portion 16 is pressed toward the fixed contact support portion 15 by the pressing force of the contact side spring member 12. As a result, the first switch 19a is turned on.

  Further, as shown in FIG. 1, when the energization to the first electromagnetic coil 2a is stopped, the magnetic flux Φ disappears, and the first plunger 3a is pressed toward the movable contact support 16 by the pressing force of the core side spring member 11a. The Then, the insulating portion 300 attached to the first plunger 3 contacts the movable contact support portion 16 and separates the movable contact support portion 16 from the fixed contact support portion 15 against the pressing force of the contact side spring member 12. As a result, the first switch 19a is turned off. Similarly, the second switch 19b is switched between an on state and an off state by switching energization or deenergization to the second electromagnetic coil 2b.

  The electromagnetic relay 10 of this example is used in the circuit shown in FIG. As shown in the figure, in this example, the electromagnetic relay 10 is provided on the power input line 66 that connects the DC power source 6 and the electronic device 63. The power input line 66 includes a positive wiring 64 that connects the positive electrode of the DC power supply 6 and the electronic device 63, and a negative wiring 65 that connects the negative electrode of the DC power supply 6 and the electronic device 63. A smoothing capacitor 61 is connected between the positive side wiring 64 and the negative side wiring 65.

  A negative switch 65 is provided with a first switch 19a, and a positive switch 64 is provided with a second switch 19b. Further, a current sensor 69 is attached to the power input line 66. The current sensor 69 is connected to the control circuit unit 60. Further, the control circuit unit 60 controls the on / off of the switches 19a and 19b.

  The electromagnetic relay 10 of this example can confirm whether or not the switches 19a and 19b are welded before starting the electronic device 63. That is, first, only the first electromagnetic coil 2a is energized by the control circuit unit 60, and the first switch 19a is turned on (see FIG. 2). At this time, if no current is detected by the current sensor 69, it is determined that the second switch 19b is not welded. Thereafter, the first switch 19a is turned off, only the second electromagnetic coil 2b is energized, and the second switch 19b is turned on (see FIG. 3). If no current is detected by the current sensor 69, it is determined that the first switch 19a is not welded. After confirming that these two switches 19a and 19b are not welded together, the two switches 19a and 19b are turned on (see FIGS. 4 and 5). As a result, power is supplied to the electronic device 63 through the two switches 19.

  On the other hand, as shown in FIG. 1, a plunger insertion hole 410 and a through hole 412 are formed in the first connection yoke 41. The second plunger 3b is inserted through the plunger insertion hole 410. A first plunger 3 a is disposed in the through hole 412. A plunger insertion hole 420 is formed in the second connection yoke 42. The first plunger 3 a is inserted through the plunger insertion hole 420. When the plunger 3 (3a, 3b) moves back and forth, the plunger 3a, 3b comes into sliding contact with the inner peripheral surfaces of the plunger insertion holes 420, 410.

  As shown in FIG. 1, the first plunger 3 a includes a plunger main body 30 and a contact / separation portion 31 that is magnetically coupled to the plunger main body 30. The contact / separation part 31 has a diameter larger than that of the plunger main body part 30. A gap d is formed between the inner peripheral surface of the through hole 412 and the plunger main body 30. The outer diameter of the contact / separation part 31 is larger than the inner diameter of the through hole 412.

  As shown in FIG. 4, at the suction position where the first plunger 3a is sucked into the first fixed core 5a, the contacting / separating portion 31 approaches the first connecting yoke 41, and the distance between them in the Z direction is relatively narrow. Become. In this example, the contact / separation part 31 contacts the peripheral part 427 of the through hole 412 at the suction position. As shown in FIG. 3, in the non-suction position where the first plunger 3a is not attracted by the first fixed core 5a, the contact / separation portion 31 is separated from the first connection yoke 41, and these intervals in the Z direction are attracted. It becomes wider than the position.

As shown in FIGS. 1 and 7, a core connection yoke 43 is connected to the second connection yoke 42. The core connection yoke 43 includes a first core connection portion 431 connected to the first fixed core 5 a and a first connection portion 432 that connects the first core connection portion 431 and the second connection yoke 42.
Between the 2nd core connection part 425 which is the part connected to the 2nd fixed core 5b among the 2nd connection yokes 42, and the 1st core connection part 431, it suppresses that magnetic flux (PHI) flows between these. A notch 491 is formed.

  The first connection yoke 41 and the second connection yoke 42 are connected by a second connection portion 442.

  The first connecting portion 432 is an end portion 422 of the second connecting yoke 42 and the first core connecting portion 431 on the side far from the second electromagnetic coil 2b in the arrangement direction (X direction) of the two plungers 3a and 3b. , 433 are connected. The second connecting portion 442 connects the end portions 411 and 421 of the first connecting yoke 41 and the second connecting yoke 42 on the side farther from the first electromagnetic coil 2a in the X direction.

  The first connection yoke 41, the second connection yoke 42, the core connection yoke 43, and the second connection portion 442 are formed in a plate shape. As shown in FIG. 1, the second connecting yoke 42 has a protruding wall portion 419 protruding toward the first fixed core 5 a. The inside of the projecting wall portion 419 is the plunger insertion hole 420 described above. The first connection yoke 41 includes a protruding wall portion 429 that protrudes toward the second fixed core 5b. The inside of the protruding wall portion 429 is the plunger insertion hole 410 described above.

  As shown in FIG. 2, when only the first electromagnetic coil 2a of the two electromagnetic coils 2 is energized, a magnetic flux Φ is generated, and this magnetic flux Φ flows through the first magnetic circuit C1. The first magnetic circuit C1 includes a first plunger 3a, a second connection yoke 42, a core connection yoke 43, and a first fixed core 5a.

  In addition, since the notch part 491 is formed between the 1st core connection part 431 and the 2nd core connection part 425, magnetic flux (PHI) cannot flow easily between these. Therefore, when only the first electromagnetic coil 2a of the two electromagnetic coils 2 is energized, the magnetic flux Φ becomes the first fixed core 5a, the first plunger 3a, the first connection yoke 41, the second plunger 3b, the second It becomes difficult to flow through the magnetic circuit composed of the fixed core 5b, the second core connection portion 425, and the first core connection portion 431. Therefore, the second plunger 3b is hardly attracted to the second fixed core 5b by the magnetic flux Φ of the first electromagnetic coil 2a.

  When switching from both non-energized states (see FIG. 1) to a state where only the second electromagnetic coil 2b is energized as shown in FIG. 3, the magnetic flux Φ of the second electromagnetic coil 2b flows through the second magnetic circuit C2. The second plunger 3b is attracted to the second fixed core 5b by the magnetic force generated thereby. The second magnetic circuit C2 includes a second plunger 3b, a first connection yoke 41, a second connection portion 442, a second connection yoke 42, and a second fixed core 5b.

  As shown in FIG. 1, when the solenoid device 1 is in a non-energized state and the first plunger 3 a is in the non-suction position, the contacting / separating portion 31 is separated from the first connecting yoke 41, Magnetic resistance increases. Therefore, as shown in FIG. 3, the magnetic flux Φ is less likely to flow through the third magnetic circuit C3 even when the second electromagnetic coil 2b is energized as shown in FIG. 41 is not sucked. Therefore, only the second plunger 3b of the two plungers 3 is sucked.

  As shown in FIG. 4, when both energized states are established, the magnetic flux Φ of the first electromagnetic coil 2a flows through the first magnetic circuit C1, and the magnetic force generated thereby causes the first plunger 3a to move to the first fixed core. While being attracted by 5a, the magnetic flux Φ of the second electromagnetic coil 2b flows through the second magnetic circuit C2, and the magnetic force generated thereby attracts the second plunger 3b to the second fixed core 5b. Further, when the first plunger 3a is attracted to the first fixed core 5a, the contact / separation portion 31 approaches the first connection yoke 41, and the magnetic resistance therebetween becomes small. Therefore, the magnetic flux Φ of the second electromagnetic coil 2b is likely to flow through the third magnetic circuit C3.

  The effect of this example will be described. When the solenoid device 1 of this example is in both energized states (see FIG. 4), the magnetic flux Φ of the second electromagnetic coil 2b flows to the third magnetic circuit C3. When the energization to the first electromagnetic coil 2a is stopped while the energization to the second electromagnetic coil 2b is maintained from both the energized states (see FIG. 5), the magnetic flux Φ of the second electromagnetic coil 2b is the second. The magnetic force generated by flowing through the magnetic circuit C2 and the third magnetic circuit C3 attracts the second plunger 3b to the second fixed core 5b and holds the first plunger 3a in the attracting position. Accordingly, even if the first electromagnetic coil 2a is not energized, the two plungers 3a and 3b can be simultaneously attracted only by energizing the second electromagnetic coil 2b, the switches 19a and 19b are turned on, and the electronic device 63 ( (See FIG. 6). In this example, as described above, when power is supplied to the electronic device 63, it is not necessary to energize the first electromagnetic coil 2a, so that power consumption by the electromagnetic coil 2 can be reduced.

  Further, when the solenoid device 1 of the present example is in the first energized state (see FIG. 2), only the first plunger 3 a of the two plungers 3 is attracted to the fixed core 5. Further, when the two energized states (see FIG. 1) are changed to the second energized state (see FIG. 3), the magnetic flux Φ of the second electromagnetic coil 2b does not flow to the third magnetic circuit C3. Only the second plunger 3 b is sucked into the fixed core 5. Therefore, the first plunger 3a and the second plunger 3b can be attracted to the fixed core 5 separately. Thereby, it is possible to confirm whether or not the switches 19a and 19b are welded.

As shown in FIGS. 1 and 7, the contact / separation portion 31 of this example has a larger diameter than the plunger main body portion 30. When the first plunger 3a moves to the suction position, the contact / separation part 31 contacts the peripheral part 427 of the through hole 412.
Therefore, when the first plunger 3a moves to the suction position, the contact / separation part 31 can be brought into contact with the entire periphery of the through hole 412. Therefore, the contact area between the contact / separation part 31 and the first connection yoke 41 can be increased. Therefore, as shown in FIG. 4, when the magnetic flux Φ of the second electromagnetic coil 2b flows to the third magnetic circuit C3, a strong magnetic force is generated in the contact / separation portion 31. As a result, the first plunger 3a can be reliably held at the suction position.

In this example, as shown in FIG. 4, a gap d is formed between the inner peripheral surface of the through hole 412 and the plunger main body 30.
Therefore, when both energized states are established, the magnetic flux Φ of the second electromagnetic coil 2 b is less likely to pass between the inner peripheral surface of the through hole 412 and the plunger main body 30. Therefore, the magnetic flux Φ of the second electromagnetic coil 2b can easily flow between the peripheral part 427 and the contact / separation part 31, and the contact / separation part 31 can be attracted by a strong magnetic force. Moreover, if it is set as the said structure, it can suppress that the plunger main-body part 30 is strongly attracted | sucked to the internal peripheral surface of the through-hole 412 by magnetic force. Therefore, the advance / retreat operation of the first plunger 3a can be performed smoothly.

Further, as shown in FIG. 3, the plunger 3 of this example has a flange portion 38 protruding in the radial direction of the plunger 3. And it is comprised so that the magnetic flux (PHI) generate | occur | produced by the electricity supply to the electromagnetic coil 2 may flow through the collar part 38. FIG.
If it does in this way, since magnetic flux (PHI) flows through the collar part 38, the quantity of magnetic flux (PHI) which flows into the plunger 3 can be increased. Therefore, when the electromagnetic coil 2 is energized, the magnetic force generated in the plunger 3 can be increased, and the plunger 3 can be attracted with a strong magnetic force.

  As described above, according to this example, a solenoid device that can individually attract individual plungers to a fixed core and can reduce power consumption of an electromagnetic coil when simultaneously attracting a plurality of plungers is provided. can do.

(Example 2)
In this example, the shape of the yoke 4 is changed. As shown in FIG. 8, the solenoid device 1 of this example includes two first connection portions 432 and two second connection portions 442. The two first connecting portions 432a and 432b are formed at positions sandwiching the first electromagnetic coil 2a in a direction (Y direction) orthogonal to both the X direction and the Z direction. Further, the two second connecting portions 442a and 442b are formed at positions where the second electromagnetic coil 2b is sandwiched in the Y direction.

  The effect of this example will be described. In this example, since each of the first connecting portion 432 and the second connecting portion 442 is provided, the amount of the magnetic flux Φ generated from the electromagnetic coil 2 and flowing through the first connecting portion 432 or the second connecting portion 442 can be increased. it can. Therefore, the suction force of the plunger 3 can be increased. Moreover, the shape of the yoke 4 can be simplified and the assemblability can be improved.

  Others are the same as in the first embodiment. Moreover, among the symbols used in the drawings relating to this example, the same symbols as those used in the first embodiment represent the same configurations as in the first embodiment unless otherwise indicated.

(Example 3)
In this example, the advancing and retreating direction of the second plunger 3b is reversed. As shown in FIGS. 9 and 10, in this example, the second electromagnetic coil 2b, the second plunger 3b, the second fixed core 5b, and the second switch 19b are connected to the first electromagnetic coil 2a and the like Z. Arranged in the opposite direction. When the first electromagnetic coil 2a is energized, the first plunger 3a moves in a direction approaching the bottom wall 181 of the case 18, and the second plunger 3b moves in a direction away from the bottom wall 181 when the second electromagnetic coil 2b is energized. To do.

  The solenoid device 1 of this example includes a first connection yoke 41 and a second connection yoke 42 as in the first embodiment. The first connection yoke 41 is connected to the core connection yoke 43. The first connecting yoke 41 and the second connecting yoke 42 are connected by a second connecting portion 442.

  Similar to the first embodiment, the first plunger 3 a includes a plunger main body portion 30 and a contact / separation portion 31. In this example, when the first plunger 3a is moved to the suction position (see FIG. 10), the contact / separation portion 31 approaches the second connection yoke 42, and the distance therebetween becomes relatively narrow. Further, when the first plunger 3a moves to the non-suction position (see FIG. 9), the contact / separation portion 31 is separated from the second connection yoke 42, and these intervals are relatively wide.

  If it is set as the said structure, the electromagnetic relay 10 can be used also in the place where a vibration arises easily like a vehicle, for example. That is, when the plungers 3a and 3b are attracted in the same direction by energizing the electromagnetic coils 2a and 2b, when the vibration occurs and the plungers 3a and 3b simultaneously move in the same direction, the two switches 19a and 3b There is a possibility that 19b is turned on at the same time. Therefore, there is a possibility that electric power is supplied to the electronic device 63 (see FIG. 6) when it is not intended. However, if the two plungers 3a and 3b are configured to be attracted in different directions by the electromagnetic coil 2, even if the two plungers 3a and 3b move in the same direction due to vibration, the two switches One of the switches 19a and 19b can be turned off. Therefore, in this case, power can be prevented from being supplied to the electronic device 63.

  In the present example, the second plunger 3b is configured to advance and retract in a direction different from the first plunger 3a by 180 °. However, this angle may be arbitrary, and may be different by 90 °, for example.

  Others are the same as in the first embodiment. Moreover, among the symbols used in the drawings relating to this example, the same symbols as those used in the first embodiment represent the same configurations as in the first embodiment unless otherwise indicated.

Example 4
In this example, the number of electromagnetic coils 2, plungers 3, fixed cores 5, and switches 19 is changed. As shown in FIG. 11, the electromagnetic relay 10 of this example includes the electromagnetic coil 2, the plunger 3, the fixed core 5, and three switches 19. The first electromagnetic coil 2a, the second electromagnetic coil 2b, the first plunger 3a, the second plunger 3b, the first fixed core 5a, the second fixed core 5b, the first switch 19a, and the second switch 19b in this example 1 has the same structure. In this example, in addition to these, a third electromagnetic coil 2c, a third plunger 3c, a third fixed core 5c, and a third switch 19c are provided. The third plunger 3c moves back and forth in the Z direction as the third electromagnetic coil 2c is energized. The third fixed core 5c is disposed at a position facing the third plunger 3c in the Z direction. The third switch 19c is turned on when the third plunger 3c is sucked into the third fixed core 5c (see FIG. 12), and is turned off when the third plunger 3c is not sucked (see FIG. 11).

  As shown in FIGS. 11 and 12, the solenoid device 1 of this example includes a third plunger yoke 49 through which the magnetic flux Φ of the third electromagnetic coil 2c passes and the third plunger 3c is in sliding contact. A third plunger insertion hole 428 is formed in the third plunger yoke 49. The third plunger 3c is inserted through the third plunger insertion hole 428. A second core connection yoke 45 is connected to the third plunger yoke 49. The second core connection yoke 45 includes a third core connection part 451 connected to the third fixed core 5c, and a third connection part 452 connecting the third core connection part 451 and the third plunger yoke 49. Between the 3rd core connection part 451 and the 1st core connection part 431, the 2nd notch part 492 which suppresses that magnetic flux (PHI) flows between these is formed. The third plunger yoke 49 and the second connecting yoke 42 are made of a single yoke material and are integrated.

  As shown in FIGS. 11 to 14, the third plunger 3 c of the present example is not affected by the magnetic flux Φ generated by energization of the first electromagnetic coil 2 a or the second electromagnetic coil 2 b, and is applied to the third electromagnetic coil 2 c. The actuator moves forward and backward only under the influence of the magnetic flux Φ generated by energization. Further, the first plunger 3a and the second plunger 3b are configured not to advance and retract under the influence of the magnetic flux Φ of the third electromagnetic coil 2c.

That is, when only the third electromagnetic coil 2c is energized among the three electromagnetic coils 2 (2a to 2c) (see FIG. 12), the magnetic flux Φ of the third electromagnetic coil 2c flows through the fourth magnetic circuit C4 and is thereby generated. Due to the magnetic force, only the third plunger 3c of the three plungers 3 is attracted to the fixed core 5 (third fixed core 5c). Accordingly, the third switch 19c is turned on. The fourth magnetic circuit C4 includes a third plunger 3c, a third plunger yoke 49, a second core connection yoke 45, and a third fixed core 5c.
When only the first electromagnetic coil 2a is energized among the three electromagnetic coils 2 (see FIG. 13), the second plunger 3b is not sucked and only the first plunger 3a is sucked, as in the first embodiment. Along with this, the first switch 19a is turned on. At this time, the third plunger 3c is not sucked.
Further, when switching from a state in which none of the three electromagnetic coils 2 is energized (see FIG. 11) to a state in which only the second electromagnetic coil 2b is energized (see FIG. 14), as in the first embodiment, the first plunger 3a. Is not sucked, but only the second plunger 3b is sucked. Along with this, the second switch 19b is turned on. At this time, the third plunger 3c is not sucked.

  In this example, when only the first electromagnetic coil 2a and the third electromagnetic coil 2c among the three electromagnetic coils 2 are energized (see FIG. 15), the first plunger 3a and the third plunger 3b are not attracted to the second plunger 3b. The plunger 3c is sucked. As a result, the first switch 19a and the third switch 19c are turned on.

  In this example, as shown in FIG. 16, when all three electromagnetic coils 2 are energized, all three plungers 3 are attracted. As a result, all the three switches 19a to 19c are turned on. The magnetic flux Φ of the third electromagnetic coil 2c flows through the fourth magnetic circuit C4, and the magnetic flux Φ of the first electromagnetic coil 2c flows through the first magnetic circuit C1. The magnetic flux Φ of the second electromagnetic coil 2b flows through the second magnetic circuit C2 and the third magnetic circuit C3.

  Thereafter, as shown in FIG. 17, when the energization of the first electromagnetic coil 2a and the third electromagnetic coil 2c is stopped, the magnetic flux Φ of the second electromagnetic coil 2b flows through the second magnetic circuit C2 and the third magnetic circuit C3. The first plunger 3a is held at the suction position while the second plunger 3b is attracted by the magnetic force generated by. The third plunger 3c is released from suction.

  Next, a circuit using the electromagnetic relay 10 of this example will be described. As shown in FIG. 18, in this example, the DC power source 6 and the electronic device 63 are connected by the positive side wiring 64 and the negative side wiring 65. A negative switch 65 is provided with a first switch 19a, and a positive switch 64 is provided with a second switch 19b. A smoothing capacitor 61 is connected between the positive side wiring 64 and the negative side wiring 65. A series body 67 in which the third switch 19c and the precharge resistor 62 are connected in series is connected in parallel to the second switch 19b.

  In this example, before supplying electric power to the electronic device 63, it is confirmed whether or not each switch 19 is welded. First, only the third switch 19c is turned on (see FIG. 12), and it is confirmed whether or not the current sensor 69 detects a current. When the current is detected, it is determined that the first switch 19a is welded. Subsequently, only the first switch 19a is turned on (see FIG. 13), and it is confirmed whether or not the current sensor 69 detects a current. When the current is detected, it is determined that the second switch 19b or the third switch 19c is welded. Thereafter, similarly, only the second switch 19b is turned on (see FIG. 13), and it is confirmed whether or not the current sensor 69 detects a current.

  When it is determined that all the switches 19 are not welded, power supply to the electronic device 63 is started. First, the third electromagnetic coil 2c and the first electromagnetic coil 2a are energized to turn on the third switch 19c and the first switch 19a (see FIG. 15). As a result, a current is passed through the precharge resistor 62 to precharge the smoothing capacitor 61. By flowing a current through the precharge resistor 62, the flow of the inrush current is suppressed, and the switch 19 is prevented from being welded. Further, after the charging of the smoothing capacitor 61 is completed, the second electromagnetic coil 2b is further energized to turn on the second switch 19b (see FIG. 16). Thereafter, the energization of the third electromagnetic coil 2c and the first electromagnetic coil 2a is stopped (see FIG. 17), and only the second electromagnetic coil 2b is energized, whereby two switches, the first switch 19a and the second switch 19b. Continue to turn 19 on. Thereby, electric power is supplied to the electronic device 63. In this example, the two switches 19a and 19b can be turned on only by energizing the second electromagnetic coil 2b without energizing the first electromagnetic coil 2a, and power can be supplied to the electronic device 63. it can. Therefore, power consumption by the electromagnetic coil 2 can be reduced.

  In this example, as shown in FIG. 11, the third plunger yoke 49 is integrated with the second connection yoke 42. Therefore, the number of parts can be reduced. Thereby, the manufacturing cost of the solenoid device 1 can be reduced.

  Others are the same as in the first embodiment. Moreover, among the symbols used in the drawings relating to this example, the same symbols as those used in the first embodiment represent the same configurations as in the first embodiment unless otherwise indicated.

  In this example, the third plunger yoke 49 is integrated with the second connection yoke 42, but the third plunger yoke 49 may be integrated with the first connection yoke 41. Also in this case, the number of parts can be reduced, and the manufacturing cost of the solenoid device 1 can be reduced.

(Example 5)
In this example, the shape of the yoke 4 is changed. As shown in FIG. 19, the solenoid device 1 of this example includes two first connection portions 432, second connection portions 442, and third connection portions 452. The two first coupling portions 432a and 432b are provided at positions that sandwich the first electromagnetic coil 2a from the Y direction. The two first connecting portions 432a and 432b connect the second connecting yoke 42 and the first core connecting portion 431, respectively. Further, the two second connecting portions 442a and 442b are provided at positions where the second electromagnetic coil 2b is sandwiched from the Y direction. The two second connection portions 442a and 442b connect the first connection yoke 41 and the second connection yoke 42, respectively. Further, the two third connecting portions 452a and 452b are provided at positions where the third electromagnetic coil 2c is sandwiched from the Y direction. The two third connecting portions 452a and 452b connect the third plunger yoke 49 and the third core connecting portion 451, respectively.

  The effect of this example will be described. Since the yoke 4 of this example includes two each of the first connecting portion 432, the second connecting portion 442, and the third connecting portion 452, the first connecting portion 432 generated from the electromagnetic coil 2 or the second connecting portion is generated. The amount of the magnetic flux Φ flowing through the portion 442 or the third connecting portion 452 can be increased. Therefore, the suction force of the plunger 3 can be increased.

  Others are the same as in the first embodiment. Moreover, among the symbols used in the drawings relating to this example, the same symbols as those used in the first embodiment represent the same configurations as in the first embodiment unless otherwise indicated.

DESCRIPTION OF SYMBOLS 1 Solenoid apparatus 2a 1st electromagnetic coil 2b 2nd electromagnetic coil 3a 1st plunger 3b 2nd plunger 41 1st connection yoke 42 2nd connection yoke 5a 1st fixed core 5b 2nd fixed core C1 1st magnetic circuit C2 2nd magnetism circuit

Claims (5)

A first electromagnetic coil (2a) and a second electromagnetic coil (2b) that generate magnetic flux when energized;
A first plunger (3a) that moves forward and backward with energization of the first electromagnetic coil (2a);
A second plunger (3b) that moves forward and backward with energization of the second electromagnetic coil (2b);
A first fixed core (5a) disposed at a position facing the first plunger (3a) in the advancing / retreating direction of the first plunger (3a);
A second fixed core (5b) disposed at a position facing the second plunger (3b) in the advancing and retracting direction of the second plunger (3b);
A first connecting yoke (41) for connecting the first plunger (3a) and the second plunger (3b);
A second connecting yoke (42) for connecting the first plunger (3a) and the second fixed core (5b) ;
A first magnetic circuit constituting yoke (43) through which the magnetic flux of the first electromagnetic coil (2a) flows,
The first magnetic circuit constituting yoke (43) and the second coupling yoke (42) are separated from each other on the side where the first fixed core (5a) is provided in the forward / backward direction,
The end of the second connection yoke (42) opposite to the side connected to the second fixed core (5b) is close to the first plunger (3a),
In a state where only the first electromagnetic coil (2a) is energized among the two electromagnetic coils (2) of the first electromagnetic coil (2a) and the second electromagnetic coil (2b), the first electromagnetic coil (2a) Of the first magnetic circuit constituting yoke (43), the first plunger (3a), and the first magnetic core (5a) including the first fixed core (5a). The first plunger (3a) is sucked into the first fixed core (5a) without sucking the two plungers (3b) into the second fixed core (5b);
When only the second electromagnetic coil (2b) of the two electromagnetic coils (2) is energized from both non-energized states where the energization to the two electromagnetic coils (2) is stopped, the second The magnetic force generated by the magnetic flux of the electromagnetic coil (2b) flowing through the second magnetic circuit (C2) including the second plunger (3b) and the second fixed core (5b) causes the first plunger (3a) to move. Sucking the second plunger (3b) into the second fixed core (5b) without sucking into the first fixed core (5a);
In both energized states in which both the two electromagnetic coils (2) are energized, the magnetic flux of the two electromagnetic coils (2) flows through the first magnetic circuit (C1) and the second magnetic circuit (C2). The first plunger (3a) is attracted to the first fixed core (5a) and the second plunger (3b) is attracted to the second fixed core (5b) by the magnetic force generated by the above, and the second part of the magnetic flux of the electromagnetic coil (2b) is, the first connecting yoke (41) and the first plunger (3a) and said second connecting yoke (42) and the second stationary core (5b) and the second A third magnetic circuit (C3) including a plunger (3b) and not including the first magnetic circuit configuration yoke (43) ,
When the energization to the first electromagnetic coil (2a) is stopped while the energization to the second electromagnetic coil (2b) is maintained from the both energized states, the magnetic flux of the second electromagnetic coil (2b) is The first plunger while attracting the second plunger (3b) to the second fixed core (5b) by the magnetic force generated by flowing through the second magnetic circuit (C2) and the third magnetic circuit (C3). A solenoid device (1) configured to hold (3a) at a suction position that is a position sucked by the first fixed core (5a).   The solenoid device (1) according to claim 1, wherein the first plunger (3a) includes a plunger main body portion (30), and a contact / separation portion (31) magnetically coupled to the plunger main body portion (30). In the suction position, the contact / separation part (31) approaches the first connection yoke (41) or the second connection yoke (42), and the distance therebetween becomes relatively narrow, In the non-suction position where the first plunger (3a) is not attracted to the first fixed core (5a), the contact / separation part (31) is separated from the first connection yoke (41) or the second connection yoke (42). A solenoid device (1), wherein the solenoid device (1) is configured to be separated from each other so that these intervals are wider than the suction position.   The solenoid device (1) according to claim 2, wherein the contact / separation portion (31) has a diameter larger than that of the plunger main body portion (30), and the first connection yoke (41) or the second connection yoke. (42) is formed with a through hole (412) inserted through the plunger body (30), and when the first plunger (3a) moves to the suction position, the contact / separation part (31) A solenoid device (1) configured to be in contact with a peripheral portion (427) of the through hole (412).   The solenoid device (1) according to claim 3, wherein a predetermined gap (d) is formed between an inner peripheral surface of the through hole (412) and the plunger main body (30). A solenoid device (1). The solenoid device (1) according to any one of claims 1 to 4, wherein a third electromagnetic coil (2c) that generates magnetic flux by energization and advancing and retreating with energization to the third electromagnetic coil (2c). A third plunger (3c), a third fixed core (5c) disposed at a position facing the third plunger (3c) in the advancing and retreating direction of the third plunger (3c), and the third electromagnetic coil ( 2c) and a third plunger yoke (49) in which the third plunger (3c) is slidably contacted, and the third plunger (3c) is configured by the first electromagnetic coil (2a) or the second electromagnetic coil (2a). not affected by the magnetic flux generated by the energization of the electromagnetic coil (2b), and advanced and retracted by receiving only the influence of magnetic flux generated by the energization of the the third electromagnetic coil (2 c), the first plunger (3a ) And above The plunger (3b) is configured not to move forward and backward under the influence of the magnetic flux of the third electromagnetic coil (2c), and the third plunger yoke (49) can be the first connection yoke (41) or the first A solenoid device (1) characterized by being integrated with a two-connection yoke (42).

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