JP5284830B2 - Electromagnetic relay - Google Patents

Description

  The present invention relates to an electromagnetic relay that can improve operation reliability and that allows a plunger to operate smoothly.

2. Description of the Related Art Conventionally, there is known an electromagnetic relay that includes a plurality of switches each composed of a movable contact portion and a fixed contact portion, and allows a current to flow through the circuit or cuts off the current by switching on and off the switch.
A conventional electromagnetic relay has one electromagnetic coil, and includes one plunger inside the electromagnetic coil (see Patent Document 3 below). This electromagnetic relay is configured such that the plunger moves forward and backward depending on whether or not the electromagnetic coil is energized. A plurality of movable contact portions are attached to one plunger, and the plurality of movable contact portions move as the plunger advances and retreats, and come into and out of contact with the fixed contact portion.

JP 2003-288830 A JP 2007-335082 A JP 2001-176370 A

However, when the plunger moves back and forth, frictional heat is generated and may be fixed to other parts. In the conventional electromagnetic relay, since all the movable contact portions are moved by one plunger, there is a problem that all the switches do not operate when this plunger breaks down and is fixed to other parts.
In addition, heat may be generated by the current flowing through the switch and may be welded. As described above, since the conventional electromagnetic relay moves all the movable contact portions with one plunger, when one of a plurality of switches is welded, other switches do not operate. In such a case, all the switches are turned on.
Therefore, an electromagnetic relay that can further improve the operation reliability is desired.

  The present invention has been made in view of such conventional problems, and an object of the present invention is to provide an electromagnetic relay with high operational reliability.

The present invention has a plurality of switches composed of a movable contact portion and a fixed contact portion, and is an electromagnetic relay that switches between an on state and an off state of the switch,
One electromagnetic coil that generates magnetic flux when energized;
Provided inside of the electromagnetic coil, at least a portion with is made of a magnetic material, and a plurality of plunger advanced and retracted in the axial direction of the solenoid coil by the presence or absence of the energization of the said electromagnetic coil,
The movable contact portion is attached to each of the plurality of plungers,
The electromagnetic relay is characterized in that the fixed contact portion is provided at a position where the movable contact portion is brought into contact with or separated from the plunger as the plunger moves forward and backward.

The function and effect of the present invention will be described.
The electromagnetic relay of the present invention has a plurality of switches each composed of a movable contact portion and a fixed contact portion, and a plunger is individually attached to each movable contact portion. Therefore, for example, when used in the circuit shown in FIG. 6, even if one of the plurality of plungers is fixed or one switch is welded, the other plungers operate, so that the electromagnetic relay as a whole Can ensure normal operation. Therefore, the operation reliability of the electromagnetic relay can be improved.
Moreover, the electromagnetic relay of this invention has only one electromagnetic coil. Although it is possible to provide a plurality of electromagnetic coils, problems such as an increase in manufacturing cost and an increase in size of the electromagnetic relay are likely to occur. However, such a problem can be avoided if there is only one electromagnetic coil.

  The electromagnetic relay of the present invention can be suitably used for a circuit that allows a large current to flow. When a large current is applied, the switch may be welded by resistance heat. However, if a plunger is provided for each switch as in the present invention, the other switches operate normally even if one switch is welded, so that the electromagnetic relay as a whole operates normally. For this reason, the electromagnetic relay of the present invention is particularly effective when used in a circuit through which a large current flows. For example, it can be suitably used for a vehicle inverter.

  As described above, according to the present invention, it is possible to provide an electromagnetic relay with high operational reliability.

Sectional drawing of the electromagnetic relay in the state which the switch in Example 1 opened. Sectional drawing of the electromagnetic relay in the state which the switch in Example 1 closed. BB sectional drawing of FIG. CC expanded sectional view of FIG. AA sectional drawing of FIG. The example of the circuit in which the electromagnetic relay in Example 1 is used. The top view of the plate-shaped member which formed three plunger penetration holes 6 in Example 1. FIG. The top view of the plate-shaped member in a comparative example. The top view of the plate-shaped member in Example 2. FIG.

A preferred embodiment of the present invention described above will be described.
The electromagnetic relay of the present invention is used in a circuit that connects a power source and a load, and one of the two switches is provided on a wiring that connects the first electrode of the power source and the load, and the other switch The switch is preferably provided on a wiring connecting the second electrode of the power source and the load.
In this way, even when one of the two switches is welded or the like, the other switch operates normally, so that the power supply can be turned on and off with only the normal switch. Thereby, the reliability of a circuit can be improved.

In the present invention, a plate-like member made of a magnetic material is provided, and the plate-like member has a shape similar to the outer shape of the plunger and has a plunger insertion hole formed in the plate thickness direction with a predetermined clearance. the aforementioned plate-like member, which forms part of a magnetic circuit the magnetic flux generated from the electromagnetic coil passes, notch for equalizing force acting in the radial direction to the plunger by the flux above It is preferably formed on a plate-like member (claim 2).
By providing a plate-like member made of a magnetic material in this way, the magnetic field generated around the electromagnetic coil can be strengthened, and the plunger can be advanced and retracted with a strong force. The magnetic flux generated by the electromagnetic coil passes through the plunger, moves to the plate member, and spreads around the plunger insertion hole.
Here, when a plurality of plunger insertion holes are formed in the plate-like member and the notch is not formed, the magnetic flux is directed toward the higher density of the magnetic material, so another plunger insertion hole is formed. Magnetic flux tends to flow in a direction that is not performed. Therefore, the flow of magnetic flux becomes unbalanced, and the radial force applied to the plunger tends to be unbalanced. Therefore, the problem that the plunger does not move smoothly tends to occur.

  However, the magnetic flux density around the plunger insertion hole can be made uniform by forming the notch in the plate member. Thereby, the force applied to the plunger in the radial direction becomes uniform, and the plunger moves smoothly. Therefore, problems such as the plunger sticking are less likely to occur, and the operation reliability of the electromagnetic relay can be improved.

Also has two said plunger insertion hole, a line connecting the centers of the two plungers insertion holes, it is preferable that the cutout portion is formed on the outer position of the two plungers insertion hole (Claim 3).
If it does in this way, it will become easy to make the magnetic flux density around a plunger penetration hole uniform. That is, since the magnetic flux tends to flow in a direction in which the density of the magnetic material is higher, if two plunger insertion holes are provided adjacent to each other and no notch is formed, the area around each plunger insertion hole The magnetic flux tends to go to the opposite side (outside) of the counterpart plunger insertion hole. Therefore, the magnetic flux density on the outside increases, and the force applied to the plunger becomes unbalanced.
However, it is possible to make the magnetic flux density uniform by providing the outer portion with a notch. Thereby, the radial force applied to the plunger can be made uniform, and the plunger moves smoothly. Therefore, sticking of the plunger is less likely to occur.

Further, the cutout portion is not integral with the plunger insertion hole, it is preferable that the predetermined distance is formed at a position familiar from the plunger insertion hole (Claim 4).
Although the cutout portion can be formed integrally with the plunger insertion hole, in this case, the boundary between the plunger insertion hole and the cutout portion may have an angular shape. Therefore, it may be difficult to operate smoothly when the plunger comes into contact with this portion.
However, if the notch portion is provided at a position different from the plunger insertion hole as described above, the degree of freedom of the shape of the notch portion is increased, and an angular portion is not formed, thus avoiding such a problem. It becomes possible to do.

Example 1
FIG. 1 is a cross-sectional view of the electromagnetic relay 1 in a state where the switch 2 is opened. 2 is a cross-sectional view of the switch 2 in a closed state, and FIG. 3 is a cross-sectional view taken along the line BB of FIG. 4 is an enlarged cross-sectional view taken along the line CC of FIG.
As shown in FIG. 1, this example is an electromagnetic relay 1 that includes a plurality of switches 2 including a movable contact portion 21 and a fixed contact portion 20, and switches the switch 2 between an on state and an off state. The electromagnetic relay 1 includes one electromagnetic coil 3 that generates magnetic flux when energized. In addition, a plurality of plungers 4 that are at least partially made of a magnetic material and that move forward and backward in the axial direction of the electromagnetic coil 3 depending on whether or not the electromagnetic coil 3 is energized are provided inside the electromagnetic coil 3.
A movable contact portion 21 is attached to each of the plurality of plungers 4. In addition, a fixed contact portion 20 is provided at a position where the movable contact portion 21 comes into contact with or separates from the plunger 4 when the plunger 4 moves back and forth.
The details will be described below.

As shown in FIG. 1, the plunger 4 has a magnetic part 40 made of a magnetic material and an insulating part 41 made of an insulator. Further, springs 10 and 11 are attached to the plunger 4. When the electromagnetic coil 3 is not energized, the plunger 4 is urged upward in the figure by the urging force of the spring 10, so that the fixed contact portion 20 and the movable contact portion 21 are not in contact with each other.
When the electromagnetic coil 3 is energized, the magnetic flux Φ flows through the magnetic portion 40, the plate-like member 5, and the yoke material 14 as shown in FIG. As a result, the magnetic portion 40 is magnetized and drawn downward in the figure, the fixed contact portion 20 and the movable contact portion 21 come into contact with each other, and the switch 2 is turned on.

  The electromagnetic relay 1 of this example is provided with two switches 2A and 2B as shown in FIG. The switches 2A and 2B are 2a contacts that are turned on only when the electromagnetic coil 3 is energized.

  On the other hand, as shown in FIG. 4, the fixed contact portion 20 includes contacts 22a and 22b made of noble metal, and the movable contact portion 21 includes contacts 23a and 23b. When the plunger 4 is drawn downward in the figure by energizing the electromagnetic coil 3, the contacts 22a and 23a come into contact with each other, and the contacts 22b and 23b come into contact with each other. Thereby, a current flows from the fixed contact portion 20a through the movable contact portion 21 to the fixed contact portion 20b.

  When the switch 2 is cut off, an arc 24 is generated between the contacts 22a-23a and 22b-23b. In order to extinguish this arc 24 quickly, a magnet 12 is provided as shown in FIGS. The Lorentz force F acts on the arc 24 by the magnetic field of the magnet 12, and the arc 24 is stretched and extinguished quickly. Further, the electromagnetic relay 1 of this example includes an arc extinguishing chamber 13 for extinguishing the arc 24.

  FIG. 5 is a cross-sectional view taken along the line AA in FIG. The plate-like member 5 will be described with reference to FIG. The plate member 5 is made of a magnetic material. The plate-like member 5 has a plunger insertion hole 6 that is similar in shape to the outer shape of the plunger 4 and is formed through the plate thickness direction with a predetermined clearance. The plunger 4 and the plate-like member 5 constitute a part of a magnetic circuit through which the magnetic flux Φ generated from the electromagnetic coil 3 passes (see FIG. 2). Further, as shown in FIG. 5, a notch portion 7 is formed in the plate-like member 5 for equalizing the force acting on the plunger 4 in the radial direction by the magnetic flux Φ.

  The magnetic flux Φ generated from the electromagnetic coil 3 flows through the plunger 4 and then spreads from the plunger insertion hole 6 into the plate member 5. In this example, since the notch 7 is formed in the plate-like member 5, the magnetic flux Φ spreads from the plunger insertion hole 6 substantially evenly. Therefore, the radial force applied to the plunger 4 is not biased and becomes equal.

  Moreover, as shown in FIG. 5, the plate-like member 5 has two plunger insertion holes 6a and 6b. A notch portion 7 is formed on a line connecting the centers of the two plunger insertion holes 6a and 6b and at an outer position of the two plunger insertion holes 6a and 6b.

  As shown in FIG. 5, two cutout portions 7, that is, a first cutout portion 7 a and a second cutout portion 7 b are formed. Further, the notch 7 is not integrated with the plunger insertion hole 6 and is formed at a position separated from the plunger insertion holes 6a and 6b by a predetermined distance. Each notch part 7a, 7b is formed in the shape used as object about line A which connects the centers of plunger penetration holes 6a, 6b. Each of the notches 7 a and 7 b has a shape having an arcuate outer peripheral edge 70 and an inner peripheral edge 71.

Next, an example of a circuit using the electromagnetic relay 1 of this example is shown in FIG. As shown in the figure, the electromagnetic relay 1 of this example is used for an inverter 8 for a vehicle. The inverter 8 converts the voltage of the DC power supply 82 mounted on the vehicle into AC. Then, the three-phase AC motor 81 is driven by this AC voltage to drive the vehicle.
When connecting the DC power source 82 and the inverter 8, the electromagnetic coil 3 (see FIG. 1) of the electromagnetic relay 1 is energized, and the switches 2A and 2B are turned on. In this example, there are a case where the motor 81 is driven using electric power of the DC power source 82 and a case where the motor 81 is used as a generator when the vehicle is braked and the DC power source 82 is charged. In any case, the DC power supply 82 and the inverter 8 are connected by turning on the electromagnetic relay 1.

  In the above embodiment, an example in which two plunger insertion holes 6 are provided has been described. However, as shown in FIG. 7, three plunger insertion holes 6 may be provided. In this case, three plunger insertion holes 6 may be arranged in a straight line, and two notches 7 may be provided on both sides thereof. Similarly, four or more plunger insertion holes 6 can be formed.

The effect of the electromagnetic relay 1 of this example is demonstrated.
As shown in FIGS. 1 to 4, the electromagnetic relay 1 of the present invention has a plurality of switches 2 each composed of a movable contact portion 21 and a fixed contact portion 20, and a plunger 4 is individually provided for each movable contact portion 21. It was. Thus, for example, when used in the circuit shown in FIG. 6, even if one of the plurality of plungers 4 is fixed or one switch 2 is welded, the other plunger 4 operates, As a whole, the electromagnetic relay 1 can ensure normal operation. Therefore, the operation reliability of the electromagnetic relay 1 can be improved.
For example, there is a possibility that the magnetic portion 40 of the plunger 4 and the plate-like member 5 are fixed by frictional heat, or the fixed contact portion 20 and the movable contact portion 21 are welded by heat due to electric current. Even in this case, since the plunger 4 is separated, the plunger that is not fixed operates normally.

  Moreover, the electromagnetic relay 1 of this example has only one electromagnetic coil 3. Although a plurality of electromagnetic coils 3 can be provided, there is a problem that the manufacturing cost of the electromagnetic relay 1 is increased and the size is increased. However, such a problem can be avoided if there is only one electromagnetic coil 3.

  The electromagnetic relay 1 of this example can be suitably used for a circuit that allows a large current to flow. When a large current is applied, the switch may be welded by resistance heat. However, if the plunger 4 is provided for each switch 2 as in the present invention, the other switch 2 operates even when one switch 2 is welded, so that the electromagnetic relay 1 as a whole can ensure normal operation.

Further, as shown in FIG. 6, the electromagnetic relay 1 of this example is used in a circuit that connects a power source 82 and loads 8 and 81, and one of the two switches 2A and 2B has one switch 2A. The other switch 2B is provided on the wiring connecting the second electrode (negative electrode) of the power source 82 and the loads 8, 81. The other switch 2B is provided on the wiring connecting the one electrode (positive electrode) and the loads 8, 81.
In this way, even if one of the two switches 2A and 2B is welded or the like, the other switch operates normally, so that the power supply 82 can be turned on and off with only the normal switch. . Thereby, the reliability of a circuit can be improved.

In this example, as shown in FIGS. 1 and 5, a plate-like member 5 made of a magnetic material and having a plunger insertion hole 6 is provided, and the plate-like member 5 is provided with a notch 7.
By providing the plate-like member 5 made of a magnetic material in this way, the magnetic field generated around the electromagnetic coil 3 can be strengthened, and the plunger 4 can be advanced and retracted with a strong force.
As shown in FIGS. 2 and 5, the magnetic flux Φ generated by the electromagnetic coil 3 passes through the magnetic portion 40 of the plunger 4, moves to the plate-like member 5, and spreads around the plunger insertion hole 6.

  Here, as shown in the comparative example of FIG. 8, in the case where a plurality of plunger insertion holes 96 are formed in the plate-like member 95 and the notch portion is not formed, the magnetic flux Φ has a higher magnetic density. Therefore, the magnetic flux easily flows in the direction in which the other plunger insertion holes are not formed. Therefore, the flow of the magnetic flux Φ is unbalanced, and the radial force applied to the plunger 94 tends to be unbalanced. Therefore, the problem that the plunger 94 cannot move smoothly tends to occur.

  However, as shown in FIG. 5, the magnetic flux density around the plunger insertion hole 7 can be made uniform by forming the notch 7 in the plate-like member 5. As a result, the radial force applied to the plunger 4 becomes uniform, and the plunger 4 moves smoothly. Therefore, problems such as the plunger 4 sticking are less likely to occur, and the operation reliability of the electromagnetic relay 1 can be improved.

Further, in this example, as shown in FIG. 5, the plunger insertion holes 6 are provided on the line connecting the centers of the two plunger insertion holes 6a and 6b, and the two plunger insertion holes 6a and 6b. Cutout portions 7a and 7b are formed at the outer positions.
If it does in this way, it will become easy to make the magnetic flux density around the plunger penetration hole 6 uniform. That is, since the magnetic flux Φ tends to flow in a direction in which the density of the magnetic body is higher, as shown in the comparative example of FIG. 8, the two plunger insertion holes 96 are provided adjacent to each other, and the notch portion is not formed. Then, the magnetic flux Φ around each plunger insertion hole 96 tends to go to the opposite side (outside) from the other plunger insertion hole 96. Therefore, the magnetic flux density on the outside increases, and the force applied to the plunger 94 becomes unbalanced.
However, as shown in FIG. 5, it is possible to make the magnetic flux density uniform by providing the cutout portion 7 in the outer portion. Thereby, the radial force applied to the plunger 4 can be made uniform, and the plunger 4 moves smoothly. Therefore, the plunger 4 is less likely to stick.

Further, in this example, as shown in FIG. 5, the notch 7 is not integrated with the plunger insertion hole 6, and is formed at a position separated from the plunger insertion hole 6 by a predetermined distance.
Although the notch 7 can be formed integrally with the plunger insertion hole 6, in this case, the boundary between the plunger insertion hole 6 and the notch 7 may have an angular shape. Therefore, when the plunger 4 comes into contact with this portion, it may be difficult to smoothly advance and retract.
However, if the notch portion 7 is provided at a position different from the plunger insertion hole 6 as described above, the degree of freedom of the shape of the notch portion 7 is increased, and an angular portion is not formed. Problems can be avoided.

  Moreover, it is preferable that the electromagnetic relay 1 comprises the 2a contact from which the two switches 2 open when the electromagnetic coil 3 is not energized. When the contact point 2a is used, it is sufficient to energize only when the switch 2 is turned on, so that power consumption can be reduced. Further, when two switches 2 are attached, it is easy to cut off the current I.

(Example 2)
In this example, the shape of the cutout portion 7 is changed. As shown in FIG. 9, in this example, the plunger insertion hole 6 and the notch 7 are integrally formed. If it does in this way, since the notch part 7 is formed in the immediate vicinity of the plunger penetration hole 6, the effect of the notch part 7 will appear strongly compared with the case where it forms far. Therefore, even when the size of the notch 7 is small, the magnetic flux Φ can be made uniform, and consequently the radial force applied to the plunger 4 can be made uniform.
In addition, the same configuration and effects as those of the first embodiment are obtained.

DESCRIPTION OF SYMBOLS 1 Electromagnetic relay 2 Switch 20 Fixed contact part 21 Movable contact part 3 Electromagnetic coil 4 Plunger 5 Plate-shaped member 6 Plunger insertion hole 7 Notch

Claims (4)

An electromagnetic relay that has a plurality of switches composed of a movable contact portion and a fixed contact portion, and switches between an on state and an off state of the switch,
One electromagnetic coil that generates magnetic flux when energized;
Provided inside of the electromagnetic coil, at least a portion with is made of a magnetic material, and a plurality of plunger advanced and retracted in the axial direction of the solenoid coil by the presence or absence of the energization of the said electromagnetic coil,
The movable contact portion is attached to each of the plurality of plungers,
The electromagnetic relay according to claim 1, wherein the fixed contact portion is provided at a position where the movable contact portion is brought into contact with or separated from the plunger as the plunger moves forward and backward. 2. The plunger according to claim 1, further comprising a plate-like member made of a magnetic body, the plate-like member having a shape similar to the outer shape of the plunger and having a plunger insertion hole penetrating in the plate thickness direction with a predetermined clearance. and is the plate-like member, which forms part of a magnetic circuit the magnetic flux generated from the electromagnetic coil passes, notch for equalizing force acting in the radial direction to the plunger by the magnetic flux It is formed in the said plate-shaped member, The electromagnetic relay characterized by the above-mentioned. In Claim 2, it has two said plunger insertion holes, and is on the line which connects the center of said two plunger insertion holes, Comprising: The said notch part is formed in the outer position of said two plunger insertion holes. An electromagnetic relay characterized by that. In claim 3, the electromagnetic relay, characterized in that the notch is not integral with the plunger insertion hole, a predetermined distance from the plunger insertion hole is formed at a position familiar.

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