This application is a U.S. national stage application of the PCT international application No. PCT/JP2014/003864.
The present technology relates to an electromagnetic relay opening and closing a contact device by an electromagnet device.
When a voltage is applied to coil 502, movable element 503 is attracted by permanent magnet 505. Thereby, fixed contact 510 and movable contact 511 are brought into contact with each other, and contact device 520 is turned on. Then, even after excitation of coil 502 is released, movable element 503 is held by magnetic flux of permanent magnet 505, and contact device 520 is continued to be on.
When an abnormal current such as an overcurrent and a short-circuit current flows into contact device 520, movable element 503 is driven by overcurrent detection coil 513 in a reverse direction to permanent magnet 505, and contact device 520 is turned off. Thus, electromagnetic relay 500 forcibly restores movable element 503 by using magnetic flux generated when an abnormal current flows. That is to say, electromagnetic relay 500 can detect generation of an abnormal current and disconnect an electric circuit. As prior art literatures of the above-mentioned conventional technology, for example, PTL 1 is well known.
Patent Literature 1: Japanese Patent Application Unexamined Publication No. S57-163939
An electromagnetic relay includes an electromagnet device, a contact device, and a trip device.
The electromagnet device includes a first stator, a movable element, and a first exciting coil. The movable element is disposed facing the first stator. The first exciting coil is wound around at least a part of the first stator. When the first exciting coil is energized, the electromagnet device attracts the movable element to the first stator by first magnetic flux generated by the first exciting coil, and moves the movable element from a first position to a second position.
The contact device includes a movable contact and a fixed contact. The movable contact is disposed on the opposite side to the movable element with respect to the first stator, and linked to the movable element. The fixed contact is disposed facing the movable contact.
A trip device includes a second exciting coil, and is disposed on the opposite side to the contact device with respect to the electromagnet device. The second exciting coil is coupled to the contact device. The trip device moves the movable element to a third position by a second magnetic flux generated by the second exciting coil when not less than a prescribed value of electric current flows in the contact device in a state in which the movable element is in the second position.
When the movable element is in the first position and the third position, the movable contact and the fixed contact are away from each other to form an open state. When the movable element is in the second position, the movable contact and the fixed contact are brought into contact with each other to form a closed state.
A conventional electromagnetic relay 500 needs space for disposing overcurrent detection coil 513 between coil 502 and contact device 520. Furthermore, in conventional electromagnetic relay 500, movable element 503 is attracted by magnetic flux generated by overcurrent detection coil 513. However, since overcurrent detection coil 513 is disposed between coil 502 and contact spring 512, a structure of movable element 503 is restricted. Therefore, it is necessary to form a component such as movable element 503 into a special shape. That is to say, in conventional electromagnetic relay 500, it is necessary to specially design a component such as movable element 503 to turn off contact device 520 when an abnormal current such as an overcurrent and a short-circuit current flows into contact device 520. Thus, when overcurrent detection coil 513 is disposed, it is difficult to share components with a movable element and the like when overcurrent detection coil 513 is not provided.
Electromagnetic relay 1 includes electromagnet device 3, contact device 2, and trip device 4.
Electromagnet device 3 includes first stator 33, movable element 32, and first exciting coil 31. Movable element 32 is disposed facing first stator 33. First exciting coil 31 is wound around at least a part of first stator 33. At the time of energization of the first exciting coil, electromagnet device 3 attracts movable element 32 to first stator 33 by first magnetic flux generated by first exciting coil 31, and moves movable element 32 from the first position to the second position.
Contact device 2 includes movable contacts 21a and 21b and fixed contacts 22a and 22b. Movable contacts 21a and 21b are disposed on the opposite side to movable element 32 with respect to first stator 33, and linked to movable element 32. Fixed contacts 22a and 22b are disposed facing movable contacts 21a and 21b.
Trip device 4 includes second exciting coil 41, and is disposed on the opposite side to contact device 2 with respect to electromagnet device 3. Second exciting coil 41 is coupled to contact device 2. Trip device 4 moves movable element 32 to a third position by a second magnetic flux generated by second exciting coil 41 when not less than a prescribed value of electric current flows in contact device 2 in a state in which movable element 32 is in the second position.
When movable element 32 is in the first position and the third position, movable contacts 21a and 21b and fixed contacts 22a and 22b are away from each other to form an open state. When movable element 32 is in the second position, movable contacts 21a and 21b and fixed contacts 22a and 22b are brought into contact with each other to form a closed state.
Herein, it is preferable that trip device 4 further includes second stator 43 disposed on the opposite side to first stator 33 with respect to movable element 32. In this case, movable element 32 is attracted to second stator 43 by the magnetic flux generated due to an abnormal current in second exciting coil 41.
Hereinafter, electromagnetic relay 1 of this exemplary embodiment is described. However, electromagnetic relay 1 described below is just an example of the present invention. The present invention is not limited to the following exemplary embodiments and may include other exemplary embodiments. Various modifications can be made depending on designs and the like without departing from the scope of the technical idea in accordance with the present invention.
Electromagnetic relay 1 includes contact device 2, electromagnet device 3, and trip device 4. Furthermore, electromagnetic relay 1 may include shaft 15, case 16, and connector 17. In addition, electromagnetic relay 1 may include first output terminal 51 and second output terminal 52 on a power supply path of direct-current power from travelling battery 101 to load 102, and input terminals 53 and 54 connected to excitation power source 105 (see
Contact device 2, electromagnet device 3, and trip device 4 are disposed in one direction (on the same straight line). Trip device 4 is disposed on the opposite side to contact device 2 with respect to electromagnet device 3.
In this exemplary embodiment, electromagnetic relay 1 is mounted on electric vehicle (EV). As shown in
Next, electromagnet device 3 is described. Electromagnet device 3 includes first exciting coil 31, movable element 32, and first stator 33. Furthermore, electromagnet device 3 may include first yoke 34, return spring 35, and cylindrical body 36. In addition, electromagnet device 3 may include a coil bobbin (not shown) which is made of synthetic resin and around which first exciting coil 31 is wound.
Movable element 32 is attracted to first stator 33 by magnetic flux generated by first exciting coil 31 when first exciting coil 31 is energized, and movable element 32 moves from the first position shown in
First yoke 34 includes yoke upper plate 341, yoke lower plate 342, yoke lateral plate 343, and bush 344. Yoke upper plate 341, yoke lower plate 342, yoke lateral plate 343, and bush 344 are formed of magnetic material. That is to say, first yoke 34 is formed of magnetic material. Furthermore, first stator 33 and movable element 32 are also formed of magnetic material. Consequently, first yoke 34, together with first stator 33 and movable element 32, forms a magnetic path (first magnetic path) through which the magnetic flux generated at the time of energization of first exciting coil 31 passes (detail thereof is described later with reference to
Yoke upper plate 341 and yoke lower plate 342 are provided on both sides of first exciting coil 31 and face each other. In the side cross-section of electromagnetic relay 1 shown in
Yoke lateral plate 343 links the peripheral edge of yoke upper plate 341 and the peripheral edge of yoke lower plate 342 to each other. Bush 344 is formed in a cylindrical shape protruding upward from the center portion of the upper surface of yoke lower plate 342. Each of yoke upper plate 341 and yoke lower plate 342 is formed in a rectangular shape. These yoke lateral plate 343 and yoke lower plate 342 are formed continuously and unitarily from one plate. Holding hole 27 is formed in the center portion of yoke lower plate 342. The lower end part of bush 344 is fitted into holding hole 27 of yoke lower plate 342.
First exciting coil 31 is disposed in space surrounded by yoke upper plate 341, yoke lower plate 342 and yoke lateral plate 343. Then, bush 344, first stator 33, and movable element 32 are disposed in the inner side of first exciting coil 31. Both ends of first exciting coil 31 are connected to input terminals 53 and 54, respectively (see
First stator 33 is a cylindrical fixed iron core, and protrudes downward from the center portion of yoke upper plate 341. The upper end part of first stator 33 is fixed to yoke upper plate 341 of first yoke 34. Specifically, fitting hole 26 is formed in the center portion of yoke upper plate 341. The upper end part of first stator 33 is fitted into fitting hole 26 of yoke upper plate 341. The outer diameter of first stator 33 is formed to be smaller than the inner diameter of bush 344. Furthermore, a clearance (gap) is formed between the lower end surface of first stator 33 and the upper end surface of bush 344 in the vertical direction.
Movable element 32 is a columnar movable iron core, and is disposed such that the upper end surface thereof faces the lower end surface of first stator 33. The outer diameter of movable element 32 is formed to be equal to the outer diameter of first stator 33 and smaller than the inner diameter of bush 344. Movable element 32 moves in the vertical direction along the inner peripheral surface of bush 344. In other words, movable element 32 moves between the first position in which the upper end surface of movable element 32 is away from the lower end surface of first stator 33 (see
Return spring 35 is disposed in the inner side of first stator 33, and it is a coil spring urging movable element 32 downward (to the first position). Housing space 331 for housing return spring 35 is formed in the inner side of first stator 33. When movable element 32 is attracted to first stator 33 and moves from the first position to the second position, return spring 35 is housed in housing space 331 while it is compressed. Consequently, movable element 32 can be brought into contact with first stator 33.
Cylindrical body 36 is formed of non-magnetic material having a bottomed cylindrical shape with a top surface opened. Cylindrical body 36 houses first stator 33 and movable element 32. The upper end part (peripheral edge of the opening part) of cylindrical body 36 is fixed to yoke upper plate 341, and the lower part of cylindrical body 36 is fitted into the inner side of bush 344. A distance from the bottom surface of cylindrical body 36 to the lower end surface of first stator 33 is sufficiently larger than the dimension in the vertical direction of movable element 32. That is to say, cylindrical body 36 is set such that a clearance is generated between the lower end surface of movable element 32 and the bottom surface of cylindrical body 36 in a state in which movable element 32 is away from first stator 33, that is, in the first position.
With the above-mentioned configuration, movable element 32 can move inside cylindrical body 36 from the second position in which movable element 32 is brought into contact with first stator 33 to the third position by way of the first position. When movable element 32 is in the second position, gap G1 (see
Note here that the central axes of first exciting coil 31, bush 344, first stator 33, and movable element 32 are located in the same line along the vertical direction.
When first exciting coil 31 is not energized (at the time of non-energization), since a magnetic attractive force is not generated between movable element 32 and first stator 33, movable element 32 is located in the first position by a spring force of return spring 35 (see
In other words, at the time of energization of first exciting coil 31, first exciting coil 31 generates magnetic flux in a magnetic path (first magnetic path) formed by first yoke 34, first stator 33, and movable element 32. Movable element 32 moves so as to reduce magnetic resistance of this magnetic path. Specifically, at the time of energization of first exciting coil 31, movable element 32 moves from the first position to the second position so as to fill a gap between the lower end surface of first stator 33 and the upper end surface of bush 344 with movable element 32.
In short, movable element 32 is attracted to first stator 33 by the magnetic flux generated by first exciting coil 31 at the time of energization of first exciting coil 31, and movable element 32 moves from the first position to the second position. Then, while the energization of first exciting coil 31 continues, since an attractive force continues to be generated between first stator 33 and movable element 32, movable element 32 is held in the second position. Furthermore, when the energization of first exciting coil 31 is stopped, movable element 32 moves from the second position to the first position by the spring force of return spring 35. Thus, in response to switching of the energization states of first exciting coil 31, an attractive force acting on movable element 32 is controlled. As a result, movement of movable element 32 in the vertical direction switches the states of contact device 2 between an open state and a closed state.
Herein, at the time of non-energization of first exciting coil 31, movable element 32 is located not in the third position that is the bottom end of the moving range (see
At the time of non-energization of first exciting coil 31, movable element 32 of electromagnet device 3 is located in the first position that is an intermediate position between the second position and the third position. Therefore, shaft 15 is drawn downward by electromagnet device 3. At this time, shaft 15 pushes movable contactor 13 downward by flange 151 provided at the upper end part of shaft 15. Since upward movement of movable contactor 13 is restricted by flange 151 of shaft 15, movable contacts 21a and 21b are in the open position and are away from fixed contacts 22a and 22b. In this state, since contact device 2 is in an open state, contact bases 11 and 12 are not conducting with each other, and first output terminal 51 and second output terminal 52 are not conducting with each other.
Although details are described later, as shown in
At this time, an appropriate over-travel is set to shaft 15 so that shaft 15 can be further pushed up after movable contacts 21a and 21b are brought into contact with fixed contacts 22a and 22b. Since movable contactor 13 is urged upward by contact pressure spring 14, contact pressure between movable contacts 21a and 21b and fixed contacts 22a and 22b is secured. In a state shown in
Next, contact device 2 is described in detail. As shown in
When movable contacts 21a and 21b move in response to the movement of movable element 32 and movable element 32 is in the second position, contact device 2 is in a closed state in which movable contacts 21a and 21b are brought into contact with fixed contacts 22a and 22b. When movable element 32 is in the first position and the third position, contact device 2 is in an open state in which movable contacts 21a and 21b are away from fixed contacts 22a and 22b.
A pair of contact bases 11 and 12 of contact device 2 are arranged in one direction in a plane perpendicular to the vertical direction above electromagnet device 3. Contact bases 11 and 12 are formed in a columnar shape having a circular horizontal sectional. The pair of contact bases 11 and 12 are fixed at a predetermined distance from first yoke 34 and first stator 33 of electromagnet device 3.
Specifically, the pair of contact bases 11 and 12 are fixed to case 16 which is joined to first yoke 34. Case 16 is formed in a box shape whose bottom surface is opened. Fixed contacts 22a and 22b and movable contacts 21a and 21b are disposed between case 16 and yoke upper plate 341. Case 16 is formed of, for example, heat-resistant material such as ceramic. The peripheral edge of the bottom portion of case 16 is joined to the peripheral edge of the upper surface of yoke upper plate 341 via connector 17. Contact bases 11 and 12 are joined to case 16 in a state in which contact bases 11 and 12 are respectively inserted through round holes 19a and 19b formed in base plate 161 (upper wall) of case 16.
Note here that it is desirable that case 16, connector 17, yoke upper plate 341, and cylindrical body 36 form a hermetic container having space inside. Furthermore, it is desirable that the inside of the hermetic container be filled with arc-extinguishing gas mainly containing hydrogen. Thus, even if an arc discharge occurs when fixed contacts 22a and 22b and movable contacts 21a and 21b housed in the hermetic container become an open state, the arc discharge is quickly cooled by the arc-extinguishing gas and can be arc-extinguished rapidly. However, fixed contacts 22a and 22b and movable contacts 21a and 21b are not necessarily housed in a hermetic container.
Fixed contacts 22a and 22b are provided on the lower end part of contact bases 11 and 12, respectively. Contact bases 11 and 12 are formed of conductive material. The upper end parts of contact bases 11 and 12 are formed larger as compared with parts other than the upper end parts. First output terminal 51 is coupled to the upper end part of first contact base 11 via second exciting coil 41. Second output terminal 52 is coupled to the upper end part of second contact base 12. That is to say, second exciting coil 41 is inserted between first contact base 11 and first output terminal 51. As shown in
Movable contactor 13 is formed in a rectangular plate shape, and is disposed below contact bases 11 and 12 so that both end parts of movable contactor 13 in the longitudinal direction thereof face the lower end parts of contact bases 11 and 12. Movable contactor 13 is formed of conductive material. Movable contacts 21a and 21b are provided to movable contactor 13 in the portions confronting fixed contacts 22a and 22b of contact bases 11 and 12.
Movable contactor 13 is driven in the vertical direction by electromagnet device 3. Thus, movable contacts 21a and 21b provided to movable contactor 13 move between a closed position in which movable contacts 21a and 21b are brought into contact with the corresponding fixed contacts 22a and 22b and an open position in which movable contacts 21a and 21b are away from fixed contacts 22a and 22b. When movable contacts 21a and 21b are in the closed position, that is, contact device 2 is in a closed state, first contact base 11 and second contact base 12 are short-circuited to each other via movable contactor 13. Consequently, in a state in which contact device 2 is closed, first output terminal 51 and second output terminal 52 conduct with each other via second exciting coil 41, so that direct-current power is supplied from travelling battery 101 to load 102 via second exciting coil 41.
Contact pressure spring 14 is disposed between first stator 33 and movable contactor 13, and is a coil spring urging movable contactor 13 upward. A spring force of contact pressure spring 14 is set smaller than that of return spring 35.
Shaft 15 is formed of non-magnetic material having a round-bar shape extending in the vertical direction. Shaft 15 transmits a driving force generated in electromagnet device 3 to contact device 2 provided above electromagnet device 3. Shaft 15 has flange 151 at the upper end part thereof. The outer diameter of flange 151 is larger than that of the upper end part of shaft 15. Movable contactor 13 has hole 25 at the center portion thereof. The outer diameter of hole 25 is smaller than that of flange 151 of shaft 15. Shaft 15 is inserted through hole 25 of movable contactor 13 so that the upper surface of shaft 15 is brought into contact with flange 151 on the upper surface of movable contactor 13. Furthermore, shaft 15 passes through the inside of contact pressure spring 14, first stator 33, and return spring 35. The lower end part of shaft 15 is fixed to movable element 32.
From the above-mentioned configuration, the driving force generated in electromagnet device 3 is transmitted to movable contactor 13 by shaft 15. In response to the movement of movable element 32 in the vertical direction, movable contactor 13 moves in the vertical direction.
Next, trip device 4 is described. Trip device 4 has second exciting coil 41 connected in series to contact device 2. Trip device 4 moves movable element 32 to the third position with magnetic flux generated by second exciting coil 41 by not less than a prescribed value of abnormal current flowing through contact device 2 in a state in which movable element 32 is in the second position. Contact device 2, electromagnet device 3, and trip device 4 are arranged in one direction, and trip device 4 is disposed on the opposite side to contact device 2 with respect to electromagnet device 3.
Trip device 4 may include second stator 43 disposed on the opposite side to (i.e., below) first stator 33 with respect to movable element 32. In addition, trip device 4 may include second yoke 44.
When not less than a prescribed value of abnormal current flows through contact device 2 in a state in which movable element 32 is in the second position, magnetic flux is generated by second exciting coil 41. Then, with the magnetic flux, an attractive force in a reverse direction to first stator 33 acts on movable element 32. As s a result, movable element 32 is attracted to second stator 43, and movable element 32 moves to the third position.
That is to say, trip device 4 moves movable element 32 to the third position by the magnetic flux generated by second exciting coil 41 when second exciting coil 41 is energized. Thus, contact device 2 is forced to be an open state. Hereinafter, an operation in which trip device 4 makes contact device 2 to be in an open state is referred to as “trip.” In other words, the “trip” denotes that movable element 32 moves (trips) from the second position to the first position or the third position.
Herein, the third position is on an extension of a moving axis of movement element 32 linking between the second position and the first position, and on the opposite side to (i.e., below) the second position with respect to the first position. In other words, the first position is a position (middle position) between the second position and the third position. In a state in which trip device 4 is not operated, movable element 32 is in the first position at the time of non-energization of first exciting coil 31, and in the second position at the time of energization of first exciting coil 31. When trip device 4 is operated, movable element 32 is in the third position as shown in
Second yoke 44 of trip device 4 includes lower plate 442 and lateral plate 443. Lower plate 442 and lateral plate 443 are formed of magnetic material. That is to say, second yoke 44 is formed of magnetic material. Second stator 43 is also formed of magnetic material. Consequently, second yoke 44, together with second stator 43 and movable element 32, forms a magnetic path (second magnetic path) through which magnetic flux generated at the time of energization of second exciting coil 41 passes (see
Yoke lower plate 342 and bush 344 of first yoke 34 are used also as the upper plate of second yoke 44. Second yoke 44 has lower plate 442 below second exciting coil 41. Lower plate 442 faces yoke lower plate 342 of first yoke 34. Hereinafter, yoke lower plate 342 used also as the upper plate of second yoke 44, and bush 344 are described not only as a part of first yoke 34, but also as a member composing a part of second yoke 44.
Lateral plate 443 links the peripheral edge of yoke lower plate 342 and the peripheral edge of lower plate 442 to each other. Since yoke lower plate 342 and lower plate 442 are formed in a rectangular plate shape, respectively, a pair of lateral plates 443 are provided so that a pair of sides facing each other in the bottom surface of yoke lower plate 342 and a pair of sides facing each other in the top surface of lower plate 442 are linked to each other. Lateral plate 443 and lower plate 442 are formed unitarily by one plate.
Second exciting coil 41 is disposed in space surrounded by second yoke 44, and second stator 43 is disposed in the inner side of second exciting coil 41. Furthermore, in the inner side of second exciting coil 41, the lower end part of cylindrical body 36 is disposed. That is to say, cylindrical body 36 penetrates through yoke lower plate 342 of first yoke 34, and the lower end part of cylindrical body 36 extends to the inner side of second exciting coil 41.
Second stator 43 is a columnar fixed iron core protruding upward from the center portion of the upper surface of lower plate 442. The lower end part of second stator 43 is fitted into holding hole 28 formed in the center portion of lower plate 442, and thereby second stator 43 is fixed to second yoke 44. The outer diameter of second stator 43 is the same as that of movable element 32. That is to say, the outer diameter of second stator 43 is the same as that of first stator 33. Note here that the outer diameter of second stator 43 is not necessarily the same as the outer diameters of movable element 32 and first stator 33, it may be larger or smaller than the outer diameter of movable element 32. The effect when the outer diameter of first stator 33 is smaller than the outer diameter of second stator 43 is described later.
Herein, second stator 43 is disposed so that the upper end surface of second stator 43 is brought into contact with the lower surface of cylindrical body 36. Thus, in a state in which movable element 32 is in the second position (the state shown in
Herein, trip device 4 is configured such that all of movable element 32, second exciting coil 41, and second stator 43 have a central axis on the same line along the vertical direction.
Trip device 4, contact device 2, and electromagnet device 3 are arranged in one direction (vertical direction). Trip device 4 is disposed on the opposite side to contact device 2 with respect to electromagnet device 3. That is to say, trip device 4 is disposed below electromagnet device 3.
Herein, second exciting coil 41 is connected in series to contact device 2 between first output terminal 51 and second output terminal 52 as described above. In this exemplary embodiment, second exciting coil 41 is connected between first contact base 11 and first output terminal 51. Thus, second exciting coil 41 forms a part of a path of a load current supplied from travelling battery 101 to load 102 in a state in which contact device 2 is closed, and second exciting coil 41 is excited by the load current.
Note here that bypass path 6 may be electrically connected in parallel to second exciting coil 41 so that a load current can be allowed to flow in a path other than second exciting coil 41 (see
At this time, due to magnetic flux generated by second exciting coil 41, a magnetic attractive force is generated between movable element 32 and second stator 43. That is to say, a force to attract movable element 32 downward is generated. In other words, second exciting coil 41 generates magnetic flux to a magnetic path formed by second yoke 44, second stator 43, and movable element 32. Consequently, an attractive force, in a direction in which movable element 32 is moved such that the magnetic resistance of the magnetic path is reduced, acts on movable element 32. In other words, trip device 4 allows an attractive force to act on movable element 32 in a direction in which movable element 32 is moved from the second position to the third position such that a gap in the magnetic path between the upper end surface of second stator 43 and the lower end surface of bush 344 is filled with movable element 32.
As a result, in electromagnetic relay 1 having the above-mentioned configuration, in a state in which first exciting coil 31 is energized and contact device 2 is closed, that is, in a state in which movable element 32 is in the second position (see
The first force F1 is an attractive force acting on movable element 32 from first stator 33 by magnetic flux generated by first exciting coil 31 when first exciting coil 31 is energized in electromagnet device 3. The second force F2 is a force synthesizing a spring force acting on movable element 32 from return spring 35 and a spring force acting on movable element 32 from contact pressure spring 14 via movable contactor 13 and shaft 15. That is to say, the second force F2 is a force obtained by subtracting a force acting upward from contact pressure spring 14 to movable element 32 from a force acting downward on movable element 32 from return spring 35. The third force F3 is an attractive force acting on movable element 32 from second stator 43 by magnetic flux generated by second exciting coil 41 when second exciting coil 41 is energized, in trip device 4.
The third force F3 as an attractive force acting on movable element 32 from second stator 43 is represented by the following mathematical formula (Math. 1).
In the formula discussed above, “N” represents the number of windings of second exciting coil 41, “I” represents an amount of electric current flowing in second exciting coil 41, “S” represents an area of movable element 32 facing second stator 43, “μ0 to” represents magnetic permeability in vacuum, “g” is a clearance (gap) between movable element 32 and second stator 43.
In electromagnetic relay 1, in a state in which movable element 32 is in the second position, when the first force F1 is smaller than a sum of the second force F2 and the third force F3 (F1<F2+F3), movable element 32 is moved to the third position by trip device 4, and contact device 2 is forced to be in an open state. In short, movable element 32 is in the second position when the first force F1 acting upward is larger than the sum of the second force F2 and the third force F3 acting downward, and movable element 32 moves to the third position when the first force F1 is smaller than the sum of the second force F2 and the third force F3.
Herein, trip device 4 trips not when a load current simply flows in second exciting coil 41, but trips for the first time when the third force F3 as an attractive force acting on movable element 32 from second stator 43 satisfies the above-mentioned condition (F1<F2+F3). The attractive force acting on movable element 32 from second stator 43 varies depending upon the amount of electric current (load current) flowing in second exciting coil 41. Thus, trip device 4 is configured such that the third force F3 as an attractive force acting on movable element 32 from second stator 43 satisfies the above-mentioned condition (F1<F2+F3) when the electric current flowing in second exciting coil 41 becomes an abnormal current that is not less than the prescribed value of electric current.
That is to say, when not less than a prescribed value of abnormal current such as an overcurrent and a short-circuit current flows in contact device 2, trip device 4 moves movable element 32 to the third position. Specifically, in trip device 4, the number of windings of second exciting coil 41 and gaps G1 (see
Thus, when an abnormal current such as an overcurrent and a short-circuit current flows through contact device 2, trip device 4 moves movable element 32 to the third position, and thus contact device 2 is forced to be in an open state. When contact device 2 is in a closed state, movable element 32 is attracted to first stator 33 by the magnetic flux generated by first exciting coil 31. Then, when the sum of the second force F2 and the third force F3 is larger than the attractive force, movable element 32 is attracted to second stator 43. Furthermore, in tripping, the nearer to second stator 43 movable element 32 is, the larger the attractive force between second stator 43 and movable element 32 becomes. Consequently, a speed at which contact device 2 is opened is gradually increased.
As mentioned above, electromagnetic relay 1 forcibly restores movable element 32 by using the magnetic flux generated when an abnormal current flows. As a result, generation of the abnormal current is promptly detected, and an electric circuit (contact device 2) is disconnected rapidly.
Herein, a member for forming a magnetic path through which magnetic flux generated by second exciting coil 41 is allowed to pass is referred to as a second magnetic path member. The second magnetic path member includes movable element 32, second stator 43, and second yoke 44. Furthermore, second yoke 44 includes yoke lower plate 342, bush 344, lower plate 442, and lateral plate 443. It is desirable that the second magnetic path member be configured such that the minimum value of a cross-sectional area of the magnetic path becomes a predetermined lower limit value or more. That is to say, in trip device 4, when the cross-sectional area of the above-mentioned magnetic path is made to be larger, even when excessive electric current such as a short-circuit current flows into second exciting coil 41, magnetic saturation does not easily occur.
Furthermore, a member for forming a magnetic path through which the magnetic flux generated by first exciting coil 31 is allowed to pass is referred to as a first magnetic path member. The first magnetic path member includes movable element 32, first stator 33, and first yoke 34. Furthermore, first yoke 34 includes yoke upper plate 341, yoke lower plate 342, yoke lateral plate 343, and bush 344. It is desirable that the first magnetic path member be configured such that the minimum value of a cross-sectional area of the magnetic path is smaller as compared with the second magnetic path member. That is to say, it is desirable that the minimum value of the cross-sectional area of the first magnetic path be smaller than the minimum value of the cross-sectional area of the second magnetic path. For example, it is preferable that the diameter of at least a part of the first magnetic path member (for example, first stator 33) is formed to be smaller than the diameter of a part of the second magnetic path member (for example, second stator 43). That is to say, when first stator 33 is a cylindrical fixed iron core, and second stator 43 is a columnar fixed iron core, it is preferable that the outer diameter of first stator 33 is smaller than the outer diameter of second stator 43.
Thus, magnetic resistance of the magnetic path through which the magnetic flux generated by first exciting coil 31 passes is relatively higher than the magnetic resistance of the magnetic path through which the magnetic flux generated by second exciting coil 41 passes. Therefore, an attractive force generated between movable element 32 and second stator 43 becomes larger. Consequently, the speed at which contact device 2 is opened is increased, and electromagnetic relay 1 can rapidly disconnect the electric circuit (contact device 2) by using the magnetic flux generated when an abnormal current flows.
Furthermore, it is desirable that the first magnetic path member be configured such that the minimum value of a cross-sectional area of the magnetic path is a predetermined upper limit value or less. For example, it is preferable that the diameter of at least a part of the first magnetic path member (for example, first stator 33) is formed to be smaller than the diameter of a part of the second magnetic path member (for example, second stator 43).
Thus, the magnetic path through which the magnetic flux generated by first exciting coil 31 passes is easily magnetically saturated, and an attractive force generated between movable element 32 and first stator 33 becomes smaller. Therefore, an attractive force of movable element 32 necessary for tripping becomes smaller, trip device 4 can trip by a relatively small force. As a result, the speed at which contact device 2 is opened is increased, electromagnetic relay 1 can rapidly disconnect the electric circuit (contact device 2) by using the magnetic flux generated when an abnormal current flows.
Next, a configuration in which electromagnetic relay 1 is provided with trip device 4 mentioned above, an electric circuit can be promptly disconnected in response to an abnormal current from the closed state of contact device 2 is briefly described with reference to
In the case of load current X2 when trip device 4 is not provided, the electromagnetic relay is short-circuited at time t0, and cannot immediately make contact device 2 open even when load current X2 increases and reaches prescribed value I1 at time t1. In this case, load current X2 starts to decrease from time t3 at which electronic control unit 103 senses occurrence of an abnormal current by a protection function, and turns off switching element 104 by a control signal, so that energization of first exciting coil 31 is stopped. Further interrupting time period T2 is required by the time when the arc discharge between fixed contacts 22a and 22b and movable contacts 21a and 21b is arc-extinguished, and load current X2 is interrupted. Therefore, load current X2 is interrupted at time t4 when time period T20 has passed from time t0.
On the other hand, when trip device 4 is provided, electromagnetic relay 1 is short-circuited at time t0, and then, a load current X1 increases and reaches prescribed value I1 at time t1, trip device 4 makes contact device 2 open. Therefore, in this case, the load current X1 starts to decrease from time t1 at which the load current X1 reaches the prescribed value. Further interrupting time period T1 is required by the time when the arc discharge between fixed contacts 22a and 22b and movable contacts 21a and 21b is arc-extinguished, and a load current X1 is interrupted. The load current X1 is interrupted at time t2 when time period T10 has passed from time t0. Herein, time period T10 is much shorter than time period T20.
Note here that, in electromagnetic relay 1 having trip device 4, trip device 4 trips using a load current. Therefore, by time t3 at which the energization of first exciting coil 31 is stopped, after the load current is interrupted, contact device 2 becomes a closed state again and chattering may occur. In
Furthermore, it is also advantageous that when electromagnetic relay 1 has trip device 4, an increase of the load current can be reduced. That is to say, if trip device 4 is not provided, even when load current X2 reaches a predetermined electric current (overcurrent), contact device 2 is not immediately opened. Therefore, load current X2 may continue to increase and reach a short-circuit current larger than the overcurrent. On the contrary, when trip device 4 is provided, when the load current X1 reaches an overcurrent, contact device 2 is immediately opened. Therefore, the electric circuit is disconnected before load current X1 reaches a short-circuit current. Herein, the overcurrent is, for example, an electric current that is about 5 to 10 times larger than the rated current; the short-circuit current is, for example, about several tens of times larger than the rated current.
As mentioned above, electromagnetic relay 1 of this exemplary embodiment has trip device 4. Consequently, when not less than a prescribed value of abnormal current flows through contact device 2, movable element 32 is attracted due to magnetic flux generated by second exciting coil 41, and movable element 32 moves to the third position. Therefore, electromagnetic relay 1 can promptly turn off contact device 2 when an abnormal current such as an overcurrent and a short-circuit current flows in contact device 2.
Furthermore, contact device 2, electromagnet device 3, and trip device 4 are disposed in one direction; trip device 4 is disposed on the opposite side to contact device 2 with respect to electromagnet device 3. Since trip device 4 is added to the outer side of electromagnet device 3 and contact device 2, it is possible to share components such as movable element 32 with the components of an electromagnetic relay without having trip device 4. As a result, in electromagnetic relay 1, components such as movable element 32 may not be particularly designed.
In addition, it is preferable that trip device 4 has second stator 43 disposed on the opposite side to first stator 33 with respect to movable element 32. When second stator 43 attracts movable element 32, movable element 32 moves to the third position. When second stator 43 is disposed, an attractive force acting on movable element 32 becomes larger as compared with the case where second stator 43 is not provided, movable element 32 moves to the third position promptly. As a result, when an abnormal current such as an overcurrent and a short-circuit current flows in contact device 2, contact device 2 is turned off promptly. Note here that second stator 43 is not essential configuration, it may be omitted appropriately.
In this exemplary embodiment, as shown in
Therefore, an attractive force (first force F1 in
However, as another configuration example of this exemplary embodiment, as shown in
In trip device 4 shown in
Furthermore, in this exemplary embodiment, electromagnet device 3 is a so-called plunger type electromagnet device configured so as to allow movable element 32 to travel in a straight line in the vertical direction between the first position and the second position as mentioned above. Therefore, electromagnet device 3 and trip device 4 may allow attractive forces to act in the opposite direction to each other on movable element 32, thus enabling an attractive force to act efficiently. Herein, second yoke 44, together with movable element 32 and second stator 43, forms a magnetic path through which magnetic flux generated by second exciting coil 41 is allowed to pass.
Furthermore, yoke lower plate 342 and bush 344 are magnetically connected to second yoke 44 and movable element 32, respectively. It is preferable that the shortest distance from yoke lower plate 342 and bush 344 to second stator 43 is longer than the shortest distance from movable element 32 to second stator 43. In other words, as shown in
With this configuration, in magnetic flux generated by second exciting coil 41, leakage of magnetic flux passing between second stator 43 and yoke lower plate 342 or bush 344 without passing through movable element 32 is reduced. Consequently, the magnetic flux generated by the second exciting coil 41 is concentrated on between movable element 32 and second stator 43, thus increasing an attractive force acting between movable element 32 and second stator 43. Therefore, when an electric current value (prescribed value) at which tripping is carried out is the same, the number of windings of second exciting coil 41 can be reduced. When the number of windings of second exciting coil 41 is the same, an electric current value at which tripping is carried out can be made small.
Furthermore, it is desirable that second exciting coil 41 be wound around a moving axis of movable element 32, and disposed such that at least a part of second exciting coil 41 overlaps with movable element 32 in the second position in the direction perpendicular to the direction in which movable element 32 moves. That is, it is preferable that at least a part of the second exciting coil is disposed in the periphery of at least a part of the movable element located in the second position. That is to say, second exciting coil 41 is configured such that the lower end part of movable element 32 in the second position is inserted. In other words, in the second position as shown in
With this configuration, a part (lower end part) of movable element 32 is disposed in the inner side of second exciting coil 41 having magnetic flux density larger than in the outer side of second exciting coil 41, so that an attractive force acting between movable element 32 and second stator 43 is increased. Therefore, when the electric current value (prescribed value) at which tripping is carried out is the same, the number of windings of second exciting coil 41 can be reduced. When the number of windings of second exciting coil 41 is the same, an electric current value at which tripping is carried out can be reduced.
In addition, it is desirable that a distance between second stator 43 and movable element 32 located in the second position be shorter. When movable element 32 is located in the second position, that is, when contact device 2 is in the closed state, as a gap between second stator 43 and movable element 32 is smaller, an attractive force of movable element 32, which is required for tripping, is reduced. Therefore, trip device 4 can trip with a relatively small force.
Furthermore, as shown in
A load current supplied from travelling battery 101 to load 102 flows through second exciting coil 41. Therefore, in order to suppress loss (copper loss) in second exciting coil 41, it is desirable that the coil wire (copper wire) have a larger wire diameter and a shorter wire length. When the number of windings of second exciting coil 41 is suppressed to not more than one turn, in second exciting coil 41, the wire diameter can be made larger and the wire length can be made shorter in the coil wire. Furthermore, when the wire length of the coil wire of second exciting coil 41 is short, reduction in cost and size can be achieved.
In addition, it is desirable that second exciting coil 41 be formed of metal. By subjecting a metal plate to processing such as punching and bending, second exciting coil 41 can be formed. In this case, the number of windings of second exciting coil 41 may be one turn as shown in
Herein, when first exciting coil 31 and second exciting coil 41 are wound around the same axis (the moving axis of movable element 32) along the movement direction of movable element 32 (vertical direction), at least a part of second exciting coil 41 may be disposed to overlap with first exciting coil 31 as shown in
Furthermore, in this exemplary embodiment, contact device 2 includes contact pressure spring 14 generating a force in the direction pressing movable contacts 21a and 21b against fixed contacts 22a and 22b when movable element 32 is in the second position. Therefore, contact device 2 can secure a sufficient contact pressure force between movable contacts 21a and 21b and fixed contacts 22a and 22b when movable element 32 is in the second position.
In a state in which movable element 32 is in the second position, an electromagnetic repulsive force is generated in the direction so as to separate movable contacts 21a and 21b from fixed contacts 22a and 22b by an electric current flowing in contact device 2. It is desirable that an electric current value (prescribed value) at which tripping is carried out be set smaller than a value of electric current flowing in contact device 2 when the above-mentioned electromagnetic repulsive force is balanced with a spring force of contact pressure spring 14. That is to say, in electromagnetic relay 1, it is desirable that the electric current value (prescribed value) at which tripping is carried out be set considering the electromagnetic repulsive force and the spring force of contact pressure spring 14.
In more detail, at the time of energization of first exciting coil 31, an electromagnetic repulsive force generated by an electric current flowing through movable contactor 13 from one of contact bases 11 and 12 to the other acts downward in movable contactor 13 (see
Since this electromagnetic repulsive force is smaller than a spring force of contact pressure spring 14 in normal time, movable contactor 13 receives an upward force from contact pressure spring 14 and maintains a state in which movable contacts 21a and 21b are brought into contact with fixed contacts 22a and 22b. However, when an electric current flowing in contact device 2 becomes a large electric current such as a short-circuit current, the electromagnetic repulsive force acting on movable contactor 13 exceeds the spring force of contact pressure spring 14. As a result, movable contacts 21a and 21b may be away from fixed contacts 22a and 22b. In this way, in a state in which the electromagnetic repulsive force exceeds the spring force of contact pressure spring 14, an arc discharge may occur between movable contacts 21a and 21b and fixed contacts 22a and 22b and contact welding may occur. Occurrence of the contact welding increases a force necessary to move movable contactor 13 so as to separate movable contacts 21a and 21b from fixed contacts 22a and 22b. As a result, electromagnetic relay 1 is required to have a larger force necessary for tripping.
It is therefore desirable that an electric current value (prescribed value) at which tripping is carried out be set smaller than a value of electric current in a balanced state with the spring force of contact pressure spring 14. Thus, even if an electric current flowing in contact device 2 is increased, tripping can be carried out before the electromagnetic repulsive force exceeds the spring force of contact pressure spring 14. Thus, contact welding caused by the electromagnetic repulsive force does not easily occur.
When adjusting member 18 is disposed between movable element 32 and first stator 33, even when movable element 32 is in the second position, movable element 32 is not brought into contact with first stator 33. That is to say, even when contact device 2 is in a closed state, movable element 32 is away from first stator 33, so that an attractive force acting between movable element 32 and first stator 33 is reduced.
With the configuration of electromagnetic relay 63 shown in
In an example of
In a configuration in which a part of first yoke 34 is used as a part of second yoke 44 (see
Specifically, as shown in
In addition, as shown in
With the above-mentioned configuration, in a state in which movable element 32 is located in the middle of first stator 33 and second stator 43, an attractive force acting on movable element 32 from second stator 43 is relatively larger than an attractive force acting on movable element 32 from first stator 33. Therefore, in tripping, the speed at which contact device 2 is opened is increased, electromagnetic relay 1 can rapidly disconnect the electric circuit (contact device 2) by using magnetic flux generated when an abnormal current flows.
With this configuration, a clearance is generated between movable element 32 and first stator 33 when movable element 32 is in the second position. Herein, as shown in
In
With the above-mentioned configuration, in a state in which movable element 32 is in the second position, an attractive force acting on movable element 32 from first stator 33 becomes relatively small as compared with a case where a clearance by the recess and the protrusion are not provided. Therefore, an attractive force of movable element 32 necessary for tripping becomes smaller, trip device 4 can carry out tripping by a relatively small force. As a result, the speed at which contact device 2 is opened is increased, electromagnetic relay 1 can rapidly disconnect the electric circuit (contact device 2) by using the magnetic flux generated when an abnormal current flows.
Note here that the above-mentioned configurations described in the first exemplary embodiment can be appropriately combined.
In an example of
During the input period in which movable element 32 is moved from the first position to the second position, input coil 311 is energized. During the holding period in which movable element 32 is held in the second position, holding coil 312 is energized. That is to say, when contact device 2 of electromagnetic relay 71 is closed, electronic control unit 103 energizes input coil 311 for a predetermined input period. After the input period has passed, energization of input coil 311 is stopped and then the energization to that of holding coil 312 is switched.
Herein, in order to close contact device 2 in an open state, attractive force Z1 acting upward on movable element 32 needs to exceed spring force Z3 acting downward on movable element 32. Since attractive force Z2 acting on movable element 32 at the time of energization of holding coil 312 (holding period) is less than spring force Z3 in some periods, electromagnetic relay 71 cannot close contact device 2 in an open state even when holding coil 312 is energized. On the contrary, since input coil 311 generates larger magnetic flux density than holding coil 312, attractive force Z1 acting on movable element 32 at the time of energization (input period) of input coil 311 exceeds spring force Z3 in the entire section. Therefore, when input coil 311 is energized, contact device 2 in an open state is closed.
On the other hand, in electromagnetic relay 71, when contact device 2 becomes a closed state, and the input period is switched to the holding period, an attractive force acting on movable element 32 is reduced from “F11” of “Z1” to “F13” of “Z2”. However, attractive force Z2 (F13) in the holding period is set to exceed at least spring force Z3 because movable element 32 is required to be held in the second position. At this time, since an attractive force (third force F3 shown in
According to the configuration of this exemplary embodiment described above, in the holding period rather than the input period, that is to say, in a state in which movable element 32 is in the second position, an attractive force acting between first stator 33 and movable element 32 is reduced. Consequently, it is advantageous that an attractive force necessary for tripping can be made smaller. In addition, power consumption of holding coil 312 can be suppressed to be smaller than that of input coil 311. Consequently, as compared with the input period, power consumption in the holding period can be suppressed to be small.
Furthermore, as another example of this exemplary embodiment, as mentioned above, a configuration in which an attractive force acting between first stator 33 and movable element 32 is smaller in the holding period than in the input period can be achieved by a single first exciting coil 31.
In this example, electromagnet device 3 can switch the amount of electric current flowing through first exciting coil 31 between an input electric current and a holding electric current that is smaller than the input electric current. In addition, electromagnet device 3 is configured so that the input electric current is supplied to first exciting coil 31 in the input period, and the holding electric current is supplied to first exciting coil 31 in the holding period. The input period herein denotes a period in which the movable element 32 is allowed to move from the first position to the second position as mentioned above. The holding period is a period in which the movable element 32 is held in the second position.
Specifically, for example, electronic control unit 103 (see
With this configuration, in the holding period rather than the input period, an attractive force acting between first stator 33 and movable element 32 becomes smaller in a state in which movable element 32 is in the second position. Consequently, it is advantageous that an attractive force necessary for tripping can be made smaller. In addition, since power consumption of first exciting coil 31 can be suppressed to be smaller in the holding period than in the input period, power consumption in the holding period can be suppressed to be small. Furthermore, since first exciting coil 31 may be a single coil, the cost and the size can be reduced as compared with the case where a plurality of coils is used as first exciting coil 31.
As shown in
Magnetic flux generated in space in the inner side of second exciting coil 41 at the time of energization of second exciting coil 41 is concentrated on a region in which the number of windings of second exciting coil 41 is larger than the other region in one direction (vertical direction). Therefore, the magnetic flux density in space in the inner side of second exciting coil 41 is maximum in a region in which the number of windings of second exciting coil 41 is larger than the other region in one direction (vertical direction). Consequently, magnetic flux passing through movable element 32 in the second position is increased in tripping as compared with the case where the number of windings of second exciting coil 41 is uniform throughout the entire part in one direction (vertical direction). As a result, an attractive force acting on movable element 32 becomes larger.
In more detail, forces acting on movable element 32 when trip device 4 is operated are roughly divided into the following two types. The first type of force is an attractive force (third force F3) acting on movable element 32 from second stator 43, and the second type of force is a force acting on movable element 32 by magnetic flux generated in the space. Third force F3 among these attractive forces acting on movable element 32 from second stator 43 is inversely proportional to a square of a clearance (gap) between movable element 32 and second stator 43 as represented by the above-mentioned Mathematical formula 1 (Math. 1). At the starting time of tripping, movable element 32 is in the second position, the gap between movable element 32 and second stator 43 is relatively large, and therefore the second type of force is more dominant than the first type of force (third force F3) as the force acting on movable element 32.
Then, the second type of force becomes larger as the magnetic flux density in movable element 32 becomes larger. Therefore, as mentioned above, when magnetic flux is concentrated on a part of space in the inner side of second exciting coil 41, the second type of force is also increased. As a result, the speed at which contact device 2 is opened in tripping is increased, electromagnetic relay 81 can rapidly disconnect the electric circuit (contact device 2) by using magnetic flux generated when an abnormal current flows.
Next, electromagnetic relay 81 is provided with second exciting coil 41 and therefore can promptly disconnect the electric circuit from the closed state of contact device 2 in response to an abnormal current. This point briefly is described with reference to
Load current X4 shows a load current in a case where electromagnetic relay 81 of this exemplary embodiment is used. In
Since the case where electromagnetic relay 1 of the first exemplary embodiment is used and the case where trip device 4 is not provided are the same as described in the first exemplary embodiment, the description therefor is omitted herein.
On the other hand, electromagnetic relay 81 of this exemplary embodiment is short-circuited at time t0, and immediately makes contact device 2 open by trip device 4, when load current X4 increases and reaches prescribed value I2 at time W. Herein, when the same amount of load current flows in second exciting coil 41, an attractive force acting on movable element 32 becomes larger in electromagnetic relay 81 than in electromagnetic relay 1. Therefore, a load current (prescribed value) to start tripping is reduced. Therefore, electromagnetic relay 81 starts tripping at time t11 earlier by time period T100 from time t1 at which load current X1 of electromagnetic relay 1 reaches prescribed value I1.
In addition, an attractive force acting on movable element 32 is larger in electromagnetic relay 81 than in electromagnetic relay 1. Therefore, the speed at which contact device 2 is opened is increased. As a result, electromagnetic relay 81 can disconnect load current X4 at time t12 earlier by time period T200 from time t2 at which load current X1 of electromagnetic relay 1 is interrupted.
Furthermore, it is also advantageous that electromagnetic relay 81 can further suppress an increase of a load current. That is to say, electromagnetic relay 81 can shorten the time from the time at which short-circuit occurs to the time at which load current X4 is interrupted. Therefore, even if overshooting occurs in load current X4, load current X4 can be interrupted before it increases to the short-circuit current. Note here that the short-circuit current herein denotes an electric current that is, for example, about several times to several tens of times larger than the rated current.
According to the above-described electromagnetic relay 81 of this exemplary embodiment, trip device 4 can attract movable element 32 by the magnetic flux generated by second exciting coil 41 by not less than the prescribed value of abnormal current flowing through contact device 2, and rapidly move movable element 32 to the third position. Therefore, electromagnetic relay 81 can turn off contact device 2 more promptly when an abnormal current such as an overcurrent and a short-circuit current flows into contact device 2.
Note here that in
Furthermore, in electromagnetic relay 81, second exciting coil 41 may be wound to be overlapped so that the number of windings is larger in a part than in the other regions, in one direction (vertical direction) of trip device 4 in the direction perpendicular to the one direction. Therefore, as shown in
For example, second exciting coil 41 may be wound to be overlapped in the direction perpendicular to one direction (diameter direction of cylindrical body 36) in the center portion or the bottom portion in the one direction (vertical direction) of trip device 4. In addition, the number of windings of second exciting coil 41 can be appropriately changed.
Furthermore, second exciting coil 41 may be wound to be overlapped in a part in one direction (vertical direction) in trip device 4, and the number of windings of second exciting coil 41 may be 0 (zero) in the other region. That is to say, second exciting coil 41 may be wound only in a part in one direction of trip device 4. Then, in a part in one direction of trip device 4, second exciting coil 41 may be wound separately in a plurality of stages. In this case, the number of windings of second exciting coil 41 in stages of the plurality of stages may be the same. That is to say, for example, when the number of turns (the number of windings) of second exciting coil 41 is four turns, second exciting coil 41 is preferably wound such that it is separated into three turns and one turn, but may be separated into two turns each.
That is to say, electromagnetic relay 81 of this exemplary embodiment may have a configuration in which second exciting coil 41 is wound to be overlapped in a direction perpendicular to one direction so that the number of windings is larger than in a part in the one direction of trip device 4 other than the other region. Thus, electromagnetic relay 81 can move movable contact 32 more rapidly as compared with electromagnetic relay 1. Accordingly, it is possible to appropriately change whether or not second exciting coil 41 is wound in the above-mentioned other region, or how second exciting coil 41 is wound in the above-mentioned part.
Note here that, the configuration described in this exemplary embodiment may be appropriately combined with the second exemplary embodiment not only with the first exemplary embodiment.
The first magnetic path member includes movable element 32, first stator 33, and first yoke 34. Furthermore, first yoke 34 includes yoke upper plate 341, yoke lower plate 342, yoke lateral plate 343, and bush 344. Furthermore, the second magnetic path member includes movable element 32, second stator 43, and second yoke 44. Second yoke 44 includes yoke lower plate 342, bush 344, lower plate 442, and lateral plate 443.
At least a part of the first magnetic path member and the second magnetic path member is made of material having higher electrical resistivity than that of fixed contacts 22a and 22b (see
Specifically, at least one of movable element 32 and first stator 33 is made of material having higher electrical resistivity than that of fixed contacts 22a and 22b. Herein, examples of the material for movable element 32 and first stator 33 include electromagnetic SUS (stainless steel), magnetic powder body (magnetic powder), and ferrite. When the magnetic powder is used, movable element 32 and first stator 33 are formed by mixing insulating material such as magnetic powder and synthetic resin, molding thereof, and heat-curing thereof.
By using material having higher electrical resistivity than that of fixed contacts 22a and 22b for at least a part of the first magnetic path member and the second magnetic path member, occurrence of the eddy current can be suppressed.
Furthermore, as shown in
In this way, when the surfaces of movable element 32 and first stator 33 are covered (coated) with covering members 321 and 332, shock generated when movable element 32 collides with first stator 33 can be mitigated (buffered). As a result, it is possible to avoid generation of distortion and the like of movable element 32 and first stator 33 due to shock in collision. This leads to improvement of reliability of electromagnetic relay 91. In particular, when movable element 32 and first stator 33 are made of material having higher electrical resistivity as compared with that of fixed contacts 22a and 22b, the strength of movable element 32 and first stator 33 is easily reduced. Thus, movable element 32 and first stator 33 can be reinforced by covering members 321 and 332.
Note here that a surface of at least one of movable element 32 and first stator 33 may be covered with a covering member. Both surfaces of movable element 32 and first stator 33 are not necessarily covered with the covering member.
According to the configuration of this exemplary embodiment, the generation of an eddy current can be suppressed in at least a part of the first magnetic path member forming the magnetic path through which magnetic flux generated by first exciting coil 31 is allowed to pass and the second magnetic path member forming the magnetic path through which magnetic flux generated by second exciting coil 41 is allowed to pass. That is to say, electromagnetic relay 91 of this exemplary embodiment can suppress an eddy current of the first magnetic path member and the second magnetic path member at the time of change (rising time) of electric current flowing in first exciting coil 31 or second exciting coil 41. When such an eddy current generates new magnetic flux, the new magnetic flux repels the magnetic flux generated by first exciting coil 31 or second exciting coil 41. As a result, an attractive force acting on movable element 32 may be reduced. In this exemplary embodiment, by suppressing the generation of eddy current, reduction of the attractive force acting on movable element 32 can be suppressed.
Specifically, first stator 33 includes a plurality of layers. In detail, a plurality of layers 333 and 334 are laminated in the cross-section of first stator 33 perpendicular to the magnetic flux.
In the example of
According to this exemplary embodiment, when at least a part of the first magnetic path member and the second magnetic path member is formed in a laminated structure, electrical resistance in the direction in which the eddy current flows is increased. Consequently, generation of the eddy current can be suppressed. Note here that the laminated structure is not limited to a two-layered structure as shown in
Note here that, the configuration described in this exemplary embodiment may be appropriately combined with the second and third exemplary embodiments not only with the first exemplary embodiment.
Each of the above-mentioned exemplary embodiments shows an example of a case in which movable element 32 is located in the first position in an open state of contact device 2 in which trip device 4 is not operated, and movable element 32 is located in the third position that is different from the first position when trip device 4 is operated. However, the first position and the third position may be the same as each other. That is to say, the third position is used as the first position, and movable element 32 may be in the third position at the time of non-energization of first exciting coil 31. In this configuration, movable element 32 is in the third position in both the open state of contact device 2 in which trip device 4 is not operated and the open state of contact device 2 in which trip device 4 is operated.
Furthermore, in the above-mentioned exemplary embodiments, similar to second stator 43, second yoke 44 is not essential component and it can be appropriately omitted. Herein, second yokes 44 of each of electromagnetic relays 1, 61, and 63 include lower plate 442 and lateral plate 443. Furthermore, second yoke 44 of electromagnetic relay 65 includes upper plate 441, lower plate 442 and lateral plate 443.
Furthermore, in this exemplary embodiment, a cross-sectional shape of the coil wire (copper wire) used in first exciting coil 31 and second exciting coil 41 is made to be a circular shape. However, a cross-sectional shape of the coil wire (copper wire) used in first exciting coil 31 and second exciting coil 41 is not necessarily limited to a circular shape, but may be, for example, a sectional polygonal shape.
As mentioned above, in this exemplary embodiment, a contact device, an electromagnet device, and a trip device are arranged in one direction, and the trip device is disposed on the opposite side to the contact device with respect to the electromagnet device. When an abnormal current such as an overcurrent and a short-circuit current flows in the contact device, the contact device can be turned off. With this configuration, components such as a movable element are not required to be designed for exclusive use.
An electromagnetic relay can turn off a contact device when an abnormal current flows, and is therefore useful for controlling electronic apparatuses and devices, and the like.
Number | Date | Country | Kind |
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2013-161072 | Aug 2013 | JP | national |
2014-111586 | May 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/003864 | 7/23/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/015761 | 2/5/2015 | WO | A |
Number | Name | Date | Kind |
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1204485 | Randall | Nov 1916 | A |
4292611 | Bresson | Sep 1981 | A |
5986528 | Meier | Nov 1999 | A |
6150909 | Meier | Nov 2000 | A |
8860537 | Sora | Oct 2014 | B2 |
Number | Date | Country |
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474087 | Mar 1929 | DE |
57-163939 | Oct 1982 | JP |
4-087130 | Mar 1992 | JP |
Entry |
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International Search Report of PCT application No. PCT/JP2014/003864 dated Aug. 19, 2014. |
Number | Date | Country | |
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20160181038 A1 | Jun 2016 | US |