The present disclosure particularly relates to a connection unit including an electromagnetic relay and a bus bar.
Conventionally, an electromagnetic relay that opens and closes a current path is connected to a power supply source and other electronic components through a bus bar. Examples of such electromagnetic relays include an electromagnetic relay disclosed in Patent Document 1. A description will be given of the electromagnetic relay disclosed in Patent Document 1 with reference to
According to Patent Document 1, bringing a pair of contact portions 130a of a movable contact 130 into contact with respective fixed contacts 118a of fixed contacts 111 and 112 causes a current Ip to flow. Further, in the fixed contacts 111 and 112, contact conductors 115 each including the fixed contact 118a have a C shape and an inverted C shape, thereby generating a section where directions in which the current Ip flows through each of the contact conductors 115 and the movable contact 130 are opposite to each other. In the section, an electromagnetic repulsive force generated by the Lorentz force caused by the current Ip flowing through each of the contact conductors 115 and the movable contact 130, the electromagnetic repulsive force causing each of the contact conductors 115 and the movable contact 130 to repel each other, increases contact pressure between the pair of contact portions 130a of the movable contact 130 and the fixed contacts 118a.
However, since a current tends to flow through the shortest path, even when the contact conductors 115 have a C shape and an inverted C shape, the current Ip does not flow through portions W, adjacent to a connecting shaft 131, of upper plate portions 116 of the C shape and the inverted C shape and only flows through portions around both ends of the movable contact 130. As a result, an electromagnetic repulsive force is generated by the Lorentz force only around both the ends of the movable contact 130. Therefore, another electromagnetic repulsive force generated between the contact portions 130a of the movable contact 130 and the fixed contacts 118a may cause the contacts to come out of contact with each other.
In light of the above-described problems, it is an object of the present disclosure to provide a connection unit that prevents contacts from coming out of contact with each other due to an electromagnetic repulsive force generated between the contacts.
A connection unit according to one aspect of the present disclosure includes an electromagnetic relay, and a bus bar connected to the electromagnetic relay. In such a connection unit, the electromagnetic relay includes a case, a first fixed contact terminal fixed to the case, the first fixed contact terminal extending outward from an inside of the case and including a first fixed contact, a second fixed contact terminal fixed to the case, the second fixed contact terminal extending outward from the inside of the case and including a second fixed contact, and a movable touch piece including, on one surface of the movable touch piece, a first movable contact and a second movable contact configured to come into and out of contact with the first fixed contact of the first fixed contact terminal and the second fixed contact of the second fixed contact terminal in a contact-making and breaking direction that is a direction in which the first movable contact and the second movable contact come into or out of contact with the first fixed contact and the second fixed contact, the movable touch piece being disposed in the case and configured to move in the contact-making and breaking direction. The bus bar includes, outside the case, a first bus bar connected to the first fixed contact terminal, and a second bus bar connected to the second fixed contact terminal, the first bus bar is disposed facing another surface of the movable touch piece located on an opposite side of the movable touch piece from the one surface in the contact-making and breaking direction, with a gap provided between the first bus bar and the movable touch piece in the contact-making and breaking direction, the first bus bar extends in a direction that intersects the contact-making and breaking direction and in which the first movable contact and the second movable contact of the movable touch piece are arranged, and at least part of the first bus bar lies over the movable touch piece in plan view in the contact-making and breaking direction.
In respective regions of the first bus bar and the movable touch piece that lie over each other in plan view in the contact-making and breaking direction, a direction in which a current flows through the first bus bar extending in the direction that intersects the contact-making and breaking direction and in which the first movable contact and the second movable contact of the movable touch piece are arranged is opposite to a direction in which a current flows through the movable touch piece. As a result, a force that is applied to the movable touch piece to push the movable contacts against the fixed contacts is generated by the Lorentz force, and it is thus possible to increase contact pressure between the movable contacts of the movable touch piece, and the first fixed contact and the second fixed contact. Therefore, an electromagnetic repulsive force derived from the Lorentz force can prevent the movable touch piece from coming out of contact with the first fixed contact terminal and the second fixed contact terminal.
According to the present disclosure, it is possible to provide the connection unit capable of preventing contacts from coming out of contact with each other due to an electromagnetic repulsive force generated between contacts.
A description will be given below of an embodiment of the present disclosure with reference to the accompanying drawings. In the following description, terms representing specific directions or positions (for example, terms including “up”, “down”, “right”, and “left”) are used as necessary, and note that these terms are used to facilitate understanding of the disclosure with reference to the drawings, and the technical scope of the present disclosure is not limited by the meanings of these terms. Further, the following description will be given by way of example only in nature and is not intended to limit the present disclosure, entities to which the present disclosure is applied, or uses of the present disclosure. Furthermore, the drawings are schematic illustrations, and the ratios of dimensions and the like do not necessarily match the actual ratios.
First, a description will be given of an example of a case where the present disclosure is applied with reference to
The battery 3 and the motor 5 are connected to each other through the connection unit 1 and an inverter 7. The motor 5 and a generator 8 are connected to the inverter 7. The connection unit 1 opens and closes a current path for power supply, the current path extending from the battery 3 to the motor 5 through the inverter 7. Further, the connection unit 1 opens and closes a current path for charging, the current path extending from the generator 8 to the battery 3 through the inverter 7. Further, a capacitor 9 is provided in parallel with the inverter 7.
A relay 10 for precharging and a resistor 11 are connected in between the battery 3 and the inverter 7 in parallel with the connection unit 1. The relay 10 and the resistor 11 are provided to prevent an excessive inrush load from being applied to the connection unit 1 when the circuit is closed.
The connection unit 1 includes an electromagnetic relay 13 and a bus bar 15 connected to the electromagnetic relay 13. As shown in
A description will be given of the connection unit 1 according to a first embodiment of the present disclosure with reference to
As shown in
As shown in
As shown in
The first terminal portion 19 and the second terminal portion 22 are made of metal and have a flat plate shape. The support conductor 18 and the first terminal portion 19, and the support conductor 21 and the second terminal portion 22 are connected, for example, by brazing. Alternatively, the support conductor 18 and the first terminal portion 19, and the support conductor 21 and the second terminal portion 22 may be connected by fit or connected with screws, rather than brazing. In the following description, a direction in which a first movable contact 35a and a second movable contact 35b of a movable touch piece 35 come out of contact with a first fixed contact 19a and a second fixed contact 22a is defined as an upward direction, and a direction in which the first movable contact 35a and the second movable contact 35b come into contact with the first fixed contact 19a and the second fixed contact 22a is defined as a downward direction. A contact-making and breaking direction is a direction in which the first movable contact 35a and the second movable contact 35b come into or out of contact with the first fixed contact 19a and the second fixed contact 22a.
The support conductors 18 and 21 have screw holes 18a and 21a that are blind holes extending from one end toward the other end. The first bus bar 15a is fixed to the support conductor 18 made of metal with a screw 25 screwed into the screw hole 18a. The second bus bar 15b is fixed to the support conductor 21 made of metal with a screw 26 screwed into the screw hole 21a. The support conductors 18 and 21 extend outward from the inside of the case 24, and protrude through openings 24b provided on an outer surface 24a serving as an upper surface of the case 24.
A height Ha from the outer surface 24a of the case 24 to a connection end surface 18b of the support conductor 18 that is in contact with the first bus bar 15a is greater than a height Hb from the outer surface 24a of the case 24 to a connection end surface 21b of the support conductor 21 that is in contact with the second bus bar 15b. As described above, the height Ha of the connection end surface 18b of the first fixed contact terminal 17 and the height Hb of the connection end surface 21b of the second fixed contact terminal 20 relative to the outer surface 24a of the case 24 are different from each other. Accordingly, with an insulation spacing provided between the two bus bars 15a and 15b, the first bus bar 15a can be disposed above the second bus bar 15b. This in turn makes it possible to prevent the first bus bar 15a and the second bus bar 15b from interfering with each other.
Further, the electromagnetic relay 13 further includes a contact mechanism unit 29 and an electromagnet unit 30 in the case 24.
The contact mechanism unit 29 includes a movable shaft 31 configured to move up and down along an axis of the movable shaft 31, a movable iron core 33 coupled to a lower portion of the movable shaft 31, the movable touch piece 35 through which the movable shaft 31 is inserted, a contact spring 37 that pushes the movable touch piece 35 downward in the contact-making and breaking direction, a stopper 38 that stops the movable touch piece 35 from moving downward, and a return spring 39 that pushes the movable iron core 33 upward in the contact-making and breaking direction.
The movable shaft 31 includes an upper portion passing through the movable touch piece 35 and a lower portion fixed to the movable iron core 33. The lower portion of the movable shaft 31 is inserted and supported in the electromagnet unit 30 together with the movable iron core 33, and the movable shaft 31 is configured to reciprocate along the axis of the movable shaft 31. The movable shaft 31 include a disk-shaped guard portion 31a at an upper end of the movable shaft 31. The contact spring 37 is provided between the disk-shaped guard portion 31a and the movable touch piece 35 and pushes the movable touch piece 35 toward the contact position in the contact-making and breaking direction.
The movable touch piece 35 is disposed in the case 24 and is configured to move in the contact-making and breaking direction. The movable touch piece 35 includes the first movable contact 35a and the second movable contact 35b on a surface facing the electromagnet unit 30 in the direction in which the axis of the movable shaft 31 extends (that is, the lower surface), the first movable contact 35a and the second movable contact 35b being configured to come into and out of contact with the first fixed contact 19a and the second fixed contact 22a in the contact-making and breaking direction. The first movable contact 35a faces the first fixed contact 19a of the first fixed contact terminal 17 and is configured to come into and out of contact with the first fixed contact 19a. Further, the second movable contact 35b faces the second fixed contact 22a of the second fixed contact terminal 20 and is configured to come into and out of contact with the second fixed contact 22a. The first bus bar 15a is disposed facing an upper surface of the movable touch piece 35 located on an opposite side of the movable touch piece 35 from the lower surface in the contact-making and breaking direction, with a gap provided between the first bus bar 15a and the movable touch piece 35 in the contact-making and breaking direction. Further, the outer surface 24a of the case 24 is located between the first bus bar 15a and the movable touch piece 35.
A lower end of the movable iron core 33 is supported by the return spring 39. When the electromagnet unit 30 has not been energized, the movable iron core 33 is pushed upward by a pushing force of the return spring 39, and when the electromagnet unit 30 has been energized, the movable iron core 33 is pulled downward against the pushing force of the return spring 39.
The electromagnet unit 30 includes a coil 41, a spool 43 having insulation properties, a first yoke 45, a second yoke 47 having a U shape, and a stopper 49. The coil 41 is wound around a body 43a of the spool 43. The first yoke 45 is fixed between upper ends serving as open ends of the second yoke 47. The stopper 49 is disposed on an upper portion of the first yoke 45 and restricts upward movement of the movable iron core 33.
Reference is now made to
The first bus bar 15a extends, in plan view in the contact-making and breaking direction, facing a center portion 35c of the movable touch piece 35 in a direction in which the first movable contact 35a and the second movable contact 35b are arranged. Further, the first bus bar 15a lies over, in plan view in the contact-making and breaking direction, a whole of the movable touch piece 35 in the direction in which the first movable contact 35a and the second movable contact 35b are arranged.
Next, a description will be given of an operation of the connection unit 1 having the above-described structure. First, as shown in
Next, when a voltage is applied to the coil 41 to energize the coil 41, the movable iron core 33 slides downward against the spring force of the return spring 39 as shown in
The first bus bar 15a is disposed facing the other surface (upper surface) located on the opposite side of the movable touch piece 35, in the contact-making and breaking direction, from the surface (lower surface) having the first movable contact 35a and the second movable contact 35b, with a gap provided between the first bus bar 15a and the movable touch piece 35. Further, the first bus bar 15a extends in a direction that intersects the contact-making and breaking direction and in which the first movable contact 35a and the second movable contact 35b of the movable touch piece 35 are connected. Therefore, for example, when the current Ic flows from the first bus bar 15a toward the second bus bar 15b, a section D is generated where, in respective regions of the first bus bar 15a and the movable touch piece 35 that lie over each other in plan view in the contact-making and breaking direction, a direction in which the current Ic flows through the first bus bar 15a extending above the movable touch piece 35 is opposite to a direction in which the current Ic flows through the movable touch piece 35. In this section D, the Lorentz force generates an electromagnetic repulsive force F that causes the first bus bar 15a and the movable touch piece 35 to repel each other in the contact-making and breaking direction. As a result, a force that is applied to the movable touch piece 35 to push the movable touch piece 35 against the first fixed contact 19a and the second fixed contact 22a along the axis of the movable shaft 31. Therefore, the electromagnetic repulsive force F pushes the first movable contact 35a and the second movable contact 35b against the first fixed contact 19a and the second fixed contact 22a, and it is thus possible to prevent the movable touch piece 35 from coming out of contact with the first fixed contact terminal 17 and the second fixed contact terminal 20. Further, unlike the conventional example, there is no need to arrange the first fixed contact terminal 17 and the second fixed contact terminal 20 directly above the movable touch piece 35 inside the electromagnetic relay 13, preventing an increase in size of the electromagnetic relay 13.
Note that at least part of the first bus bar 15a may lie over the movable touch piece 35 in plan view in the contact-making and breaking direction, and the electromagnetic repulsive force F is generated in each of the regions lying over each other. The larger the regions where the first bus bar 15a and the movable touch piece 35 lie over each other in plan view in the contact-making and breaking direction is, the larger the Lorentz force becomes. Further, since the Lorentz force is proportional to the square of a value of the current, the larger the value of the current flowing through the movable touch piece 35 is, the larger the contact pressure applied from the first movable contact 35a and the second movable contact 35b to the first fixed contact 19a and the second fixed contact 22a becomes. This in turn makes it possible to prevent the contacts from coming out of contact with each other.
Further, the first bus bar 15a extends, in plan view in the contact-making and breaking direction, facing the center portion 35c of the movable touch piece 35 in a direction in which the two movable contacts 35a and 35b, the first movable contact 35a and the second movable contact 35b, are connected. This makes it possible to push, when the current Ic flows in the closed state, the center portion 35c of the movable touch piece 35 downward, which in turn makes it possible for the first movable contact 35a and the second movable contact 35b located at both ends of the movable touch piece 35 to evenly come into contact with the two fixed contacts of the first fixed contact terminal 17 and the second fixed contact terminal 20.
Further, the first bus bar 15a lies over, in plan view in the contact-making and breaking direction, a whole of the movable touch piece 35 in the direction in which the two movable contacts, the first movable contact 35a and the second movable contact 35b, are connected. This applies a downward force to the whole of the movable touch piece 35, making it possible to prevent the movable touch piece 35 from coming out of contact with the first fixed contact 19a of the first fixed contact terminal 17 and the second fixed contact 22a of the second fixed contact terminal 20.
Further, since the connection end surface 18b of the support conductor 18 connected to the first bus bar 15a and the connection end surface 21b of the support conductor 21 connected to the second bus bar 15b are different from each other in height relative to the outer surface 24a, the first bus bar 15a can extend facing the movable touch piece 35, and in some case, the first bus bar 15a can also extend facing the second bus bar 15b. This increases a degree of freedom in layout design of the first bus bar 15a and the second bus bar 15b.
Next, a description will be given of a connection unit 1a according to a second embodiment of the present disclosure with reference to
The second fixed contact terminal 20 according to the second embodiment does not include the support conductor 21 according to the first embodiment. According to the second embodiment, the second terminal portion 22 having a flat plate shape extends outward from the inside of the case 24. A connection end surface 22b of the second terminal portion 22 protrudes outward of the case 24 through an opening 24d provided on the outer surface 24c of the case 24 that is different from and intersects with the outer surface 24a. The second terminal portion 22 is connected to the second bus bar 15b with the screw 26 at the connection end surface 22b. Further, the connection end surface 18b of the first fixed contact terminal 17 protrudes from one outer surface 24a of the case 24 and is connected to the first bus bar 15a.
Reference is made to
Next, a description will be given of a connection unit according to a third embodiment of the present disclosure with reference to
The first fixed contact terminal 17 of an electromagnetic relay 13b according to the third embodiment does not include the support conductor 18 according to the second embodiment. As shown in
According to the third embodiment, as shown in
The second fixed contact terminal 20 extends from a side surface of the case 24 in a direction intersecting the contact-making and breaking direction, and it is thus possible to connect the second fixed contact terminal 20 to the bus bar 15b in a direction intersecting the contact-making and breaking direction relative to the case 24. This allows the first bus bar 15a to be disposed in proximity to the outer surface 24a (that is, the upper surface) of the case 24 in the contact-making and breaking direction. Further, the first fixed contact terminal 17 extends outward from the outer surface 24e in the direction intersecting the contact-making and breaking direction, and it is thus possible for the connection end surface 19b that is in contact with the first bus bar 15a to be disposed in proximity to the outer surface 24a in the contact-making and breaking direction. This makes it possible to reduce the distance between the first bus bar 15a and the movable touch piece 35, which in turn makes it possible to increase the electromagnetic repulsive force F that is generated by the Lorentz force and is applied to the movable touch piece 35.
As shown in
Next, a description will be given of a connection unit 1c according to a fourth embodiment of the present disclosure with reference to
The insulating member 61 may be made of a synthetic resin such as polyester or epoxy resin, or may be made of an inorganic material such as mica or glass fiber. The insulating member 61 is disposed between the first bus bar 15a and the second bus bar 15b outside the case 24, and it is thus possible to prevent a short circuit between the first bus bar 15a and the second bus bar 15b.
Next, a description will be given of a connection unit 1d according to a fifth embodiment of the present disclosure with reference to
The reinforcing plate 63 connects the second fixed contact terminal 20 located outside the case 24 to the outer surface 24c of the case 24. The reinforcing plate 63 may be made of metal or an insulating member. This makes it possible to prevent the second bus bar 15b from being warped even when the electromagnetic repulsive force is generated by the Lorentz force between the first bus bar 15a and the second bus bar 15b arranged in parallel with each other.
Next, a description will be given of a connection unit 1e according to a sixth embodiment of the present disclosure with reference to
The movable iron core 33 according to the sixth embodiment includes a hollow hole 64 that results from hollowing out a portion of the movable iron core 33 where the movable shaft 31 is inserted. The contact spring 37 is inserted in the hollow hole 64. On a side of the contact spring 37 adjacent to the movable touch piece 35, a ring 65 is disposed in the hollow hole 64. The contact spring 37 is disposed between the ring 65 and a ring 66 in a state where the contact spring 37 keeps pushing the movable shaft 31 toward the contact position in a contact-opening and breaking direction.
The ring 65 is fixed to the movable iron core 33 and has a through hole, and the movable shaft 31 slides through the through hole. The ring 66 is fixed to the lower end of the movable shaft 31. The ring 66 is held between a lower end of the contact spring 37 and a bottom surface of the hollow hole 64 of the movable iron core 33.
When a voltage is applied to the coil 41 to energize the coil 41, the contact mechanism unit 29 slides downward against the spring force of the return spring 39. This brings about the closed state where the first movable contact 35a and the second movable contact 35b are in contact with the first fixed contact 19a and the second fixed contact 22a, respectively. After being brought into the closed state, the movable iron core 33 and the ring 65 further move downward to compress the contact spring 37 to maintain contact pressure between the first movable contact 35a and the first fixed contact 19a and contact pressure between the second movable contact 35b and the second fixed contact 22a.
Since the contact spring 37 is not disposed between the disk-shaped guard portion 31a of the movable shaft 31 and the movable touch piece 35, it is possible to further reduce the distance between the first bus bar 15a and the movable touch piece 35, which in turn makes it possible to increase the electromagnetic repulsive force F that is generated by the Lorentz force and is applied to the movable touch piece 35.
The present disclosure is not limited to the above embodiments and can be modified as follows.
According to the first embodiment, the height of the connection end surface 18b of the support conductor 18 relative to the outer surface 24a of the case 24 is greater than the height of the connection end surface 21b of the support conductor 21, but the present disclosure is not limited to this structure. The height of the connection end surface 18b and the height of the connection end surface 21b may be the same. In this structure, at least one of the first bus bar 15a and the second bus bar 15b has an L shape or a U shape, so that interference between the first bus bar 15a and the second bus bar 15b can be prevented.
Further, the height of the connection end surface 21b of the support conductor 21 relative to the outer surface 24a of the case 24 may be greater than the height of the connection end surface 18b of the support conductor 18. In this structure, the first bus bar 15a has an L shape or a U shape, so that interference between the first bus bar 15a and the support conductor 21 of the second fixed contact terminal 20 can be prevented.
According to the third embodiment, the first terminal portion 19 extends outward through the opening including the opening 24b provided on the outer surface 24a serving as the upper surface of the case 24 and the opening 24f provided at the upper end of the outer surface 24e that faces the outer surface 24c, but the present disclosure is not limited to this structure. Like the connection unit 1f shown in
The detailed description has been given of various embodiments according to the present disclosure with reference to the drawings, and, in conclusion, a description will be given of various aspects of the present disclosure. Note that, in the following description, reference numerals are also given as an example.
The connection unit 1, la to 1f of a first aspect of the present disclosure includes the electromagnetic relay 13, 13a, 13b, and the bus bar 15 connected to the electromagnetic relay 13, 13a, 13b. In the connection unit 1, 1a to 1f, the electromagnetic relay 13, 13a, 13b includes the case 24, the first fixed contact terminal 17 fixed to the case 24, the first fixed contact terminal 17 extending outward from the inside of the case 24 and including the first fixed contact 19a, the second fixed contact terminal 20 fixed to the case 24, the second fixed contact terminal 20 extending outward from the inside of the case 24 and including the second fixed contact 22a, and the movable touch piece 35 including, on one surface of the movable touch piece 35, the first movable contact 35a and the second movable contact 35b configured to come into and out of contact with the first fixed contact 19a of the first fixed contact terminal 17 and the second fixed contact 22a of the second fixed contact terminal 20 in the contact-making and breaking direction that is a direction in which the first movable contact 35a and the second movable contact 35b come into or out of contact with the first fixed contact 19a and the second fixed contact 22a, the movable touch piece 35 being disposed in the case 24 and configured to move in the contact-making and breaking direction. The bus bar 15 includes, outside the case 24, the first bus bar 15a connected to the first fixed contact terminal 17, and the second bus bar 15b connected to the second fixed contact terminal 20, the first bus bar 15a is disposed facing the other surface of the movable touch piece 35 located on the opposite side of the movable touch piece 35 from the one surface in the contact-making and breaking direction, with a gap provided between the first bus bar 15a and the movable touch piece 35 in the contact-making and breaking direction, the first bus bar 15a extends in a direction that intersects the contact-making and breaking direction and in which the first movable contact 35a and the second movable contact 35b of the movable touch piece 35 are arranged, and at least part of the first bus bar 15 lies over the movable touch piece 35 in plan view in the contact-making and breaking direction.
According to the connection unit 1, la to 1f of the first aspect, in respective regions of the first bus bar 15a and the movable touch piece 35 that lie over each other in plan view in the contact-making and breaking direction, a direction in which a current flows through the first bus bar 15a extending in the direction that intersects the contact-making and breaking direction and in which the first movable contact 35a and the second movable contact 35b of the movable touch piece 35 are arranged is opposite to a direction in which a current flows through the movable touch piece 35. As a result, a force that is applied to the movable touch piece 35 to push the movable contacts toward the fixed contacts is generated by the Lorentz force, and it is thus possible to increase contact pressure between the movable contact 35a of the movable touch piece 35 and the first fixed contact 19a, and contact pressure between the movable contact 35b of the movable touch piece 35 and the second fixed contact 22a. Therefore, an electromagnetic repulsive force derived from the Lorentz force can prevent the movable touch piece 35 from coming out of contact with the first fixed contact terminal 17 and the second fixed contact terminal 20.
In the connection unit 1, la to 1f of a second aspect of the present disclosure, the first bus bar 15a extends facing, in the plan view, the center portion 35c of the movable touch piece 35 in the direction in which the first movable contact 35a and the second movable contact 35b are arranged.
According to the connection unit 1, la to 1f of the second aspect, it is possible to push, when the current Ic flows in a closed state, the center portion 35c of the movable touch piece 35 downward, which in turn makes it possible for the first movable contact 35a and the second movable contact 35b located at both ends of the movable touch piece 35 to evenly come into contact with the two fixed contacts of the first fixed contact terminal 17 and the second fixed contact terminal 20.
In the connection unit 1, la to 1f of a third aspect of the present disclosure, the first bus bar 15a lies over, in the plan view, a whole of the movable touch piece 35 in the direction in which the first movable contact 35a and the second movable contact 35b are arranged.
According to the connection unit 1, 1a-1f of the third aspect, a downward force applied to the whole of the movable touch piece 35 is generated, and it is thus possible to prevent the movable touch piece 35 from coming out of contact with the first fixed contact 19a of the first fixed contact terminal 17 and the second fixed contact 22a of the second fixed contact terminal 20.
In the connection unit 1 of a fourth aspect of the present disclosure, the connection end surface 18b of the first fixed contact terminal 17 connected to the first bus bar 15a and the connection end surface 21b of the second fixed contact terminal 20 connected to the second bus bar 15b protrude outward relative to the outer surface 24a of the case 24, and the connection end surface of the first fixed contact terminal 17 and the connection end surface 21b of the second fixed contact terminal 20 relative to the first outer surface 24a of the case 24 are different in height from each other.
According to the connection unit 1 of the fourth aspect, with an insulation spacing provided between the first bus bar 15a and the second bus bar 15b, the first bus bar 15a can be disposed above the second bus bar 15b, for example. This in turn makes it possible to prevent the first bus bar 15a and the second bus bar 15b from interfering with each other.
In the connection unit 1a of a fifth aspect of the present disclosure, the connection end surface 18b of the first fixed contact terminal 17 protrudes from the first outer surface 24a of the case 24 and is connected to the first bus bar 15a, and the connection end surface 21b of the second fixed contact terminal 20 protrudes outward of the case 24 from the second outer surface 24c of the case 24 intersecting with the first outer surface 24a and is connected to the second bus bar 15b.
According to the connection unit 1a of the fifth aspect, the second fixed contact terminal 20 extends from the second outer surface 24c of the case 24 in a direction intersecting the contact-making and breaking direction, and it is thus possible to connect the second fixed contact terminal 20 to the bus bar 15b in the direction intersecting the contact-making and breaking direction relative to the case 24. This allows the first bus bar 15a to be disposed in proximity to a surface of the case 24 in the contact-making and breaking direction, and it is thus possible to reduce the distance between the first bus bar 15a and the movable touch piece 35. This in turn makes it possible to increase the electromagnetic repulsive force F that is generated by the Lorentz force and is applied to the movable touch piece 35.
In the connection unit 1b, 1e of a sixth aspect of the present disclosure, the first bus bar 15a is disposed along the first outer surface 24a of the case 24.
According to the connection unit 1b, 1e of the sixth aspect, the first bus bar 15a is disposed along the first outer surface 24a, and it is thus possible to further reduce the distance between the first bus bar 15a and the movable touch piece 35. This in turn makes it possible to increase the electromagnetic repulsive force F that is generated by the Lorentz force and is applied to the movable touch piece 35.
In the connection unit 1b to 1f of a seventh aspect of the present disclosure, the first bus bar 15a is disposed on the first outer surface 24a of the case 24, the first fixed contact terminal 17 and the second fixed contact terminal 20 are disposed protruding outward of the case 24 from the second outer surface 24c and the third outer surface 24e of the case 24 that intersect with the first outer surface 24a and face each other, and the first fixed contact terminal 17 and the second fixed contact terminal 20 are connected to the first bus bar 15a and the second bus bar 15b.
According to the connection unit 1b to 1f of the seventh aspect, the second fixed contact terminal 20 extends from the second outer surface 24c of the case 24 in a direction intersecting the contact-making and breaking direction, and it is thus possible to connect the second fixed contact terminal 20 to the bus bar 15b in the direction intersecting the contact-making and breaking direction relative to the case 24. This allows the first bus bar 15a to be disposed in proximity to the first outer surface 24a of the case 24 in the contact-making and breaking direction. Further, the first fixed contact terminal 17 extends outward from the third outer surface 24e in a direction intersecting the contact-making and breaking direction, and it is thus possible for the connection end surface 19b that is in contact with the first bus bar 15a to be disposed in proximity to the outer surface 24a in the contact-making and breaking direction. This makes it possible to reduce the distance between the first bus bar 15a and the movable touch piece 35, which in turn makes it possible to increase the electromagnetic repulsive force F that is generated by the Lorentz force and is applied to the movable touch piece 35.
In the connection unit 1c of an eighth aspect of the present disclosure, outside the case 24, the insulating member 61 is disposed between the first bus bar 15a and the second bus bar 15b.
According to the connection unit 1c of the eighth aspect, the insulating member 61 is disposed between the first bus bar 15a and the second bus bar 15b, and it is thus possible to prevent a short circuit between the first bus bar 15a and the second bus bar 15b.
Note that any suitable combination of embodiments or modifications out of the various embodiments or modifications can exhibit their respective effects. Further, a combination of the embodiments, a combination of the examples, or a combination of an embodiment and an example are possible, and a combination of features in different embodiments or examples are also possible.
While the present disclosure has been fully described in connection with preferred embodiments with reference to the accompanying drawings, various variations and modifications will be apparent to those skilled in the art. Such variations and modifications are to be understood as included within the scope of the present disclosure as set forth in the appended claims.
The connection unit according to the present disclosure is also applicable to a connection unit including either a direct current or alternating current electromagnetic relay.
Number | Date | Country | Kind |
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2017-155928 | Aug 2017 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2018/029947 | 8/9/2018 | WO | 00 |