The present application claims priority to Chinese Patent Application No. 20182158444.1; filed Sep. 27, 2018, entitled CONTACTOR, the disclosure of which is incorporated herein by reference in its entirety.
The present utility model relates to a switching device, and in particular, to a contactor.
A contactor is an electrical apparatus used for connecting or disconnecting a circuit, and is commonly used in situations related to power, power distribution, and power utilization. A contactor includes an electromagnetic mechanism, a contact system, a transmission mechanism, a spring, a housing, and the like, among which electromagnetic mechanism is an important component. An electromagnetic mechanism includes a static iron core, a movable iron core, a coil bobbin fitted on the static iron core, and a coil wound on the coil bobbin. The principle of the electromagnetic mechanism is as follows: when the coil of the contactor is energized, a strong magnetic field is created, such that the static iron core generates a magnetic force to attract the movable iron core; the movable iron core drives contacts to act, causing a normally closed contact to open or a normally open contact to close. When the coil is deenergized, the magnetic force disappears. The movable iron core is released under the action of the spring, causing the contacts to recover, i.e., causing the normally closed contact to close or the normally open contact to open.
Existing 7-15 Amp contactors have a width of 45 millimeters. Due to the wide width and the large space they consume, existing contactors are unsuited in situations where the installation space is narrow.
In view of the aforementioned technical problem existing in the prior art, the present utility model provides a contactor, comprising: a housing, comprising a first side plate and a second side plate disposed opposite to each other, and a static iron core and a movable iron core located inside the housing, a coil bobbin fitted on the static iron core, a coil wound on the coil bobbin, an elastic device located between the coil bobbin and the movable iron core, and a moving contact and a static, contact disposed opposite to each other, wherein the coil bobbin comprises a contact end surface facing the movable iron core and a first fixing part and a second fixing part fixed to edges of the contact end surface, length directions of the first fixing part and the second fixing part are parallel to the first side plate and the second side plate, the first fixing part is in contact with and connected to the first side plate, and the second fixing part is in contact with and connected to the second side plate.
Preferably, the coil bobbin comprises: a bobbin body, the bobbin body comprising the contact end surface; a first connecting piece integrally formed with the first fixing part, one end of the first connecting piece extending out from the first fixing part; and a second connecting piece integrally formed with the second fixing part, one end of the second connecting piece extending out from the second fixing part.
Preferably, a side wall of the first fixing part is provided with a first positioning protrusion, and the first side plate has a side plate through-hole corresponding to the first positioning protrusion; a side wall of the second fixing part is provided with a second positioning protrusion, and the second side plate has a side plate through-hole corresponding to the second positioning protrusion.
Preferably, the side wall of the first fixing part is provided with two first positioning protrusions, the side wall of the second fixing part is provided with two second positioning protrusions, and a spacing between the two first positioning protrusions is unequal to a spacing between the two second positioning protrusions.
Preferably, the first side plate comprises a first sub-side plate and a second sub-side plate located on the same plane, the first sub-side plate has a slot and/or a fastener, and the second sub-side plate has a fastener and/or a slot engaged with the slot and/or the fastener of the first sub-side plate; the second side plate comprises a third sub-side plate and a fourth sub-side plate located on the same plane, the third sub-side plate has a slot and/or a fastener, and the fourth sub-side plate has a fastener and/or a slot engaged with the slot and/or the fastener of the third sub-side plate.
Preferably, the housing comprises an electrode top plate, the electrode top plate having a first expanded hole and a second expanded hole; the first fixing part and the second fixing part respectively have a first auxiliary bole and a second auxiliary hole; the contactor further comprises: a first auxiliary metal piece, one end of the first auxiliary metal piece being located in the first auxiliary hole, and the other end being located at an opening of the first expanded hole or extending out from the first expanded hole, and a second auxiliary metal piece, one, end of the second auxiliary metal piece being located in the second auxiliary hole, and the other end being located at an opening of the second expanded hole or extending out, from the second expanded hole.
Preferably, the elastic device is a spring, one end of the spring being abutted against the contact end surface of the coil bobbin, and the other end being in contact with the movable iron core.
Preferably, the contactor comprises an isolating plate located between the movable iron core and one end of the first connecting piece and an isolating plate located between the movable iron core and one end of the second connecting piece.
Preferably, one end of the first connecting piece has a threaded hole, and one end of the second connecting piece has a threaded hole.
Preferably, the contactor further comprises an auxiliary wiring module located outside the housing, two connection terminals of the auxiliary wiring module being respectively in contact with one end of the first connecting piece and one end of the second connecting piece.
Preferably, the contactor comprises: a supporting member fixedly connected to the movable iron core; four moving contacts fixedly connected to the supporting member, wherein an arrangement direction of the four moving contacts is perpendicular to the first side plate and the second side plate; and four sets of static contacts in one-to-one correspondence with the four moving contacts.
Preferably, the supporting member has a spring positioning pin extending toward the coil bobbin, the elastic device comprises a spring corresponding to the spring positioning pin, and one end of the spring is fixed to or fitted on the spring positioning pin, and the other end is abutted against the coil bobbin.
The contactor according to the present utility model has a narrower width, saves installation space, and is suitable for various situations where installation space is narrow
Embodiments of the present utility model are further described below with reference to the accompanying drawings, in which:
To make objectives, technical solutions, and advantages of the present utility model clearer and more comprehensible, the present utility model is further described in detail below through specific embodiments with reference to the accompanying drawings.
The electrode top plate 121 is provided with eight electrode through-holes for electrode wires to pass through. The eight electrode through-holes are arranged into two rows, where four electrode through-holes 1211, 1212, 1213, 1214 in the first row are close to the auxiliary wiring module 13 and are arranged in succession in the width direction; the four electrode through-holes 1215, 1216, 1217, 1218 in the second row are similarly arranged in succession in the width direction. The electrode top plate 121 is further provided with an expanded hole 1241 and an expanded hole 1242. The expanded hole 1241 and the expanded hole 1242 are located between the first row of electrode through-holes and the second row of electrode through-holes.
Each moving contact 152 and a corresponding set of static contacts are used to achieve connection or disconnection clone electrode wire. Here, only one set of static contacts and one moving contact are used as an example for descriptive purposes. A set of static contacts 153 includes a static contact piece 1531 and a static contact piece 1535. One end of the static contact piece 1531 is disposed opposite to one end of one moving contact 152; the other end of the static contact piece 1531 corresponds to the electrode through-hole 1211 and is used for electrical connection to an electrode wire (not shown in
The static iron core 141 is E-shaped, located in, the accommodation space 113, and is fixed to the inner side of the mounting bottom plate 4.
The coil bobbin 143 is integrally formed and includes a bobbin body 1431, a fixing part 1433, and a fixing part 1434. The bobbin body 1431 is generally annular column-shaped, and the middle thereof is provided with a bobbin through-hole matching in shape with a middle column of the static iron core 141. The bobbin body 1431 has a contact end surface 1432 facing the movable iron core 142 and the supporting member 151 (see
The coil bobbin 143 further includes a first connecting piece and a second connecting piece. The first connecting piece and the second connecting piece are made of a metal material, and are firmly fixed together with the fixing parts 1433 and 1434 by integral forming (for example, an injection molding process). The first connecting piece generally has the same shape as that of the fixing part 1433; only two ends 1437 and 1437′ of the first connecting piece as shown in
The coil 144 is wound on an outer side wall of the bobbin body 1431, and two ends of the coil 144 are respectively electrically connected to one end 1437 of the first connecting piece, and one end 1438 of the second connecting piece. The coil 144 can be conveniently energized by the auxiliary wiring module.
Please refer again to
The supporting member 151 is further provided with two spring positioning pins 1511 extending toward the coil bobbin 143. In other embodiments of the present utility model, one end of a spring matching in size with the spring locating pin 1511 may further be fixed to or fined on the spring locating pin 1511, and the other end may be abutted against the coil bobbin 143, so that the spring applies a spring force to the supporting member 151, the movable iron core 142, and the moving contacts 152 to keep the movable iron core 142 away from the static iron ore 141. The quantity, shape, and size of the spring positioning pins 1511 are not limited in the present utility model.
The working principle of the contactor 1 is briefly described below. The coil 144 is energized by the auxiliary wiring module 13. The static iron core 141 generates a magnetic force and attracts the movable iron core 142. The movable iron core 142 simultaneously drives the supporting member 151 and the four moving contacts 152 to move toward the static iron core 141 (namely, in the direction indicated by the arrow A1), so that the four moving contacts 152 are respectively in contact with the four sets of static contacts 153 to attain electrical connection. The main circuit is thus in a connected state. When the main circuit needs to be disconnected, the current in the coil 144 is cut off, the static iron core 141 releases the movable iron, core 142, the spring 16 applies a spring force in the direction indicated by the arrow A2 to the movable iron core 142 and the supporting member 151, and the movable iron core 142 is kept away from the static iron core 141 so that the four moving contacts 152 are respectively separated from the four sets of static contacts 153. As a result, the main circuit is disconnected. Accordingly, the opening or closing of the four moving contacts 152 and the four sets of static contacts 153 is implemented.
The fixing parts 1433 and 1434 are disposed at two opposite edges of the contact end surface 1432 of the bobbin body 1431, and the length directions of the fixing parts 1433 and 1434 are parallel to the side plate 2 and the side plate 3 of the contactor 1 (namely, perpendicular to the width direction of the contactor 1). Thus, the size of the bobbin body 1431 in the width direction is not additionally increased.
The two positioning protrusions 1435 on the side wall of the fixing part 1433 are located in the side plate through-holes 1111 of the sub-side plate 111, and the two positioning protrusions 1436 on the side wall of the fixing, part 1434 are located in the side plate through-holes 1121 of the sub-side plate 112. The side plate 2 is in contact with and connected to the fixing part 1435, and the side plate 3 is in contact with and connected to the fixing part 1436. Adding a fixing and connecting component inside or outside the side plate 2 and the side plate 3 to fixedly mount the coil bobbin 143 inside the housing 5 is not necessary. The distance between the side plate 2 and the side plate 3 (namely, the width of the contactor 1) is designed to be consistent with the width of the coil bobbin 143, thereby producing a 4-pole contactor having a width of 36 millimeters and a current of 7 to 15 amperes.
The slots 1112 on the sub-side plate 111 of the side plate 2 are engaged with the fasteners 1271 on the sub-side plate 127 without the need to additionally provide a fixing and connecting device outside the sub-side plate 111 and the sub-side plate 127; similarly, the slots 1122 on the sub-side plate 112 of the side plate 3 are engaged with the fasteners 1281 on the sub-side plate 128 without the need to additionally provide a fixing and connecting device outside the sub-side plate 112 and the sub-side plate 128, thereby further reducing the width of the contactor 1.
The first connecting piece and the second connecting piece of the present utility model are integrally formed with the fixing parts 1433 and 1434. The installation process of the first connecting piece and the second connecting piece is omitted, and meanwhile, the first connecting piece and the second connecting piece are precisely and firmly fixed to the fixing parts 1433 and 1434. In addition, the present utility model does not require manufacturing various fixing and connecting components on the first connecting piece and the second connecting piece having a width of about 2 millimeters. Therefore, the first connecting piece and the second connecting piece have a simple manufacturing process.
On the coil bobbin 143, the spacing between the two positioning protrusions 1436 is different from the spacing between the two positioning protrusions 1435, thereby preventing mis-assembly of the coil bobbin 143.
The two isolating plates 125 increase the creepage distance between the side column 1422 of the movable iron core 142 and one end 1437 of the first connecting piece, and increase the creepage distance between the side column 1422 of the movable iron core 142 and one end 1438 of the second connecting piece. Similarly, the two isolating plates 126 increase the creepage distance between the side column 1423 of the movable iron core 142 and the other end 1437′ of the first connecting piece, and increase the creepage distance between the side column 1423 of the movable iron core 142 and the other end 1438′ of the second connecting piece. When a current is introduced between the first connecting piece and the second connecting piece, mis-operation of the moving contacts 152 due to short-circuit of the first connecting piece and the second connecting piece is avoided.
One ends of the auxiliary metal piece 171 and the auxiliary metal piece 172 are respectively electrically connected to the first connecting piece and the second connecting piece, and the other ends are located at openings of the expanded holes 1241 and 1242. Expandable ports of the contactor 1 are thus increased, and the monitoring and controlling of the current in the coil 144 is facilitated.
In other embodiments of the present utility model, the ends of the first connecting piece and the second connecting piece are provided with threaded holes suitable for electrical connection to power wires outside the contactor 1.
In other embodiments of the present utility model, the quantity of the positioning protrusions 1435 on the fixing part 1433 and the quantity of the side plate through-holes 1111 corresponding to the positioning protrusions 1435 may be more or less than two, and the quantity of the positioning protrusions 1436 on the fixing part 1434 and the quantity of the side plate through-holes 1121 corresponding to the positioning protrusions 1436 may be more or less than two. In other embodiments, the spacing between the two positioning protrusions 1435 is less than or equal to the spacing between the two positioning protrusions 1436.
In other embodiments of the present utility model, the sub-side plate 127 of the side plate 2 has any quantity of fasteners and/or slots, and accordingly, the sub-side plate 111 has slots and/or fasteners engaged therewith. The sub-side plate 128 of the side plate 3 has any quantity of fasteners and/or slots, and accordingly, the sub-side plate 112 has slots and/or fasteners engaged therewith.
The present utility model is not intended to limit the shape of the spring 16, which may be a tower-shaped spring, a cylindrical spring, or the like.
In other embodiments of the present utility model, a plurality, of springs are employed in place of the spring 16 in the aforementioned embodiment; one ends of the plurality of springs are fixed to the spring positioning pins 1511, and the other ends are abutted against the contact end surface 1432 of the coil bobbin 143. Springs of appropriate quantity and specifications are selected according to the specifications and size of the contactor and the spring force required by the movable iron core. In other embodiments, other elastic devices may further be selected for applying a force to the movable iron core to keep it away from the static iron core.
In other embodiments of the present utility model, other magnetic cores such as EI-shaped, EF-shaped, and U-shaped magnetic cores are employed in place of the E-shaped magnetic cores in the aforementioned embodiment.
Although the present utility model has been described through preferred embodiments, the present utility model is not limited to the embodiments described herein, and further includes various changes and variations made without departing from the scope of the present utility model.
Number | Date | Country | Kind |
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201821584441.0 | Sep 2018 | CN | national |
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