Patent Grant
11158973
The application relates to a connector and a connector assembly.
Connectors are common components used for electrical connections. The connector is generally provided with a cavity in which a connection terminal is disposed, and the plug-in connection between two connectors enables a plug-in connection between a female terminal and a male terminal to achieve an electrical connection.
In order to enable the connection terminals to be tightly plugged in and connected, it often requires a larger force to plug the male terminal and the female terminal in place. Therefore, the connection terminal is prone to being bent or broken when plugged with a larger force during the plugging-unplugging process. Due to the suspending arrangement of the connection terminal without any protective structure, it is prone to damage in the plugging-unplugging process and inconvenient to use. In the case of many connection terminals, a larger initial force is required to plug and unplug a plurality of male terminals and female terminals simultaneously, resulting in difficulty in plugging and inconvenience in use.
One of the objectives of the present application is to provide a connector assembly convenient in use to overcome at least one of the deficiencies of the prior art.
According to an aspect of the application, there is provided a connector comprising:
a housing provided with a cavity; and
a terminal retaining part which is disposed in the cavity and configured for fixing connection terminals, wherein the terminal retaining portion is provided with a plurality of first mounting holes configured for accommodating first connection terminals and a plurality of second mounting holes configured for accommodating second connection terminals; the first mounting hole has a cross sectional size larger than that of the second mounting hole; and the plurality of first mounting holes are arranged around all of the second mounting holes.
According to one embodiment of the application, in the first mounting hole is disposed a first stopper configured to prevent the first connection terminal from exiting; and/or
in the second mounting hole is provided a second stopper configured to prevent the second connection terminal from exiting.
According to one embodiment of the application, the first stopper comprises a plurality of first clamping jaws spaced apart circumferentially along the first mounting hole; each of the first clamping jaws is disposed to be elastic; in an insertion direction of the connection terminal, a plurality of the first clamping jaws are arranged to form a tapered tube shape, and/or
the second stopper comprises a plurality of second clamping jaws spaced apart circumferentially along the second mounting hole; each of the second clamping jaw is disposed to be elastic; in an insertion direction of the connection terminal, a plurality of the second clamping jaws are arranged to form a tapered tube shape.
According to one embodiment of the application, in a length direction of the housing, the plurality of first clamping jaws in the first mounting hole are arranged in a staggered manner; the plurality of second clamping jaws in the second mounting hole are arranged in a staggered manner; and/or the first clamping jaw in the first mounting hole and the second clamping jaw in the second mounting hole are staggered with respect to each other.
According to one embodiment of the application, the connector further comprises a plurality of first connection terminals and a plurality of second connection terminals, wherein the first connection terminal has a size larger than that of the second connection terminal; the first connection terminal is provided with a first plug-in end and disposed in the first mounting hole; and the second connection terminal is provided with a second plug-in end and disposed in the second mounting hole.
According to one embodiment of the application, in an axial direction of the first connection terminal, the first plug-in ends of the plurality of first connection terminals are arranged in a staggered manner, the second plug-in ends of the plurality of second connection terminals are arranged in a staggered manner, and/or the first plug-in end of the first connection terminal and the second plug-in end of the second connection terminal are staggered with respect to each other.
According to one embodiment of the application, the plurality of first connection terminals are identical.
According to one embodiment of the application, the plurality of second connection terminals are identical.
According to one embodiment of the application, the connector further comprises a terminal retainer detachably disposed in the cavity, wherein the terminal retainer is configured for fixing the first connection terminal and/or the second connection terminal.
According to one embodiment of the application, the terminal retainer comprises a plate body which is provided with a plurality of first through-holes and a plurality of second through-holes, wherein the plurality of first through-holes are arranged around the plurality of second through-holes; each of the first through-holes is disposed to be axially aligned with one of the first mounting holes; and each of the second through-holes is disposed to be axially aligned with one of the second mounting holes.
According to one embodiment of the application, the terminal retainer further comprises a plurality of bushings, wherein the bushing has a tube wall and a tube cavity; one end of the bushing is disposed on the plate body, and the other end thereof protrudes from the plate body; and the tube cavity is arranged to be aligned with the first through-hole or the second through-hole in position so that the connection terminal can be inserted into the first through-hole or the second through-hole from the tube cavity.
According to one embodiment of the application, the bushings comprise a first bushing and a second bushing, wherein the first bushing is provided with a first tube wall and a first tube cavity; each of the first tube cavities is disposed in position to be aligned with one of the first through-holes; the second bushing is provided with a second tube wall and a second tube cavity; and each of the second tube cavities is disposed in position to be aligned with one of the second through holes.
According to one embodiment of the application, on the plate body is provided a retaining block which extends to a selected height from the plate body; and some or all of the bushings are inserted into the retaining block.
According to one embodiment of the application, the terminal retainer further comprises a hook, wherein the hook has one end disposed on the plate body and extends to a selected height from the plate body.
According to one embodiment of the application, the plate body is provided with a third through-hole which runs through the plate body and is disposed on one side of the hook.
According to one embodiment of the application, in the cavity of the housing is provided a mating structure which is mated with the hook to interconnect the terminal retainer and the housing.
According to one embodiment of the application, the terminal retainer further comprises a terminal isolation plate; and the terminal isolation plate has one end disposed on the plate body and extends to a selected height from the plate body.
According to one embodiment of the application, the terminal isolation plate is disposed between the plurality of first through-holes and/or the plurality of second through-holes.
According to one embodiment of the application, the connector further comprises a sealing ring which is disposed between the terminal retainer and the housing to enable the terminal retainer and the housing to be sealingly connected.
According to one embodiment of the application, the connector further comprises a seal which is provided with a plurality of perforations and configured for sealing a gap between the first connection terminal and/or the second connection terminal and the housing.
According to one embodiment of the application, the connector further comprises a back cover which is connected with the housing to keep the seal in the cavity of the housing.
According to a second aspect of the application, there is provided a connector assembly comprising two of the connectors as described above, one of which is provided with a male terminal and the other is provided with a female terminal; and the two connectors are pluggably in plug-in connection, and the male and female terminals are pluggably in plug-in connection.
Compared with prior art, in the connector assembly provided by the application, the first through-holes are arranged around the second through-holes, so that the connection terminals having larger sizes for larger current therethrough can be disposed at the surrounding and be farther away from each other to help reduce the internal temperature rise of the connector thereby to be safe and convenient for use. The provision of the terminal retainer can help the connection terminal to be stable and firm. During plugging in, the terminal retainer can prevent the connection terminal from being bent or broken under stress, so that it is safe and convenient to use. The terminal retainer is provided with a bushing, so that the connection terminals can be isolated from each other to avoid mutual interference. The arrangement of the retaining block may enhance the firmness of the terminal retainer, and enable the connection terminal to be more stable and safer to use. The arrangement of the terminal isolation plate enables the terminal retainer to be more suitable for mounting the male terminal; the bushing and the isolation plate are separately provided on two surfaces of the plate body, and therefore the male terminals on either side of the plate body can be isolated or protected. Different heights of the bushings may enable the ends of the connection terminals to be axially staggered, so that during plugging in some of the male terminals firstly contact some of the female terminals, which requires a small force to plug in. Compared with the situation in which all of the male terminals are in contact and plug-in connection with all of the female terminals simultaneously at the beginning, the application can reduce the initial force during plugging in. The terminal retainer is provided with a hook, so that the terminal retainer can be conveniently hooked up and connected with the mating structure in the connector cavity. The plate body is provided with a third through-hole disposed on one side of the hook, so that the hook can be disconnected from the mating structure through the third through-hole, and the terminal retainer can be conveniently disassembled.
Other features and advantages of the present application will become apparent from the following detailed description of exemplary embodiments thereof with reference to the accompanying drawings.
The present application is described in detail below with reference to the accompanying drawings.
As shown in
The mating connector assembly 100 shown in
The mating connector assembly 100 includes a mating connector 120 and a mating terminal retainer 130. The mating connector 120 has a mating housing 121 and a mating cavity 122. The mating housing 121 extends lengthwise for a selected length, and a desirable length and outer shape can be determined according to a circumstance of application. The mating housing 121 encloses the mating cavity 122. The mating connector 120 is configured for mounting a connection terminal, and in this embodiment, the connection terminal are illustrated as the female terminal 110. The female terminal 110 includes a first female terminal 111 and a second female terminal 112. A structure for mounting the female terminal 110 is provided in the mating cavity 122. The structure may be a solid structure or another usable structure as long as it can fixedly mount the female terminal 110 in the mating housing 121. In the illustrated example, within the mating cavity 122 is provided a female terminal retaining portion 123 configured for fixing the female terminal 110. The female terminal retaining portion 123 is provided with a plurality of first female terminal mounting holes 124 configured for receiving the first female terminal 111 and a plurality of second female terminal mounting holes 125 configured for receiving the second female terminal 112. The first female terminal mounting hole 124 has a cross-sectional dimension larger than that of the second female terminal mounting hole 125. In the illustrated example, the first female terminal mounting hole 124 and the second female terminal mounting hole 125 are both round holes, and the first female terminal mounting hole 124 has a diameter larger than that of the second female terminal mounting hole 125. In this embodiment, the number of the first female terminal mounting holes 124 is four. The number of the second female terminal mounting holes 125 is sixteen. The four first female terminal mounting holes 124 are disposed around all of the sixteen second female terminal mounting holes 125. The four first female terminal mounting holes 124 are provided at four corners, and the sixteen second female terminal mounting holes 125 are provided within a rectangular shape defined by the four first female terminal mounting holes 124.
Within the first female terminal mounting hole 124 is provided a first stopper configured for preventing the first female terminal 111 from exiting. In the illustrated example, the first stopper includes a plurality of first female terminal clamping jaws 126 spaced circumferentially along the first female terminal mounting hole 124; each of the first female terminal clamping jaws 126 is disposed to be elastic. In an insertion direction of the first female terminal 111, a plurality of the first female terminal clamping jaws 126 are provided to form a tapered tube shape; that is, in the illustrated example, the first female terminal clamping jaws 126 reduce gradually in size from left to right.
Within the second female terminal mounting hole 125 is provided a second stopper configured for preventing the second female terminal 112 from exiting. The second stopper includes a plurality of second female terminal clamping jaws 127 spaced circumferentially along the second female terminal mounting hole 125; each of the second female terminal clamping jaws 127 is disposed to be elastic; in an insertion direction of the second female terminal 112, the plurality of the second female terminal clamping jaws 127 are arranged to form a tapered tube shape, that is, in the illustrated example, the second female terminal clamping jaws 127 reduce gradually in size from left to right.
In a length direction of the mating housing 121, the plurality of the first female terminal clamping jaws 126 in the first female terminal mounting hole 124 are arranged in a staggered manner; the plurality of the second female terminal clamping jaws 127 in the second female terminal mounting hole 125 are arranged in a staggered manner; and/or the first female terminal clamping jaw 126 in the first female terminal mounting hole 124 and the second female terminal clamping jaw 127 in the second female terminal mounting hole 125 are arranged in a staggered manner with respect to each other. In the example shown in
An inner surface of the mating cavity 122 of the mating housing 121 is provided with a mating protrusion 128. The mating protrusion 128 is configured to hook a hook 135 described below as a mating structure to the hook 135.
In the illustrated example, the female terminal 110 includes a first female terminal 111 and a second female terminal 112. The first female terminal 111 and the second female terminal 112 are both cylindrical. The first female terminal 111 has a cross-sectional dimension larger than that of the second female terminal 112; i.e., the first female terminal 111 has a diameter larger than that of the second female terminal 112. The first female terminal 111 has a first female terminal plug-in end 113, and is provided with a first female terminal flange 115. The second female terminal 112 has a second female terminal plug-in end 114, and is provided with a second female terminal flange 116. There are provided a plurality of the first female terminals 111 and the second female terminals 112. The size and number of the first female terminal 111 and the second female terminal 112 can be determined according to the actual circumstance of application. In the illustrated example, the number of the first female terminals 111 is four, and the four first female terminals 111 are identical. The number of the second female terminals 112 is sixteen, and the sixteen second female terminals 112 are identical. The four first female terminals 111 are arranged around the sixteen second female terminals 112. In the illustrated example, the four first female terminals 111 are arranged all around to define a rectangular shape, and the sixteen second female terminals 112 are disposed in the rectangular space defined by the four first female terminals 111. The first female terminal 111 is larger in size and configured for conducting a larger current, while the second female terminal 112 is smaller in size and configured for conducting less current. In the axial direction of the female terminal 110, the first female terminal plug-in end 113 is staggered with respect to the second female terminal plug-in end 114; that is, in the example shown in
The mating terminal retainer 130 has a structure including a mating plate body 131. The mating plate body 131 has a selected thickness. In the thickness direction, the mating plate body 131 is provided with a plurality of mating first through-holes 132 and a plurality of mating second through-holes 133 running through the mating plate body 131. The mating first through-hole 132 is configured for an end of the first female terminal 111 to be inserted in, and the mating first through-hole 132 is shaped and sized to adapt to the first female terminal 111. The mating second through-hole 133 is configured for an end of the second female terminal 112 to be inserted in, and the mating second through-hole 133 is shaped and sized to adapt to the second female terminal 112. The mating first through-hole 132 is larger in size than the mating second through-hole 133. The mating first through-hole 132 and the mating second through-hole 133 are positioned to correspond to the first female terminal 111 and the second female terminal 112, respectively. The number of the mating first through-holes 132 is four, and the number of the mating second through-holes 133 is sixteen. The four mating first through-holes 132 are disposed around the sixteen mating second through-holes 133. In the illustrated example, the four mating first through-holes 132 are arranged around to define a rectangular shape, and the sixteen mating second through-holes 133 are disposed in the rectangular space defined by the four mating first through-holes 132.
The mating plate body 131 is provided with a mating retaining block 134 which extends to a selected height from the mating plate body 131. To enhance the strength of the mating terminal retainer 130, the mating retaining block 134 has a specific height that can be determined according to practical requirements.
The mating terminal retainer 130 is further provided with a plurality of mating bushings 140 configured for protecting the female terminals 110 and isolating the female terminals 110 from each other. Therefore, according to the types of the female terminal 110, there are provided two types of the mating bushings 140, namely, a mating first bushing 141 and a mating second bushing 142. Each mating bushing 140 includes a mating tube wall 143 and a mating tube cavity 144. The mating tube wall 143 encloses the mating tube cavity 144. The mating first bushing 141 and the mating second bushing 142 are both connected to the mating plate body 131 at their ends. The mating tube cavity 144 of the mating first bushing 141 is aligned with the mating first through-hole 132 in position, and the end of the first female terminal 131 is inserted into the mating first through-hole 132 after the first female terminal 111 passes through the mating tube cavity 144 of the mating first bushing 141. The mating tube cavity 144 of the mating second bushing 142 is aligned with the mating second through-hole 133, and the end of the second female terminal 112 is inserted into the mating second through-hole 133 after the second female terminal 132 passes through the mating tube cavity 144 of the mating second bushing 142. The mating first bushing 141 and/or the mating second bushing 142 are/is connected to the mating retaining block 134. In the illustrated example, the mating second bushing 142 is connected to the mating retaining block 134, with a portion of the mating second bushing 142 passing through the mating retaining block 134. In the axial direction of the female terminal 110, the ends of the plurality of mating first bushings 141 and the ends of the plurality of mating second bushings 142 are arranged in a staggered manner so as to enable the plug-in ends of the plurality of female terminals 110 to be staggered. According to an embodiment of the present application, the plug-in ends of the first female terminal 111 and the second female terminal 112 may be staggered with respect to each other, or the plug-in ends of a plurality of the first female terminals 111 may be staggered with respect to each other, or the plug-in ends of a plurality of the second female terminals 112 may be staggered with respect to each other.
The mating terminal retainer 130 also includes a mating hook 135. The mating hook 135 is approximately a reverse U-shaped structure, which is connected with the mating plate body 131 and extends and protrudes from the mating plate body 131. The mating hook 135 is provided on the same side of the mating plate body 131 as the mating bushing 140 and the mating retaining block 134. The mating plate body 131 is further provided with a mating third through-hole 136 running through the plate body 131. The mating third through-hole 136 is provided at one side of the mating hook 135. The mating hook 135 is configured to be in hookup connection with the mating protrusion 128. From one side of the mating plate body 131, a force can be applied to the mating hook 135 through the mating third through-hole 136 using a tool to release the connection between the mating hook 135 and the mating protrusion 128. The mating terminal retainer 130 is further provided with an accommodating groove 137. The accommodating groove 137 extends from the mating plate body 131 to the mating retaining block 134 and is configured for accommodating a terminal isolation plate 237 described below.
The mating connector 120 in this embodiment also includes a sealing ring 150 and a first seal 160. The sealing ring 150 is disposed between the mating terminal retainer 130 and the housing 121 so that the two are sealed and connected. The first seal 160 is provided with a plurality of first perforations 161 and is configured for sealing a gap between the first female terminal 111 and/or the second female terminal 112 and the housing 121. The sealing ring 150 and the first seal 160 are positioned at the right and left ends of the mating connector 120, respectively, to seal both ends of the cavity 122. An end of the mating connector 120 is provided with a mating back cover 170 that confines the first seal 160 within the mating cavity 122.
The mating terminal retainer 130 is partially inserted into the mating cavity 122 of the mating housing 121. The mating bushing 140 is disposed inward, and the mating plate body 131 is disposed outward. The mating hook 135 hooks onto the mating protrusion 128. The mating hook 135 is mutually mated with the mating protrusion 128 to secure the mating terminal retainer 130 within the mating cavity 122. The first sealing ring 150 is fitted over the mating terminal retainer 130. The first female terminal 111 is inserted into the mating cavity 122 of the mating connector 120 through the mating first through-hole 161 and the mating first bushing 141 so that the end of the first female terminal 111 is located in the mating first through-hole 132. The second female terminal 112 is inserted into the mating cavity 122 of the mating connector 120 through the mating first through-hole 161 and the mating second bushing 142 so that the end of the second female terminal 112 is located in the mating second through-hole 133.
As shown in
The connector 220 has a housing 221 and a cavity 222. The housing 221 extends lengthwise for a selected length, and a desirable length and outer shape can be determined according to a circumstance of application. The housing 221 encloses the cavity 222. The connector 220 is configured for mounting a connection terminal, and in this embodiment, the connection terminal are illustrated as the male terminal 210. The male terminal 210 includes a first male terminal 211 and a second male terminal 212. A structure for mounting the male terminal 210 is provided in the cavity 222. The structure may be a solid structure or another usable structure as long as it can fixedly mount the male terminal 210 in the housing 221. In the illustrated example, within the cavity 222 is provided a male terminal retaining portion 223 configured for fixing the male terminal 210. The male terminal retaining portion 223 is provided with a plurality of first male terminal mounting holes 224 configured for receiving the first male terminal 211 and a plurality of second male terminal mounting holes 225 configured for receiving the second male terminal 212. The first male terminal mounting hole 224 has a cross-sectional dimension larger than that of the second male terminal mounting hole 225. In the illustrated example, the first male terminal mounting hole 224 and the second male terminal mounting hole 225 are both round holes, and the first male terminal mounting hole 224 has a diameter larger than that of the second male terminal mounting hole 225. In this embodiment, the number of the first male terminal mounting holes 224 is four. The number of the second male terminal mounting holes 225 is sixteen. The four first male terminal mounting holes 224 are disposed around all of the sixteen second male terminal mounting holes 225. The four first male terminal mounting holes 224 are provided at four corners, and the sixteen second male terminal mounting holes 225 are provided within a rectangular shape defined by the four first male terminal mounting holes 224.
Within the first male terminal mounting hole 224 is provided a first stopper configured for preventing the first male terminal 211 from exiting. In the illustrated example, the first stopper includes a plurality of first male terminal clamping jaws 226 spaced circumferentially along the first male terminal mounting hole 224; each of the first male terminal clamping jaws 226 is disposed to be elastic. In an insertion direction of the first male terminal 211, a plurality of the first male terminal clamping jaws 226 are provided to form a tapered tube shape; that is, in the example shown, the first male terminal clamping jaws 226 reduce gradually in size from right to left.
Within the second male terminal mounting hole 225 is provided a second stopper configured for preventing the second male terminal 212 from exiting. The second stopper includes a plurality of second male terminal clamping jaws 227 spaced circumferentially along the second male terminal mounting hole 225; each of the second male terminal clamping jaws 227 is disposed to be elastic; in an insertion direction of the second male terminal 212, a plurality of the second male terminal clamping jaws 227 are arranged to form a tapered tube shape; that is, in the example shown, the second male terminal clamping jaws 227 reduce gradually in size from right to left.
In a length direction of the housing 221, the plurality of the first male terminal clamping jaws 226 in the first male terminal mounting hole 224 are arranged in a staggered manner; the plurality of the second male terminal clamping jaws 227 in the second male terminal mounting hole 225 are arranged in a staggered manner; and/or the first male terminal clamping jaws 226 in the first male terminal mounting hole 224 and the second male terminal clamping jaws 227 in the second male terminal mounting hole 225 are arranged in a staggered manner with respect to each other. In the example shown in
A protrusion 228 is provided in the cavity 222 of the housing 221. The protrusion 228 is configured to hook a hook 235 described below as a mating structure to the hook 235.
In the example shown, the male terminal 210 includes a first male terminal 211 and a second male terminal 212. The first male terminal 211 and the second male terminal 212 are both cylindrical. The first male terminal 211 has a cross-sectional dimension larger than that of the second male terminal 212; i.e., the first male terminal 211 has a diameter larger than that of the second male terminal 212. The first male terminal 211 has a first male terminal plug-in end 213, and is provided with a first male terminal flange 215. The second male terminal 212 has a second male terminal plug-in end 214, and is provided with a second male terminal flange 216. There are provided a plurality of the first male terminals 211 and the second male terminals 212. The size and number of the first male terminal 211 and the second male terminal 212 can be determined according to the actual circumstance of application. In the example shown, the number of the first male terminals 211 is four, and the four first male terminals 211 are identical. The number of the second male terminals 212 is sixteen, and the sixteen second male terminals 212 are identical. The four first male terminals 211 are arranged around the sixteen second male terminals 212. In the illustrated example, the four first male terminals 211 are arranged all around to define a rectangular shape, and the sixteen second male terminals 212 are disposed in the rectangular space defined by the four first male terminals 211. The first male terminal 211 is larger in size and configured for conducting a larger current, while the second male terminal 212 is smaller in size and configured for conducting less current. In the axial direction of the male terminal 210, the first male terminal plug-in end 213 is staggered with respect to the second male terminal plug-in end 214; that is, in the example shown in
The terminal retainer 230 has a structure including a plate body 231. The plate body 231 has a selected thickness. In the thickness direction, the plate body 231 is provided with a plurality of first through-holes 232 and a plurality of second through-holes 233 running through the plate body 231. The first through-hole 232 is configured for an end of the first male terminal 211 to be inserted in, and the first through-hole 232 is shaped and sized to adapt to the first male terminal 211. The second through-hole 233 is configured for an end of the second male terminal 212 to be inserted in, and the second through-hole 233 is shaped and sized to adapt to the second male terminal 212. The first through-hole 232 is larger in size than the second through-hole 233. The first through-hole 232 and the second through-hole 233 are positioned to correspond to the first male terminal 211 and the second male terminal 212, respectively. The number of the first through-holes 232 is four, and the number of the second through-holes 233 is sixteen. The four first through-holes 232 are disposed around the sixteen second through-holes 233. In the example shown, the four first through-holes 232 are arranged all around to define a rectangular shape, and the sixteen second through-holes 233 are disposed in the rectangular space defined by the four first through-holes 132.
The plate body 231 is provided with a retaining block 234 which extends to a selected height from the plate body 231. The retaining block 234 is configured to enhance the strength of the terminal retainer 230 and a specific height thereof can be determined according to practical requirements.
The second terminal retainer 230 is further provided with a bushing 240 configured for protecting the male terminals 210 and isolating the male terminals 210 from each other. Therefore, according to the types of the male terminal 210, there are provided two types of the bushing 240, namely, a first bushing 241 and a second bushing 242. Each bushing 240 includes a tube wall 243 and a tube cavity 244. The tube wall 243 encloses the tube cavity 244. The first bushing 241 and the second bushing 242 are both connected to the plate body 231 at their ends. The tube cavity 244 of the first bushing 241 is aligned with the first through-hole 232 in position, and the end of the first male terminal 211 protrudes from the plate body 231 after the first male terminal 211 passes through the tube cavity 244 of the first bushing 241 and the first through-hole 232. The tube cavity 244 of the second bushing 242 is aligned with the second through-hole 233, and the end of the second male terminal 212 protrudes from the plate body 231 after the second male terminal 212 passes through the tube cavity 244 of the second bushing 242 and the second through-hole 233. The first bushing 241 and/or the second bushing 242 are/is connected to the retaining block 234. In the example shown, the second bushing 242 is connected to the retaining block 234, with a portion of the second bushing 242 passing through the retaining block 234.
The second terminal retainer 230 also includes a hook 235. The hook 235 is a reverse U-shaped structure, which is connected with the plate body 231 and extends and protrudes from the plate body 231. The hook 235 is provided on the same side of the plate body 231 as the bushing 240 and the retaining block 234. The plate body 231 is further provided with a third through-hole 236 running through the plate body 231. The third through-hole 236 is provided at one side of the hook 235. The hook 235 is configured to be in hookup connection with the protrusion 228. From one side of the plate body 231, a force can be applied to the hook 235 through the third through-hole 236 using a tool to release the connection between the hook 235 and the protrusion 228.
The terminal retainer 230 further includes a terminal isolation plate 250. An end of the terminal isolation plate 250 is disposed on the plate body 231 and extends to a selected height from the plate body 231. The terminal isolation plate 250 is disposed between a plurality of the first through-holes 232, between a plurality of the second through-holes 233, and/or between the first through-hole 232 and the second through-hole 233. In the example shown, the terminal isolation plate 250 is positioned between a plurality of the second through-holes 233 to isolate the plurality of second through-holes 233. The terminal isolation plate 250 may either form a closed tube cavity surrounding the second through-hole 233, or form a semi-open space only partially surrounding the second through-hole 233.
In the example shown, the terminal isolation plate 250 includes a plurality of vertical plates 251 and a plurality of transverse plates 252, the plurality of vertical plates 251 being disposed to intersect the plurality of transverse plates 252. As shown, there are provided one vertical plate 251 and two transverse plates 252 in total. The vertical plate 251 extends from an upper portion to a lower portion of the plate body 231 to isolate two adjacent rows of the second through-holes 233. The two transverse plates 252 extend from a left portion to a right portion of the plate body 231 to isolate two adjacent upper and lower rows of the second through-holes 233.
The terminal isolation plate 250 further includes a short baffle 253 which is provided on the vertical plate 251 and/or the transverse plate 252 and protrudes from the vertical plate 251 or the transverse plate 252 toward one side or both sides. The short baffle 253 protrudes from both sides of the transverse plate 252 to an identical or different length; the short baffle 253 protrudes from both sides of the vertical plate 251 to an identical or different length. In the example shown, at either end of the vertical plate 251 is provided a short baffle 253 that extends toward either side of the vertical plate 251 and protrudes from the vertical plate 251 to a different length. At either end of each transverse plate 252 is provided a short baffle 253 which extends up and down the transverse plate 252 and protrudes from the transverse plate 252 to a different length. Each of the short baffles 253 is positioned between two adjacent second through-holes 233 to isolate the two adjacent second through-holes 233. The vertical plate 251, the transverse plate 252 and the short baffle 253 surround the second through-hole 233 in a semi-closed manner. In the illustrated example, the terminal isolation plate 250 is a centrosymmetric structure, i.e., its structure being the same before and after a rotation of 180 degrees.
The connector 220 in this embodiment also includes a second seal 280. The second seal 280 is provided with a plurality of perforations 281 and is configured for sealing the gap between the first male terminal 211 and/or the second male terminal 212 and the housing 221. The second seal 280 is positioned at the right end of the housing 221. At the right end of the connector 220 is provided a back cover 270 which confines the second seal 280 within the cavity 222.
The second terminal retainer 230 is disposed within the cavity 222 of the housing 221. The bushing 240 is disposed inward and the plate body 231 is disposed outward. The hook 235 hooks onto the protrusion 228. The hook 235 is mutually mated with the protrusion 228 to secure the second terminal retainer 230 within the cavity 222. The first male terminal 211 is inserted into the cavity 222 of the connector 220, and the second male terminal 212 passes through the second perforation 281, the first bushing 241 and the plate body 231 to protrude from the plate body 231. The second male terminal 212 is inserted into the cavity 222 of the connector 220, and the second male terminal 212 passes through the second perforation 281, the second bushing 242, and the plate body 231, with the end thereof protruding from the plate body 231. The terminal isolation plate 237 isolates a plurality of the second male terminals 212.
The terminal isolation plate 280 further includes a short baffle 263 which is provided on both the vertical plate 261 and the transverse plate 262 and protrudes from the vertical plate 261 or the transverse plate 262 toward either side. The short baffle 263 protrudes from either side of the transverse plate 262 to an identical length; the short baffle 263 protrudes from either side of the vertical plate 261 to an identical length. In the example shown, at either end of the vertical plate 261 is provided one short baffle 263 that extends toward either side of the vertical plate 261 and protrudes from the vertical plate 261 to an identical length. At either end of the transverse plate 262 is provided one short baffle 263 which extends up and down the transverse plate 262 and protrudes from the transverse plate 262 to an identical length. Each of the short baffles 263 is positioned between two adjacent first through-holes 232 to isolate the two adjacent first through-holes 232. The vertical plate 261, the transverse plate 262 and the short baffle 263 surround the first through-hole 232 in a semi-closed manner. In the illustrated example, the terminal isolation plate 280 is a centrosymmetric structure, i.e., its structure being the same before and after a rotation of 180 degrees.
In use, the mating connector assembly 100 of Embodiment 1 is mated and connected with the connector assembly 200 of Embodiment 2. The mating connector 120 is in plug-in connection with the connector 220, and the male terminal 210 is in plug-in connection with the female terminal 110. The terminal isolation plate 250 or the terminal isolation plate 280 is inserted into the accommodating groove 137. During plugging in, the first female terminal 111 firstly contacts the first male terminal 211, and the second female terminal 112 contacts the second male terminal 212 after plugging in by a length.
Both the mating connector assembly 100 and the connector assembly 200 are embodiments of the connector assembly in the present application. Both the mating connector 120 and the connector 220 are embodiments of the connector in the present application. Both the first female terminal 111 and the second female terminal 112 are embodiments of the female terminal in the present application. Both the first male terminal 211 and the second male terminal 212 are embodiments of the male terminal in the present application. Both the first female terminal mounting hole 124 and the first male terminal mounting hole 224 are embodiments of the first mounting hole in the present application. Both the second female terminal mounting hole 125 and the second male terminal mounting hole 225 are embodiments of the second mounting hole in the present application.
Either of the mating terminal retainer 130 and the terminal retainer 230 is one of the embodiments of the terminal retainer described in the present application.
Compared with prior art, in the connector assembly provided by the application, the first through-holes are arranged around the second through-holes, so that the connection terminals having larger sizes for larger current therethrough can be disposed at the surrounding and be farther away from each other to avoid a short circuit and thus to be safe and convenient for use. The provision of the terminal retainer can help the connection terminal to be stable and firm. During plugging in, the terminal retainer can prevent the connection terminal from being bent or broken under stress, so that it is safe and convenient to use. The terminal retainer is provided with a bushing, so that the connection terminals can be isolated from each other to avoid mutual interference. The arrangement of the retaining block may enhance the firmness of the terminal retainer, and enable the connection terminal to be more stable and safer to use. The arrangement of the terminal isolation plate enables the terminal retainer to be more suitable for mounting the male terminal; the bushing and the isolation plate are separately provided on two surfaces of the plate body, and therefore the male terminals on either side of the plate body can be isolated or protected. Different heights of the bushings may enable the ends of the connection terminals to be axially staggered, so that during plugging in some of the male terminals firstly contact some of the female terminals, which requires a small force to plug in. Compared with the situation in which all of the male terminals are in contact and plug-in connection with all of the female terminals simultaneously at the beginning, the application can reduce the initial force during plugging in. The terminal retainer is provided with a hook, so that the terminal retainer can be conveniently hooked up and connected with the mating structure in the connector cavity. The plate body is provided with a third through-hole disposed on one side of the hook, so that the hook can be disconnected from the mating structure through the third through-hole, and the terminal retainer can be conveniently disassembled.
| Number | Date | Country | Kind |
|---|---|---|---|
| 201821947052.X | Nov 2018 | CN | national |
| Number | Name | Date | Kind |
|---|---|---|---|
| 4684190 | Clark | Aug 1987 | A |
| 4944688 | Lundergan | Jul 1990 | A |
| 6398585 | Fukuda | Jun 2002 | B1 |
| 8029325 | Bardet | Oct 2011 | B2 |
| Number | Date | Country | |
|---|---|---|---|
| 20200169025 A1 | May 2020 | US |
