DE102015207685A1 - Power distribution unit - Google Patents

Abstract

The present invention relates to the field of power distribution and provides a power distribution apparatus comprising a U-shaped busbar groove and a connector component, wherein at the upper edge of the two inner side walls of the busbar groove, a groove is arranged protruding, and wherein at the busbar groove matching two side surfaces of the Plug component each having a protruding strip and a wedge-shaped projection are arranged projecting, and wherein between the protruding strip and the wedge-shaped projection a point of closure is formed, wherein at the bottom portion of the busbar groove a bus bar is arranged, and wherein on the bottom surface of the connector component, a pin is arranged. During assembly, the pin is first aligned with the busbar and clamped to the busbar. At the same time the connector between the connector component and the busbar groove is realized in that the channel is connected to the buckle with buckles. The respective socket components on the same busbar groove are separate from each other. If a power outlet component or device fails, the power consumption of the power outlet component will not affect the security of powering other power outlet components for other equipment, thereby improving the reliability of equipment. Moreover, the socket component can be easily disassembled and replaced separately with a fault, or it is replaced with a socket component satisfying the standards of various countries, thereby expanding the field of use of the power distribution apparatus. Further, mass production of the connector component such as socket component is possible, thereby shortening the processing time to improve the production efficiency.

Description

Technical area

The present invention relates to the technical field of power distribution, in particular a power distribution device.

State of the art

• 1. Wenn eine einzelne Steckdose beschädigt wird, kann sie nicht repariert oder ausgetauscht werden.
• 2. Dabei besteht eine hohe Anforderung an Schweißverbindungs- und Pressverbindungsqualität. Bei der Produktion sollen mehrere Steckdosen gleichzeitig verbunden oder geschweißt werden, deshalb haben die Produkte eine lange Verarbeitungsdauer und eine niedrige Produktionseffizienz.
• 3. An der Installationsposition können die Einheitsprodukte nicht um 180 Grad gedreht und benutzt werden, oder die Steckdosen können nicht um 180 Grad gedreht und benutzt werden, nämlich kann die obere und untere Installationsrichtung nicht geändert werden.
• 4. Da die Steckdosen oder Funktionsmodule an den Einheitsprodukten nicht demontiert werden, können die Steckdosen oder Funktionsmodule an den Einheitsprodukten nicht nach Bedarf ausgetauscht oder aktualisiert werden.

In the existing power distribution unit (PDU) in the communication cabinets, cabinets and other products, its socket power source typically has a welded or press-fit connection, mounting multiple outlets as a one-piece body, and slidably mounting the panel. The following problems exist:

• 1. If a single outlet is damaged, it can not be repaired or replaced.
• 2. There is a high requirement for welding connection and press connection quality. In production, several outlets are to be connected or welded simultaneously, so the products have a long processing life and a low production efficiency.
• 3. In the installation position, the unit products can not be rotated and used by 180 degrees, or the sockets can not be rotated and used 180 degrees, namely, the upper and lower installation directions can not be changed.
• 4. Because the sockets or function modules on the unitized products are not dismantled, the sockets or function modules on the unitary products can not be replaced or updated as needed.

Content of the invention

It is an object of the present invention to provide a power distribution apparatus that solves the problem with the existing PDU that a damaged power outlet can not be repaired and replaced.

To solve the above technical problem, a technical solution of the present invention relates to a power distribution apparatus comprising a U-shaped busbar groove and a connector component which is detachably connected to the inside of the cable slot, wherein at the upper edge of the two inner side walls of the busbar groove a groove projecting along the longitudinal direction of the busbar groove, and wherein a protruding strip and a wedge-shaped protrusion are respectively projected on the busbar groove-fitting two side surfaces of the connector component, and wherein between the protruding strip and the wedge-shaped protrusion there is a snap-fit to the snap connection the trough is formed, wherein at the bottom portion of the busbar groove, a bus bar is arranged, which is connected to the power source, and wherein on the bottom surface of the connector component, a St Ift is arranged, which can be strained on the busbar.

Preferably, the connector component is a socket component, the socket component having a voided bottom housing and a cover housing coupled to the bottom housing, and wherein the protruding strip and the wedge-shaped projection are disposed on the busbar groove mating side surfaces of the bottom housing, and wherein the pin is disposed on the bottom surface of the bottom case, and wherein a plug socket is disposed in the cover housing, and wherein in the cavity a printed circuit board is arranged, and wherein on the circuit board a plug-in terminal is arranged, and wherein the plug-in terminal passes through the pin and on the busbar is arranged clamped.

Preferably, a suspending coupling column is arranged at the coupled edges of the bottom housing and the cover housing, wherein at the coupled edges of the bottom housing and the cover housing, a Verkubplungsnut is arranged, and wherein the coupling column is connected to the inside of the Verkupplungsnut plugging.

Preferably, the bottom housing and the cover housing are rectangular, with four coupling columns are arranged, and wherein two coupling columns are distributed at both ends of two rectangular opposite sides of the rectangle, and wherein the number of coupling groove is identical to the number of the coupling column.

Preferably, the coupling column is arranged on the side surface.

Preferably, the thickness of the protruding thickness of the wedge-shaped protrusion on the side surface gradually decreases along the direction approaching the bottom surface of the bottom case, the protruding strip being near the side with a large thickness of the wedge-shaped protrusion.

Preferably, four wedge-shaped projections are arranged, wherein on each side surface in each case two mutually parallel wedge-shaped projections are arranged.

Preferably, the busbar includes rail L1, rail L2, rail L3, rail N, rail PE, first bridging rail and second bridging rail, wherein the rail L1, the rail L2 and the rail L3 are respectively connected to the three-phase conductors of the power source, and wherein the Rail N is connected to the neutral conductor of the power source, and wherein the rail PE is respectively connected to the outer shell of the device and the ground, and wherein the rail L2 and the first bridging rail are electrically connected to each other via a first first bridging structure, and wherein the rail L3 and the second bridging rail are electrically connected to each other via a second bridging structure.

In the busbar groove, a mounting seat for fixing the busbar is preferably arranged, wherein a slot is arranged on the mounting seat, and wherein the rail L1, the rail L2, the rail L3, the rail N, the rail PE, the first bridging rail and the second bridging rail each disassembled in the slot are arranged sticking.

On the inner wall of the busbar groove, a chute is preferably arranged, which extends along the longitudinal direction of the busbar groove, wherein a slide is arranged on the attachment seat, and wherein the slide is arranged in the chute in plug-in manner.

Compared with the prior art, the present invention has the following advantages:
The power distribution apparatus employs a busbar groove and a connector component. At the upper edge of the two inner side walls of the busbar groove a channel is arranged in each case. At the two side surfaces of the connector component, a protruding strip and a wedge-shaped projection are respectively arranged protruding. Between the projecting strip and the wedge-shaped projection a point of closure is formed. During assembly, the pin on the bottom surface of the connector component is first aligned with the bus bar at the bottom portion of the bus bar groove and clamped to the bus bar. At the same time the plug connection between the connector component and the busbar groove is realized in that the channel is connected to the interior of the buckle with a buckle. When disassembling the channel is released from the buckling points of the two sides of the connector component, then the pin is pulled out of the busbar. The assembly and disassembly process of the individual connector component is completed in the busbar groove. The connector component may be a socket component, a function module or a switching module, etc.

In summary, a single connector component such as a socket component in the power distribution apparatus can be detachably installed in the busbar groove. Compared to the prior art, the respective socket components on the same busbar groove in the present power distribution device are separate from each other. If a socket component in the busbar groove or a device has a fault, the power consumption of the socket component will not affect the safety of powering other socket components for other devices, thereby improving the reliability of equipment. Moreover, the socket component can be easily disassembled and replaced separately with a fault, or it is replaced with a socket component satisfying the standards of various countries, thereby expanding the field of use of the power distribution apparatus. Further, mass production of the connector component such as socket component is possible, thereby shortening the processing time to improve the production efficiency.

Short description of the drawing

1 shows a perspective structural view of the power distribution device in the embodiment of the present invention.

2 shows an exploded perspective view of the power distribution device in the embodiment of the present invention.

3 FIG. 12 is a perspective structural view of the busbar groove of the power distribution apparatus in the embodiment of the present invention. FIG.

4 Fig. 10 is a plan view of the power distribution apparatus in the embodiment of the present invention.

5 Fig. 10 is a plan view of the bus bar of the power distribution apparatus in the embodiment of the present invention.

Detailed embodiments

In the context of figures and embodiments, the present invention will be explained in more detail below, so that the object, the technical solutions and the advantages of the present invention become clearer. It is understood that the The detailed embodiments described herein are merely illustrative of the present invention, rather than limiting the present invention.

The preferred embodiments of the present invention are as in 1 to 5 shown.

It should be noted that one component may be directly on another component or may simultaneously be a middle component, if described as having the component "attached" or "disposed" to the other component. When it is described that one component is "connected" to another component, it may be directly connected to the other component, or a middle component may exist simultaneously.

Further, it should be noted that the position words such as left, right, up and down etc. in the present embodiment are only relative terms or are in the normal condition of use, they should not be construed as limitations.

As in 1 to 3 shown, a power distribution device 10 in the present embodiment, having a U-shaped busbar groove 11 and a connector component 12 , which can be disassembled with the interior of the cable slot 11 is connected, wherein at the upper edge of the two inner side walls of the busbar groove 11 a gutter 111 protruding along the longitudinal direction of the busbar groove 11 extends, and wherein at the busbar groove 11 matching two side surfaces 1253 the connector component 12 one projecting strip each 121 and a wedge-shaped projection 122 are arranged above, and wherein between the protruding strip 121 and the wedge-shaped projection 122 a point of sale 123 for snap connection of the gutter 111 is formed, wherein at the bottom portion of the busbar groove 11 a busbar 13 is arranged, which is connected to the power source, and wherein on the bottom surface of the connector component 12 a pen 124 is arranged on the busbar 13 can be tense.

Compared to the prior art has the power distribution device 10 in the present embodiment, the following advantages: As in 1 to 3 represented, sets the power distribution device 10 a busbar trunk 11 and a connector component 12 one. At the upper edge of the two inner side walls of the busbar groove 11 is each a gutter 111 arranged. On the two side surfaces 1253 the connector component 12 are each a prominent strip 121 and a wedge-shaped projection 122 arranged above. Between the protruding strip 121 and the wedge-shaped projection 122 is a point of sale 123 educated. When mounting the pen 124 on the bottom surface of the connector component 12 first on the busbar 13 at the bottom portion of the busbar groove 11 aligned and at the busbar 13 tense. At the same time the plug connection between the connector component 12 and the busbar groove 11 realized by that the gutter 111 strapping to the inside of the point of sale 123 connected is. When disassembling the gutter 111 from the strong points 123 the two sides of the connector component 12 solved, then the pin 124 from the busbar 13 pulled out. In this case, the assembly and disassembly process of the individual connector component 12 in the busbar groove 11 completed. The connector component 12 can be a power outlet component 125 , a functional module or a switching module, etc.

In summary, a single connector component 12 like socket component 125 in the power distribution device 10 removable in the busbar groove 11 be installed as in 1 shown. Compared to the prior art, the respective socket components 125 at the same busbar groove 11 at the present power distribution device 10 separate from each other. If a socket component 125 in the busbar groove 11 or a device have a fault, the power consumption of the outlet component becomes 125 do not affect the security of the power supply of other socket components for other equipment, thereby improving the reliability of equipment. In addition, the outlet component 125 It can easily be disassembled and replaced separately with a fault, or it can be replaced by a socket component that meets the standards of various countries 125 replaced, thereby the field of application of the power distribution device 10 extended.

Furthermore, the mass production of the connector component 12 like socket component 125 possible, thereby shortening the processing time to improve the production efficiency.

The preferred embodiment of the concrete structure of the connector component 12 in the present embodiment, as in FIG 1 to 3 shown, wherein the connector component 12 a socket component 125 is, and where the outlet component 125 a cavity housing provided with a cavity 1251 and a lid housing 1252 having that with the floor housing 1251 is coupled, and wherein the protruding strip 121 and the wedge-shaped projection 122 to the busbar groove 11 matching two side surfaces 1253 of the bottom housing 1251 is arranged, and wherein the pin 124 on the bottom surface of the bottom housing 1251 is arranged, and wherein in the lid housing 1252 a socket 1254 is arranged, and wherein in the cavity a circuit board 1255 is arranged, and being on the circuit board 1255 a plug-in terminal 1256 is arranged, and wherein the plug-in terminal 1256 through the pen 124 go and at the busbar 13 is arranged clamped. Thus, when installing the socket component 125 becomes the plug-in terminal 1256 in the pen 124 on the busbar 13 aligned, then the bottom housing 1251 into the busbar groove 11 pressed, so that the wedge-shaped projections 122 on the two side surfaces 1253 of the bottom housing 1251 the gutter 111 bump and open until the gutter 11 the protruding strip 121 butt, namely the gutter 111 along the wedge-shaped projections 122 slipping and falling with the inside of the point of sale 123 is connected with a strap.

It should be noted that the outlet 1254 can have two or three jacks, as in 4 shown. The power outlet 1254 can C13 module 20 , C19 module 21 , German-French standard 22 , English standard 23 , American standard (not shown) or Japanese standard (not shown), etc.

The connector component 12 can be a functional module 24 Be that with the prominent strip 121 and the wedge-shaped projection 122 provided bottom housing 1251 and the lid housing 1252 and can realize certain functions, such as radio reception component, radio transmission component, control component, voltage and current detection component, monitoring component and display elements, etc., wherein the functional component is 24 about mating between the protruding strip 121 , the wedge-shaped projection 122 and the gutter 111 removable in the busbar groove 11 arranged sticking.

As the above functional component 24 as required from the busbar groove 11 can be disassembled and replaced, the power distribution device 10 Compared to the prior art, the replacement and updating of the functional component 24 such as radio reception component, radio transmission component, control component, voltage and current detection component, monitoring component and display elements, etc., so that the power distribution apparatus can perform long-term improvement and modification for the intelligent function such as wireless connection. This is conducive to the expansion of the product range and layout of the product strategy, so that the power distribution device 10 more competitive.

It can also be understood that compatible fuse (not shown), switch (not shown), air switch (not shown), overvoltage protection module (not shown), power display module (not shown) or junction box module 25 and other structures on the bottom case 1251 are arranged, thereby the removable plug-in arrangement in the busbar groove 11 also be realized.

The preferred embodiment of the concrete coupling method between the bottom housing 1251 and the lid housing 1252 in the present embodiment, as in FIG 2 shown. This is a suspended coupling column 1257 at the coupled edges of the bottom housing 1251 and the lid housing 1252 arranged on the at the coupled edges of the bottom housing 1251 and the lid housing 1252 a coupling groove 1258 is arranged, and wherein the coupling column 1257 stuck with the inside of the coupling groove 1258 connected is. This allows the coupling between the bottom housing 1251 and the lid housing 1252 be realized by the fact that the coupling column 1257 coupling in the coupling groove 1258 is arranged.

As in 2 shown, is the bottom casings 1251 preferably rectangular, wherein the lid housing 1251 the shape of the bottom casing 1251 fits and is also rectangular, leaving the lid housing 1252 and the bottom case 1253 are more stable coupled together. There are four coupling columns 1257 arranged, two coupling columns 1257 are distributed at the two ends of two rectangular opposite sides of the rectangle, accordingly, the number of Verkopplungsnut 1258 identical to the number of coupling column 1257 , while four coupling grooves are arranged. In this case, the lid housing 1257 stable with the bottom housing 1251 coupled that the four coupling columns 1257 at the four right angles of the rectangle with the four coupling grooves 1258 are coupled.

As in 2 shown, is the coupling column 1257 preferably on the side surface 1253 arranged to mount the cover housing 1252 and the bottom case 1251 to facilitate. Of course, the coupling columns 1257 Also, each be arranged on the two opposite surfaces, which are in the vicinity of the side surface 1253 are.

The preferred embodiment of the concrete structure of the wedge-shaped projection 122 in the present embodiment, as in FIG 1 to 3 shown. So when pressing the bottom housing 1251 into the busbar groove 11 the gutter 111 smoother along the wedge-shaped projection 122 slides, the thickness of the protruding thickness of the wedge-shaped projection decreases 122 on the side surface 1253 gradually along the bottom surface of the bottom casing 1251 approximate direction, the protruding strip 121 near the side with a large thickness of the wedge-shaped projection 122 , When installing the bottom housing 1251 becomes the pen 124 on the bottom surface of the bottom housing 1251 on the busbar 13 aligned. During the pressing process into the busbar groove 11 pushes the gutter 111 First on one end of the wedge-shaped projection with a small thickness and slides along the wedge-shaped projection 122 until the gutter on the protruding strip 121 butts and in the lock 123 falls.

The preferred embodiment of the concrete arrangement position of the wedge-shaped projection 122 in the present embodiment, as in FIG 1 and 2 shown. There are four wedge-shaped projections 122 arranged on each side surface 1253 two mutually parallel wedge-shaped projections 122 are arranged. This forms the gutter 111 under the action of the two mutually parallel wedge-shaped projections 122 made two impact points, so that the wedge-shaped projections the gutter 111 more stable and reliable opening.

The preferred embodiment of the concrete structure of the busbar 13 in the present embodiment, as in FIG 3 and 5 shown. In this case, the busbar 13 Rail L1 131 , Rail L2 132 , Rail L3 133 , Rail N 134 , Rail PE 135 , first bridging rail 136 and second bridging rail 137 on, with the rail L1 131 , the rail L2 132 and the rail L3 133 are each connected to the three-phase conductors of the power source, and wherein the rail N 134 is connected to the neutral conductor of the power source, and wherein the rail PE 135 each connected to the outer shell of the device and the ground, and wherein the rail L2 132 and the first bridging rail 136 via a first bridging structure 1361 electrically connected to each other, and wherein the rail L3 133 and the second bridging rail 137 via a second bridging structure 1362 are electrically connected to each other.

The busbar 13 and the connector component 12 can have different methods of patching, with a single-phase current input and a three-phase current input, and the output is always a single-phase output.

As in 3 and 5 shown, the single-phase power input: the connector component 12 has an output as a single phase product, such as socket component 125 , their adjustment method: that the pen 124 at the bottom housing 1251 each with the rail L1 131 , the rail N 134 and the rail PE 135 is connected clamped. Thus, the single-phase product has only one set of output, namely, single-phase input and single-phase output.

Input of the three-phase power source: The connector component 12 has an output as a three-phase product, eg socket component 125 , It has three adjustment methods: 1. The pen 124 at the bottom housing 1251 is in each case with the rail L1 131 , the rail N 134 and the rail PE 135 clamped connected; 2. The pen 124 at the bottom housing 1251 is each with the first bridging rail 136 , the rail N 134 and the rail PE 135 clamped connected; 3. The pen 124 at the bottom housing 1251 is each with the second bridging rail 137 , the rail N 134 and the rail PE 135 clamped connected. Therefore, the three-phase product has more than three sets of output.

As in 3 and 5 shown are the rail L1 131 , the first bridging track 136 and the second bridging rail 137 preferably arranged in rows. Therefore, they are arranged in parallel by the rail L1 131 , the first bridging track 136 and the second bridging rail 137 form a row, the rail L2 132 , the rail L3 133 , the rails 134 and the rail PE 135 to form a row. The single-phase product and the three-phase product each have 3 pins 137 on, the rail L1 131 , the first bridging rail 136 , the second bridging rail 137 , the rail N 134 and the rail PE 135 are arranged accordingly in three rows. Next have the rail L1 131 , the rails 134 and the rail PE 135 each at an identical distance from each other, corresponding to the single-phase product, the three-phase product and the three rows of pins 124 an identical distance from each other, so that under limited conditions of use of the power distribution device 10 the busbar groove 11 can be rotated 180 degrees at the installation position and used, or the position of the busbar groove 11 is not adjusted while the connector component 12 , like socket component 125 is rotated 180 degrees and used to change the upper and lower installation directions, so that the power distribution device has a wider application area.

The preferred embodiment of the concrete arrangement method of the busbar 13 in the present embodiment, as in FIG 3 shown. In the busbar groove 11 is a mounting seat 14 for fastening the busbar 13 arranged, wherein the attachment seat 14 a slot 141 is arranged, and wherein the rail L1 131 , the rail L2 132 , the rail L3 133 , the rails 134 , the rail PE 135 , the first bridging track 136 and the second bridging rail 137 each removable in the slot 141 are arranged sticking. This allows the busbar 13 be dismantled and replaced separately.

As in 3 shown is the busbar 13 preferably oblong T-shaped. So that the busbar 13 stuck in the slot 141 arranged, the shapes of the slot fit 141 and the busbar 13 each other, this is the slot 141 T-shaped.

The preferred embodiment of the concrete arrangement method of the attachment seat 14 in the present embodiment, as in FIG 3 shown. On the inner wall of the busbar groove 11 is a slide 112 arranged along the longitudinal direction of the busbar groove 11 extends, wherein the attachment seat 14 a slider 142 is arranged, and wherein the slider 142 stuck in the chute 112 is arranged. Thus, the attachment seat 14 thereby sliding in the busbar groove 11 arranged that the slider 142 stuck in the chute 112 arranged.

The above content is a detailed explanation of the present invention in the context of preferred embodiments. However, the invention is not limited to the described embodiments. All changes, equivalent substitutions and improvements made within the spirit and principles of the present invention should be considered to be within the scope of the present invention.

Claims (10)

Power distribution apparatus, characterized in that it comprises a U-shaped busbar groove and a connector component which is detachably connected to the inside of the cable slot, wherein at the upper edge of the two inner side walls of the busbar groove a channel is arranged projecting along the longitudinal direction of the busbar groove and wherein at the busbar groove fitting two side surfaces of the connector component are each a projecting strip and a wedge-shaped projection projecting above, and wherein formed between the protruding strip and the wedge-shaped projection is an access point for snap connection of the channel, wherein at the bottom portion of the busbar groove a Bus bar is arranged, which is connected to the power source, and wherein on the bottom surface of the connector component, a pin is arranged, which may be clamped to the busbar. Power distribution apparatus according to claim 1, characterized in that the connector component is a socket component, wherein the socket component has a cavity provided with a bottom housing and a cover housing, which is coupled to the bottom housing, and wherein the projecting strip and the wedge-shaped projection to the busbar groove mating is arranged on both sides of the bottom housing, and wherein the pin is arranged on the bottom surface of the bottom housing, and wherein a plug socket is arranged in the cover housing, and wherein in the cavity a circuit board is arranged, and wherein on the circuit board, a plug-in terminal is arranged, and wherein the plug-in terminal goes through the pin and is clamped to the busbar. Power distribution device according to claim 1 or 2, characterized in that a suspending coupling column is arranged at the coupled edges of the bottom housing and the cover housing, wherein at the coupled edges of the bottom housing and the cover housing a Verkupplungsnut is arranged, and wherein the coupling column plugged with the Inside the Verkupplungsnut is connected. A power distribution apparatus according to claim 3, characterized in that the bottom case and the lid case are rectangular with four coupling columns arranged, and two coupling columns are distributed at both ends of two rectangular opposite sides of the rectangle, and wherein the number of coupling grooves is identical to the number the coupling columns is. Power distribution apparatus according to claim 3 or 4, characterized in that the coupling column is arranged on the side surface. A power distribution apparatus according to any one of claims 3 to 5, characterized in that the thickness of the protruding thickness of the wedge-shaped projection on the side surface gradually decreases along the direction approaching the bottom surface of the bottom case, the above Strip near the side with a large thickness of the wedge-shaped projection. Power distribution device according to claim 6, characterized in that four wedge-shaped projections are arranged, wherein on each side surface in each case two mutually parallel wedge-shaped projections are arranged. Power distribution device according to one of claims 1 to 7, characterized in that the bus bar rail L1, rail L2, rail L3, rail N, rail PE, first bridging rail and second bridging rail, wherein the rail L1, the rail L2 and the rail L3 respectively are connected to the three-phase conductors of the power source, and wherein the rail N is connected to the neutral conductor of the power source, and wherein the rail PE is respectively connected to the outer shell of the device and the ground, and wherein the rail L2 and the first bridging rail via a first Bridging structure are electrically connected to each other, and wherein the rail L3 and the second bridging rail are electrically connected to each other via a second bridging structure. Power distribution apparatus according to claim 8, characterized in that in the busbar groove, a mounting seat for fixing the bus bar is arranged, wherein the fastening seat a slot is arranged, and wherein the rail L1, the rail L2, the rail L3, the rail N, the rail PE , The first bridging rail and the second bridging rail are each arranged removably plugged in the slot. Power distribution apparatus according to claim 8 or 9, characterized in that on the inner wall of the busbar groove, a chute is arranged, which extends along the longitudinal direction of the busbar groove, wherein a slide is arranged on the mounting seat, and wherein the slider is arranged in the chute plug.

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