CN111082378A - a composite bus - Google Patents

Abstract

The invention discloses a composite busbar. On the basis of a traditional power supply busbar, the composite busbar integrates a low-voltage direct current power supply busbar and a communication busbar. Integrated high-voltage insulation bracket, ground wire insulation bracket, low-voltage power supply busbar insulation bracket, communication busbar insulation bracket, multiple high-voltage copper bars with C-shaped insulating caps, grounding copper bars, communication bus small copper bars and low-voltage power supply in the tank body Small busbars, etc. The composite busbar realizes the integration of traditional power supply busbar, low-voltage power supply busbar and communication busbar. It adopts side-end sliding assembly, which is flexible and convenient to assemble, and realizes a low-cost, easy-to-operate integrated and modular design.

Description

Composite bus

Technical Field

The invention relates to an electrical connector, in particular to a composite bus.

Background

The terminal bus is a power distribution device of an electric terminal, which is generally composed of a copper conductor and an aluminum alloy shell, and realizes the function of supplying power to specific equipment through a device such as a plug box matched with the power distribution device. Especially, in a data center, a network cabinet power supply mode and a tail end bus power supply mode increasingly replace a traditional cable power supply mode of a column head cabinet, the power supply mode can provide larger power output capacity, has strong expansion capacity, saves precious space resources after replacing the column head cabinet, and enables users to more deploy the network cabinet. The tail end bus has the characteristics of series matching, commodity production, large capacity, short design and construction period, convenient assembly and disassembly, no combustion, safety, reliability and long service life. The end bus product is suitable for the power supply engineering of a three-phase four-wire and three-phase five-wire system data center network cabinet with 50Hz alternating current, 380V rated voltage and 250A-1000A rated current. The main design characteristics of the tail-end bus are plug-and-play, namely, the plug-in box matched with the bus is utilized to realize quick and convenient output, the design of the tail-end bus allows the plug-in box to be plugged in any position of the bus according to actual requirements to complete power output, meanwhile, the plug-in box also has the functions of monitoring electric energy and the like, and the electric energy service condition can be monitored in real time.

For a smart device such as a jack box, the supply of power and the connection to a network must be considered. There are two general ways of providing power: a bus electricity taking mode or an external power supply mode. The jack box itself has connected the generating line, and consequently the generating line is got the electric mode and is realized very easily, but the problem that this kind of mode brought is that the circuit of jack box can influence the test and the maintenance of generating line, if carry out the generating line and suppress the test, then must take off whole jack boxes and just can go on. Yet another way is to provide power externally, typically via a cable, to the jack box with a low voltage DC power supply (e.g., DC 24V). The communication connection of the jack box basically adopts RS485 network connection, and usually adopts shielded twisted-pair wires for cascade connection.

Thus, the terminal bus jack box devices are typically connected by 1 communication line, and some systems may also have a power line connection for DC 24V. The disadvantages of using a cable connection are: the field wiring workload is large; the cable cascade fault points are many; the cable is required to be changed when equipment is added, so that the communication of the existing equipment is influenced; it is not aesthetically pleasing.

Disclosure of Invention

In order to overcome the disadvantages of the prior art, the present invention provides a composite bus bar, which can solve the above problems.

The design principle is as follows: the design of the composite bus integrates the power supply bus, the low-voltage direct-current power supply bus and the communication bus in the bus design, and the integration of the three buses avoids the defects of the existing terminal bus system completely, so that intelligent equipment such as a plug box matched with the buses can be used in a plug and play mode in the true sense completely, and an external cable is not needed completely.

The technical scheme is as follows: the purpose of the invention is realized by adopting the following technical scheme.

A composite bus comprises a composite bus duct, and an integrated high-voltage insulation support, a ground wire insulation support, a plurality of high-voltage copper bars with C-shaped insulation caps, a grounding copper bar, a communication bus and a low-voltage power supply bus which are detachably connected to the composite bus duct, wherein the composite bus duct comprises a high-voltage insulation support groove, a ground wire insulation support groove, a communication bus duct and a low-voltage direct-current power supply bus duct, the high-voltage insulation support groove, the ground wire insulation support groove, the communication bus duct and the low-voltage direct-current power supply bus duct are formed in one side edge, the ground wire insulation support groove is arranged close to the high-voltage insulation support groove, and; the integrated high-voltage insulation support is arranged in the high-voltage insulation support groove, the ground wire insulation support is arranged in the ground wire insulation support groove, the communication bus is arranged in the communication bus groove, and the low-voltage power supply bus is arranged in the low-voltage direct-current power supply bus groove.

Preferably, the inner side surface of a high-voltage insulation support groove of the composite bus duct is outwards convexly provided with three T-shaped stop plates, a plurality of positioning plates are formed by the parallel extension of the top surface and the bottom surface of the high-voltage insulation support groove towards the groove inner direction, a plurality of positioning plates are formed by the parallel extension of the top surface and the bottom surface of the ground wire insulation support groove towards the groove inner direction, a C-shaped backward buckling plate is formed by the inward extension of the outer edges of the communication bus duct and the low-voltage direct-current power supply bus duct towards the groove, and a backward buckling groove is formed between the backward buckling plate and two adjacent groove walls.

Preferably, the top end and the bottom end of the composite bus duct are respectively provided with a C-shaped hoisting groove for mounting and fixing with an external device.

Preferably, the radiating fins are uniformly distributed on the other side of the composite bus duct.

Preferably, a plurality of groove body cavities are formed in the body of the composite bus duct. The effects of heat dissipation, material consumption reduction and light weight design are achieved.

Preferably, the integrated high-voltage insulating support comprises four bus bar slots which are formed in parallel at intervals in an integrated manner, three support stop slots and support positioning rib plates which are arranged at the top end and the bottom end of the integrated high-voltage insulating support and are formed by protruding outwards, and the support positioning rib plates are matched with the positioning plates in a sliding and abutting manner; the bus bar slot is opened towards the outside, and a bus bar positioning convex rib is arranged in the bus bar slot; the support stop groove and the female slot spaced of arranging set up the inboard at integrated form high voltage insulation support, and the top surface and the relative two spacing fin that set up in bottom surface in support stop groove, spacing fin with the adaptation that T shape backstop board supported and leaned on.

Preferably, a plurality of outer support baffles are arranged on the outer side of the integrated high-voltage insulating support and spaced from the opening of the busbar slot.

The outer baffle of support includes the outer baffle of three T shape that the centre set up and the flat baffle that sets up at both ends.

Preferably, a plurality of support cavities are formed in the body of the integrated high-voltage insulating support.

Preferably, the ground wire insulation support comprises a ground wire copper bar clamping groove formed by a n-shaped support, a ground wire copper bar positioning convex rib formed by upward protruding the inner wall of the ground wire copper bar clamping groove, and a ground wire insulation support positioning rib plate is formed by outward vertical extension of the top end and the bottom end of the ground wire insulation support.

Preferably, the bottom surface of the high-voltage copper bar is provided with a first arc-shaped positioning inner groove matched with the busbar positioning convex rib, the bottom surface of the grounding copper bar is provided with a second arc-shaped positioning inner groove matched with the ground wire copper bar positioning convex rib, and the outer end of the high-voltage copper bar is provided with a C-shaped flange matched with the C-shaped insulating cap.

Preferably, the communication bus and the low-voltage power supply bus comprise a C-shaped insulating groove body, an inner end buckle and an outer end backward buckle are arranged at the two ends of the top wall and the bottom wall of the C-shaped insulating groove body, a top plate is vertically arranged on the inner wall surface of the top wall and the inner wall surface of the bottom wall, and the top wall or the bottom wall of the C-shaped insulating groove body, the inner end buckle, the outer end backward buckle and the top plate form a mounting groove of a low-voltage copper bar.

Compared with the prior art, the invention has the beneficial effects that: the utility model provides a compound generating line has carried out compound integrated design with low pressure power supply generating line, communication generating line and traditional power supply generating line, when can reaching the smart machine and inserting traditional power supply generating line, inserts on low pressure power supply generating line and the communication generating line, need not traditional wiring work, has realized perfect plug and play.

Drawings

FIG. 1 is a schematic structural diagram of one embodiment of a composite bus bar of the present invention;

FIG. 2 is a front view of an assembly of composite bus bars;

FIG. 3 is an exploded schematic view of a composite bus bar;

FIG. 4 is an exploded view in elevation of a composite bus bar;

FIG. 5 is a schematic structural diagram of a composite bus duct;

FIG. 6 is a schematic structural diagram of an integrated high-voltage insulating bracket;

FIG. 7 is a schematic structural diagram of a ground wire insulating bracket;

fig. 8 is a schematic structural diagram of a communication bus.

In the figure: 100. a composite bus duct; 101. a high voltage insulating support slot; 102. a ground wire insulating bracket slot; 103. a communication bus duct; 104. a low-voltage DC power supply bus duct; 105. c-shaped hoisting grooves; 106. a heat sink; 107. a T-shaped stop plate; 108. positioning a plate; 109. a backward buckling plate; 110. a backward clamping groove; 111. a tank cavity;

200. an integrated high voltage insulating support; 201. a bus slot; 202. a bracket stopping groove; 203. a support positioning rib plate; 204. bus bar positioning convex ribs; 205. a bracket outer baffle; 206. limiting convex ribs; 207. a stent lumen;

300. a ground wire insulating support; 301. a ground wire copper bar clamping groove; 302. a ground wire insulating bracket positioning rib plate; 303. the ground wire copper bar positioning convex rib;

400. a C-shaped insulating cap;

500. high-voltage copper bars; 501. a first arcuate locating inner groove; 502. a C-shaped flange;

600. a ground copper bar; 601. a second arc-shaped positioning inner groove;

700. a communication bus; 701. a C-shaped insulating tank body; 702. an inner end buckle; 703. the outer end is buckled backwards; 704. a top plate; 705. low-voltage copper bars;

800. a low voltage power supply bus.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive step based on the embodiments of the present invention, are within the scope of the present invention.

Referring to fig. 1 to 8, the composite bus comprises a composite bus duct 100, and an integrated high-voltage insulating support 200, a ground wire insulating support 300, a plurality of high-voltage copper bars 500 with C-shaped insulating caps 400, a grounding copper bar 600, a communication bus 700 and a low-voltage power supply bus 800 which are detachably connected to the composite bus duct 100.

Composite bus duct

The composite bus duct 100 comprises a high-voltage insulating support groove 101, a ground wire insulating support groove 102, a communication bus duct 103 and a low-voltage direct-current power supply bus duct 104, wherein the side edge of the high-voltage insulating support groove 101 is provided with the ground wire insulating support groove 102, the communication bus duct 103 and the low-voltage direct-current power supply bus duct 104 are arranged at two end parts of the side surface of the composite bus duct 100; the integrated high-voltage insulating support 200 is arranged in the high-voltage insulating support groove 101, the ground wire insulating support 300 is arranged in the ground wire insulating support groove 102, the communication bus 700 is arranged in the communication bus duct 103, and the low-voltage power supply bus 800 is arranged in the low-voltage direct-current power supply bus duct 104.

The composite bus duct 100 is characterized in that three T-shaped stop plates 107 are arranged on the inner side surface of a high-voltage insulation support groove 101 of the composite bus duct 100 in an outward protruding mode, a plurality of positioning plates 108 are formed by the parallel extension of the top surface and the bottom surface of the high-voltage insulation support groove 101 towards the groove inner direction, a plurality of positioning plates 108 are formed by the parallel extension of the top surface and the bottom surface of the ground wire insulation support groove 102 towards the groove inner direction, a reverse buckle plate 109 is formed by the inward extension of the outer edges of the C-shaped communication bus duct 103 and the low-voltage direct-current power supply bus duct 104 towards the groove inner direction, and a reverse buckle groove 110 is formed between the.

Further, in order to facilitate the fixed connection with an external device, such as a chassis or a control cabinet, C-shaped hoisting grooves 105 are respectively disposed at the top end and the bottom end of the composite bus duct 100. Alternatively, a mounting lug or a mounting plate provided with a long waist-shaped hole and the like can be arranged.

Further, referring to fig. 5, in order to dissipate heat, cooling fins 106 are uniformly distributed on the other side of the composite bus duct 100.

In consideration of the purposes of heat dissipation, material consumption reduction and light weight design, a plurality of groove cavities 111 are formed in the body of the composite bus duct 100.

Integrated high-voltage insulating support

The integrated high-voltage insulating support 200 comprises four bus bar slots 201 which are formed in parallel at intervals, three support stopping slots 202 and support positioning ribbed plates 203 which are arranged at the top end and the bottom end of the integrated high-voltage insulating support 200 and are formed by protruding outwards, wherein the support positioning ribbed plates 203 are matched with the positioning plates 108 in a sliding and abutting mode; the bus bar slot 201 is open towards the outside, and a bus bar positioning convex rib 204 is arranged in the bus bar slot 201; the support stop groove 202 and the bus bar slot 201 are arranged on the inner side of the integrated high-voltage insulating support 200 at intervals, two limiting convex ribs 206 are arranged on the top surface and the bottom surface of the support stop groove 202 opposite to each other, and the limiting convex ribs 206 are matched with the T-shaped stop plate 107 in an abutting mode.

Further, a plurality of outer support baffles 205 are arranged at intervals between the outer side of the integrated high-voltage insulating support 200 and the opening of the busbar slot 201. And the bracket outer baffle 205 comprises three T-shaped outer baffles arranged in the middle and flat baffles arranged at two ends.

Similarly, in consideration of the purposes of heat dissipation, material consumption reduction and light weight design, a plurality of support cavities 207 are formed in the body of the integrated high-voltage insulating support 200.

Ground wire insulating support

The ground wire insulating support 300 comprises a ground wire copper bar clamping groove 301 formed by a n-shaped support, a ground wire copper bar positioning convex rib 303 formed by upward protruding on the inner wall of the ground wire copper bar clamping groove 301, and a ground wire insulating support positioning rib plate 302 formed by outward vertical extension of the top end and the bottom end of the ground wire insulating support 300.

High-voltage copper bar

High-pressure copper bar 500 generally includes four, and A looks copper bar, B looks copper bar, C looks copper bar and N looks copper bar bear 1000A's load the highest load that bears of this application high-pressure copper bar 500's bottom surface setting and female first arc location inner groovy 501 of arranging location fin 204 looks adaptation, and high-pressure copper bar 500's outer end is along setting up the C shape flange 502 with C shape insulator cap 400 looks adaptation.

Grounding copper bar

The length of the ground copper bar 600 is the same as that of the high-voltage copper bar 500, but the width is short, and the C-shaped flange is not arranged, but the second arc-shaped positioning inner groove 601 matched with the ground wire copper bar positioning convex rib 303 is arranged on the bottom surface of the ground copper bar 600.

Low-voltage bus

The low voltage bus comprises a communication bus 700 and a low voltage power supply bus 800, which are identical in structure. Specifically, the communication bus 700 and the low-voltage power supply bus 800 both include a C-shaped insulating tank 701, an inner end buckle 702 and an outer end backward buckle 703 are arranged at two ends of the top wall and the bottom wall of the C-shaped insulating tank 701, a top plate 704 is vertically arranged on the inner wall surfaces of the top wall and the bottom wall, and the top wall or the bottom wall of the C-shaped insulating tank 701, the inner end buckle 702, the outer end backward buckle 703 and the top plate 704 form an installation groove of a low-voltage copper bar 705.

Two low-voltage copper bars 705 provide low-voltage direct current power supply (generally for DC 24V) for the low-voltage consumer, and intelligent device designs such as jack box have corresponding participating in, and when equipment fixing was on the power supply bus, this participated in and inserts simultaneously, and this equipment can obtain mains operated, and this mains operated is independent, and is irrelevant with the power supply bus, can not influence the operation and the test of power supply bus.

Two low-voltage copper bars 705 provide 2 line cascade connection functions for communication bus 700, intelligent equipment such as jack box designs and has corresponding participating in, when equipment is installed on the power supply bus, should participate in the simultaneous insertion, and the communication port (usually the A/B line of RS485 communication) of this equipment can insert, has realized the cascade of all equipment communication lines.

The alternative scheme is as follows: the integrated high-voltage insulating bracket 200 is eliminated, a plurality of partition plates are arranged on the inner side surface of the high-voltage insulating bracket groove 101 in an outward protruding mode, and a plurality of supporting springs used for installing the high-voltage copper bars 500 at intervals are arranged between the partition plates.

To sum up, this compound generating line has realized the integration of traditional power supply generating line, low pressure power supply generating line and communication generating line, and simple structure adopts the side to slide and connects, need not the fixed of extra spare part, and the equipment is nimble and convenient, has realized the compound design of low cost, easy operation.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical solutions described in the foregoing embodiments may still be modified, or some technical features may be equivalently replaced; and such modifications or substitutions do not depart from the spirit and scope of the corresponding technical solutions of the embodiments of the present invention.

Claims (10)

1. A composite busbar, characterized in that: the composite busbar comprises a composite busbar slot (100) and an integrated high-voltage insulating support (200) that is detachably connected to the composite busbar slot (100), A ground wire insulating support (300), a plurality of high-voltage copper bars (500) with C-shaped insulating caps (400), a grounding copper bar (600), a communication busbar (700) and a low-voltage power supply busbar (800), the composite busbar The slot (100) includes a high-voltage insulating support slot (101), a ground wire insulating support slot (102), a communication bus slot (103), a low-voltage DC power supply bus slot (104), and the ground wire insulating support slot (104). (102) are arranged adjacent to the high-voltage insulating support slot (101), and the communication bus slot (103) and the low-voltage DC power supply bus slot (104) are arranged at both ends of the side surface of the composite bus slot (100); so The integrated high-voltage insulating bracket (200) is arranged in the high-voltage insulating bracket slot (101), the ground wire insulating bracket (300) is arranged in the ground wire insulating bracket slot (102), and the communication bus ( 700) is arranged in the communication busbar (103), and the low-voltage power supply busbar (800) is arranged in the low-voltage DC power supply busbar (104). 2. The composite busbar according to claim 1, characterized in that: three T-shaped stop plates (107) are arranged to protrude outward from the inner side of the high-voltage insulating support groove (101) of the composite busbar groove (100). ), a plurality of positioning plates (108) are formed on the top and bottom surfaces of the high-voltage insulating support groove (101) extending in parallel in the inward direction, and the top and bottom surfaces of the ground wire insulating support groove (102) are also A plurality of positioning plates (108) are formed by extending parallel to the inward direction of the groove, and a return gusset plate ( 109) and a return card slot (110) is formed between the return buckle plate (109) and two adjacent groove walls. 3. The composite busbar according to claim 1, characterized in that: C-shaped hoisting grooves (105) are respectively provided at the top and bottom ends of the composite busbar groove (100) for installation and fixation with external devices. 4. The composite busbar according to claim 1, characterized in that radiating fins (106) are evenly arranged on the other side of the composite busbar groove (100), and are arranged on the other side of the composite busbar groove (100). ) body is provided with a plurality of groove body cavities (111). 5 . The composite busbar according to claim 2 , wherein the integrated high-voltage insulating support ( 200 ) comprises four busbar slots ( 201 ) that are formed in one piece and are arranged in parallel at intervals, and three support stops. 6 . A groove (202), a bracket positioning rib (203) formed at the top and bottom ends of the integrated high-voltage insulating bracket (200) and protruding outward, the bracket positioning rib (203) and the positioning plate ( 108) Fitting for sliding contact; the busbar slot (201) is open to the outside, and a busbar positioning rib (204) is arranged in the busbar slot (201); the bracket stops The groove (202) is arranged on the inner side of the integrated high-voltage insulating support (200) at a distance from the busbar slot (201), and two are oppositely arranged on the top surface and the bottom surface of the support stop groove (202). A limiting protruding rib (206), the limiting protruding rib (206) is adapted to abut against the T-shaped stop plate (107). 6. The composite busbar according to claim 5, characterized in that: a plurality of bracket outer blocks are arranged on the outer side of the integrated high-voltage insulating bracket (200) and the opening of the busbar slot (201) at intervals plate (205). 7. The composite busbar according to claim 5 or 6, characterized in that: a plurality of support cavities (207) are provided on the body of the integrated high-voltage insulating support (200). 8 . The composite busbar according to claim 5 , wherein the ground wire insulating support ( 300 ) comprises a ground wire copper bar clamping groove ( 301 ) formed by a ∏-shaped support, and the ground wire copper bar The ground wire copper bar positioning rib (303) is formed by the upwardly protruding inner wall of the clamping groove (301), and the top and bottom ends of the ground wire insulating support (300) vertically extend outward to form the ground wire insulating support positioning rib (302). ). 9. The composite busbar according to claim 8, characterized in that: a first arc-shaped positioning inner groove adapted to the busbar positioning ribs (204) is provided on the bottom surface of the high-voltage copper bar (500) (501), a second arc-shaped positioning inner groove (601) adapted to the grounding copper bar positioning ribs (303) is arranged on the bottom surface of the grounding copper bar (600), and the high-voltage copper bar (500) ) is provided with a C-shaped flange (502) matched with the C-shaped insulating cap (400) along the outer edge. 10. The composite busbar according to claim 1, characterized in that: both the communication busbar (700) and the low-voltage power supply busbar (800) comprise a C-shaped insulating groove body (701), and the C-shaped insulating groove body (701) Both ends of the top wall and bottom wall of the tank body (701) are provided with inner end buckles (702) and outer end return buckles (703), and a top plate (704) is vertically arranged on the inner wall surfaces of the top wall and the bottom wall, so The top wall or bottom wall of the C-shaped insulating tank body (701), the inner end buckle (702), the outer end return buckle (703) and the top plate (704) form an installation slot for the low voltage copper bar (705).

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