CONNECTION ARRANGEMENT FOR CONNECTING A BUSBAR TO A HOUSING

Abstract

The invention relates to a connection arrangement for connecting a busbar (40) to a housing (10) for electrical components (30), comprising the busbar (40) and at least one wall (11) of the housing (10) and at least one electrically insulating element (50), characterized in that the connection arrangement (20) has at least one fastening element (60; 61A; 62) for preferably detachable connection to the wall (11) of the housing (10) and the at least one electrically insulating element (50) is formed from a material having good thermal conductivity.

Claims

1-15. (canceled)

16. A connection arrangement for connecting a busbar (40) to a housing (10) for electrical components (30), comprising the busbar (40) and at least one wall (11) of the housing (10) and at least one electrically insulating element (50), wherein the connection arrangement (20) has at least one fastening element (60; 61A; 62) for connection to the wall (11) of the housing (10), and the at least one electrically insulating element (50) is made of a material that has good thermal conductivity, of more than 1.5 W/(m.Math.K) characterized in that the connection arrangement (20) has at least two fastening elements (60; 61A; 62), wherein a first fastening element (61A) connects the busbar (40) and the electrically insulating element (50) to one another, and a second fastening element (62) connects the electrically insulating element (50) to the wall (11) of the housing (10).

17. The connection arrangement as claimed in claim 16, characterized in that an electrical component (30) can be simultaneously fastened, with the busbar (40), to the wall (11) of the housing (10).

18. The connection arrangement as claimed in claim 16, characterized in that the connection arrangement (20) has at least one through-going fastening element (60; 61A) for connecting the busbar (40), the electrically insulating element (50) and the wall (11) of the housing (10).

19. The connection arrangement as claimed claim 16, characterized in that the connection arrangement (20) comprises a screw, a threaded rod, a rivet or a clamping bolt as a fastening element (60).

20. The connection arrangement as claimed in claim 16, characterized in that the connection arrangement (20) comprises a nut, a threaded sleeve or a press bushing.

21. The connection arrangement as claimed in claim 16, characterized in that the connection arrangement (20) comprises an adhesive bond (90).

22. The connection arrangement as claimed in claim 16, characterized in that the connection arrangement (20) has at least one metal element (80) that can be connected to the electrically insulating element (50).

23. The connection arrangement as claimed in claim 16, characterized in that the electrically insulating element (50) is formed by a plastic block or a plastic disk or a ceramic plate.

24. The connection arrangement as claimed in claim 16, characterized in that the electrically insulating element (50) is realized as a sleeve (54) that insulates the busbar (40) from the fastening element (60).

25. The connection arrangement as claimed in claim 16, characterized in that the electrically insulating element (50) is simultaneously realized as a fastening element (62).

26. The connection arrangement as claimed in claim 16, characterized in that the electrically insulating element (50) is fixedly arranged, as at least one layer, on the busbar (40).

27. The connection arrangement as claimed in claim 16, characterized in that the wall (11) of the housing (10) is realized as a cooling plate.

28. The connection arrangement as claimed in claim 16, characterized in that the connection arrangement (20) has at least one element (54; 61B) that allows compensation of thermal expansion of the busbar (40).

29. The connection arrangement as claimed in claim 16, characterized in that realized on an inner side (12) of the wall (11) there is at least one blind hole (13) for fastening the connection arrangement (20) to the housing (10).

Description

[0036] Exemplary embodiments of the invention are explained in greater detail in the following with reference to the drawings. There are shown:

[0037] FIG. 1 a first exemplary embodiment of a connection arrangement having a through-going fastening element;

[0038] FIG. 2 a second exemplary embodiment of a connection arrangement having a through-going fastening element;

[0039] FIG. 3 a first exemplary embodiment of a connection arrangement having at least two fastening elements;

[0040] FIG. 4 a second exemplary embodiment of a connection arrangement having at least two fastening elements, and

[0041] FIG. 5 a third exemplary embodiment of a housing comprising a connection arrangement having two fastening elements.

[0042] FIG. 1 shows a first exemplary embodiment of a housing 10 comprising a connection arrangement 20 having a through-going fastening element 60. An electrical component 30 is arranged above a busbar 40, and this in turn is arranged above an electrically insulating element 50, which is in the shape of a plastic block. Since during operation the temperature of the busbar can rise to 120° C., it is provided according to the invention that the electrically insulating element 50 is designed to be thermally highly conductive. A material having good thermal conductivity has, for example, a conductivity from about 1.5 W/(m-K) or more.

[0043] In all of the exemplary embodiments represented in FIGS. 1 to 5, the electrically insulating and thermally highly conductive element 50 is formed by a plastic block, a plastic disk or a plastic layer preferably injection-molded onto the busbar 40, for example of polypropylene (PP), polyphthalamide (PPA), polyamide (in particular PA 6, PA 66 or PA 12), thermoplastic copolyester (COPE), polyphenylene sulfide (PPS), liquid crystal polymer (LCP), thermoplastic elastomers (TPE), polycarbonate/acrylonitrile butadiene styrene (PC/ABS blend), polyetheretherketone (PEEK), polyetherimide (PEI) or polybutylene terephthalate (PBT).

[0044] Ceramic and/or mineral fillers such as, for example, aluminum oxide or boron nitride, are preferably added to these plastics to improve thermal conductivity.

[0045] Examples of particularly suitable materials for the electrically insulating and thermally highly conductive element 50 are: [0046] Laticonther® 82 CP1/800, PA12, with a thermal conductivity of 9.5 W/(m*K), [0047] Laticonther® 62 CP6-V0HF1, PA 6, with a thermal conductivity of 4 W/(m*K), [0048] Laticonther® 52 CP1/60, PPH, with a thermal conductivity of 6 W/(m*K), [0049] CoolPoly® D5506, Thermally Conductive Liquid Crystalline Polymer (LCP), with 10 W/(m*K), or [0050] CoolPoly® D3612, Thermally Conductive Polyamide (PA). with 6 W/(m*K).

[0051] Alternatively or additionally, the electrically insulating and thermally highly conductive element may also be formed by an oxidic or non-oxidic ceramic material.

[0052] Of the oxidic ceramic materials, particularly suitable in this case are, for example: [0053] aluminum oxide, [0054] ZTA (Zirconia Toughened Alumina) materials, or [0055] ATZ (Alumina Toughened Zirconia) materials.

[0056] Of the non-oxidic ceramic materials, particularly suitable in this case are, for example: [0057] aluminum nitride, [0058] silicon carbide, or [0059] silicon nitride.

[0060] The electrical component 30, the busbar 40 and the electrically insulating element 50 have a hole 33 or 43 or 53, respectively, each of which is realized as a through-hole. During assembly, a sleeve 54 made of electrically insulating material is passed through the holes 33 and 43 in an assembly direction R, as a result of which a collar 56 of the sleeve 54 is brought into bearing contact with a first side 31 of the electrical component 30, and a lower edge 57 of the sleeve 54 is flush with a second side 42 of the busbar 40. Advantageously, the sleeve 54 also at the same time allows compensation of thermal expansions of the busbar 40.

[0061] The electrically insulating element 50 has, on a first side 51, a shaft 59 that surrounds the hole 53 and is arranged inside the sleeve 54. A length L59 of the shaft 59 corresponds in this case to a length L54 of the sleeve 54. Thus, the lower edge 57 of the sleeve 54 also bears against the first side 51 of the electrically insulating element 50.

[0062] The through-going fastening element 60, which in FIG. 1 is formed by a first fastening means 61A, can be passed through a hole 55 in the sleeve 54 and the through-hole 53 of the electrically insulating element 50.

[0063] In the exemplary embodiment shown, the first fastening element 61A is formed by a threaded rod. In alternative exemplary embodiments, this may also be formed by a screw or a rivet or a clamping bolt.

[0064] In the exemplary embodiment shown, fastening the first fastening means 61A, realized as a threaded rod in FIG. 1, through the through-hole 53 of the electrically insulating element 50 is effected by means of screwing. For this purpose, realized at an upper end 65 of the first fastening means 61A there is a receiver or a socket for a tool, which in the example shown in FIG. 1 is formed by a slot for a screwdriver.

[0065] Alternatively, the first fastening means 61A can also be fastened in the electrically insulating element 50 by pressing-in, bonding or encapsulation, as shown in FIG. 3.

[0066] For the purpose of fastening the connection arrangement 20 to a wall 11 of the housing 10, the first fastening means 61A is inserted into a blind hole 13 that is arranged on an inner side 12 of the wall 11. In the exemplary embodiment shown, the blind hole 13 is realized as a threaded hole, such that a thread 64 of the first fastening means 61A can be fastened in the blind hole 13. A second side 52 of the electrically insulating element 50 is thus pressed against the inner side 12 of the wall 11, which according to the invention is realized as a cooling plate.

[0067] In order to ensure a reliable connection of the connection arrangement 20 to the wall 11 of the housing 12, the upper end 65 of the first fastening means 61A is screwed tightly by means of a second fastening means 61B realized in the manner of a nut. As a result, the collar 56 of the sleeve 54 is pressed onto the first side 31 of the electrical component 30, and a second side 32 of the electrical component 30 is pressed onto a first side 41 of the busbar 40.

[0068] The transfer of heat thus rendered possible between the electrical component 30, the busbar 40 and the wall 11 of the housing 10 effects both active and passive cooling. In this way, overheating of the electrical components 30 or 40 arranged in the housing 10 can be avoided.

[0069] In the second exemplary embodiment of a connection arrangement 20 with a continuous fastening element 60, shown in FIG. 2, the electrically insulating element 50 is realized as a plastic disk and/or as a ceramic plate made of one or more of the materials already described above.

[0070] In this exemplary embodiment also, the electrical component 30, the busbar 40 and the electrically insulating element 50 have holes 33 and 43 and 53, respectively, realized as through-holes. During assembly, the sleeve 54 is passed through the holes 33 and 43 in an assembly direction R, as a result of which a collar 56 of the sleeve 54 is brought into bearing contact with a first side 31 of the electrical component 30, and the lower edge 57 of the sleeve 54 is flush with the second side 42 of the busbar 40. Advantageously, the sleeve 54 also allows compensation of thermal expansions of the busbar 40.

[0071] Since, in the exemplary embodiment shown, the electrically insulating element 50 is in the form of a plate, the busbar 40 can be in bearing contact with the electrically insulating element 50 over a large area, and thus dissipate the heat, generated in the busbar 40, over a larger area than in the first exemplary embodiment shown, via the electrically insulating element 50, to the wall 11 of the housing 10, which is realized a cooling plate. The use of an electrically insulating element 50 realized as a plate also makes it possible to reduce the overall height of the connection arrangement 20.

[0072] In the shown exemplary embodiment according to FIG. 2 also, fastening of the connection arrangement 20 to the wall 11 of the housing 10 is effected by means of a through-going fastening element 60, the fastening means 61A of which is realized a rivet, and therefore the blind hole 13 in the wall 11 is realized with a smooth surface.

[0073] The connection arrangement 20 can therefore be connected to the wall 11 by a form-fit in the form of cold rivets, or by a force-fit in the form of hot rivets. Alternatively, however, fastening by means of a screw connection is also possible in this case.

[0074] FIG. 3 shows an exemplary embodiment of a connection arrangement 20 having at least two fastening elements 61 and 62. In this case, the first fastening element 61 is formed by a first fastening means 61A and a second fastening means 61B, and the fastening element 62 is formed by a metal element 80.

[0075] The first fastening means 61A extends through the holes 33 and 43 of the electrical component 30 and of the busbar 40, and engages in a hole 53A realized on the first side 51 of the electrically insulating element 50 that is a good conductor of heat. This hole is realized as a blind hole, arranged in which there is a second fastening means 61B. The first fastening means 61A in this case may be realized as a screw or as a threaded rod or as a clamping bolt. The fastening means 61B, which serves as a counterpart, may be realized, for example, as a nut or as a threaded sleeve or as a press bush. In this exemplary embodiment also, the fastening means 61B, if at least partially made of plastic—for example a plastic sheath—can also advantageously allow compensation of thermal expansions of the busbar 40.

[0076] The metal element 80 is arranged in a second hole 53B on the second side 52 of the electrically insulating element 50, which is likewise realized as a blind hole. The metal element 80 in this case be fastened in the electrically insulating element 50 by, for example, encapsulation or screwing-in or by bonding. In the exemplary embodiment shown, the electrically insulating element 50 having good thermal conductivity is formed as a plastic block.

[0077] In the case of the connection arrangement 20 having at least two fastening elements 61 and 62, there is no need for a sleeve 54 as an insulating element that insulates the electrical component 30 and the busbar 40 from the fastening element 60. Direct contact between the through-going fastening element 60 and the wall 11 of the housing 10 does not occur in this connection arrangement 20 because the electrically insulating element 50 having good thermal conductivity does not have a through-hole in this case, and thus completely insulates the busbar 40 and the fastening element 60 and 61A, respectively, from the wall 11.

[0078] In FIG. 3, the connection arrangement 20 is connected to the wall 11 of the housing 10 in that a thread 84 of the metal element 80 is screwed into the tapped blind hole 13. Alternatively, the screw connection may also be replaced here by a press connection or an adhesive connection.

[0079] FIG. 4 shows a second exemplary embodiment of a connection arrangement 20 having with at least two fastening elements 61 and 62. In this case the connection arrangement 20 is connected to the wall 11 of the housing 10 in two steps. In the first step, the electrically insulating element 50 is fastened to the wall 11 of the housing by means of at least two second connection elements 62. For this purpose, these are guided into two holes 53B provided in the electrically insulating element 50, the upper region of which is larger in diameter than a through-hole located in the lower region. The two second connection elements 62 in this case are preferably realized as screws. The electrical component 30 and the busbar 40 are connected by means of the first fastening element 61 in a manner similar to that of FIG. 3.

[0080] The exemplary embodiment described in FIG. 5 is a third variant of fastening by means of at least two fastening elements 61 or 62. In FIG. 5, the first fastening element 61 is realized as a fastening means 61A, for example having a fir-tree profile for pressing into a correspondingly shaped receiver. Furthermore, the electrically insulating element 50 is realized as a sleeve 54, having a first sleeve half 54A and a second sleeve half 54B. The sleeve halves 54A and 54B can be joined together at a butt joint 58, which may be effected, for example, by means of an adhesive bond or by welding. The sleeve 54 may likewise be realized in one piece and pressed into the blind hole 13 in the wall 11. The inner surface of the sleeve 54 is preferably realized with a fir-tree profile running in the opposite direction to the fir-tree profile of the first fastening element 61, such that the profiles interlock positively upon being pressed-in. Alternatively, other forms of fastening are also possible here, such as screwing into a nut formed in or received in the sleeve 54.

[0081] In the exemplary embodiment shown in FIG. 5, the sleeve 54 is simultaneously realized as an electrically insulating element 50 and as a second fastening element 62. An adhesive bond 90 connects the second side 52 of the electrically insulating element 50 to the inner side 12 of the wall 11 of the housing 10. In this exemplary embodiment, the sleeve 54 also advantageously allows compensation of thermal expansions of the busbar.

[0082] According to a further embodiment, not represented, the electrically insulating element 50 having good thermal conductivity may also be formed by a layer of plastic and/or ceramic that, for example as an encapsulation, may partially or completely surround the busbar 50 outside of its intended contact regions.

LIST OF REFERENCES

[0083] 10 housing [0084] 11 wall [0085] 12 inner side (of 11) [0086] 13 blind hole [0087] 20 connection arrangement [0088] 30 electrical component [0089] 31 (first) side [0090] 32 (second) side [0091] 33 hole [0092] 40 busbar [0093] 41 (first) side [0094] 42 (second) side [0095] 43 hole [0096] 50 insulating element (having good thermal conductivity) [0097] 51 (first) side [0098] 52 (second) side [0099] 53 hole [0100] 53A hole [0101] 53B hole [0102] 54 sleeve [0103] 54A (first) sleeve half [0104] 54B (second) sleeve half [0105] 55 hole (in 54) [0106] 56 collar (of 54) [0107] 57 lower edge [0108] 58 parting joint/butt joint [0109] 59 shaft (of 50) [0110] 60 fastening element [0111] 61 first fastening element [0112] 61A (first) fastening means [0113] 61B (second) fastening means [0114] 62 second fastening element [0115] 64 thread [0116] 65 upper end [0117] 80 metal element [0118] 81 thread [0119] 90 adhesive bond [0120] L54 length (of 54) [0121] L59 length (of 59) [0122] R assembly direction