EP1434313A1 - High current contact elements with offset compensation - Google Patents

Abstract

The high current contact element has first and second plug contacts (1,2) that are connected together via a contact element (5). Electrical contacting takes place between the plug contacts and the contact element and contact surfaces (9,24). The contact element has a deformable section (32) that compensates for angular and/or axial offsets between the plug contacts.

Description

Technical field

In high-current contacting, for example when connecting three-phase connections on power lines, is for a conductive connection between the power lines and the three-phase connections. at High current contacts also require adequate electrical conductivity and to ensure good thermal conductivity.

State of the art

In the case of high-current connections, fixed connections have so far been used which can only be Destruction can be separated. These include integral connections that for example by welding, soldering or conductive gluing. It positive high-current contacts are also known, for example be made by riveting. High current contacts are also through Non-positive connections shown, the high-current contacting of one Press or a shrink fit is pulled through.

In addition to the fixed connections, which are only broken again by destruction plug-in techniques are known in which the contact partners are non-destructive are separable from each other. So far, contact parts with restricted shape and Positional tolerances of the components used. Contact parts were therefore as assemblies from procure high accuracy, which negatively affects the manufacturing costs of such contact parts affected. For applications in which a high-current contact between components to be created, which have a large coaxiality tolerance and a large angular offset, was modified by modifying one of the plug-in partners, taking into account the required Construction space realized a high-current contact. In such cases, which are caused by a large coaxiality tolerance and a large angular offset are marked in In the extreme case a complete replacement of one of the plug partners is required, which not inconsiderable additional effort in the production of high-current contacts represents about three-phase connections.

Presentation of the invention

The solution of a high-current contact proposed according to the invention stands out by a simple structure, a pluggability as well as an easy handling. With The embodiment of a high-current contact proposed according to the invention can be a Large coaxial angular misalignment made possible or permitted by rigid contact partners be based on the execution of the proposed according to the invention High current contact can be compensated. Thus, the plug technology can be in which the electrical contact partners can be separated from one another without being destroyed are.

The solution proposed according to the invention provides a plug contact system for a High current contacting, the axial misalignment of up to several millimeters as well Angular offsets of up to 10 ° for three-phase connections, which in turn are rigid are included, balances or bridges. The proposed according to the invention A high-current contact is made of a material that on the one hand has high electrical conductivity and on the other hand good Has heat conduction properties. The material used is springy and points sufficiently large contact areas with regard to the contact resistance.

The proposed high-current contact has in particular a central section, which allows an extremely high deformability, so that larger axial misalignments as well larger angular tolerances can be taken into account.

In one of the design variants proposed according to the invention, a High current contacting can be realized in that two plug pins via a phase contact spring can be connected to each other. The phase contact spring will preferably designed as a spiral spring. The spring wire cross-section of the phase contact spring used can be circular, rectangular, trapezoidal or even ring-shaped Enclosing cavity.

In a further embodiment variant of those proposed according to the invention High-current contacting can be done by inserting two pins into its flat shape connect a rolled sleeve formed tubular member together. We then a slit of, for example, the starting material in flat form provided a slot angle of about 45 °, an increased buckling of the Pins connecting sleeve-shaped body achieved what the balance a larger coaxial or angular offset of the two electrically contacting pins allowed. In addition, the one made of flat material Have contact sleeve widened chamfer ends, or a correspondingly large have molded bevel and a collar for a pull-through or for Recording a weld. According to the second embodiment variant, this is also a Cohesive connection between pins of a high-current contact possible. Due to the large overlap between the outer surface of the rolled sleeve and the Plug contacts provide sufficiently large contact areas between the outer sides the pins and the inside of the rolled sleeves so that they are big enough There are contact surfaces, which is favorable in terms of contact resistance.

drawing

The invention is described in more detail below with reference to the drawing.

Figur 1

eine Hochstromkontaktierung zweier Steckstifte mit Spiralfeder als Phasen-Kontaktfeder,

Figur 1.1

mögliche Drahtquerschnitte des Federmaterials der Phasen-Kontaktfeder gemäß Figur 1,

Figur 2

eine zylinderförmige, mittig geschlitzte Phasen-Kontaktfeder nach einer weiteren Ausführungsvariante,

Figur 3

eine Hochstromkontaktierung mit der Phasen-Kontaktfeder gemäß Figur 2 und zwei Steckstiften,

Figur 4

eine Hochstromkontaktierung in Einbaulage,

Figur 5.1

das Kontaktierungsmaterial in ebenem Zustand mit 45°-Schlitzung,

Figur 5.2

eine aus dem Material gemäß Figur 5.1 gerollte Phasen-Kontaktfeder,

Figur 5.3

eine gestauchte Phasen-Kontaktfeder,

Figuren 6.1, 6.2

Ausgestaltungen der Stirnseiten der Phasen-Kontaktfeder mit aufgeweiteten Phasen oder Bundflächen und

Figur 7

eine weitere Ausführungsvariante einer Phasen-Kontaktfeder.

It shows:

Figure 1

a high-current contacting of two plug pins with a spiral spring as a phase contact spring,

Figure 1.1

possible wire cross sections of the spring material of the phase contact spring according to FIG. 1,

Figure 2

a cylindrical, centrally slotted phase contact spring according to a further embodiment,

Figure 3

a high-current contact with the phase contact spring according to Figure 2 and two pins,

Figure 4

a high-current contact in the installation position,

Figure 5.1

the contacting material in the flat state with 45 ° slit,

Figure 5.2

a phase contact spring rolled from the material according to FIG. 5.1,

Figure 5.3

a compressed phase contact spring,

Figures 6.1, 6.2

Embodiments of the end faces of the phase contact spring with expanded phases or collar surfaces and

Figure 7

a further embodiment of a phase contact spring.

variants

Figure 1 shows a high-current contacting of two pins with phase contact spring.

The high-current contact shown in Figure 1 comprises a first pin 1 and a second pin 2. The first pin 1 is provided with a first pin 3; the second plug pin: 2 has a second pin 4. Between the front of the The first pin 3 and the second pin 4 is located according to that in FIG. 1 The embodiment variant shown is a phase contact spring 5 designed as a spiral spring. The phase contact spring 5 is wound from spring windings 6, the spring material, from which the spring windings 6 are wound, one of those shown in Figure 1.1 Can have cross sections. In Figure 1, the spring material is circular Cross section 20.

The first pin 3 and the second pin 4 of the pins 1, 2 are in a pin length 8 formed, which the distance between a contact surface 15 on the first pin 1st and corresponds to a cone rounding 19. The pin length 8 of the second pin 2 is the dimension between the rounding 19 on the end face of the second pin 2 and a bearing surface marked with reference numeral 16 on the second pin 2. The first pin 1 and the second pin 2 and the phase contact spring located between them 5 are shown in a stretched arrangement 10. In the stretched Arrangement 10, the lines of symmetry of the first pin 1 and the second fall Pin 2 and the phase contact spring 5 together. The peripheral surface of the first Pin 3 and the second pin 4 of the pins 1, 2 is with reference numeral 9 characterized. The lateral surface 9 of the pins 3 and 4 is sufficiently large Contact surface between the first pin 1 and the second pin 2 and one Inner side 24 of the spring windings 6 of the phase contact spring 5 securely to the Contact resistances between the first pin 1 and the second pin 2 and to keep the phase contact spring 5 low.

To facilitate assembly, the spring windings 6 in their end regions, i.e. the first pin 1 and the second pin 2 opposite to be expanded. At the Join the phase contact spring 5 with the pins 3 and 4 of the first plug pin 1 and of the second plug pin 2 is a contact between the lateral surfaces 9 of the first pin 3 and the second pin 4 with the inside 24 of the spring turns on. Because of the phase contact spring 5, which in the illustration according to FIG Spiral spring is formed, axial or angular misalignments can be compensated without that the electrical connection between the lateral surface 9 of the first pin 3 and second pin 4 of the pins 1, 2 and the inside 24 of the spring turns 6 of the Phase contact spring 5 is affected. An axial offset 12 between the Line of symmetry 11 of the first plug pin 1 and line of symmetry 11 of the phase contact spring 5 and the line of symmetry of the second pin 2 can due to The nature of the phase contact spring 5 can be easily compensated for as a spiral spring. With reference numeral 13 is an angular offset of the first pin 1 relative to the phase contact spring 5 and the second pin 2 shown in the rigid installation position. Due to the inherent elasticity of the phase contact spring 5, both Compensate for axial offsets 12 as well as angular offsets 13, so that a High-current contacting also between those received in a rigid installation position second pin 2 and in an axial offset 12 and an angular offset 13 in Dashed representation shown first pin 1 can be brought about. In the Figure 1 shown pluggable high-current contacting is capable of both Axial offset 12 with respect to the first pin 1 and an angular offset 13 of the first pin 1 to compensate for the expanded area of the phase contact spring 5. Furthermore, an axial offset 12, on which an angular offset 13 is superimposed, by the Design of the phase contact spring 5 proposed according to the invention compensated be without the electrical contact between the lateral surface 9 of the first Pin 3 and the inside 24 of the spring windings 6 in the end region 18 of the phase contact spring 5 is impaired.

The high current contact shown in Figure 1 bypasses the manufacture of the contact parts with limited shape and position tolerances, so that the non-destructively separable contact partners, in the present case the first pin 1 and the second pin 2, and the phase contact spring 5 connecting them can be produced inexpensively. With the embodiment of a high-current contact shown in Figure 1, axial misalignments 12 of several millimeters and angular misalignments of up to 10 °, for example for three-phase phase connection pairs that have a rigid installation position, can be compensated for, so that the assembly is considerably simplified. In particular, the embodiment variant of the high-current contacting according to the invention shown in FIG. 1 makes it possible to avoid modifications or reworking on the pins 1 and 2, respectively. With α ₁ , α ₂ different suspension angles are referred to, in which the individual spring windings 6 of the first phase contact spring 5 can be formed. In the exemplary embodiment shown in FIG. 1, α ₁ <α ₂ .

FIG. 1.1 shows possible winding cross sections of the phase contact spring designed as a spiral spring, which the first pin 1 and the second pin 2 together combines.

The spring material from which the individual spring windings 6 of the phase contact spring 5 exist, may have a circular cross section 20 and a ring cross section 21. It is also possible to make the spring turns 6 of the phase contact spring 5 from one To produce material that has a rectangular cross section 22. It is next to it also possible, the spring windings 6 from a trapezoidal cross section 23 material to wrap.

The end regions 18 of the phase contact spring 5 shown in FIG. 1 can be used as widened areas, showing joining chamfers, according to the one to be compensated Axial offset 12 or the angular offset 13 to be compensated expanded become. Also a firm connection of one of the plug partners 1 and 2 with the phase contact spring 5 is conceivable, so that a current transition surface 9 or 24 is produced and the contact resistance between the phase contact spring 5 and the first Let pin 1 decrease. The spring windings 6 of the phase contact spring 5 offer sufficiently long lines of contact along their inside 24 with the lateral surface 9 of the first pin 3 and second pin 4.

Figure 2 shows a cylindrical, centrally slotted phase contact spring.

The illustration according to FIG. 2 shows the first pin 1 and the second pin 2 remove. The plug pins each have contact surfaces 15, 16 for end faces 39 and 40 a second phase contact spring 30 provided as a cylinder sleeve. Everyone who Pins 1 and 2 comprise a pin 3 and 4. The pins 3 and 4 extend via an axial length marked with reference numeral 8 between the contact surfaces 15 or 16 of the pins 1, 2 and the pin curves 19. In contrast to that in FIG. 1 High current contact shown is the contact area between the first pin 3 or the second pin 4 and the second phase contact spring 30 through the Inner side 33 of the second phase contact spring 30 designed as a cylinder sleeve is formed. The second phase contact spring 30 comprises a slotted center section 32, which a deformability of the second phase contact spring 30 to compensate for that in FIG. 1 shown axial offset 12 and that also indicated in Figure 1 Angular offset 13 between one of the plug partners 1 and 2 and the second phase contact spring 30 allows. The second phase contact spring 30 can also be a include convex or concave arched central section, for example, by Compression of the second phase contact spring 30 made of resilient contact material can be generated. Instead of the central section provided with slits in FIG. 2 32 of the second phase contact spring 30 can, for example, the punched-out slots also be concave or convex. This depends on the degree of Deflection, i.e. according to the axial or angular misalignment to be bridged Plug partners 1, 2 to each other.

FIG. 3 shows a high-current contact with the phase contact spring according to FIG. 2 and two pins inserted into it.

The high-current contact 35 shown in Figure 3 is by the second phase contact spring 30 manufactured.

The second phase contact spring 30, which is slotted in its center section 32 lies with their respective end faces 39 and 40 on the contact surfaces 15 and 16 on the Inside of the first pin 1 and the second pin 2. The second Phase contact spring 30 comprises a longitudinal joint 31, which is parallel to the line of symmetry 11 of the first pin 1 and the second pin 2 and the second phase contact spring 30 extends. The high flow contact 35 according to FIG. 3, shown in FIG their assembled state has a substantially extended installation position, i.e. the first pin 1 and second pin 2 are aligned with each other.

Figure 4 shows a phase contact spring in the installed state.

4 shows the first plug pin 1 and the second plug pin 2 (see illustration according to FIG. 3) omitted. The second phase contact spring 30 comprises a curved central section 34, which has convex slots 42 is enforced. Due to the weakening of the material of the arched The center section 34 of the second phase contact spring 30 is, as in FIG. 4 shown, deformable. During the end of the second having the first end face 39 Phase contact spring 30 coaxial with the line of symmetry 11 of the second phase contact spring 30 extends, is the end of the second phase contact spring having the second end face 40 30 by an angular offset 36 with respect to the line of symmetry 11 of the second phase contact spring 30 shown offset. The second face 40 of the second Phase contact spring 30 is located on the contact surface 16 of the not shown here in Figure 4 second pin 2. This is at an angular offset 36 installation position, which by the deformed area 37, i. the Center section 32 of the second phase contact spring 30 is shown. Due to the Arrangement of the slots 42 in the arch region 34 of the second phase contact spring 30 and the resulting weakening of the material can, on the one hand, the angular offset 36 balanced between the line of symmetry 11 and the position of the second end face 40 on the other hand, there is a current flow through the second phase contact spring 30 guaranteed, which is preferably made of a material that on the one hand has a high has electrical conductivity and, on the other hand, good heat-conducting properties.

Figure 5.1 shows a resilient contact material in the flat state, which in its Center area is slotted.

The second phase contact spring 30 shown in FIGS. 2, 3 and 4 adjusts rolled component, which is shown in Figure 5: 1 in its flat state resilient contact material 41 is produced. This can be within its mid-range 32 can be provided with slots 42, for example at an angle of 45 ° can extend with respect to the edges of the resilient contact material 41. Instead of the introduced in the flat contact material 41 in Figure 5.1, which extends at 45 ° The central section 32 of the planar contact material 41 (see illustration 4) also with concave or convex cutouts or Incisions are provided with which there is also a weakening of material in the can bring about resilient contact material 41. The weakening of the resilient Contact material 41 within its central section 32 facilitates this Deformability to compensate for axial misalignments 12 or angular misalignments 13 or 36 (cf. illustration according to FIGS. 1 and 4).

Figure 5.2 shows a second rolled from the resilient contact material according to Figure 5.1 Phase contact spring.

The second phase contact spring 30 as shown in FIG. 5.2 (see illustration according to Figures 2 and 3) from that shown in Figure 5.1 in the flat state resilient contact material 41 rolled. The inside 33 of the second phase contact spring 30 forms the contact surface to the lateral surfaces 9 of the first pin 3 and the second Pin 4 of the first pin 1 and the second pin 2 of the High current contact 35. Because of the arrangement of the slots 42, be straight formed, convex or concave curved, in the central region 32 of the second Phase contact spring 30, its deformability is adjusted. With reference number 39 or 40 are the end faces of the second phase contact spring 30 or respectively.

Figure 5.3 shows a compressed second phase contact spring according to the figures 2, 3 and 5.2.

The resilient contact material 41, from which the second phase contact spring 30 is manufactured, has a wall thickness 38, which depending on the application and transmitting currents is selected. The second phase contact spring 30 according to the The representation in FIG. 5.3 is within its curved central region 34 provided convex slots 42. The curvature 34 of the central area 32 can by upsetting the rolled second one, which has an axially extending parting line 31 Phase contact spring 30 are made. This is shown in Figure 5.2 cylindrically shaped second phase contact spring 30 on its first end face 39 and its second end face 40 acted upon by a compressive force, whereby the Central area 32, within which the slots 42 are formed, bulges accordingly.

Figures 6.1 and 6.2 are configurations of the end faces of the phase contact spring to see expanded phases or collar surfaces.

Figure 6.1 shows a partially sectioned representation of a second phase contact spring 30 (see Figure 5.3). the second phase contact spring 30 comprises a central region 32 which has a convex curvature 34. To facilitate insertion of the pins 3 and 4 respectively of the first pin 1 and the second pin 2 in the ends of the second phase contact spring 30 are the chamfers 43 and 44 on the peripheral surface of the second phase contact spring 30 radially expanded. With reference numeral 38 is the material thickness of the resilient contact material from which the second phase contact spring 30 is made, characterized. The slots formed within the convex region 34 42 run parallel to the axis of symmetry of the second in the illustration according to FIG. 6.1 Phase contact spring 30. FIG. 6.2 shows a second phase contact spring 30, on the one hand a chamfer 46 and one opposite at the other end area Has collar surface 45. The central section 32 weakened by the slots 42 is shown in FIG the embodiment of Figure 6.2 concave. The slots 42 extend analog to the representation of the second phase contact spring 30 according to FIG. 6.1 parallel to Axis of symmetry of the second phase contact spring 30. The in FIGS. 6.1 and 6.2 shown embodiment variants of the second phase contact spring 30 with expanded End regions 43 or 44 or with chamfer 46 and collar surface 45 can also be integrated Be part of a track. The first widened chamfer 43 or the illustrated second widened chamfer 44 and alternatively the chamfer 46 enable the compensation of one large axial offset, the deformation of section 32, be it concave it is convex, a residual prestressing force is maintained, through which the High current contact 35 between the first. Pin 1 and the second pin 2 is maintained.

The high-current contact 35 shown is characterized by non-destructive Plug-in of the contact partners 1, 2, 5 or 1, 3, 30 involved. Furthermore, this is Particularly easy to handle with regard to their assembly, since there is a large axial offset 12 and / or a large angular offset 13 or 36 with the aid of the deformable phase contact springs 5, 30 can be easily compensated without rework with regard to the position of one of the plug partners 1 or 2 or on the phase contact spring 5, 30 are required.

FIG. 7 shows a further embodiment variant of an embodiment designed according to the invention Phase contact spring.

The embodiment variant of a third phase contact spring 50 shown in FIG. 7 comprises a first section 50.1 and a second section 50.2. The difference to the first phase contact spring 5 shown in FIG. 1, sections 50.1 and 50.2 of the third phase contact spring 50 are formed in different diameters. The inner diameter of the first section 50.1 of the third phase contact spring 50, denoted by reference numeral 51 is smaller than that denoted by reference numeral 53 Inner diameter of the second section 50.2 of the third phase contact spring 50. So can differentiate about the embodiment variant according to FIG. 7, pins 1, 2 Diameter can be electrically connected to each other. Between the first section 50.1 and the second section 50.2 of the third phase contact spring 50 arises a transition region 56 due to the different inner diameters 51 and 53, which is essentially frustoconical. The axis of symmetry of the third Phase contact spring 50 is identified by reference number 52. The length of the first Section 50.1 of the third phase contact spring 50 is identified by reference numeral 54 marked and corresponds essentially to the length of one in the first section 50.1 pin to be inserted. The length of the second section 50.2 of the third Phase contact spring 50 is designated by reference numeral 57. Within the length 57 of the second section 50.2 of the third phase contact spring 50 can be an extended region 55, in which the winding spacing of the individual spring windings 6 can be larger, so that the individual spring windings 6 of the third phase contact spring 50 do not lie against one another as shown in FIG. 7. To make it easier Inserting a plug pin into the interior of the first section 50.1 of the third phase contact spring To ensure 50, at the open end of the first section 50.1 the third phase contact spring 50, one or more spring windings 6 can be expanded, as indicated in FIG. 7 by reference number 58. On the second section 50.2 of the third Phase contact spring 50 can form the end turn as a narrowed spring turn 59 be to securely fix another pin of an electrical connection reliably limited by the inner diameter 53 of the second section 50.2 To ensure the cavity of the second section 50.2.

An angular offset 13 or an axial offset 12 between the pins 1, 2 possible, a particularly light Mountability is given. The angular offsets 12, 13 are over the transition cone 56 balanced.

LIST OF REFERENCE NUMBERS

1

first pin

2

second pin

3

first cone

4

second pin

5

first phase contact spring

6

spring coil

7

winding cross

8th

Bolt length

9

lateral surface

10

stretched arrangement

11

Line of symmetry phase contact spring

12

Axial offset of the first pin

13

Angular misalignment of the first pin

14

Line of symmetry of the first pin

15

Contact surface of the first pin

16

Contact surface of the second pin

17

Auslaufwindung

18

End-of-turn widening

19

Zapf rounding

20

Circular cross-section

21

Ring cross section

22

Rectangular cross-section

23

Trapezoidal cross-section

24

Inside of spring coils 6

30

second phase contact spring

31

longitudinal joint

32

mid section

33

Inside of the second phase contact spring

34

domed area

35

Hochstromkontaktierung

36

angular displacement

37

deformed area

38

Wall thickness of the second phase contact spring 30

39

first face

40

second face

41

resilient contact material, just

42

45 ° -Schlitzung

43

first flared bevel

44

second flared bevel

45

Bund area

46

chamfer

47

concave constriction

α ₁

first spring turn angle

α ₂

second spring turn angle

50

third phase contact spring

50.1

first section

50.2

second part

51

Inside diameter of the first section

52

axis of symmetry

53

Inner diameter of the second section

54

Length of the first section

55

stretched area second section

56

Transition cone

57

Length of the second section

58

widened spring coil

59

constricted spring turn

Claims (16)

Live contacting with a first plug contact (1) and a second plug contact (2), which are connected to one another via a contact element (5, 30, 50) and between the plug contacts (1, 2) and the contact element (5, 30, 50) and contact surfaces (9, 24; 9, 33) an electrical contact is made, characterized in that the contact element (5, 30, 50) has an angular offset (13, 36) and / or axial offset (12) between the plug contacts (1, 2 ) Compensating, deformable section (32, 34, 56). Current-carrying contact according to claim 1, characterized in that the contact element (5, 30, 50) is resilient. Current-carrying contact according to claim 1, characterized in that the contact element (5, 50) is designed in the form of a spiral spring and the spring windings (6) form contact surfaces (24). Current-carrying contact according to claim 3, characterized in that the contact element (5) has an enlarged turn diameter of the spring turns (6) at its end regions (18) receiving the plug contacts (1, 2). Current-carrying contact according to claim 3, characterized in that the contact element (5, 50) has an enlarged winding angle α ₂ in a central region (32) or a section (50.2). Current-carrying contact according to claim 3, characterized in that the spring material has a circular or an annular cross section (20, 21). Current-carrying contact according to claim 3, characterized in that the spring material has a rectangular or a trapezoidal cross section (22, 23). Current-carrying contact according to claim 3, characterized in that the spring windings (6) of the spiral spring-shaped contact element (5, 50) envelop the lateral surfaces (9) of pins (3, 4) of the plug contacts (1, 2) several times. Current-carrying contact according to claim 1, characterized in that the contact element (30) is cylindrical and is made of a resilient contact material (41). Current-carrying contact according to claim 9, characterized in that the contact element (30) is provided in its central region (32) with recesses (42). Current-carrying contact according to claim 9, characterized in that the central region (32) of the contact element (30) has a convex curvature (34) or a concave constriction (47). Current-carrying contact according to claim 10, characterized in that the recesses (42) are designed as slot-shaped, convex or concave curved recesses. Current-carrying contact according to Claim 9, characterized in that the contact element (30) has chamfers (43, 44) widened at its ends. Current-carrying contact according to claim 10, characterized in that the recesses (42) run at an angle of up to 45 ° with respect to the edges of the flat, resilient contact material (41). Current-carrying contact according to claim 9, characterized in that the contact element (30) has a collar surface (45) at one end. Current-carrying contacting according to claim 9, characterized in that the contact element (30) has a longitudinal joint (31) extending parallel to the axis of symmetry (11).

Images