DE202010009326U1 - Fuse for interrupting a bridged point in the circuit of an electrical device - Google Patents

Abstract

Fuse (1) for interrupting an interruption point (3) bridged by a melt bridge (4) between two mutually spaced current path ends (2a, 2b) in the circuit of an electrical device, in particular an electric motor, the melt bridge (4) due to a temperature increase exceeding its melting temperature melts and opens the break point (3),
characterized,
that the melt bridge is a solder point (4) spanning the break point (3), and
a mechanical separating element (8) is provided which removes the solder from the point of interruption (3) when the soldering point (4) is melting.

Description

The invention relates to a fuse for interrupting a bridged by means of a melt bridge interruption point between two mutually spaced current path ends in the circuit of an electrical device, wherein the melt bridge melts due to a melting temperature exceeding temperature increase and opens the point of interruption. In this case, an electric device is understood to mean, in particular, an electric motor of a drive used in a motor vehicle for an actuating element, a radiator fan or the like.

From the DE 10 2007 011 548 A1 is an electric motor operated adjustment system of a motor vehicle, such as a window, a seat adjustment or a door or sunroof drive, with a control electronics for controlling the electric motor, taking into account a pinch protection known. In addition to software thermal protection, a thermal fuse element in the form of a spring element is held as overload protection in a conductor track section leading to the electric motor between two soldering points. When flowing over a certain time overload current, the solder is melted at one of the solder points, so that due to the spring bias of the spring element, the conductor is spontaneously interrupted. This thermal fuse can be designed as a prestressed helical spring-like spring element, as a leaf spring or as a cross-sectional constriction in the manner of a Dehndrahtsicherung.

From the DE 10 2007 025 345 B4 It is known to use in a DC fan motor of a motor vehicle, a thermal protection element in the form of a TCO element (thermal cut-off element), a fuse or a bimetallic switch in conjunction with a plastic-coated stamped grid, which is arranged between a DC voltage supply terminal and an electronic control unit and thermally coupled to this. If the temperature of the control electronics exceeds a predetermined threshold value, the thermal protection element triggers and interrupts the electrical connection between the DC voltage supply connection and the control electronics.

From the EP 1 120 888 B1 is a brushless motor with a combined equipotential bonding and heat-securing mechanism known, on the one hand balances the potential on a heat sink for power semiconductors in the form of field effect transistors to the potential of a power supply line, and on the other hand comprises a spring element, the melting of a heat-sensitive portion of an electrically conductive material , For example, a solder joint, a bridged by the spring element interruption point of an interrupted conductor section opens.

From the DE 39 09 302 A1 For example, a fuse with a fusible element made by attaching a low melting metal plate to a refractory metallic conductor is known. In order to prevent oxidation of the sections of the metal plate in contact with the metallic conductor, either the metal plate is partially fused (soldered) to the metallic conductor, or a layer of oxidation-resistant material is formed over the metal plate. Thus, by melting the electrically conductive alloys, a new alloy with a high electrical resistance, which should prevent a flow of current high currents.

At one of the WO 2008/116698 A1 known fuse is contacted in particular from a soft solder alloy existing conductor bar on auxiliary elements to the current-carrying conductor ends within a point of interruption. At a temperature increase above the melting point of the conductor bar, this melts, so that the electrical connection is interrupted due to the own surface tension of the conductor bar. The safe melting behavior in conjunction with the surface tension is achieved in that the conductor bar has a flux soul containing carboxylic acid.

In order to similarly reduce their surface tension by chemical action on such a fuse, it is known from US Pat DE-PS 1 588 425 It is known to provide a hollow cylinder made of lead pilot, in the interior of which a core of rosin is present as a flux.

The invention has for its object to provide a suitable fuse, the one hand in terms of their dimensions minimized interruption point on the one hand reliably bridged and on the other hand reliably opened during melting.

This object is achieved by the features of claim 1. Advantageous further developments, variants and embodiments are the subject of the dependent claims.

For this purpose, the point of interruption between two spaced-apart current paths is bridged by means of a melt bridge, which is designed in the form of a point of interruption spanning the solder point. A mechanical separator removes as a result of acting on this force melting soldering point the solder from the point of interruption. The force acting on the separating element can be the weight of the separating element itself or a pressing or compressive force acting on it, in particular a spring force.

The separating element may be completely or partially embedded in the soldering point. Optionally, the separating element is embedded in the soldering point to form a separation gap remaining within the point of interruption. Upon complete embedding of the separating element in the soldering point, the separating element is suitably electrically conductive and consists for example of conductor or current path material. Thus, for example, be used as a separating element for the production of the point of interruption, leaving the Strombahnenenden cut-piece of current.

According to a preferred variant, however, a separator made of electrically non-conductive material is used. In this variant, the electrically non-conductive separating element is acted upon by a contact force, so that when melting the soldering point, the separating element as a result of the contact force between the spaced-apart current paths enters the point of interruption. In this case, the separating element assumes a double function. Thus, due to the contact force, the separating element ejects the melting solder from the point of interruption on the one hand. On the other hand, the separating element is introduced as an insulating material between the two current path ends in the point of interruption.

In this variant, the length of the separating element is smaller than the length of the point of interruption determining distance between the two current path ends in order to be able to reliably penetrate into the point of interruption. In addition, the width of the separating element is greater than or equal to the width of the point of interruption. The width of the interruption point corresponds to the width of the two current path ends extending in the interconnect plane. This width dimension of the separator ensures reliable dispensing of the solder material of the melting solder point from the point of interruption.

If the contact pressure acting on the separating element is generated by means of a spring element, then this can be embodied as a spiral spring. In this embodiment, the separating element is suitably formed as a hollow body which receives the coil spring and is guided displaceably in a housing. The housing, in turn, is suitably supported in the region of the ends of the current conductor at or adjacent to these and at the same time forms the counter bearing for the spiral spring. This presses the separator due to the spring biasing force from the housing against the soldering point.

In an alternative embodiment, the spring element is designed as a leaf spring, one end of the spring is fixed in place. For example, this spring end is held fixed to the housing on a housing surrounding the current path with the bridged current conductor ends, in particular clamped in the housing. The opposite spring end of the leaf spring-like spring element then carries the separator and performs this under spring bias against the interruption point bridging solder point such that the separator automatically moves at melting Lotpunkt due to the spring bias between the current ends in the point of interruption.

In one embodiment of the leaf spring-like spring element whose separating element-side spring delivere is embedded in the soldering point. A portion of this spring end located outside the soldering point is then suitably enveloped by a non-conductive insulating layer (insulating layer, insulating sheath), the insulating layer forming the separating element. The embedded in the soldering portion of the separator-supporting spring leg is formed in particular in the form of a bent leg free. This extends suitably parallel to the current path ends and thus spans the point of interruption under gap formation to the two current path ends at least partially.

The advantages achieved by the invention are, in particular, that only a comparatively small soldering point and a minimized interruption point with respect to their dimensions can be produced within the current path of a current-carrying circuit by providing a mechanical isolating element. The interruption point is thus reliably bridged on the one hand for normal operation in the permissible temperature range. When triggered on reaching the melting temperature of the fuse produced by it is reliably and without chemical additives to reduce the surface tension in a simple manner purely mechanically virtually instantaneous removal of the molten solder point from the point of interruption and a reliable detachment of the solder from the two current end ends achieved.

Depending on the location of the point of interruption and the bridging solder point, the force of gravity of the separating element alone or, in the case of unfavorable installation conditions, a small contact pressure force is sufficient for the mechanical force action provided for this purpose acting simple spring element is generated. The soldering point forming the fused link of the fuse can therefore consist of a conventional solder material of a metal alloy based on lead, tin, zinc, silver and copper.

Embodiments of the invention will be explained in more detail with reference to a drawing. Show:

1 in a sectional view of a fuse in the form of an interruption point bridging soldering point and acted upon by a coil spring, applied to the soldering point separating element,

2 in a representation according to 1 a separating element acted upon by a leaf spring,

3 the embodiment according to 2 in a perspective plan view of the breakpoint with fuse,

4 a biased by a leaf spring-like spring element separating element with embedded in the soldering point bent-off spring delivere,

5 in a representation according to 1 a fuse with embedded in the soldering point separator, and

6 in a representation according to 5 a fuse with a bridging the bridging bridge element karftbeaufschlagenden separator.

Corresponding parts are provided in all figures with the same reference numerals.

1 shows a first variant of the fuse according to the invention 1 for interrupting a current-carrying current path 2 in case of thermal failure. In this case, between two spaced-apart current path ends 2a . 2 B a point of interruption 3 by means of a melt bridge in the form of a soldering point 4 bridged. The current path 2 is, for example, a tin surface-coated circuit board 5 , The corresponding surface coating forms the interrupted conductor or current path, whose upper and lower ends of the current conductor in the exemplary embodiment 2a . 2 B at the point of interruption 3 opposite each other. The distance a between the two opposite ends of the current conductor 2a . 2 B corresponds to the length of the point of interruption 3 ,

The current path 2 and thus the current-carrying ends 2a . 2 B can also be a stamped grid of a stamped grid, as in the 2 to 5 is indicated. The current path 2 or current ends 2a . 2 B are involved in a manner not shown in the circuit of an electrical device, in particular an electric motor. The circuit is triggered by the fuse 1 at the point of interruption 3 interrupted when this bridging soldering point 4 due to temperature or heat input melts.

The solder point 4 forms in 1 on the top a convex lotus miniscus 6 out, during the soldering point 4 on the opposite underside of the current path no or only a small, shallow bulge 7 generated. The solder point 4 but can also form another form. As solder material for the solder point 4 For example, a metal alloy based on lead, tin, zinc, silver and copper may be used. Depending on the set, ie predetermined or desired melting temperature hard or soft solder for the solder point 4 be used.

The fuse 1 further includes a mechanical separator 8th , according to the embodiment 1 as a bottom-side closed hollow body pot-shaped and made of non-conductive material. Bottom side is the separating element 8th in flight with the point of interruption 3 this one faces and lies on the plumb line 4 with a certain contact force F on. The contact force F is a spiral spring 9 produced in the hollow body or pot-like separating element 8th rests and on a housing inner wall 10 a housing 11 supported with a certain Federvrspannung. The housing 11 encloses the separating element 8th at least partially and leads this inside the housing. The housing 11 also supports, for example, strut-like support elements 12 on the circuit board 5 or at the current end of the wires 2a . 2 B from and is there by means of suitable fasteners 13 held.

Reaches the ambient temperature of the fuse 1 the melting temperature of the soldering point 4 this melts, whereupon as a result of the spiral spring 9 generated contact force F then the thixotropic solder from the point of interruption 3 is ejected. At the same time the separating element penetrates 8th in direction of force F into the point of interruption 3 between the two current ends 2a . 2 B one. This is the point of interruption 3 not only completely freed from the solder. Rather, the two current ends are also 2a . 2 B by means of the non-conductive separating element 8th electrically isolated from each other. Depending on the gradient of the temperature rise, the solder can also be used as a compact part (solder point 4 ) from the point of interruption 3 be expressed. Is melted then only the direct contact point with the conductor or conductor ends 2a . 2 B ,

In the embodiment of the 2 and 3 is the contact force F of a leaf spring 14 generated, one end of the spring 14a the separating element 8th wearing. The opposite end of the spring 14b is fixed in place. For this purpose, this spring end 14b in a housing 15 be clamped in which the current ends 2a . 2 B as well as from the Lotpunkt 4 bridged point of interruption 3 einliegen.

According to the in 3 shown coordinate system are the current ends 2a . 2 B in the xy plane, in which the distance a and thus the length of the separating element 8th and the point of interruption 3 extend in the x direction. The extending in the y direction width of the separating element 8th is greater than the width of the breakpoint 3 (in y direction). This ensures that at melting solder point 4 the solder over the entire width of the point of interruption 3 in consequence of the prestressed leaf spring 14 generated contact force F is ejected. At the same time, the separating element moves again 8th to the point of interruption 3 between the two leaders 2a . 2 B so that these are due to the non-conductive material of the separator 8th additionally insulated against each other.

In the embodiment according to 4 is the separator 8th in the form of an insulating sleeve on the spring end 14a the bent leaf spring 14 put on, for example, shrunk. In this embodiment, the spring end 14a Freiendseitig to form a thigh free 14c bent. This thigh free 14c the leaf spring 14 is in the the break point 3 bridging solder point 4 embedded. The thigh free runs 14c parallel to the conductor ends 2a . 2 B and lies in the breakpoint 3 under the formation of separating slits 16 to the respectively facing current ends 2a respectively. 2 B one.

As a result of a temperature-induced melting of the soldering point 4 moves the separator 8th due to the spring or contact force F in turn between the two current path ends 2a . 2 B and in this case carries the molten solder from the point of interruption 3 mechanically virtually residue-free.

In the embodiment according to 5 is the separator 8th' formed by a current path or punched grid section, which in the soldering point 4 within the interruption point 3 , suitably again to form separation slots 16 to the streamline ends 2a . 2 B is embedded.

In this embodiment, the ejection of the solder takes place at melting soldering point 4 from the point of interruption 3 due to the weight F 'of the embedded separator 8th' , This is electrically conductive in this embodiment and thus contributes in normal operation to the current flow over the means of the soldering point 4 bridged point of interruption 3 flowing current at.

The embodiment according to 5 can also with the spring-loaded separating elements according to the 1 to 3 be combined. In this case, the point at which the separating element 8th' soldered, subjected to the pressure or spring force F. This will when melting the soldering point 4 the solder itself as well as the soldered section (separating element 8th' ) from the point of interruption 3 expressed.

The separating element 8th' that also from a different conductive material than for example that of the leader 2 can exist, with too much to the point of interruption 3 , for example, be soldered from below. According to 6 is this with two solder joints 17 a bridge element 18 to the two current ends 2a . 2 B soldered. In this case, the separator presses 8th on the to the power rail ends 2a . 2 B soldered bridge element 18 and throw this at melting solder joints 17 out.

LIST OF REFERENCE NUMBERS

1

fuse

2

Current / conductor track

2a

Current path end

2 B

Current path end

3

breakpoint

4

Plumb point / Melting Bridge

5

circuit board

6

Lotminiskus

7

bulge

8th

separating element

9

spiral spring

10

Housing inner wall

11

casing

12

support element

13

fastener

14

leaf spring

14a

spring end

14b

spring end

14c

Free arm end

15

casing

16

separating slot

17

Perpendicular

18

bridge element

a

distance

F

contact force

F '

weight force

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102007011548 A1 [0002]
• DE 102007025345 B4 [0003]
• EP 1120888 B1 [0004]
• DE 3909302 A1 [0005]
• WO 2008/116698 A1 [0006]
• DE 1588425 [0007]

Claims (12)

Fuse ( 1 ) for interrupting one by means of a melt bridge ( 4 ) broken point ( 3 ) between two spaced-apart current-carrying ends ( 2a . 2 B ) in the circuit of an electrical device, in particular an electric motor, wherein the melt bridge ( 4 ) melts as a result of a melting temperature exceeding its temperature increase and the point of interruption ( 3 ), characterized in that the melt bridge is a break point ( 3 ) spanning solder point ( 4 ), and that a mechanical separating element ( 8th ), which at melting point ( 4 ) the lot from the point of interruption ( 3 ) away. Fuse ( 1 ) according to claim 1, characterized in that the separating element ( 8th . 8th' ) in the plumb line ( 4 ) forming at least one within the office ( 3 ) remaining separating slot ( 16 ) is embedded. Fuse ( 1 ) according to claim 1, characterized by an electrically non-conductive and with a contact force (F) acted upon separating element ( 8th ), which at melting Lotpunk ( 4 ) due to the contact force (F) between the mutually spaced current path ends ( 2a . 2 B ) to the point of interruption ( 3 ) retracts. Fuse ( 1 ) according to claim 3, characterized in that the length of the separating element ( 8th ) is smaller than the length of the breakpoint ( 3 ) determining distance (a) between the two current path ends ( 2a . 2 B ). Fuse ( 1 ) according to claim 3 or 4, characterized in that the width of the separating element ( 8th ) greater than or equal to the width of the width of the interruption point (xy) extending in the interconnect plane ( 3 ) facing stream ends ( 2a . 2 B ). Fuse ( 1 ) according to one of claims 3 to 5, characterized in that the separating element ( 8th ) acting on pressing force (F) by means of a spring element ( 9 . 14 ) is generated. Fuse ( 1 ) according to claim 6, characterized in that the separating element ( 8th ) is formed as a hollow body, which is a spiral spring ( 9 ), which together with the separating element ( 8th ) in a region near the end of the current ( 2a . 2 B ) supporting housing ( 11 ) while generating the contact force (F) via the separating element ( 8th ) on the soldering point ( 4 ) is arranged. Fuse ( 1 ) according to one of claims 3 to 6, characterized in that the separating element ( 8th ) at a spring end ( 14a ) of a leaf spring-like spring element ( 14 ) is held, whose the separating element ( 8th ) facing away from the spring end ( 14b ) is fixed in place while generating the pressing force (F). Fuse ( 1 ) according to claim 8, characterized in that the separating element ( 8th ) one the corresponding spring end ( 14a ) surrounding insulating sheath is. Fuse ( 1 ) according to claim 8 or 9, characterized in that the spring element ( 14 ) with which the separating element ( 8th ) bearing having spring end ( 14a ) in the plumb line ( 4 ) is embedded. Fuse ( 1 ) according to claim 10, characterized in that in the soldering ( 4 ) embedded spring end ( 14a ), forming one of the ends of the current ( 2a . 2 B ) at least approximately parallel Schenkelfreiendes ( 14c ) is bent. Fuse ( 1 ) for interrupting one by means of a melt bridge ( 4 ) broken point ( 3 ) between two spaced-apart current-carrying ends ( 2a . 2 B ) in the circuit of an electrical device, in particular an electric motor, wherein the melt bridge ( 4 ) melts as a result of a melting temperature exceeding its temperature increase and the point of interruption ( 3 ), characterized in that the melt bridge is a break point ( 3 ) spanning and with the current ends ( 2a . 2 B ) soldered bridge element ( 18 ), and that a, in particular spring-loaded, mechanical separating element ( 8th ) is provided, which in the case of melting solder ( 17 ) the bridge element ( 18 ) as a result of an applied force (F) from the point of interruption ( 3 ) away.

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