DE10024381A1 - Three-pole thermal switch has housing for contact bridge and two mechanically biased contact springs fixed on contact bridge by solder fuse that melts if threshold temperature exceeded - Google Patents

Abstract

The switch has a housing (2) for a contact bridge (4A) and two mechanically biased contact springs (6,7) fixed on the contact bridge by a solder fuse (8) that melts if a threshold temperature is exceeded. The contact springs are pivoted away by the mechanical bias to open the electrical contact. The housing has two halves (2A,2B) that are joined by a latching device. Independent claims are also included for the following: a use of the switch to protect temperature-sensitive components.

Description

The invention relates to a three-pole thermal switch.

DE-AS-11 08 795 describes a thermal small self switch with a free-floating, swiveling switching bridge, the one with a counter contact and on the other hand with egg interacts with a bimetal. This small thermal scarf ter is switched on by a rocker arm brings in which the swiveling switching bridge with one end at one contact and at the other end on a contact shoe of a bimetal strip. Bends when heated the bimetal strip so that the switching bridge from the contact shoe is unlocked and swiveled, the on the the other end of the jumper opens.

DE-AS-10 95 378 describes a switching device with thermal Tripping, in which a coupled with a push button,  pivotable switching bridge is provided, the one hand with a counter contact and on the other hand together with a bimetal works. The switching mechanism is controlled solely by the switching bridge formed on which acts a single switch spring, the at the same time as contact pressure, switch-off and return spring serves.

The thermally triggered switches described above have a swiveling switching bridge, which with egg at both ends nem contact is provided. The current flows when switched on over the bimetal strip and the switching bridge to the counter con clock. If an overcurrent occurs, the bime bends tall strips and gives the after a certain deflection Switch bridge free, which ver due to the action of a spring is pivoted, whereby the contacts are separated.

These switches are temperature sensitive two-pole switches that trip when an overcurrent occurs and thus open a circuit.

Such temperature-sensitive two-pole switches are used for example as a temperature switch in an overvoltage protection device, as shown in Fig. 1. Surge protection devices require temperature protection in the event that the surge protection components they contain, such as varistors, are overheated.

Fig. 1 shows a conventional surge protection device according to the prior art. A phase conductor L and a neutral conductor N are each connected via a temperature switch T and a varistor V to a star point, which is connected via a spark gap F to a protective conductor PE. The Varisto ren V ₁ , V ₂ are each thermally connected to temperature switches T ₁ , T ₂ , which trigger when overheating and separate the varistors from the respective active line L or N.

For such surge protective devices, two temperature switches T ₁ , T ₂ are used to separate the two active conductors L, N in the event of a fault from the components V ₁ , V ₂ . Such surge protective devices are expensive to manufacture due to the installation of several Tem temperature switch.

Fig. 2 shows a further surge protection device according to the prior art, as described in DE 198 19 792, wherein a three-pole temperature switch TS is built into the surge protection device. A varistor V ₁ is connected between a node K _{1 of} a phase conductor L and a first connection of a three-pole switch TS. A second varistor V ₂ is switched between a node K _{2 of} a neutral conductor N and a second connection of the three-pole switch TS. The three-pole switch TS is connected to a protective conductor PE via a spark gap F.

Fig. 3 shows the conventional three-pole switch TS shown in Fig. 2 in detail. The three-pole switch TS has a pivotable rotary contact D, which consists of three contact arms A, B, C, which are in a certain fixed spatial relationship to each other. The rotary contact D is pivotally mounted at a pivot point P. The contact arm C forms a trigger arm at the same time, which is held by a spring FE in an associated temperature-sensitive solder fuse L. The contact arms A, B, C have contacts at their ends. The contacts are in contact with the associated counter contacts when switched on.

If there is a change in temperature or if a temperature is exceeded certain fuse current value melts the fuse L, so that the trigger arm C is attracted by the spring FE. There the rotary contact D with its three contact arms A, B, C pivoted to separate the contacts from the counter contacts.

However, the three-pole switch according to the prior art shown in FIG. 3, as described in DE 198 19 792 A1, has some disadvantages. The construction of the three-pole switch TS is technically relatively complex. A spring FE is additionally provided in the switch TS as an independent additional component. This increases the manufacturing costs of the switch. Since the contact arms A, B, C must be in a very precise fixed spatial relationship to each other, the manufacturing tolerances in the manufacture of the rotary contact D are very small, so that the manufacture of the rotary contact D is relatively expensive. In addition, the assembly of the rotary contact D in the housing of the switch and the attachment to the spring FE is relatively labor-intensive, as a result of which the manufacturing costs increase further.

Another disadvantage is that even if a trigger arm A, B, C is slightly deformed, the electrical contact to the associated mating contact becomes high-resistance or is even interrupted. In such a case, the three-pole switch, as shown in Fig. 3, is no longer functional.

It is therefore the object of the present invention, a three-pin thermal switch to protect heat-sensitive To create components of a particularly simple structure having.

This object is achieved by a three-pole Thermal switch with the feature specified in claim 1 len solved.

The thermal switch according to the invention is preferably in particular for temperature monitoring of heat-sensitive components applicable.

Preferred further embodiments of the invention are in the subordinate claims specified.

The following is a preferred embodiment of the invention explained with reference to the accompanying drawings.

Show it:  

Fig. 1, an overvoltage protection device with two temperature switches according to the prior art,

Fig. 2 shows another overvoltage protection device with a three-pole circuit breaker according to the prior art,

Fig. 3 is a three-pole thermal switch according to the prior art,

Fig. 4 shows a preferred embodiment of the three-pole thermal switch according to the invention,

Fig. 5 is an enlarged section of Fig. 4 for presen- tation of the solder fuse, and

Fig. 6 is a surge protector with the inventive thermal switch.

Fig. 4 shows a three-pole thermal switch 1 for the protection of heat-sensitive components according to the invention. The thermoswitch 1 has a housing 2 , which consists of two housing halves 2 A, 2 B, which are connected by a latching device. As a result, the housing 2 can be made particularly inexpensive.

The housing halves 2 A, 2 B can be constructed or designed symmetrically to each other. Instead of a latching of the housing halves or parts 2 A, 2 B, these can be locked against one another by welding or the like.

The three-pole thermal switch 1 has three electrical connections in the form of contacts 3 , 4 , 5 . The housing 2 serves to receive a contact web 4 A, the clock having a mean Kon is connected conductively 4, wherein the contact bridge 4 are A and the center contact 4 is preferably formed as an integral component made. Two mechanically prestressed contact springs 6 , 7 rest on the contact web 4 A. The contact spring 6 is there electrically connected to the first electrical contact 3 and the contact spring 7 to the third contact 5 . In a preferred embodiment, the first electrical contact 3 and the contact spring 6 are formed by an integral component. Furthermore, the contact spring 7 and the third electrical contact 5 likewise preferably form an integral component. The contact springs 6 , 7 consist of an electrically conductive material and are mechanically pre-stressed during assembly in the housing. The mechanically biased contact springs 6 , 7 are attached with a solder fuse 8 to the contact web 4 A.

As is apparent from Fig. 4, the contact springs 6, 7 approximately V-shaped disposed within the housing 2 A, 2 B, wherein the obe ren ends of the contact springs 6, 7 by the Lotsicherung 8 at the upper end of the vertically within the Housing parts 2 A, 2 B lying contact web 4 A are attached. The contact springs 6 , 7 each extend over a contact surface 11 A, 11 B located inside the housing, over a contact surface 12 A, 12 B arranged on the housing half 2 A or 2 B and a deflection 13 A defined by a lower housing cover 16 , 13 B through openings 14 A, 14 B and end in contacts 3 and 5 , as can be clearly seen in FIG. 4.

Through these deflections 11 A, 11 B, 12 A, 12 B, 13 A, 13 B, the contact springs 6 , 7 are firmly clamped relative to the housing. The aforementioned deflecting surfaces or contact surfaces 11 A, 11 B, etc. are made of insulating material.

At the lower end of the contact web 4 A there is the contact 4 described above, which parts 2 A, 2 B protrudes downwards from the housing or from the housing and is essentially parallel to the contacts 3 , 5 .

The fact that the contacts 6 , 7 are bent from the housing wall in the direction of the solder fuse 8 results in the pretensioning of the two contact springs 6 , 7 .

When a threshold temperature is exceeded, the solder fuse 8 melts and the mechanically prestressed contact springs 6 , 7 pivot with their upper ends away from the contact web 4 A to interrupt the electrical contact. The melted during the melting of the solder fuse 8 drips down by gravity into receiving webs 9 , 10 , which collect melted-off solder residues. This prevents short circuits that could be caused by melted solder residues.

Before the solder fuse 8 melts, the contact springs 6 , 7 are electrically connected to the contact web 4 A. The Kontaktfe countries 6 , 7 are, as shown in Fig. 4, on the contact web 5 in an arc shape, the arc shape of the two contact springs 6 , 7 is mirror-symmetrical to the vertical line of symmetry of the housing 2 . The curvature of the curved contact springs 6 , 7 is relatively low, so that mechanical overloading of the contact springs 6 , 7 is prevented. However, the curvature of the contact springs 6, 7 is sufficiently high, a Schwen ken of the contact springs 6, 7 to ensure after melting the Lotsicherung 8 from the contact web 4 A clear.

The curvature of the contact springs 6 , 7 and the melting temperature value of the solder fuse 8 determine when the contact springs 6 , 7 detach from the contact web 4 A. The higher the melting temperature of the solder and the greater the curvature of the two contact springs 6 , 7 , the lower the threshold temperature at which the contact springs 6 , 7 swing away from the contact web 5 and interrupt the electrical connection. The geometry of the housing and the lengths of the Kontaktfe used therein 6 , 7 and the melting temperature of the solder fuse 8 are to be chosen according to the application of the three-pole thermal switch 1 according to the invention.

As is apparent from Fig. 4, the webs 9, 10 are approximately H-shaped, they ie webs 9, 10 consist of a base 9 a or 10 a, which surround the contact web 4 A and clock-web against the Kon 4 A spaced vertical web sections 9 b, 10 b, which are provided on the relevant base 9 a, 10 a extended downward and thereby define a container-shaped receptacle 15 below the solder fuse 8 and laterally of the contact web 4 A.

FIG. 5 shows a partial section of the three-pole thermal switch 1 according to the invention shown in FIG. 4. As can be seen from Fig. 5, the solder fuse 8 connects the central contact web 4 A with the two adjacent contact springs 6 , 7th The Lotsicherung 8 is shown in FIG. 5 approximately U-shaped 4 A applied to the web and thus maintains the upper ends of the contact springs 6, 7 A. at the upper end of the contact web 4

Fig. 6 shows an overvoltage protection device 18, wherein the three-pole thermal switch 1 of the invention is installed in accordance with. An overvoltage protection component V ₁ , for example a varistor, is connected between a phase conductor L and a first contact connection 3 of the thermal switch 1 according to the invention. A second overvoltage protection component V ₂ , for example a varistor, is closed between a neutral conductor N and a third contact connection 5 of the thermal switch 1 according to the invention. The thermal switch 1 is connected to the middle contact terminal 4 via a spark gap F to a protective conductor PE.

The structure of an overvoltage protection device shown in FIG. 6 is symmetrical, so that the phase conductor 4 and the neutral conductor N are interchangeable. The three-pole thermal switch 1 of the invention with the two elements Überspannungsschutzbauele V _1, V ₂ heat-conducting manner and opens its contacts in case of overheating of the surge protection devices _{V1, V2.}

As can be seen in FIG. 6, the connection of the overvoltage protection component V 1 facing the thermal switch _{1 is} connected to the phase L, while the connection of the overvoltage protection component V ₂ facing away from the thermal switch 1 is connected to the neutral conductor N.

As can be seen from the above description, the inventive three-pole thermal switch is of simple construction, the contact springs 6 , 7 being connected to the central contact web 4 A by simple means, namely a solder fuse 8 . Due to the additional arrangement of a receiving section 15 for melting solder remnants of the solder fuse 8 , an undershoot of the mutual contact insulation is reliably prevented. The clamping of the contact springs 6 , 7 by the system surfaces 11 A to 13 B ensures a safe separation of the contacts 6 , 7 compared to the contact point defined by the solder fuse 8 and the varistors V ₁ , V ₂ in the area of their connection 3 or 5 separated.

The switching contacts 6 , 7 have defined pivot points, which are determined in the area of the bearing or deflecting surfaces 12 A, 12 B ( FIG. 4).

Reference list

1

Thermal switch

2

casing

2

a lower housing section

2

A,

2

B housing halves

3rd

,

4

,

5

Contact connections

4

A contact bridge

6

,

7

Contact springs

8th

Solder protection

9

,

10th

Lot receiving bridges

9

a,

10th

a,

9

b

10th

b web sections

11

A,

11

B,

12th

A,

12th

B,

13

A,

13

B deflection or contact surfaces

15

Reception facility
V ₁

, V ₂

Components

Claims (10)

1. Three-pole thermal switch to protect heat-sensitive components with:
a housing ( 2 ) for receiving a contact web ( 4 A) and two mechanically preloaded contact springs ( 6 , 7 ), which are secured by a solder fuse ( 8 ) to the contact web ( 4 A), the solder fuse ( 8 ) at Exceeding a threshold temperature melts and the contact springs ( 6 , 7 ) are pivoted away by the bias of the con tact bridge ( 4 A) to interrupt the electrical contact. 2. Three-pole thermal switch according to claim 1, characterized in that the housing ( 2 ) consists of two housing halves ( 2 A, 2 B), which are connected by a locking device ver. 3. Three-pole thermal switch according to claim 1 or 2, characterized in that the contact web ( 4 A) runs essentially along the line of symmetry of the housing ( 2 ). 4. Three-pole thermal switch according to one of the preceding claims, characterized in that the mechanically preloaded contact springs ( 6 , 7 ) in a symmetry to the line of symmetry of the housing ( 2 ) mirror-symmetrical arc shape on the contact web ( 4 A). 5. Three-pole thermal switch according to one of the preceding claims, characterized in that the threshold temperature is determined by the curvature of the contact springs ( 6 , 7 ) and by the melting temperature of the solder. 6. Three-pole thermal switch according to one of the preceding claims, characterized in that the contact web ( 4 A) surrounding the receiving device ( 15 ) for receiving the solder fuse ( 8 ) melting solder residues is hen vorgese. 7. Three-pole thermal switch according to claim 6, characterized in that the receiving device ( 15 ) through the contact web ( 4 A) surrounding web sections ( 9 a, 10 a, 9 b, 10 b) is formed. 8. Three-pole thermal switch according to at least one of the preceding claims, characterized in that at least one of the housing halves ( 2 A, 2 B) of the housing ( 2 ) order steering or contact surfaces ( 11 A, 11 B, 12 A, 12 B, 13 A, 13 B) for clamping the lower ends of the contact springs ( 6 , 7 ) in the lower housing section ( 2 a). 9. Three-pole thermal switch according to claim 7, characterized in that the deflection or contact surfaces ( 11 A to 13 B) define a fulcrum for the contact springs ( 6 , 7 ). 10. Use of the three-pole thermal switch according to one of the preceding claims for the protection of temperature-sensitive components (V ₁ , V ₂ ) against overheating, the thermal switch ( 1 ) being thermally conductively connected to the components to be protected and when a temperature threshold is exceeded, those to be protected Components (V ₁ , V ₂ ) switches off.