DE4142716A1 - Thermal cut=out switch - has bimetallic disc that responds to electrical heating provided by resistive contact carrying element. - Google Patents

Abstract

A combined thermal and electrical power overload cut-out switch has a housing with a main section (17) of insulating material with a fixed contact set in the centre (10). A movable contact carrier (14) of spring strip material is set in the lower half and carries a contact in the centre (11). The carrier is in contact with conductor tracks (15). Located above the movable carrier is a bimetallic disc (13). The disc responds to the electrical heating effect produced by the resistive spring carrier (14) and trips at a set current. ADVANTAGE - Compact, providing reliable response.

Description

The invention relates to a thermal switch according to the preamble of claim 1. Under an unadjusted resistance element to understand a resistance element that a mechanical Adjustment is not accessible. Nevertheless, such an element can e.g. B. influenced by laser radiation in terms of its resistance will.

Electrical thermal switches of this type are e.g. B. from DE-OS 33 19 227 known. Such thermal switches are basically used for temperature rature monitoring of electrical heating devices and are with a Bimetallic spring washer equipped when reaching one jump around certain temperature in a known manner and thereby the remove electrical connection between contact and counter contact, so that the current flow is interrupted until the temperature has lowered again and the bimetal spring washer is in its out position jumps back gear position.

It is also from DE-OS 37 10 672 and EP-OS 4 53 596 known temperature switch, which is basically according to the advance previous paragraph are built, in addition with a higher impedance Equip resistance element for self-holding. Will in this In case of contact by jumping over the bimetal spring washer interrupted, the current escapes through the higher resistance, the heat generated thereby ensures that the Temperature switch not opening again automatically after opening closes as long as the power supply is not completely cut off becomes.

Based on this prior art, the Invention, the object of a thermal switch of the beginning to further develop the genus mentioned so that it is sensitive to current Combined thermal and overcurrent protection switch used can be.

This task is carried out by a thermal switch with the characteristics of Claim 1 solved.

With such a thermal switch, the bimetal spring washer assigned an unadjusted resistance element, which during the Production process in fine gradations with tight tolerances can be interpreted. The resistance can be, in particular, by the geometry of the resistor tracks, the material thickness and influence the specific resistance of the material so that a optimal design for every voltage as well as for very small ones Current sensitivity can be achieved.

Basically, the thermal switch is therefore also a Overcurrent protection switch suitable and lifts the electrical connection when a certain temperature is exceeded, whereby it it is irrelevant whether the required heat comes from the outside acts on the thermal switch or due to an overcurrent on Thermal switch comes into effect.

A goal of the invention is at the same time, the thermal switch training in the smallest possible design. Therefore, that too Resistance element are formed as small as possible, whereby according to claim 3, the formation of a screen printed offers ten etched part or a stamped part, in particular at this manufacture the quantities influencing the resistance easily can be changed. Therefore arise with such Training very good adaptability to the respective Needs.  

According to claim 5, the results can still occur can be further improved by the etched or stamped part on a Insulation film is arranged, a connection in the middle welding between the resistance element and the housing base allows to to enable contact to the outside. The insulation film is of advantage in two respects, since it is one electrical, but also thermal insulation, so that the heat generated by the resistor almost unimpeded on the Bimetal spring washer can act.

According to claim 7 but can also be an extreme as a resistance element thin substrate can be used, the one-sided with resistance paste is printed and has silver connection segments and for Ensure a contact in the center on the other substrate side is plated through. With this training, the substrate for itself at the same time as an isolator from the Housing bottom can be used.

Another option is the spring to train the element itself as a resistance, in addition to the Resistors previously mentioned or is suitable for itself To trigger jumping of the bimetallic spring washer (claim 9).

In order to further reduce the overall manufacturing costs, it is possible to use the lid not only as before form multi-part element but in one piece, the Cover at the same time as an abutment for the surrounding bimetal Serves disc and must therefore be suitable for doing so absorb emerging forces (claim 13).

This thermal switch can also be used for training according to the Claims 14 to 20 parallel to a high-impedance, if necessary multi-part resistor can be switched in or on the housing is attached. In particular, the arrangement on the housing offers the possibility of retrofitting any thermal switch with a to equip such equipment. This equipment ensures  for maintaining a temperature in the thermal switch a bouncing back of the bimetallic spring washer is impossible makes.

In an embodiment according to claim 15 are preferably at Use of a substrate provided at least two resistors, that are easy to match. This enables a relatively accurate Fine adjustment, which can be done, for example, by the corresponding areas of a substrate of laser radiation be subjected.

The use of a coupling ring also creates the possibility on the one hand, the heat generated by the resistor onto the thermo switch to transmit that there is no local overheating is coming. Basically, the manufacturer of the Throw ring so far pre-assembled that it will only later must still be placed on an appropriate thermal switch. For this purpose, the coupling ring also has all connections elements, so that even in the factory the strand connection pre-featured can be taken. The processing of the components according to claim 20 in SMD technology creates the possibility in one operation make all connections. This also ensures Technology increases security in that even if due to the high temperature, the solder connections become liquid, due to the capillary pressure between the holding and contacting lash and the substrate still a safe contact can be guaranteed to maintain self even in this To ensure condition still.

Further advantageous designs result from the others Subclaims.

The invention will be described in more detail below with reference to the drawings described.

Show it:  

FIG. 1 is formed by a thermal switch with internal etching or stamping, where the thermal switch to the left of the center line with a two-part and right of the center line with a one-piece cap in section,

Fig. 2 shows a section through an alternatively to use the substrate wafer,

Fig. 3 shows a thermal switch of FIG. 1 with a one-piece cover, which is assigned on its underside, a high-resistance resistor,

Fig. 4 is a plan view of a thermal switch with disposed on the lid high-resistance resistor,

Fig. 5 is a connection bracket for a high resistance in a perspective view;

Fig. 6 is an on the underside of a thermal switch arranged high-resistance resistor on a union ring, and

Fig. 7 is a section along line VII-VII of Fig. 7 by an upright collar ring without a strand.

As can be seen from Fig. 1, the thermal switch, which is seen in principle for the overtemperature protection of electrical devices, has a contact 10 , which is held centrally in the cover 17, 17 ' , and a mating contact 11 arranged in the housing 12 . In the switching position, the mating contact 11 and the contact 10 are connected to one another in an electrically conductive manner. Furthermore, a bimetal spring washer 13 is arranged in the housing, which can be acted upon by the influence of heat in such a way that the electrical connection is interrupted.

The bimetallic spring washer 13 is now associated with an unadjusted resistance element through which the switch current flows, the current's own heating or its power loss contributing to the temperature increase and thus also to the jumping around of the bimetallic spring washer 13 alone or in connection with external heat flow. Basically, this resistance element can be arranged in the housing according to FIG. 1, but it is also entirely possible to attach the resistance element to the housing from the outside, as is also proposed for a high-resistance resistor according to claims 14 to 20.

The resistance element integrated in the thermal switch according to FIG. 1 is basically arranged under the bimetallic spring washer 13 and the freely incorporated bimetallic spring washer encompasses the mating contact 11 and is supported on the spring element 14 . Now if the temperature rises above a certain value, the bimetallic spring washer jumps around in a known manner, being supported on an abutment 17 d, 17 d ', so that the force of the bimetallic spring washer generated when jumping over onto the counter contact bearing Spring element 14 is transmitted and thus contributes to a cancellation of the current flow. With such a configuration, however, contact is made again when the temperature drops, so that the switch builds up and breaks the electrical connection again and again.

Referring to FIG. 1 can be used as resistor element, which is connected to the electrically conductive spring 14 in series, z. B. a thin etched or stamped part can be provided, which has either been produced in the photo or screen printing etching process or has been punched out of a corresponding material. With such a design, the resistance of the resistance element can be influenced by an appropriate geometry of the resistive conductor tracks as well as by an appropriate choice of material and the material thickness so that the triggering temperature for the jumping over of the bimetallic spring washer 13 is reached even with small currents. The material generally has a low resistance temperature coefficient in order to be able to specifically control the temperature influence.

Preliminary tests with such thermal switches at the manufacturer have z. B. show that a corresponding triggering can be achieved even at currents less than or equal to 0.2 amperes. In order to achieve good contact of the parts, the resistance element is connected in its edge region to the spring element 14 and centrally by welding to the housing base with the outside of the thermal switch and has connection segments of high electrical conductivity. Under the etched or stamped part 15 , which is preferably designed as a disc, an insulation film, preferably a Kapton, Teflon or silicone film is arranged which serves on the one hand for electrical insulation from the substrate as well as for heat insulation, by the current flow through to radiate the heat occurring only on one side in the exemplary embodiment of FIG. 1 upwards onto the bimetal spring washer. The heat transfer takes place both by heat conduction and by heat radiation, it being possible for the corresponding heat transfer to be improved further by a suitable choice of material for the spring element 14 . In principle, the etched or stamped part 15 and the film 16 can also be produced in a composite part or as a laminate.

In the sense of a composite part, however, an alternative resistance element also acts, which is used instead of the etched or stamped part 15 . Such a resistance element can e.g. B. be formed as a substrate 15 ', which is plated through in its center 15 a' on the opposite side 15 b '. Here, the disc-shaped substrate 15 ' in the edge region with connection segments 22 of high electrical conductivity, preferably made of silver, can be fitted in order to facilitate a corresponding current flow. On its top, the substrate 15 'shown in Fig. 2' is provided with a resistance paste 23 , the specific resistance can be selected according to the respective needs. Basically, the resistance printing has a largely non-linear PTC characteristic or a high temperature resistance coefficient.

Furthermore, it offers itself as a further alternative, the spring element 14 itself or in addition to the already mentioned opposing elements also form as a resistance element and, if necessary, to equip them with connecting segments. The spring element 14 can, such as. As shown in FIGS. 1 and 3, be designed as a 4-leg spring, but it can also be produced as a round punch or etched part, which has elastic capabilities after appropriate conical material deformation and z. B. has concentric semicircular webs with connecting material bridges between the individual semicircular webs. In the latter embodiment in particular, a plurality of semicircles allows precise adjustment of the spring element 14 as a resistance element.

All training courses have in common that the unadjusted resistance element in the manufacturer can be interpreted in fine gradation with narrow tolerances. Contacting between the resistance element and the outside of the thermal switch takes place through a central opening of the film 16 to the housing bottom 12 a of the housing. As a conclusion upwards, which also bears the contact 10 , a plastic injection molded part 17 or a layer of pressed material stamped part 17 'is provided as a cover, as shown in particular in FIG. 1 (left 17' , right 17 ). The cover shown on the left has a spacer ring 17 b '. Instead of this two-part cover, the one-part cover shown on the right can also be used. In both cases it is possible to manufacture the corresponding cover as a plastic injection molded part or stamped part. This production method then also facilitates a support of the cover on the housing base or on an insulation layer arranged between the housing base and cover, for. B. through the outwardly drawn film 16 , so that no separate supports for the lid in the housing must be provided and thus the housing 12 itself can be produced in the simplest way as a deep-drawn part. About the plastic injection molded part 17 or the spacer ring 17 b ', the film 16 is sealingly clamped to the housing base in order to achieve an additional moisture seal.

As already mentioned at the beginning, the switch shown in FIG. 1 re-establishes the connection when the temperature drops, so that there is a permanent change between opening and closing the switch. To avoid this, there is now the possibility, if necessary, to connect a high-resistance resistor in parallel with the thermal switch, so that after opening the switch due to overcurrent or overtemperature, the switch remains open due to self-heating of the resistor by self-holding. This principle is known in principle and is based on the fact that, when the current flow is interrupted, the entire current is now passed through a high-resistance resistor 18 , which, through appropriate heat transfer to the thermal switch, ensures that a temperature is maintained which is above the transition temperature of the bimetallic spring disk.

This high-resistance resistor 18 can now either be integrated in the housing in a known manner, or it can be arranged on the outside of the thermal switch, such as, for. B. shown in Fig. 3. In an embodiment according to FIG. 3, the high resistance resistor 18 is, for example, on the housing base 12 is fixed a by a union ring 19. It can also be glued or soldered there. The high-impedance resistor shown in FIG. 3 consists in the specific exemplary embodiment of a substrate 25 which is provided with a resistance paste, which are arranged on the left and right of a central supply connection. This arrangement of more than one resistor allows easy adjustment to set the self-holding effect. The holding tab 20 is basically at the same potential as the resistance element (etched or stamped part 15 ) arranged in the thermal switch and is also used for contacting. In FIG. 3, not shown in the drawing, an electrical connection must also be made between the center of the substrate wafer and the mating contact, so that a current can be supplied at all via the high-resistance resistor 18 . A derivation then leads from the contact 10 in a known manner. Such contacting is shown for example in Fig. 6, wherein a strand 30 is attached to the union ring 19 via the connections 26 , 27 or alternatively 28 , which contacts the supply connection 29 with a bare area. A large-area distribution of the heat generated by the resistor then takes place via the coupling ring 19 without local overheating occurring.

The resistor can also be arranged according to FIG. 4 on the upper side of the thermal switch, since in the end it is only a question of supplying the bimetallic spring washer with heat in some way. In this case, the coating of the substrate is directed towards the lid. However, an electrical connection must now be made between the housing 12 and the contact 10 or the high-resistance resistor. For this purpose, a connection bracket 21 is provided, which is shown in Fig. 5. It encompasses or engages under the contact and, if necessary, has a long leg shown in dashed lines in FIG. 5, which is used for contacting the housing 12 . The corresponding contact can then also be produced in a simple manner. The substrate 25 is either formed with a central hole so that it can be held by the rivet of the contact 10 and clamped under the closure flange 17 e or it is attached to the contact 10 via the connection bracket 21 and contacted with the housing from above for derivation.

As a further alternative, the high-resistance resistor can also be attached to the thermal switch. For this purpose, the high-resistance resistor 18 is arranged on a collar 19 , which has a central opening 19 a, which is provided for receiving the thermal switch. The connection of the two parts is done by locking or by clamping the over ring 19 on the thermal switch. This coupling ring can be provided with connections 26 and 27 , which also enable the connection of the thermal switch itself. In Figs. 6 and 7 is still in broken lines, a terminal 28 and a mounting plate for the connection provided as an alternative. In principle, however, all connections can also be designed as stranded connections. This union ring then enables extensive pre-assembly of the entire self-holding heating substrate z. B. for quick retrofitting.

Basically, the components are connected, for example as the clamping and contacting the substrate by a Combination of clamp / rivet and solder connections in SMD technology. This type of connection also guarantees one secure contacting if it is already due to a high tempe has liquefied the solder.

Thus, according to the invention, it is possible to use a known one If necessary, thermal switches as overcurrent circuit breakers use and an interruption of the current both at To realize overcurrent as well as overtemperature.

Claims (20)

1. Thermal switch for the protection of electrical devices, in which at least one contact ( 10 ) insulated from an associated, movably arranged counter-contact ( 11 ) is attached to a housing ( 12 ), the counter-contact ( 11 ) with the contact ( 10 ) being electrically Conductively connected and acted upon by a bimetallic spring washer ( 13 ), which is influenced by heat, in such a way that the electrical connection is interrupted, characterized in that the bimetallic spring washer ( 13 ) is associated with an unadjusted resistance element through which the switch current flows, the self-heating of which contributes to increasing the temperature and jumping around the bimetallic spring washer ( 13 ) with the appropriate current. 2. Thermal switch according to claim 1, characterized in that the resistance element integrated in the thermal switch is arranged under the bimetallic spring washer ( 13 ) and the freely incorporated bimetallic spring washer against the force of an electrically conductive spring element ( 14 ) carrying the mating contact ( 11 ). separates from the contact ( 10 ) when jumping over. 3. Thermal switch according to one of claims 1 or 2, characterized in that an etching or stamping part ( 15 ) is provided as the resistance element, which is contacted on the one hand centrally, preferably through the housing base ( 12 a) of the thermal switch and on the other hand in the edge area is connected to the spring element ( 14 ), the resistance element and spring element ( 14 ) being connected in series. 4. Thermal switch according to claim 3, characterized in that the Etched or stamped part is made of materials that one have a low resistance temperature coefficient.   5. Thermal switch according to claim 3 or 4, characterized in that the etched or stamped part ( 15 ) is designed as a disc, which from the housing base ( 12 a) by an electrically insulating, centrally perforated film ( 16 ) z. B. Kapton, Teflon, or silicone film separately, preferably welded in the insulation-free center to the housing base ( 12 a) and, if necessary, equipped with connection segments ( 22 ) of high electrical conductivity. 6. Thermal switch according to one of claims 3 to 5, characterized in that the etched or stamped part ( 15 ) and the film ( 16 ) are designed as a composite part or as a laminate (not shown in the drawing). 7. Thermal switch according to claim 3, characterized in that instead of the etched or stamped part ( 15 ) as a resistance element a one-sided printed substrate ( 15 ') is provided, which in its center ( 15 a') on the other side of the substrate ( 15 b ' ) is plated through. 8. Thermal switch according to claim 7, characterized in that the substrate ( 15 ') has a resistance printing with largely non-linear PTC characteristic or with a high temperature coefficient for the resistance values. 9. Thermal switch according to one of claims 2 to 8, characterized in that the spring element ( 14 ) is designed for itself or additionally as a resistance element and, if necessary, is equipped with connection segments of high electrical conductivity. 10. Thermal switch according to one of claims 2 to 9, characterized in that the spring element ( 14 ) is preferably designed as a 4-leg spring and has high current and thermal conductivity. 11. Thermal switch according to one of the preceding claims, characterized in that a plastic injection-molded part ( 17 ) is used as the cover, in which the contact ( 10 ) is held centrally and which serves as an abutment for the bimetallic spring washer ( 13 ). 12. Thermal switch according to claim 11, characterized in that instead of the plastic injection molded part ( 17 ) a high-strength laminate stamped part ( 17 ') is provided, which is supported on a spacer ring ( 17 b'). 13. Thermal switch according to claim 11 or 12, characterized in that the one-piece plastic injection molded part ( 17 ) or the stamped part ( 17 ') on the spacer ring ( 17 b') on the housing base ( 12 a) and, if necessary, between themselves and the Clamp the bottom of the housing ( 12 a) to seal a film ( 16 ), in particular an insulating film. 14. Thermal switch according to one of the preceding claims, characterized in that it can be equipped if necessary with a high-impedance resistor ( 18 ) which is connected in parallel with the thermal switch contact and keeps the switch open by its own heating after opening the switch by overcurrent or overtemperature. 15. Thermal switch according to claim 14, characterized in that the high-impedance resistor ( 18 ) is multi-part and easily adjustable and the connections are used for electrical derivation and Teilebefesti supply. 16. Thermal switch according to claim 14 or 15, characterized in that the high-impedance resistor ( 18 ) on a coupling ring ( 19 ) or a substrate ( 25 ) carrying it is held by the holding or contacting tabs ( 20 ) and via a central supply connection ( 29 ) and bendable tabs ( 26 , 27 or 28 ) for receiving the connections, preferably strands ( 30 ). 17. Thermal switch according to one of claims 14 to 16, characterized in that the coupling ring ( 19 ) is completely fastened together with the high-resistance ( 18 ) and / or substrate ( 25 ) over the housing base ( 12 a) and stood in the high-resistance against ( 18 ) transfers heat generated over a large area to the thermal switch. 18. Thermal switch according to claim 14 or 15, characterized in that the substrate ( 25 ) is optionally formed with or without a central hole for direct mounting on the lid or via a closure flange ( 17 e) is attached to the thermal switch. 19. Thermal switch according to one of the preceding claims, characterized in that the high-impedance resistor ( 18 ) or the substrate ( 25 ) is contacted and held by means of a connecting bracket ( 21 ) on the central supply connection ( 29 ). 20. Thermal switch according to one of claims 14 to 19, characterized in that the components (retaining tab ( 20 ), connecting bracket ( 21 ), high-impedance resistor ( 18 ), substrate ( 25 )) as a clamp / rivet and solder connections in SMD -Technology are processed.