DE102011104984B4 - Temperature-dependent switch with heating resistor on carrier plate - Google Patents

Abstract

Temperature-dependent switch (40) with a temperature-dependent switching mechanism (41), the switching mechanism (15, 41) receiving housing having an upper part (43) with a first outer terminal (63) and an electrically conductive lower part (11, 44) with an outside lying bottom (66), with a support plate (25), on the upper side (26) a heating resistor (28) and two with the heating resistor (28) connected solder surfaces (27, 29) are arranged, wherein the bottom (66) of the Bottom part (44) rests on the heating resistor (28) and the lower part (44) is soldered to the first soldering surface (27) and the second soldering surface (29) serves as a second external connection, characterized in that lying on the bottom (66) side by side an electrical contact surface (37) to the first soldering surface (27) and a thermal contact surface (38) are formed to the heating resistor (28) that the bottom (66) is soldered flat on the first soldering surface (27), and that the rear derailleur ( 41) has a current transfer member (49) which cooperates with two stationary contact parts (58, 59), of which the first (58) is connected to the first outer terminal (63) and the second (59) to the second soldering surface (29) ,

Description

The present invention relates to a temperature-dependent switch with a temperature-dependent switching mechanism, a derailleur receiving housing having an upper part with a first outer terminal and an electrically conductive lower part with an outer bottom, with a support plate on top of a heating resistor and two with the Heating resistor connected solder pads are arranged, wherein the bottom of the lower part rests on the heating resistor and the lower part is soldered to the first soldering surface and the second soldering surface serves as a second external connection.

Such a switch is from the DE 43 36 564 C2 known.

The well-known switch is designed as a sealed switch with two-piece metal housing, as he also for example from the DE 21 21 802 A or the DE 196 23 570 C2 is known. The encapsulated switch is disposed on a ceramic support plate, on which is further disposed between interconnects a thick film resistor which is electrically connected at one end to the conductive bottom of the sealed switch. The other end of this heating resistor is connected to one of the conductor tracks, which serves as a soldering surface, to which a first pigtail is soldered. The second pigtail is electrically soldered to the conductive lid portion of the sealed switch.

The lower part rests with its outer bottom on the heating resistor. The thick-film resistor can be covered by an insulating layer.

The switch should be soldered to a lateral trace on the Trägeplatter, which is not mentioned in this document, as the soldering is to take place. As a result, a linear cohesive contact is produced between the lower part and the conductor track serving as the soldering surface.

This connection is not only problematic to manufacture, but also mechanically not sufficiently stable, which is why the document shows that together on the switch and carrier plate, a shrink tube is shrunk, protrude from the side of the two connecting wires. As a result, the switch and carrier plate are additionally mechanically fixed to one another.

Also the DE 41 42 716 A1 describes a switch with a metallic lower part and a top part, in which the first external connection is provided centrally. The second external connection is via the lower part. On this lower part of a supporter ring is clamped from below, which carries a substrate with a thick-film resistor, which is thus arranged electrically in series with the switch and is responsible as a heating resistor for the current sensitivity.

As a second external connection options are provided on the coupling ring or the substrate.

In the known construction is disadvantageous that, although provided for a good mechanical support of the heating resistor to the housing of the switch, the electrical connection, however, is not sufficiently reliable, especially in strong shocks.

These temperature-dependent switches are used in a known manner to protect electrical equipment from overheating. For this purpose, the switch is electrically connected in series with the device to be protected and mechanically arranged on the device so that it is in thermal communication with this.

In the housing, a temperature-dependent switching mechanism of spring washer, bimetallic snap disk and movable contact member is arranged in each case, which is in the closed state of the switch in contact with a stationary contact part inside of the upper part, as is outwardly plated through to a first outer terminal. The second external connection is the conductive lower part.

The operating current of the device to be protected flows through the two contact parts and the spring washer in the lower part.

Below the response temperature of the bimetallic snap disk, the circuit is closed and the device to be protected is powered by the switch with power. If the temperature rises above a permissible value, the bimetallic snap disk deforms, causing the switch to open and interrupting the supply of the device to be protected.

The now de-energized device can then cool down again. In this case, the thermally coupled to the device switch cools down again, which then automatically closes again. While such a switching behavior for protection z. B. a hair dryer can be quite useful, this is not desirable everywhere where the device to be protected after switching off may not automatically turn on to avoid damage. This applies z. B. for electric motors that are used as drive units.

The DE 41 42 716 A1 proposes therefore to provide a so-called self-holding resistor, which is electrically parallel to the external terminals. The self-holding resistor is in the open switch electrically in series with the device to be protected, through which only a harmless residual current now flows because of the resistance value of the self-holding resistor. However, this residual current is sufficient to heat the self-holding resistor so far that it emits a heat that holds the bimetallic snap disk above its switching temperature.

The from the DE 41 42 716 A1 and DE 43 36 564 C2 Known switches are also still equipped with a current-dependent switching function, including the heating resistor is provided, which is permanently connected in series with the external terminals. The operating current of the device to be protected thus constantly flows through this heating resistor, which can be dimensioned so that it ensures that the bimetallic snap disk is heated to a temperature above its response temperature when a certain operating current is exceeded, so that the switch at an increased Operating current already opens before the device to be protected has warmed up inadmissible.

In particular, when the known switches are used to protect high-performance engines, they must be mechanically very strong due to the strong vibrations that occur during operation and in particular when starting the engines.

Furthermore, the switches must be able to reliably protect the motors both in the limit mode with maximum allowable power and with a blocking rotor. To test whether the switch does this, usually two tests are performed.

In the so-called heating test, the motor is operated at maximum power, wherein neither the flow of current through the switch nor the case thereby transferred from the engine to the switch heat may open the switch.

In contrast, in the so-called locked rotor test, the motor is connected to the operating voltage with the rotor locked, which results in an operating current flowing through the motor which is three to five times greater than the usual operating current.

Of course, this high current also leads to a heating of the motor and thus to an increase in temperature at the switch.

However, this heating takes place so slowly that the engine may already irreversibly destroyed before the switch starts due to the increase in engine temperature. Therefore, in this test, a heater resistor must cause the switch to open very quickly.

Even with a suitable coordination between the response temperature of the bimetallic snap disk and the resistance of the heating resistor alone, however, these two conflicting conditions in the known switches described above can not be met.

Although these values could be adjusted so that the maximum allowable operating current does not cause the heating resistor heats the bimetallic snap disk to a temperature above its switching temperature, but that this is done only by the much higher current at locked rotor.

On the other hand, the response temperature of the bimetallic snap disk could be chosen to be above the temperature that the engine assumes at maximum allowable power during operation and transmits to the switch, but below the temperature to which the bimetallic snap disk is subjected by the heating resistor is heated when it is traversed by the current with blocked rotor.

However, the so set switching behavior is only achieved in static operation, so if enough time has elapsed, so that either opens at too high a temperature of the motor or too high current, the switch. To protect a powerful engine, it is also necessary that the switch starts extremely fast, especially with a blocking rotor.

This requires a very good thermal coupling of the heating resistor to the switch, so that a change in the temperature of the heating resistor is transmitted to the bimetallic snap disk in no time.

Based on this prior art, it is therefore an object of the present invention to develop the aforementioned switch such that at low cost and reliable construction a good thermal coupling of the heating resistor to the switch and at the same time a good mechanical hold between the switch and heating resistor is realized.

According to the invention, this object is achieved with the switch mentioned above in that lying on the ground next to each other an electrical contact surface to the first solder pad and a thermal contact surface are formed to the heating resistor, that the bottom is soldered flat on the first solder pad, and that Rear derailleur has a current transmitting member, which cooperates with two stationary contact parts, of which the first is connected to the first external terminal and the second to the second external terminal.

In contrast to the construction of the DE 43 36 564 C2 According to the invention, the bottom of the switch and not only the lateral transition between the bottom and side wall is soldered. The bottom of the switch is now used for two purposes, for one, it lies on the entire surface of the heating resistor, on the other hand, it is held flat by material bond on the soldering surface. As a result of this laminar material connection in addition to the heating resistor, according to the inventor, a very good thermal connection of the switch to the heating resistor results.

Due to the electrical contact surface and the thermal contact surface, the surface of the bottom can be almost completely utilized for mechanical and thermal contact.

The switch is set not only mechanically very stable on the support plate in this way, this type of fixing also leads to the desired thermal coupling.

It is also advantageous that the switch can carry significantly higher currents than the above-mentioned switch, in which the current is passed through the bimetal snap-action disc or through the spring snap-action disc. This is particularly advantageous when the switch is used to power powerful electric motors that require high operating currents.

Temperature-dependent switch with a current transmitting member, which cooperates with two stationary contact parts are, for example, from DE 26 44 411 A1 known. In these switches, the two stationary contact parts, which are arranged in the upper part, are connected in series with the supply current of the device to be protected, so that the current flows through the current transmission element, when the switch is at a temperature below the switching temperature.

The power transmission member may be a separate contact plate, but it is also possible in individual cases, to use the bimetallic snap disk or a spring snap-action as a power transmission member.

In order to be able to use the carrier plate already described above with the two soldering surfaces and the associated advantages, according to the invention the second stationary contact part is electrically connected to the electrically conductive lower part, which in turn is connected to the first soldering surface, which via the heating resistor with the second Soldering surface is connected. As a result, the current flows from the second external terminal through the heating resistor into the bottom part and from there to the second stationary contact part, from there through the current transfer member and then via the first contact part to the first external terminal.

Due to the unusual at first glance interconnection of the second contact part with the lower part, it is possible to use the advantages of the support plate for switches with a power transmission element.

Now, when the new switch is used in the Locked Rotor Test, the heating resistor now heats up very quickly due to the very high operating current and, due to the good and firm contact with the bottom of the switch, introduces this heat into the switching mechanism, thus rapidly increasing the operating current interrupts.

The problem underlying the invention is completely solved in this way.

The fixed mechanical connection by the surface soldering to the bottom of the base thus does not affect the switching behavior, for example, but provides compared with the prior art for a better thermal coupling both to the engine and to the heating resistor.

To solve the posing task, the inventor has not so from the DE 43 36 564 C2 known lateral solder joint improved by additional measures, but selected a different type of cohesive connection.

However, the inventor has not gone the way that offers itself at first glance, to connect the carrier plate in a force-fitting manner with the housing, as is known from the above-mentioned DE 41 42 716 A1 is known.

Rather, according to the invention, a large-area solder joint is produced between the bottom of the lower part and a soldering surface next to the heating resistor.

This planar connection can be produced, for example, by heating the carrier plate on a hotplate to liquefy tin tracts provided in addition to the heating resistor. Thereafter, the switch is pressed onto the carrier plates, so that the tin sheets make a large-area connection to the bottom of the switch.

This is taken care of for a firm grip of the support plate on the switch housing.

The new switch is now designed so that the heating resistor leads to a very rapid heating of the switch itself.

In general, it is preferred if solder pins are soldered to the second soldering surface and to the first external connection.

In fact, the inventor of the present application has recognized that the connection provided according to the invention is significantly stronger than in the case of lateral soldering according to the invention DE 43 36 564 C2 so that it can be dispensed with, the switch for mechanical stabilization even with a shrink cap to surround, which would hinder the heat input to the engine and thus the shutdown in overheated engine. Thus, the omission of an additional casing also allows other types of connection than laterally led-off connecting strands, for example the use of connecting pins. This type of connection is not possible with the known switches discussed in the introduction.

Preferably, the first soldering surface is formed by at least two tin tracks arranged next to the heating resistor.

The advantage here is that the at least two tin tracks ensure a large-area connection at the bottom of the switch.

In general, it is preferred if the heating resistor is a thick-film resistor, wherein preferably a heating resistor is arranged between the heating resistor and a protective film.

Here it is advantageous that a planar heating resistor is used, so that the floor can be coupled over a large area. The protective foil prevents electrical short circuits.

In this case, it is preferred if the two contact surfaces cover at least 50%, preferably 80%, of the surface of the base, wherein preferably the contact surface to the heating resistor has a larger area than the contact surface to the first soldering surface, more preferably at least 30% greater.

The advantage here is that the ratio of the sizes of the contact surfaces to each other ensures both the required mechanical hold and the required thermal coupling.

Further, it is preferred if the second contact part is electrically connected to the lower part, preferably the switching mechanism comprises a bimetallic snap disk, which is mechanically connected to the power transmission member and presses below its switching temperature against the two stationary contact parts and lifts above their switching temperature of these and further preferably, the derailleur comprises a spring washer which biases the current transfer member in the sense of abutment against the stationary contact parts, the bimetallic snap-action disc lifting the current transfer member above its switching temperature from the stationary contact parts.

Further advantages will become apparent from the description and the accompanying drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination given, but also in other combinations or in isolation, without departing from the scope of the present invention.

Embodiments of the invention are illustrated in the accompanying drawings and are explained in more detail in the following description. The embodiment of 1 to 3 does not form the subject of the present invention. Show it:

1 a schematic, not to scale longitudinal section through a known temperature-dependent switch, wherein a movable contact part cooperates with a stationary contact part;

2 in a schematic side view of the arrangement of the switch 1 on a support plate on which a heating resistor and a solder terminal are provided;

3 a plan view of the arrangement 2 but without pins;

4 a plan view of the carrier plate 2 and 3 ;

5 a perspective view of the carrier plate 4 .

6 a bottom view of the switch 1 , wherein contact surfaces are indicated on the ground;

7 in a representation like in 1 another temperature-dependent switch in which two stationary contact parts cooperate with a current transmitting member;

8th in a perspective view obliquely from above the on the support plate 5 soldered switch off 7 on the outside of which two connecting pieces connected to the stationary contacts can be seen; and

9 the provided with pigtails switch off 8th in side view and top view.

In 1 is with 10 a temperature-dependent switch called a pot-like base 11 includes that of a shell 12 is closed, with the interposition of an insulating film 13 from a beaded edge 14 on the lower part 11 is held.

In the bottom part 11 and top 12 formed housing of the switch 10 is a temperature-dependent rear derailleur 15 arranged, which is a spring snap disk 16 comprising, centrally a movable contact part 17 carries on which a freely inserted bimetallic disk 18 sitting.

The spring snap disk 16 rests on a floor 19 inside at the lower part 11 from, which is made of electrically conductive material.

The movable contact part 17 is in contact with a stationary contact part 20 on the inside 21 of the upper part 12 is provided, which is also made of metal in this embodiment.

In this way, the temperature-dependent rear derailleur 15 in the in 1 low-temperature position shown an electrically conductive connection between the upper part 12 and the lower part 11 forth, with the operating current through the stationary contact part 20 , the movable contact part 17 as well as the spring snap disc 16 flows.

It is alternatively possible, instead of Federschnappscheibe 18 directly insert a bimetal, that the movable contact part 17 carries and thus with the switch closed 10 the operating current leads.

Increases at the switch 10 out 1 the temperature of the bimetallic disc 18 about her response temperature, so she snaps from the in 1 shown convex position in its concave position in which they are the movable contact part 17 against the force of the spring washer 16 from the stationary contact part 20 lifts and thus opens the circuit.

Such a temperature-dependent switch 10 is for example from the DE 196 23 570 A1 The contents of which are hereby made the subject of the present disclosure.

A first connection surface 22 is off at the switch 1 in a central area of the upper part 12 arranged. A second connection surface 23 can on the edge 14 be provided.

To these connection surfaces 22 . 23 can be soldered in a known manner depending on a terminal lug with its respective inner end.

So the switch 10 thermally coupled to an electrical device to be protected, it has a flat, external floor 24 on, which is designed as a heat transfer surface and comes into contact with the electrical device to be protected.

To now provide the switch with a heating resistor, it is on a thin carrier plate 25 soldered as it is in 2 in a schematic side view and in 3 is shown in plan view.

The carrier plate 25 is formed as a ceramic substrate, on its upper side 26 in 2 from right to left next to each other a first soldering surface 27 , a heating resistor 28 in the form of a thick film resistor and a second soldering surface 29 are arranged.

To the soldering surface 29 and the interface 22 are pins 31 . 32 soldered, which serve the external connection. These pins are in 3 Not shown.

The 4 and 5 show the carrier plate 25 without soldered switch 10 ,

The heating resistor 28 is designed as a thick-film resistor, which at its in 4 right side with the soldering surface 29 is directly connected.

In 4 to the left of the heating resistor is the soldering surface 27 arranged in the unsoldered state, three tin tracks 33 . 34 . 35 has, which are parallel to each other. At least one of the tin tracks 33 . 34 . 35 is with the heating resistor 28 connected.

When the switch 10 on the carrier plate 25 is to be mounted, this is heated to the extent that the tin tracks 33 . 34 . 35 liquefy. Then the switch 10 with the ground 24 on top 26 the carrier plate 25 pressed on, so that the tin tracks 33 . 34 . 35 to the soldering surface 27 connect and for a full-surface cohesive connection to the ground 24 to care.

At the same time the floor gets into a fixed mechanical system with the heating resistor 28 Made of a thin protective film 36 be covered can make the thick-film resistor electrically opposite the ground 24 isolated.

Between ground 24 and soldering surface 27 or heating resistor 28 form two contact surfaces 37 . 38 out, in 6 are indicated in which the switch 10 out 1 shown from below, leaving its bottom 24 you can see.

From the 6 it can be seen that both the heating resistor 28 as well as the soldering surface 27 large area and side by side with the ground 24 keep in touch. In this way, more than 80% of the area of the soil 24 from the two contact surfaces 37 . 38 covered. The contact surface 38 to the heating resistor 28 is more than approx. 30% larger than the contact surface 37 to the soldering surface 27 ,

In 7 is with 40 another temperature-dependent switch referred to, together with the carrier plate 25 out 4 can be used as the switch 10 out 1 ,

The desk 40 includes a temperature-dependent rear derailleur 41 that in a housing 42 is housed. The housing 42 has a top made of insulation material 43 on, which is an electrically conductive base 44 closes, its edge 45 the top 43 on the lower part 44 sets.

The rear derailleur 41 includes a spring snap-action disc 46 and a bimetal snap-action disc 47 , which together with the spring snap-action disc 46 centric of a peg-like rivet 48 is accessed by this with a power transmission element 49 are mechanically connected in the form of a contact plate.

The spring snap-action disc 46 is with her edge 51 between a circumferential shoulder 52 inside in the lower part 44 and a spacer ring 53 sandwiched, on which the shell 43 with its inside 54 rests

The bimetallic snap disk 47 rests with its edge 55 inside at the bottom 56 of the lower part 44 from.

The round, in the present case circular power transmission element 49 points in the direction of the upper part 43 a circumferential, electrically conductive contact surface in the circumferential direction 57 on, with two stationary contact parts 58 . 59 interacts on the inside 54 of the top 43 are arranged.

The stationary contact parts 58 . 59 are as inner heads of contact rivets 61 . 62 formed the top part 43 reach through and with their outer sections 63 . 64 serve the external connection. Between the sections 63 . 64 is an insulating bridge 65 intended. Isolated from the jetty 65 is a floor 66 of the lower part 44 designed as a heat contact surface.

At the outer sections 63 . 64 is ever a connector 67 respectively. 68 attached, which serves the external connection.

In 8th is the switch 40 out 7 on the carrier plate 25 presented in connection with the 4 and 5 has been described. The lower part 44 was with the in 8th unrecognizable 1st soldering surface 27 soldered and lies with its bottom 66 with interposition of the protective film 36 on the heating resistor 28 on.

Between the ground 66 and the 1st soldering surface 27 or the heating resistor 28 The two contact surfaces, which are formed in 6 for the switch 10 out 1 are indicated.

In 8th are also on the two outer sections 63 . 64 the contact rivets 61 . 62 attached fitting 67 respectively. 68 to recognize, which ever an upper, u-shaped flap 69 respectively. 71 exhibit. To contact the switch 40 become the upper, u-shaped tabs 69 . 71 down to the sections 63 respectively. 64 folded over and inserted in the form of "tunnel" usually stripped ends of connecting strands and soldered.

In 9 is shown that in this way the first stationary contact part 58 associated tab 69 with a first pigtail 72 was connected, which is the first external connection of the switch 40 forms.

The second stationary contact part 59 associated tab 71 is similarly electrically connected to a connector 73 connected to the conductive base 44 over its edge 45 connected is. In the simplest case, the connecting part 73 Soldering the edge 45 electrically and mechanically with the connection piece 68 combines.

At the second soldering surface 29 is a second pigtail 74 soldered, which forms the second external connection.

As the power transmission element 49 in 7 in contact with the two stationary contact parts 58 . 59 is, there is a continuous electrically conductive connection of the first pigtail 72 over the connection piece 67 to the first stationary contact part 58 , from there via the power transmission element 49 , the second stationary contact part 59 , the second connector 68 and the connecting part 73 to the edge 45 and from there to the lower part 44 ,

The lower part 44 is with his bottom 66 over the 1st soldering surface 27 with the heating resistor 28 connected at the other end with the 2nd soldering surface 29 connected to the second pigtail 74 is soldered.

The desk 40 is like the switch 10 thermally very good to the heating resistor 28 coupled, but at the same time electrically isolated from this. At the same time is the switch 40 over the ground 66 of the lower part 44 and the 1st soldering surface 27 mechanically fixed to the carrier plate 25 connected.

Claims (10)

Temperature-dependent switch ( 40 ) with a temperature-dependent switching mechanism ( 41 ), the rear derailleur ( 15 . 41 ) receiving housing which is a top ( 43 ) with a first external connection ( 63 ) and an electrically conductive lower part ( 11 . 44 ) with an external floor ( 66 ), with a carrier plate ( 25 ), on the upper side ( 26 ) a heating resistor ( 28 ) and two with the heating resistor ( 28 ) bonded solder surfaces ( 27 . 29 ), the ground ( 66 ) of the lower part ( 44 ) on the heating resistor ( 28 ) and the lower part ( 44 ) with the first soldering surface ( 27 ) is soldered and the second soldering surface ( 29 ) serves as a second external connection, characterized in that at the bottom ( 66 ) lying next to each other an electrical contact surface ( 37 ) to the first soldering surface ( 27 ) and a thermal contact surface ( 38 ) to the heating resistor ( 28 ) are formed, that the ground ( 66 ) flat on the first soldering surface ( 27 ), and that the rear derailleur ( 41 ) a power transmission element ( 49 ), which with two stationary contact parts ( 58 . 59 ), of which the first ( 58 ) with the first external connection ( 63 ) and the second ( 59 ) with the second soldering surface ( 29 ) connected is. Switch according to claim 1, characterized in that the heating resistor ( 28 ) is a thick film resistor. Switch according to claim 1 or 2, characterized in that the second soldering surface ( 29 ) and to the first external terminal pins ( 32 . 31 ) are soldered. Switch according to one of claims 1 to 3, characterized in that the first soldering surface ( 27 ) by at least two adjacent to the heating resistor ( 28 ) arranged tin tracks ( 33 . 34 . 35 ) is formed. Switch according to one of claims 1 to 4, characterized in that between heating resistor ( 28 ) and ground ( 66 ) a protective film ( 36 ) is arranged. Switch according to one of claims 1 to 5, characterized in that the two contact surfaces ( 37 . 38 ) at least 50%, preferably 80% of the area of the soil ( 24 . 66 ) cover. Switch according to claim 6, characterized in that the thermal contact surface ( 38 ) to the heating resistor ( 28 ) has a larger area than the electrical contact area ( 37 ) to the first soldering surface ( 27 ), preferably at least 30% larger. Switch according to claim 7, characterized in that the second contact part ( 59 ) electrically to the lower part ( 44 ) connected is. Switch according to one of claims 1 to 8, characterized in that the rear derailleur ( 41 ) a bimetallic snap disk ( 47 ) mechanically connected to the power transmission element ( 49 ) is connected and this below its switching temperature against the two stationary contact parts ( 58 . 59 ) presses and lifts above their switching temperature of these. Switch according to claim 9, characterized in that the switching mechanism ( 41 ) a spring washer ( 46 ) having the current transmission member ( 49 ) in the sense of an abutment against the stationary contact parts ( 58 . 59 ), wherein the bimetal snap disc ( 47 ) the power transmission element ( 49 ) above its switching temperature of the stationary contact parts ( 58 . 59 ) takes off.

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