EP2654057A1 - Temperature-dependent switch - Google Patents

Abstract

The switch (1) has housing that is provided with a cover portion (12) and a base portion (11). A temperature-dependent switching mechanism (15) is arranged in the housing, and is set in electrically conductive connection between the cover portion and the base portion. Two housing outer ports (22,23) are arranged on the top surface (25) of switch main portion, and are connected with two connecting wires respectively. A protective cap made of steel is arranged on the top surface of the cover portion for covering the housing outer ports and the connecting wires leading out sideways. An independent claim is included for a method of assembling temperature-dependent switch.

Description

The present invention relates to a temperature-dependent switch having a housing which has a cover part and a lower part, and having a temperature-dependent switching mechanism arranged in the housing, which establishes or opens an electrically conductive connection between two external connections provided on the housing depending on its temperature, at least one of which is arranged on an upper side of the switch and connected to the connecting leads.

Such a switch is, for example, from the DE 103 01 803 A1 known.

The temperature-dependent switch is used in a conventional manner to monitor the temperature of a device. For this purpose, for example, it is brought into thermal contact with the device to be protected via one of its outer surfaces, so that the temperature of the device to be protected influences the temperature of the derailleur.

The switch is electrically connected via the soldered to its outer terminals leads in series in the supply circuit of the device to be protected, so that below the response temperature of the switch, the supply current of the device to be protected flows through the switch.

The known switch has a deep-drawn lower part, in which an inner circumferential shoulder is provided, on which a lid part rests. The lid part is held by a raised and flanged edge of the base firmly on this shoulder.

Since the cover part and lower part are made of electrically conductive material, an insulating film is provided between them, which extends parallel to the cover part and is pulled up laterally, so that the flanged edge presses with the interposition of the insulating film on the cover part.

The temperature-dependent switching mechanism here comprises a spring snap-action disk, which carries the movable contact part, as well as a bimetallic disk which is put over the movable contact part. The spring snap-action disk carries a so-called movable contact part, which presses the spring disk against a stationary contact part on the inside of the cover part.

With its edge, the spring snap-action disk is supported in the lower part of the housing, so that the electric current flows from the lower part through the spring snap-action disk and the movable contact part into the stationary contact and from there into the cover part.

The first external connection is a contact surface, which is arranged centrally on the cover part. As the second outer terminal provided on the flanged edge of the base contact surface. Both external connections are here on the top of the known switch. But it is also possible to arrange the second outer terminal not on the edge but laterally on the current-carrying housing.

On the other hand it is from the DE 198 27 113 C2 known to attach to the spring snap-action disk, a so-called contact bridge, which is pressed by the spring snap-action disc against two provided on the cover part stationary contacts. The current then flows from the one stationary contact through the contact bridge in the other stationary contact, so that the spring snap disk itself is not traversed by the operating current.

This design is particularly chosen when very high currents must be switched, which can not be easily passed through the spring washer itself.

In both design variants, a bimetal disc is provided for the temperature-dependent switching function, which rests below its critical temperature without force in the switching mechanism, wherein it is arranged geometrically between the contact part or the contact bridge and the spring snap-action disc.

Increases now the temperature of the bimetallic disc due to a temperature increase in the device to be protected beyond the critical temperature addition, the bimetallic disc changes its configuration and presses with its edge against an abutment, which is usually provided on the cover part. In this case, the bimetallic disc presses with its central region against the spring snap-action disc and thus lifts the movable contact part of the stationary contact or the current transfer member of the two stationary contacts, so that the switch opens and the device to be protected is turned off and not further can heat up.

In these constructions, the bimetallic disc is mounted mechanically free of forces below its transition temperature, the bimetallic disc is also used in any case to guide the flow.

It is advantageous that the bimetallic discs have a long mechanical life, and that the switching point, so the critical temperature of the bimetal disc, not changed even after many switching cycles.

If lower demands on the mechanical reliability or the stability of the transition temperature are tolerable, the bimetallic disc can also take over the function of the spring snap-action, so that the switching mechanism comprises only a bimetallic disc, which then carries the movable contact part or the current transfer member and in the closed State of the switch also conducts the current.

Moreover, it is known to provide such switches with a parallel resistor which is connected in parallel with the external terminals. When the switch is open, this parallel resistor takes over part of the operating current and keeps the switch at a temperature above the transition temperature, so that the switch does not automatically close again after cooling down. Such switches are called self-holding.

It is also known to provide such switches with a series resistor, which is traversed by the operating current flowing through the switch. In this way, an ohmic heat is generated in the series resistor, which is proportional to the square of the flowing current. If the current exceeds a permissible level, the heat of the series resistor causes the rear derailleur to open.

In this way, a device to be protected is already switched off from its supply circuit when too high current flow is recorded, which has not yet led to excessive heating of the device.

All these different design variants can be realized with the switch according to the invention, in particular, the bimetallic disc can take over the function of the spring snap-action disc.

Instead of a generally round bimetallic disc and a cantilever clamped on one side can be used, which carries a movable contact part or a contact bridge.

From the DE 195 17 310 A1 is one to the from the above-mentioned DE 103 01 803 A1 Comparable constructed temperature-dependent switch known in which the cover part, however, is made of a PTC thermistor and rests without interposition of an insulating film on an inner peripheral shoulder of the lower part to which it is pressed by the flanged edge of the lower part.

The first external connection is an external head of a rivet sitting centrally in the cover part, the inside head of which serves as a fixed mating contact. As a second outer terminal also serves a provided on the flanged edge of the base contact surface.

In this way, the PTC thermistor cover is electrically connected in parallel to the two outer terminals, so that it gives the switch a self-holding function.

From the DE 198 27 113 C2 is a self-holding temperature-dependent switch with contact bridge is known in which the cover part is also made of PTC thermistor. At the lid part here two rivets are arranged, the outer heads form the two outer terminals, and interact their inner heads as stationary contacts with the contact bridge.

Although the switches described so far have proven themselves in everyday use and have many advantages in terms of operation, they encounter some concerns when they are to be installed on a protected device so that, for example, by windings or heat contact surfaces of the device, a high pressure on the Housing is exercised.

In particular, if the cover part is a PTC thermistor cover, this high pressure can cause the cover part to be mechanically damaged, which can lead to malfunction or even failure of the switch.

Furthermore, the external connections and the electrically conductive parts of the housing must still be electrically insulated after the soldering of connecting leads.

As insulation and pressure protection, the known switches are therefore often used in enclosing or protective caps that serve the mechanical and / or electrical protection and often the case should also protect against the entry of impurities. Examples of this can be found for example in the DE 91 02 841 U1 , the DE 92 14 543 U1 , of the DE 37 33 693 A1 , of the DE 197 05 153 A1 and the DE 197 54 158 ,

In the in the DE 197 05 153 A1 As shown, a shrink cap is used, which is slid onto the switch and shrunk after leads have been soldered to the switch. The leads are on the opposite side of the shrink cap of the switch from this.

On the other hand, it is known to put on the switch connection caps to provide a defined external connection and the sealing of the housing. Examples of this can be found for example in the DE 10 2005 001 371 B4 or the DE 10 2009 030 353 B3 ,

At the time of the DE 10 2009 030 353 B3 known construction, the protective cap is attached to the switch before two terminal lugs are soldered to two provided on the outside of the housing of the switch pads. For this purpose, the protective cap has a first opening as access to the first connection surface and a second opening as access for the second connection surface.

From the DE 85 00 845 U1 a protective cap for covering electrical connections of a mechanically actuated electrical switch is known. The protective cap has an elongated base part which has an inner shape which is adapted to the outer shape of the switch. The base part is provided with an insertion opening for the switch, which is surrounded by an edge, which rests against a switch provided on the collar when plugging the switch, wherein the switch jammed in the base part.

The base part merges at its end opposite the insertion opening into a flexible hose, through which leads connected to the terminals of the switch are routed.

Furthermore, it is from the DE 41 43 671 A1 known to overmold the outer terminals with a one-component thermosetting plastic. From the DE 10 2009 039 948 It is known to cast terminal lugs with an epoxy resin.

The use of housings or connection caps is often perceived as too expensive and with respect to the thermal connection to the device to be protected as unsatisfactory. Therefore, known temperature-dependent switches are recently potted at the applicant's company with an epoxy resin to electrically isolate them while mechanically stabilizing.

Although this measure shows good results, it can not be used especially with the pressure-sensitive switches with PTC thermistor cover parts, because the PTC thermally incompatible with the epoxy resin.

Switches with PTC thermistor cover part are therefore encapsulated with silicone, which indeed brings the required electrical insulation, but not in any case, the desired improvement in mechanical stability.

Against this background, the present invention seeks to increase the pressure stability in the known switch in a structurally simple and inexpensive way.

According to the invention, this object is achieved in the case of the switch mentioned above in that a protective cap is seated on top of the cover part, which covers the at least one outer connection on the upper side and out of which the connecting strand connected to the at least one outer connection leads out laterally.

Due to the additional protective cap, which is placed only on top of a switch of any type, according to the inventor already provided for a sufficient mechanical protection of the cover part. Furthermore, the connection of the pigtail to the external terminal on the lid parts is protected.

Namely, according to the inventor's knowledge, neither the surrounding housing nor the terminal cups are often required to mechanically provide so much stability to a switch that it can be wrapped in windings of a motor or transformer.

Even if the cover part consists of a PTC thermistor, the pressure exerted on the switch, in particular from above and below, does not cause the PTC cover to be damaged.

The inventor has just not gone the way to stiffen the case from the inside or equip it with a thicker lid part.

On the contrary, the inventor of the present application has recognized that the pressure acting from above on the switch can be directed into the side walls of the housing by a protective cap applied from above onto the cover part, so that loading of the cover part is completely prevented or at least reduced.

The protective cap can be mechanically held on the housing, for example by crimping, clamping, beading or grafting.

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

It is particularly preferred if both outer terminals are arranged on the upper side and provided there with connecting leads, which lead laterally out of the protective cap.

Here it is advantageous that the protective cap at the same time provides for the insulation and the protection of the two outer terminals, since it covers them.

It is preferred if on the top of an adhesive, preferably a silicone adhesive or a resin is applied, which covers at least one outer terminal or the two outer terminals and the protective cap glued to the switch.

In this measure, it is advantageous that the protective cap is not or not exclusively held purely mechanically but also / only cohesively. It is automatically determined when the adhesive cures on the switch, so to speak. The adhesive, which is preferably a silicone adhesive, thereby covers at least the outer terminals of the switch and the possibly still free stripped ends of the connecting wires, so that no short circuit between the outer terminals on the material of the protective cap is effected.

The silicone adhesive or resin also provides strain relief for the leads soldered to the external terminals, although the silicone adhesive does not provide the degree of stability that an epoxy resin would provide. Nevertheless, the combination of silicone adhesive and protective cap ensures on the one hand excellent mechanical stability and pressure compatibility of the new switch as well as adequate electrical and mechanical protection of the cover part. The switch can therefore also be wrapped in a winding of a coil when the cover part consists of a PTC thermistor material.

In the event that the cover part consists of an electrically conductive material, the silicone adhesive further provides for an electrical insulation of the cover part relative to the protective cap, which itself can be electrically connected to the lower part.

The provided with the protective cap switch can then be subsequently introduced into a cap made of a shrink tubing to the Total switch to isolate to the outside, as it is, for example, from the DE 19 05 153 is known, the content of which is hereby made the subject of the present application.

Further, it is preferred if the protective cap has a lateral opening, from which protrudes a pigtail or the two connecting wires protrude.

In this measure, it is advantageous that only a small portion of the protective cap is not the cover of the lid portion of the switch, the opening being led out laterally from the cap, so that the cap itself remains closed at the top, from where when wrapping the switch greatest pressure is exerted on the switch.

Further, it is preferred if the protective cap has a shoulder, with which it rests on an edge of a wall of the lower part, which preferably defines the lid part on the lower part, wherein more preferably on the protective cap in the direction of the wall of the lower part of the shoulder adjoining cylindrical wall is arranged, which bears against the outside of the wall of the lower part.

This measure is particularly advantageous in terms of design, since the shoulder exerts the force exerted on the protective cap in the wall of the lower part of the switch, so that the cover part of the switch is completely relieved of the pressure exerted on the protective cap.

The cylindrical wall of the protective cap, which adjoins the shoulder, thereby ensuring a simple centering of the protective cap on the lower part, wherein the cylindrical wall of the cap at the same time by resting against the wall of the lower part ensures that the space between the protective cap and the top Switch is sealed to the outside, so that gases, liquids or dirt particles can not get to the top of the switch and from there into the interior of the switch.

In particular, when this space between the top of the switch and the protective cap is filled with silicone adhesive, in this way ensures excellent sealing of the interior of the switch against the entry of contaminants.

In addition, if the cylindrical wall of the protective cap has an opening angle to an axis of symmetry of the protective cap, which is preferably between 2 ° and 10 °, the protective cap can easily be arranged on the switch.

In general, it is preferred if the protective cap has a dome-like cover, under which at least the outer terminal lies or the outer terminals are located.

The design of the top of the cap as a dome-like lid also gives the cap itself excellent pressure stability, on the lid of the cap force exerted along the cap in the shoulder and from this into the wall of the base.

It is preferred if a cylindrical wall is arranged on the protective cap between the lid and shoulder.

The advantage here is that the distance between the shoulder and the lid can be designed so large by the cylindrical wall that the selected fastening technology, in particular the solder pads or welding surfaces are easily accommodate under the cap.

Further, it is preferred if the protective cap made of metal, preferably made of steel.

In this measure, it is advantageous that the protective cap itself has excellent pressure stability, wherein it can be manufactured as a simple deep-drawn part.

Against this background, the present invention also relates to a protective cap for the new switch, with a dome-like cover which is fixed to a shoulder, via which the protective cap can be placed on an edge on a wall of the switch.

The new protective cap has the features described above in connection with the new switch, whereby it can be supplied as a separately transportable part of a manufacturer of the temperature-dependent switch via a third party.

Overall, the present invention further relates to a method for final assembly of a temperature-dependent switch, comprising the steps:

a) providing a temperature-dependent switch having a housing which has a cover part and a lower part, and having a temperature-dependent switching mechanism arranged in the housing, which establishes or opens an electrically conductive connection between two external connections provided on the switch depending on its temperature,

b) soldering one pigtail each to the external connections,

c) applying an adhesive to the top of the switch so that the adhesive covers at least one outer terminal provided on the upper side or two outer terminals provided on the upper side; and before the curing of the adhesive

d) Place the new protective cap on the switch so that the shoulder of the protective cap is seated on one edge on one wall of the switch and the pigtail connected to the external connection or the external connections on the top are connected laterally out of an opening in the protective cap ; and

e) allowing the adhesive to cure.

With the new method, pre-assembled switches, in which the switching mechanism has been installed in the housing, can be provided with connecting leads at any time and then equipped with a protective cap, so that they can be wrapped, for example, in windings of transformers.

Because of the adhesive on the top of the switch, oils or outgassing fluids used in this wrapping can not diffuse or creep into the interior of the switch, so that the switch is not only mechanically stable but also highly sealed against the environment.

The new method and the new protective cap can be used on switches of any design, and changes to the switches themselves are not required.

In the following exemplary embodiments, three types of switches are shown by way of example, each having a pot-like lower part with a wall, the edge of which is flanged inwardly to fix the cover part on a shoulder of the lower part.

In the cover part, at least one outer terminal is provided for a pigtail, wherein the other Au βenanschluss is also provided on the cover part when the temperature-dependent switching mechanism carries a contact plate, or the edge itself or the bottom or a wall of the electrically conductive base partially can be designed as another external connection.

Such switches are often distributed by the applicant's company, they can be equipped with a cover part of PTC thermistor or with a lid part made of insulating material or with a cover part of electrically conductive material, each corresponding insulation measures are provided so that no short circuit between electrically conductive parts that affects the operation of the switch.

According to the invention, a protective cap adapted in its geometry to the respective type of switch is now placed on these existing switches as required, which is supported with an inner shoulder on the flanged edge of the wall of the lower part, for example.

Other features and 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 respectively specified combinations, but also in other combinations or alone, without departing from the scope of the present invention.

Fig. 1

eine schematische Schnittdarstellung in Seitenansicht eines temperaturabhängigen Schalters in einem ersten Ausführungsbeispiel;

Fig. 2

in einer Darstellung wie Fig. 1 ein weiteres Ausführungsbeispiel eines temperaurabhängigen Schalters, der ein Deckelteil aus Kaltleitermaterial aufweist;

Fig. 3

eine schematische Draufsicht auf den Schalter aus Fig. 1 oder Fig. 2, mit angelöteten Anschlusslitzen;

Fig. 4

in einer Darstellung wie Fig. 1 ein weiteres Ausführungsbeispiel eines temperaturabhängigen Schalters, der eine Kontaktbrücke und ein Deckelteil aus Kaltleitermaterial aufweist;

Fig. 5

eine schematische Draufsicht auf den Schalter aus Fig. 4, mit angelöteten Anschlusslitzen;

Fig. 6

eine schematische Draufsicht auf den Schalter aus Fig. 3 oder Fig. 5, mit aufgesteckter Schutzkappe;

Fig. 7

eine Schnittdarstellung durch die Schutzkappe aus Fig. 6 längs der Linie VII-VII aus Fig. 6; und

Fig. 8

eine geschnittene Seitenansicht des Schalters aus Fig. 6, gesehen läng des Pfeils VIII aus Fig. 6;

Embodiments of the invention are illustrated in the drawings and are explained in more detail in the following description. Show it:

Fig. 1

a schematic sectional view in side view of a temperature-dependent switch in a first embodiment;

Fig. 2

in a presentation like Fig. 1 a further embodiment of a temperament-dependent switch having a cover part of PTC thermistor material;

Fig. 3

a schematic plan view of the switch Fig. 1 or Fig. 2 , with soldered pigtails;

Fig. 4

in a presentation like Fig. 1 a further embodiment of a temperature-dependent switch having a contact bridge and a cover part of PTC thermistor material;

Fig. 5

a schematic plan view of the switch Fig. 4 , with soldered pigtails;

Fig. 6

a schematic plan view of the switch FIG. 3 or FIG. 5 , with attached protective cap;

Fig. 7

a sectional view through the protective cap Fig. 6 along the line VII-VII Fig. 6 ; and

Fig. 8

a sectional side view of the switch Fig. 6 seen from the arrow VIII Fig. 6 ;

In Fig. 1 is a schematic, not to scale and shown in lateral section a temperature-dependent switch 1, which comprises a cylindrical wall 10 exhibiting, electrically conductive cup-shaped base 11 which is closed by a plate-like, electrically conductive cover member 12, the interposition of an insulating film 13 of a flanged edge 14 of the wall 10 is held on the housing lower part 11.

In the housing formed by the lower part 11 and cover part 12 of the switch 1, a temperature-dependent switching mechanism 15 is arranged, which comprises a spring-snap disk 16 which carries a movable contact member 17 centrally on which a freely inserted bimetallic disc 18 is seated.

In the context of the present invention, a bimetallic disc is understood to mean a multilayer, active, sheet-metal component made of two, three or four components which are inseparably connected to one another and have different expansion coefficients. The connection of the individual layers of metals or metal alloys are cohesively or positively and are achieved for example by rolling.

The spring snap disk 16 is supported on a bottom 19 inside of the lower part 11, while the movable contact part 17 is in contact with a fixed contact part 20 which is provided on an inner side 21 of the cover part 12.

As external terminals 22 and 23 are used in the switch Fig. 1 On the one hand, a central region of the cover part 12 and, on the other hand, a region on the flanged edge 14.

The two outer terminals 22, 23 are thus adjacent to one another at an upper side 25 of the switch. 1

In this way, the temperature-dependent switching mechanism 15 in the in Fig. 1 shown low-temperature position an electrically conductive connection between the two outer terminals 22, 23 forth, the operating current on the fixed contact part 20, the movable contact part 17, the spring snap disk 16 and the lower part 11 flows.

Increased at the switch 1 off Fig. 1 the temperature of the bimetallic disc 18 beyond its response temperature, so it snaps from the in Fig. 1 shown convex position in its concave position in which it lifts the movable contact member 17 against the force of the spring washer 16 of the fixed contact member 20 and thus opens the circuit.

Fig. 2 shows a temperature-dependent switch 1 ', which is constructed similar to the switch 1 off Fig. 1 , Same constructive features are denoted by the same reference numerals as in FIG Fig. 1 Mistake.

In contrast to the switch 1, in the case of the switch 1 ', the cover part 12 is not made of electrically conductive material but of a cold conductor material 26 which acts as a self-holding resistor, so that the switch 1' is held in the open state until the supply voltage is switched off.

In the context of the present invention, a "PTC thermistor material" is understood as meaning an electrically conductive ceramic material which has a positive temperature coefficient, so that its electrical resistance increases with increasing temperature increased. The course of the electrical resistance value over the temperature is non-linear.

Such PTC thermistors are also referred to as PTC resistors. They are made, for example, from semiconductive, polycrystalline ceramics such as BaTiO3.

The stationary contact part 20 is formed by an inner head of a rivet 27, which passes through the lid part and forms the outer terminal 22 with its outer head.

Fig. 3 shows a schematic plan view of the switches 1 and 1 ', which do not differ significantly in this view.

To the outer terminals 22, 23 is in Fig. 3 each one pigtail 27, 28 soldered with their respective stripped end 29, 31.

While the switches 1 and 1 from the Fig. 1 and 2 are provided with a switching mechanism 15, in which the current flows through the spring snap disk 16, shows Fig. 4 a switch 1 "', in which the current is passed through a contact plate, so that this switch 1" can switch higher currents.

In Fig. 4 the temperature-dependent switch 1 "comprises a temperature-dependent switching mechanism 111 housed in a housing 112.

The housing 112 comprises a bottom wall 114 having a cylindrical wall 113 and a cover part 115 closing this, which is held by a flanged edge 116 of the wall 113 of the base 114 at this. Between the lower part 114 and the lid part 115, a ring 117 is arranged, which is supported on a shoulder 118 of the lower part 114 and there leads a spring snap-action disc 121 of the rear derailleur 111 at its edge.

The rear derailleur 111 additionally comprises, in addition to the spring snap-action disc 121, a bimetallic disc 122 which, together with the spring snap-action disc 121, is centrally penetrated by a pin-like rivet 123, by which these are mechanically connected to a current transfer member in the form of a contact plate 124. The rivet 123 has a first shoulder 125 on which the bimetallic disc 122 sits with radial and axial play, with a second shoulder 126 is provided, on which the spring snap disc 121 also sits with radial and axial play.

The bimetallic disc 122 is supported with its peripheral edge inside in the lower part 114.

The already mentioned contact plate 124 has, in the direction of the cover part 115, two electrically interconnected, large-area contact surfaces 127 which cooperate with two stationary contacts 131, 132 arranged on the inner side 129 of the cover part 115, which are inner heads of contact rivets 133, 134 pass through the lid member 115 and serve with their outer heads 135, 136 on the upper surface 138 of the lid member 115 as Außenanschlüsse22 and 23.

In the in Fig. 4 shown switching position spring snap disc 121 and bimetallic disc 122 press the contact plate 124 against the stationary contacts 131 and 132, which are thus connected to each other via the contact surfaces 127; the switch 1 "is thus closed.

Increases the temperature of the bimetallic disc 122 beyond its response temperature, it snaps from the convex shown in a concave shape and supports itself with its edge in the region of the ring 117 and pulls the contact plate 124 against the force of the spring snap disc 121st away from the stationary contacts 131, 132; Switch 1 "is now open.

The switch described so far is from the DE 198 27 113 C2 known. Like the one from the DE 198 27 113 C2 Known switch, the cover member 115 is made of a PTC resistor 26, so represents a PTC resistor, the is electrically connected between the stationary contacts 131, 132. The cover part 115 thus acts as a self-holding resistor.

Fig. 5 shows a plan view of the switch 1 "in a representation like Fig. 3 , Here, too, a pigtail 27, 28 are soldered to the outer terminals 22, 23 each with their respective stripped end 29, 31.

In order to mechanically protect the switches 1, 1 and 1 "', in particular the cover parts 12, 112 and the soldered connecting leads 27, 28, the switches 1, 1' already assembled with the connecting leads 27, 28 are mounted on the upper side 25 or 138. , 1 "a protective cap 41 is placed, as in the plan view of Fig. 6 is shown.

The protective cap 41 made of metal, preferably as a deep-drawn part or a turned part made of steel, covers the entire upper side 25, 138 of the switch 1, 1 ', 1 "and has a lateral opening 42 from which the two connecting leads 27, 28 lead out In this way, both the cover part 12, 115 and the external connections 22, 23 are protected against the direct introduction of mechanical forces, in particular against pressure.

In Fig. 7 the protective cap 41 is in cross section along the line VII-VII Fig. 6 shown.

The protective cap 41 has a dome-like cover 43, to which in Fig. 7 downwardly connects a cylindrical wall 44 which merges into an outwardly and downwardly facing inner shoulder 45 to which a downwardly facing wall 46 connects, which widens slightly in the direction of its insertion opening 50 to the outside.

The wall 46 thus closes with the symmetry axis 47 of the protective cap 41 at an angle indicated at 48, which is between 2 ° and 10 ° degrees, in the present case is about 5 °.

In Fig. 8 is for the switch 1 'off Fig. 2 the arrangement Fig. 6 in a view along the line VIII-VIII shown. The shoulder 45 rests on the edge 14 of the switch 1 ', so that pressure, which is exerted from above on the lid 43 of the cap 41, is passed over the edge 14 in the wall 10 of the lower part 11.

The lateral opening 42, from which the connecting strands 27, 28 protrude, is in each case partially cut out of the cover 43, the wall 44, the shoulder 45 and the wall 46.

The area between the upper side 25 and the cover 43 is filled with an adhesive, in particular a silicone adhesive 49, which is placed on the upper side 25 of the switch 1 'before the protective cap 41 is placed, around the free ends 29, 31 of the connecting leads 27, 28 as well to electrically isolate the external terminals 22, 23 and to provide a certain strain relief for the connecting leads 27, 28.

Because the protective cap is placed on the switch 1 'prior to the silicone curing, the silicone also ensures that the protective cap 41 is firmly held on the switch 1'. At the same time, the adhesive (49) isolates the cover part (12) from the protective cap (41).

The wall 46 of the protective cap 41 is located on the outside of the wall 10 of the switch 1 'and thereby provides mechanical support and for sealing the interior of the protective cap against the entry of gases, liquids or dirt particles.

The small opening angle 48 of the wall 46 ensures during assembly of the protective cap 41 on the switch 1 'that the protective cap 41 can be easily plugged despite the silicone layer. In the same way, the switches 1 and 1 "can be protected by the protective cap 41, wherein for use with the switch 1, the shoulder 45 of the protective cap 41 can be inclined slightly downwards, so that it rests flush on the inclined edge 14 of the wall 10 ,

Claims (15)

Temperature-dependent switch having a housing which has a cover part (12; 115) and a lower part (11; 114) and with a temperature-dependent switching mechanism (15; 111) arranged in the housing which, depending on its temperature, forms an electrically conductive connection between two external terminals (22, 23) provided on the housing, of which at least one is arranged on an upper side (25) of the switch, and to which the connecting leads (27, 28) are connected, characterized in that on top of the cover part (12; 115) a protective cap (41) sits which covers the at least one outer terminal (22, 23) on the upper side (25) and from which the pigtail (27, 28) connected to the at least one outer terminal (22, 23) leads out laterally. Switch according to Claim 1, characterized in that both outer terminals (22, 23) are arranged on the upper side (25) and provided there with connecting strands (27, 28) which lead laterally out of the protective cap (41). Switch according to claim 1 or 2, characterized in that on the upper side (25) an adhesive, preferably a silicone adhesive (49) or a resin is applied, the at least one outer terminal (22, 23) or the two outer terminals (22, 23 ) and the protective cap (41) with the switch (1, 1 ', 1 ") glued. Switch according to one of Claims 1 to 3, characterized in that the protective cap (41) has a lateral opening (42) from which the one connecting strand (27, 28) protrudes or the two connecting strands (27, 28) protrude. Switch according to one of claims 1 to 4, characterized in that the protective cap (41) has a shoulder (45) with which it rests on an edge (14; 116) of a wall (10) of the lower part (11; 114), which preferably defines the cover part (12; 115) on the lower part (11; 114). Switch according to Claim 4, characterized in that a cylindrical wall (46) adjoining the shoulder (45) in the direction of the wall (10) of the lower part (11; 114) is arranged on the protective cap (41) Wall (10) of the lower part (11; 114) is present. Switch according to claim 6, characterized in that the cylindrical wall (46) of the protective cap (41) has an opening angle (48) to an axis of symmetry (47) of the protective cap (41) which is between 2 ° and 10 °. Switch according to one of claims 1 to 7, characterized in that the protective cap (41) has a dome-like cover (43) under which at least the outer terminal (22, 23) is located or the outer terminals (22, 23). Switch according to Claims 5 and 8, characterized in that a cylindrical wall (44) is arranged on the protective cap (41) between cover (43) and shoulder (45). Switch according to one of claims 1 to 9, characterized in that the protective cap (41) made of metal, preferably made of steel. A protective cap for a switch according to any one of claims 1 to 10, having a dome-like cover (43) fixed to a shoulder (45) over which the protective cap (41) is fitted to a rim (14; 116) on a wall (10) ) of the switch (1, 1 ', 1 ") can be placed. Protective cap according to Claim 11, characterized in that it has a conical wall (46) adjoining the shoulder (45) remote from the cover (43) and having an opening angle (48) to its axis of symmetry (47) between 2 ° and 10 ° ° is. Protective cap according to claim 11 or 12, characterized in that a lateral opening (42) is provided in the cover (43), shoulder (45) and wall (46). Protective cap according to one of claims 11 to 13, characterized in that it is made of metal, preferably made of steel. Method for final assembly of a temperature-dependent switch according to one of claims 1 to 10, comprising the steps: a) providing a temperature-dependent switch (1, 1 ', 1 ") having a housing which has a cover part (12, 115) and a lower part (11, 114) and with a temperature-dependent switching mechanism (15, 111 ) which establishes or opens an electrically conductive connection between two external connections (22, 23) provided on the switch, depending on its temperature, b) soldering each of a pigtail (27, 28) to the outer terminals (22, 23); c) applying an adhesive to the upper side (25) of the switch (1; 1 '; 1 "), so that the adhesive has at least one outer connection (22, 23) provided on the upper side (25) or two outer connections provided on the upper side (25). 22, 23) and before curing of the adhesive d) placing a protective cap (41) according to any one of claims 10 to 13 on the switch (1; 1 '; 1 "), so that the shoulder (45) of the protective cap (41) on a rim (14; Wall (10) of the switch (1, 1 ', 1 ") is seated and the external connection or the external connections at the top connected pigtail (27, 28) or connected pigtails laterally from an opening (42) in the protective cap (41) lead out; and e) allowing the adhesive to cure.

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