DE102013022331B4 - Temperature dependent switch - Google Patents

Abstract

Temperature-dependent switch (10, 10 ', 10 ") with a first and a second external connection (11, 12), a stationary contact part (15) which is electrically conductively connected to the first external connection (11), and a stationary contact part (15) which interacts with the stationary contact part (15) movable contact part (16) which is fastened to a spring part (17) which is electrically conductively connected to the second external connection (12) and which presses the movable contact part (16) against the stationary contact part (15), a bimetallic part (19 ) and a plunger (21) arranged between the bimetal part (19) and the spring part (17), the bimetal part (19) pressing the plunger (21) against the spring part (17) and thereby the movable contact part (16) when a switching temperature is exceeded ) lifts off from the stationary contact part (15) in order to effect a switching process in which the switch (10, 10 ', 10 ") is opened, characterized in that the switch (10, 10', 10") also has a spring snap part (33) au That, at least when the switching temperature is exceeded, presses the plunger (21) against the spring part (17) and, together with the bimetallic part (19), exerts a combined pressure on the spring part (17) in order to increase the dynamics of the switching process.

Description

The present invention relates to a temperature-dependent switch according to claim 1 with a first and a second external connection, a stationary contact part which is electrically conductively connected to the first external connection, a movable contact part which cooperates with the stationary contact part and which is attached to a spring part which is electrically conductive with the second external connection is connected, and which presses the movable contact part against the stationary contact part, a bimetal part and a plunger arranged between the bimetal part and the spring part, the bimetal part pressing the plunger against the spring part when a switching temperature is exceeded and thereby pushes the movable contact part away from the stationary Contact part lifts to cause a switching process in which the switch is opened.

A switch according to the preamble of claim 1 is from DE 10 2011 016 896 B3 known.

The known switch is a temperature protection switch in which the switching movement of a bimetal disc is transmitted via a plunger to a current-carrying closing spring which carries a movable contact part which it presses against a stationary contact part when the switch is closed. The stationary contact part and the closing spring are each connected to a connecting plate. The two connection plates are fixed on an insulator body from which they protrude laterally. The temperature protection switch has a flat housing from which the two connection plates protrude as external connections.

Such temperature-dependent switches are used in a known manner to protect electrical devices from overheating. For this purpose, the switch is electrically connected in series with the device to be protected via its two external connections and mechanically arranged on the device in such a way that it is in thermal connection with it.

In the implementation of a switch according to DE 44 28 226 C1 A temperature-dependent switching mechanism consisting of a spring snap disk, a bimetal snap disk and a movable contact part is arranged in a housing, which when the switch is closed is in contact with a stationary contact part on the inside of the upper part, which is through-contacted to a first connection on the upper part. The conductive lower part serves as the second connection.

The operating current of the device to be protected flows through the two contact parts and the spring snap disk into the lower part.

The one from the DE 44 28 226 C1 known switch is provided with a heating resistor which is arranged electrically in series with the external connections and ensures a current-dependent switching function. The operating current of the device to be protected thus flows constantly through this heating resistor, which can be dimensioned in such a way that, when a certain operating current is exceeded, it ensures that the bimetal snap-action disk is heated to a temperature above its response temperature, so that the switch at an increased Operating current already opens before the device to be protected has heated up to an impermissible level.

The circuit is closed below the response temperature of the bimetal snap-action disk and the device to be protected is supplied with power via the switch. If the temperature rises above a permissible value either as a result of an operating current that is too high or as a result of the device to be protected being overheated, the bimetal snap-action disk deforms, causing the spring snap-action disk to change from its first stable geometric configuration, in which it is the movable contact part presses against the stationary contact part, jumps into its second stable geometric configuration in which it lifts the movable contact part from the stationary contact part. The switch is opened and the supply to the device to be protected is interrupted.

The now de-energized device can then cool down again. The switch that is thermally coupled to the device also cools down and then closes again automatically. While such switching behavior is used for protection e.g. a hair dryer can make sense, this is not desirable wherever the device to be protected must not automatically switch on again after being switched off in order to avoid damage. This applies e.g. for electric motors that are used as drive units.

In known temperature-dependent switches, a so-called self-holding resistor is therefore often provided, which is electrically parallel to the connections, as is also shown in FIG DE 44 28 226 C1 is described. When the switch is open, the self-holding resistor is electrically in series with the device to be protected, through which only a harmless residual current now flows due to the resistance value of the self-holding resistor. However, this residual current is sufficient to heat up the self-holding resistor to such an extent that it radiates heat that keeps the bimetal snap-action disk at a temperature above its switching temperature.

Deviating from the design of the switch according to DE 44 28 226 C1 the temperature-dependent switching mechanism can also only comprise a bimetal snap-action disk which carries the movable contact part and thus carries the operating current.

The switching mechanism can also comprise a bimetallic spring tongue, as is shown in FIG DE 198 16 807 A1 is described. This bimetallic spring tongue has a movable contact part at its free end, which interacts with a stationary mating contact. The stationary mating contact is electrically connected to the first connection, the second connection being electrically connected to the clamped end of the bimetallic spring tongue. The bimetallic spring tongue conducts the operating current of the electrical device to be protected.

If the temperature-dependent switch is to carry particularly high currents, a current transmission element in the form of a contact bridge or a contact plate is often used, which is moved by a spring part and carries two contact parts that interact with two stationary counter-contacts; see for example the DE 26 44 411 A1 .

In this way, the operating current of the device to be protected flows from the first mating contact via the first contact part into the contact plate, through this to the second contact part and from there into the second mating contact. The spring part is thus de-energized. It is also known to use the spring part itself, for example a bimetallic snap disk or a spring snap disk working against a bimetal part, as a contact bridge that carries the operating current.

The known switches must be able to reliably protect motors both in limit operation at maximum permissible power and when the rotor is locked. To check whether the switch can do this, two tests are usually carried out.

In the so-called heating test, the motor is operated at maximum power, whereby neither the current flow through the switch nor the heat transferred from the motor to the switch is allowed to open the switch.

In the so-called locked rotor test, on the other hand, the motor is connected to the operating voltage when the rotor is locked, which means that an operating current flows through the motor that is three to five times greater than the normal operating current.

This high current naturally also leads to the motor heating up and thus to an increase in temperature at the switch. In order to protect the motor from overheating, a good thermal coupling between the switch and the motor must be ensured.

In addition to the good thermal coupling, the switch must also meet the required number of switching cycles, which should be at least 3,000 for typical requirements as described above.

So that the switch can carry high operating currents without the bimetal disc being heated up to its switching temperature, the generic one strikes DE 10 2011 016 896 B3 propose to increase the distance between the current-carrying closing spring and the bimetal disc by the mechanically interposed plunger.

The bimetal disk is also arranged in a recess on an outside of the insulator body in order to thermally decouple it on the one hand from the current-carrying closing spring and on the other hand to enable good thermal coupling of the bimetal disk to the device to be protected.

The temperature-dependent switching mechanism used in the known switch is basically constructed like a so-called thermostat switch, which is used to regulate the temperature of a device equipped with it, for example a heating plate to regulate the temperature. Examples of such thermostat switches can be found in the following property rights: DE 31 36 312 A1 , DE 196 37 706 A1 , U.S. 3,972,016 A , U.S. 4,669,182 A , U.S. 5,059,937 A and US 2004/0066269 A1 .

The one from the generic DE 10 2011 016 896 B3 known switch thus deviates from the usual structure of a temperature-dependent switch according to FIG DE 44 28 226 C1 even though it is not designed as a thermostat but as a temperature protection switch.

With the switch according to the DE 10 2011 016 896 B3 It is particularly disadvantageous that at higher operating currents it can withstand only a small number of switching cycles, i.e. it fails prematurely.

Tests in the applicant's premises have shown that the known switch often no longer opens after 300 switching cycles with a current of 35 A flowing through the closing spring in the locked rotor test with 120 VAC, because the contact parts were welded together by arcing.

The U.S. 3,931,603 A shows a temperature monitor with a bimetallic snap disk, spring washer and contact bridge. Between bimetal Snap washer and spring washer are acted on by a bolt which is fastened at one end to the bimetallic snap disk. The spring washer is seated at the other end of the bolt, a contact bridge being arranged between the spring washer and the bimetal snap disk on the bolt and a compression spring between the contact bridge and the bimetal snap disk.

Below its switching temperature, the bimetal snap disk pushes the bolt in the direction of two stationary mating contacts, against which the contact bridge rests under the force of the compression spring, which is supported at the other end on the bimetal snap disk.

If the temperature of the bimetal snap disk increases, it pulls the bolt away from the two stationary mating contacts, the bolt lifting the contact bridge from the mating contacts so that the switch is opened.

The DE 26 25 120 B2 also shows a temperature-dependent switch with a bimetallic snap disk, spring snap disk and contact bridge, in which a plunger is connected at one end to the spring snap disk and at its other end to the contact bridge, which interacts with two stationary mating contacts.

On the side of the spring snap-action disk remote from the plunger, a bimetal snap-action disk is arranged which, below its switching temperature, lies loosely below the spring snap-action disk, so that the switch is closed.

If the temperature of the bimetal snap disk increases, it presses against the plunger and the spring snap disk so that the contact bridge lifts off the stationary mating contacts and the spring snap disk snaps from its first to its second mechanically stable position. In this open state, both the spring snap-action disk and the bimetal snap-action disk push the contact bridge away from the stationary mating contacts.

A switching plunger is provided above the contact bridge, which is arranged on an actuating button via a second bistable spring snap disk. When the actuating button is pressed into the housing of the switch, the switching plunger presses against the contact bridge when the switch is open. The actuating force of the second spring snap disk is less than the sum of the actuating forces of the first spring snap disk and the bimetal snap disk, so that when the actuation button is pressed into the housing, the second spring snap disk snaps over into its inactive position when the bimetal Snap disk is above its switching temperature.

If the temperature of the bimetal snap disk falls again, it jumps back into its unloaded position, but the contact bridge is held in the open position by the first spring snap disk. Pressing the actuating button again now causes the switching plunger to press the contact bridge downwards, so that the first spring snap-action disk jumps back into its first stable position in which the switch is closed. The actuating force of the second spring snap disk must be greater than that of the first spring snap disk.

From the U.S. 4,908,596 A a temperature-dependent switch is known in which a bimetallic snap disk acts via a plunger on a switching arm which carries a movable contact part at its free end, which interacts with a stationary counter-contact.

The bimetal snap disk is fixed on a shoulder of the housing of the temperature-dependent switch via a spring washer. The spring washer enables the bimetal snap disk to snap over and dampens the movement of the bimetal snap disk during the switching processes and is intended to improve the heat exchange between the bimetal snap disk and the housing.

The U.S. 3,755,770 A discloses a thermostat comprising a support and a thermally responsive bimetal element having a peripheral portion adjacent the support and a central portion adapted to move with respect to the peripheral portion in response to changes in temperature of the bimetal element. A spring is provided to bias one of the contacts. An actuating piston is mounted between the bimetal element and the spring for movement in response to movement of the central portion of the bimetal element. Furthermore, temperature drift control means are provided which comprise an energy-absorbing damper which is arranged between the peripheral portion of the bimetal element and the carrier.

On the basis of this prior art, it is the object of the present invention to develop the switch mentioned at the beginning in such a way that it still provides a sufficient number of switching cycles with a simple and inexpensive construction even with higher switching currents.

According to the invention, this object is achieved in the aforementioned switch in that the switch has a spring snap-in part which presses the plunger against the spring part at least when the switching temperature is exceeded and, together with the bimetal part, a combined one Exerts pressure force on the spring part in order to increase the dynamics of the switching process.

In an embodiment that is not part of the invention, the plunger, in contrast to the known switch, not only transmits the movement of the bimetal part to the spring part when the switch is opened but also when the switch is closed, the closing speed is increased, which according to the invention no longer only by Closing spring is determined.

In this case, the arc formation itself is not influenced or the spring part is redesigned, but the switching dynamics of the known switch are increased in that a forced coupling is provided between the closing spring and the bimetal part.

This positive coupling is achieved in a structurally simple and inexpensive manner in that the plunger not only transfers a pressure force from the bimetal part to the spring part when opening, but also transfers a tensile force from the bimetal part to the spring part when closing.

This measure increases the closing speed of the switch, which, contrary to expectations, already significantly reduces the contact wear, especially at high switched currents, which, according to the inventors of the present application, already significantly increases the service life, i.e. the number of switching cycles.

It is particularly advantageous that the actuating force of the spring part is not increased, but that an additional closing force is applied by the bimetal disc. In this way, the opening speed of the switch is not adversely affected, because when opening the bimetal disc only has to overcome the previous closing force of the spring part.

The inventors of the present application have recognized on the basis of the experiments and considerations leading to the present invention that under certain conditions the forced coupling between the plunger and the spring part can be dispensed with without all of the above-mentioned advantages being lost.

If only the spring snap part and the bimetal part are connected to the plunger, the advantage of the increased opening speed is retained. When the switch is closed, the combined action of the spring snap-in part and the bimetal part means that the plunger is withdrawn so quickly that the closing speed is lower than that from the DE 10 2011 016 896 B3 known switch is also significantly increased.

The inventors of the present application have also recognized on the basis of the experiments and considerations leading to the invention that under certain conditions the forced coupling between the plunger and the spring snap-in part and the bimetal part can be dispensed with without all of the above-mentioned advantages being lost.

If the additional spring snap part is provided, the advantage of the increased opening speed is retained. When the switch is closed, the action of the spring snap part on the bimetal part also causes the plunger to be withdrawn so quickly that the closing speed is lower than that from the DE 10 2011 016 896 B3 known switch can still be increased.

This measure is unusual in that the known switch already has a spring part that works in a known manner against the force of the bimetal part.

According to the invention, a spring snap part is now additionally provided in order to further increase the dynamics of the switching process.

This means that the new switch can withstand the required number of switching cycles even with high switching currents

The object on which the invention is based is completely achieved in this way.

Preferably, the spring snap part and the bimetal part are arranged at a first end of the plunger and the spring part at a second end of the plunger, wherein the spring snap part and the bimetal part are furthermore preferably connected to the plunger in such a way that they transmit compressive and tensile forces to the plunger, more preferably, the plunger has a shaft which has a tapered section at its first end which carries a head that is wider than the tapered section, the bimetal part and the spring snap-in part with their respective through-hole being arranged on the tapered section in such a way that the bimetal part and the spring snap is held with play between the head and the shaft.

Like the positive coupling of the plunger on both sides discussed above, these measures also lead to improved switching dynamics, so that the number of switching cycles is increased.

The tapered portion can be formed in one piece with the head or the shaft, either the tapered section is inserted into a blind hole provided in the shaft or the head is placed on the tapered section. The head can also be designed as a rivet, the bolt of which is inserted into a blind hole provided in the tapered section.

It is preferred if the bimetal part is arranged between the plunger and the spring snap part.

The advantage here is that the spring snap part lies on the outside of the bimetal part and protects it.

Alternatively, it is preferred if the spring snap part is arranged between the plunger and the bimetal part.

The advantage here is, on the one hand, that the bimetal part located on the outside can be thermally well coupled to a device to be protected, and it is also advantageous that the bimetal part has the spring snap-in part above it in the direction of the plunger even without a forced coupling between the plunger and bimetal part and spring snap part Opening the switch makes it snap very quickly.

In the context of the present invention, a “spring snap part” is understood to mean a spring part which has two stable geometric configurations, as is generally known for spring snap disks in temperature-dependent switches. The spring snap part is pressed by the bimetal part from its one in the direction of the other, geometrically stable configuration, until the spring snap part then suddenly springs over completely.

The switch can each be provided with a heating resistor for defined current-dependent switching and, if necessary, additionally with a self-holding resistor so that the open switch does not cool down and close again automatically.

It is also preferred if the bimetal part is designed as an elongated tongue, which is arranged on its opposite narrow sides between two abutments that are opposite in the longitudinal direction of the plunger, further preferably the spring snap-in part is designed as an elongated tongue which is in each case on their opposite narrow sides is arranged between two abutments that are opposite each other in the longitudinal direction of the plunger, further preferably the bimetal part is designed as a bimetal disc, which is arranged at its edge between two abutments that are opposite in the longitudinal direction of the plunger, further preferably the spring snap part as a spring Snap disk is formed, which is arranged at its edge between two abutments which are opposite in the longitudinal direction of the plunger.

These measures relate to the possible configurations of the spring snap part and the bimetallic part as an elongated tongue or disc. Whereby a “disk” in the context of the present invention is understood to mean a generally round, circular, oval or rounded part.

In general, it is preferred if the first and second external connections are fixed to an insulator body, the first and second external connections preferably being designed as first and second connection plates, the two connection plates protruding from the insulator body, and the insulator body being arranged in a housing , further preferably the spring part has a first and a second leg, the movable contact part is attached to the first leg, the second leg is electrically connected to the second connection plate, and the plunger is arranged between the first leg and the bimetal part, more preferably that Housing has an upper side and a lower side, which are connected to one another via narrow sides, and the housing has an opening on one of its narrow sides and is plugged with this opening onto the insulator body, further preferably the two legs to interrupt a conductive connection between d en both connection plates are bent apart by the plunger, further preferably the second leg rests against the second connection plate, further preferably the insulator body is composed of two sub-bodies, and the two connection plates lie between the two sub-bodies.

Furthermore, it is preferred if the bimetal part is arranged in a recess on an outside of the insulator body, more preferably the spring snap part is arranged in a recess on an outside of the insulator body, and finally a ring inserted from the outside is provided in the recess, which acts as an abutment serves for the spring snap part and / or the bimetal part

These measures are structurally advantageous, they lead to a compact, inexpensive switch.

Further advantages emerge from the description and the attached drawing.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the respectively specified combination, but also in other combinations or alone, without departing from the scope of the present invention.

• 1 einen schematischen, nicht maßstabsgetreuen Längsschnitt durch ein Ausführungsbeispiel eines temperaturabhängigen Schalters, das nicht Gegenstand der vorliegenden Erfindung ist und bei dem in einem Schaltwerk ein bewegliches Kontaktteil mit einem stationären Kontaktteil zusammenwirkt, und bei dem zwischen einem Bimetallteil und einem Federteil ein Stößel angeordnet ist;
• 2 in einer schematischen Explosionsdarstellung einen Schalter, der das Schaltwerk aus 1 verwendet;
• 3 den zusammengebauten Schalter aus 2 in einem Längsschnitt;
• 4 den Schalter aus 3 in Draufsicht, jedoch ohne Gehäuse;
• 5 in einer Darstellung wie 1 ein erstes erfindungsgemäßes Ausführungsbeispiel für den temperaturabhängigen Schalter; und
• 6 in einer Darstellung wie 1 ein zweites erfindungsgemäßes Ausführungsbeispiel für den temperaturabhängigen Schalter.

Exemplary embodiments of the invention are shown in the accompanying drawings and are explained in more detail in the following description. Show it:

• 1 a schematic, not true to scale longitudinal section through an embodiment of a temperature-dependent switch, which is not the subject of the present invention and in which a movable contact part cooperates with a stationary contact part in a switching mechanism, and in which a plunger is arranged between a bimetal part and a spring part;
• 2 in a schematic exploded view of a switch that switches off the switching mechanism 1 used;
• 3 the assembled switch 2 in a longitudinal section;
• 4th the switch off 3 in plan view, but without housing;
• 5 in a representation like 1 a first embodiment of the invention for the temperature-dependent switch; and
• 6 in a representation like 1 a second inventive embodiment for the temperature-dependent switch.

In 1 is an embodiment of a temperature-dependent switch, which is not part of the present invention, and is shown very schematically 10 shown, the first and a second external connection 11 , 12 as well as a rear derailleur 14th comprises which, depending on the temperature, has an electrically conductive connection between the external connections 11 , 12 establishes or opens.

The rear derailleur 14th comprises one with the first external connection 11 electrically conductive connected stationary contact part 15th and one with the stationary contact part 15th cooperating movable contact part 16 attached to a spring part 17th is attached, which is electrically conductive to the second external connection 12 is connected and acts as a closing spring that the movable contact part 16 against the stationary contact part 15th presses.

The spring part 17th is designed in this simplified embodiment as a leaf spring in the area of the second external connection 12 on a schematically shown insulator body 18th is determined, on which the first external connection 11 and the stationary contact part 15th are set.

The rear derailleur 14th further comprises a bimetal part 19th and one between the bimetal part 19th and the spring part 17th arranged plunger 21st . Spring part 17th and bimetal part 19th are on opposite ends 20a and 20b of the ram 21st arranged.

The bimetal part presses in a manner known per se 19th the plunger if a switching temperature is exceeded 21st against the spring part 17th and thereby lifts the movable contact part 16 from the stationary contact part 15th from.

The bimetal part 19th is designed in the embodiment shown as an elongated tongue on their opposite narrow sides 22nd and 23 each with sufficient mechanical play between two in the longitudinal direction for snapping over 24 of the ram 21st opposite abutments 25th , 26th are arranged. The upper abutments 25th are part of the insulator body 18th while the lower abutment 26th as a fastening ring for the bimetal part 19th are trained.

The plunger 21st is about an upper head 27 and a lower head 28 on tension and pressure with the spring part 17th or the bimetal part 19th connected. Between a shaft 29 of the ram 21st and the lower head 28 is a tapered section 31 provided on which the bimetal part 17th sitting with game. Also the spring part 17th can with play on the plunger 21st be fixed. The head 27 and the head 28 are opposite the tapered section 31 or the shaft 29 widened.

The shaft 29 of the plunger is in one in the isolation part 18th arranged through hole 30th out to protect it from tilting and / or jamming.

In the in 1 The switching state shown is the switch 10 closed. The spring part 17th presses the moving contact part 16 on the stationary contact part 15th so that between the two external connections 11 , 12 the circuit is closed and the operating current of a device to be protected through the spring part 17th flows.

The narrow sides 22nd , 23 of the bimetal part, which is in its first geometric configuration, lie on the upper abutments 25th and thus support the closing pressure with which the moving contact part 16 on the stationary contact part 15th is pressed.

If its switching or response temperature is exceeded, the bimetal part folds 17th in such a way in its other geometric configuration that the narrow sides 22nd , 23 in contact with the lower abutment 26th arrive so that the bimetal part 17th the plunger 21st in 1 upwards along the arrow 32 presses. This pushes the plunger 21st the spring part 17th upwards so that the moving contact part 16 from the stationary contact part 15th lifted and the circuit is opened.

The temperature of the bimetal part drops 19th again, it jumps back to its first geometric configuration, which is shown in 1 is shown. In doing so, it exercises along the arrow using the pestle 32 downward a tensile force on the spring part 17th from, whereby the closing speed with which the movable contact part 16 back on the stationary contact part 15th on top of a structure of the rear derailleur 14th is increased in which the bimetal part 19th only a compressive force on the spring part 17th exercises.

Parallel to the bimetal part 19th is a spring snap-in part also designed as an elongated tongue 33 at the end 20b of the ram 21st arranged, the opposite narrow sides 34 and 35 also with play between the abutments 25th and 26th lie. The spring snap part also sits on the tapered section with play 31 of the ram 21st so that there are compressive and tensile forces on the spring part via the plunger 17th can exercise.

The spring snap part 33 can either be between the bimetal part 19th and plunger 21st be arranged, or on that of the plunger 21st groundbreaking side of the bimetal part 19th like it in the 1 to 5 is shown.

The spring snap part 33 increases the switching dynamics of the rear derailleur 14th continue. In the manner described above, on the one hand, the closing speed is increased further because the spring snap-in part is also 33 when closing the switch 10 of its a stable configuration in which the narrow sides 34 , 35 at the abutments 26th abut, jumps back into its other stable configuration, in which the narrow sides are against the abutments 25th prop up. The spring snap part exercises 33 like the bimetal part 19th over the plunger 21st a tensile force on the spring part 17th out.

The jumping over of the spring snap part 33 between its two stable geometric configurations is made by the temperature-dependent jumping of the bimetal part 19th triggered between its two geometric configurations.

Because the spring snap part 33 over the plunger 21st also a compressive force on the spring part 17th exerts, the opening speed with which the movable contact part is also increased 16 from the stationary contact part 15th picks up when the switch 10 by jumping around the bimetal part 19th is opened.

2 shows an exploded view for a specific embodiment of the switch 10 out 1 .

The desk 10 comprises a two-part insulator body 18th who has a top 18a and a base 18b having. The first outside connection 11 is as a connection plate 36 formed that the stationary contact part 15th wearing. The second outside connection 12 is as a connection plate 37 formed with the spring part 17th is electrically connected, this is a first leg 38 has on which the movable contact part 16 is consolidated.

The spring part 17th also has a second leg 39 on that is parallel to the first leg 38 runs and a laterally protruding side wing 41 has, which when assembled in contact with the second connection plate 37 got.

When assembling the switch 10 become the connecting plates 36 , 37 and on top of them the feather part 17th so between the top 18a and the lower part 18b of the insulator body 18th pinched that the connecting plates 36 , 37 laterally from the insulator body 18th stick out as shown in the top view of the assembled switch 10 in 4th can be seen.

The insulator body 18th is then converted into an in 2 recognizable flat housing 42 pushed that a top 43 and a bottom 44 has that over narrow sides 45 are connected to one another, the housing on one of its narrow sides 45 an opening 46 has and with this opening 46 on the insulator body 18th is plugged as it is in 3 can be seen.

The bimetal part 19th is as a bimetal disc 47 and the spring snap 33 as a spring snap disk 48 educated. Both discs have an edge 51 or. 52 on and are so in one on the lower outside 18c of the lower part 18b arranged, outwardly open recess 53 introduced that they are attached to circumferential abutments 25a or. 25b of the lower part 18th b support when the switch 10 closed is.

Into the recess 53 is a ring 54 inserted that the edges 51 , 52 overlaps radially inward and the abutment 26th forms on which the bimetal disc 47 and the spring snap disk 48 with their edges 51 or. 52 prop up when they hit the switch 10 to open.

Between the abutments 25th and 26th are the edges 51 and 52 guided with mechanical play so that the Bimetal disc 47 and the spring snap disk 48 can expand from its one to its other geometric configuration when it is snapped up.

The plunger 21st includes the shaft 29 with the lower tapered section 31 on which the bimetal disc 47 and the spring snap disk 48 with their respective through hole 55 or. 56 are attached with play.

After assembly, the ram runs 21st by that in the lower part 18b formed through hole 30th .

The head 27 is with a bolt 57 and the head 28 with a bolt 58 Mistake. The bolt 57 sits in an upper blind hole 61 in the shaft 29 , the bolt 58 in a lower blind hole 62 in the tapered section 31 .the heads 27 and 28 are opposite the bolts 57 and 59 as well as the shaft 29 executed wider in diameter.

The first leg 38 has a through hole 63 on with which he is on the bolt 57 is arranged with game.

This way are first legs 38 and bimetal disc 47 as well as spring snap disk 48 connected to each other under tension and pressure.

Will the plunger 21st when opening the switch 10 pressed upwards, it bends both legs 38 , 39 of the spring part 17th apart.

In 5 is a switch in a first embodiment of the present invention 10 ' and in 6 in a second embodiment of the present invention a switch 10 " shown, each in a representation as in 1 . The same reference symbols denote identical features with identical properties, so that due to the basic structure and the basic function, the above description of the 1 is referred.

The desk 10 ' out 5 has only the lower head 28 on over which the bimetal part 19th and the spring snap 33 so with the pestle 21st connected that they follow the arrow 32 in 5 move up and down if the bimetal part 19th and as a result also the spring snap part 33 snaps from its respective one to the other geometric configuration.

So although the head 27 absent, there is no risk of the plunger 21st tilted or jammed because it is in the through hole 30th guided.

The spring part 17th is at the top 20a of the ram 21st on so that it opens the switch 20a due to the combined pressure of the bimetal part 19th and spring part 33 is pushed up very quickly.

When the switch is closed 10 ' the bimetal part jumps 19th in his in 5 shown configuration and pulls the plunger 21st downward. Because the spring snap 33 also with the ram 21st is connected, it is initially there where the plunger 21st attacks on it, pressed down until it also enters its in 5 The other stable geometric configuration shown springs back.

Thereby the spring part 17th not active by the plunger 17th pulled down because of the head 27 out 1 is not provided here. Nevertheless, the switch closes 10 ' faster than a switch without forced coupling between the plunger 21st and bimetal part 19th as well as spring snap part 33 because of the plunger 21st is moved downward so quickly that it causes the closing movement of the spring part 17th offers no resistance.

At the switch 10 ' Thus, both the opening speed and the closing speed are increased compared with a switch in which only one bimetal part 19th is provided, which also not with the plunger 21st is forcibly coupled.

Because at the switch 10 ' on the head 27 is omitted, the assembly is also easier than with the switch 10 from the 1 to 4th .

When assembling the insulator body is first 18th joined together so that the two connection plates 36 , 37 and the spring part 17th between the top 18a and lower part 18b be pinched.

The plunger 21st is then over your head 28 captive with the bimetal part 19th and the spring snap part 33 connected, and this unit afterwards in 2 from below into the pre-assembled insulator body 18th , so in the recess 53 in the lower part 18b used. The plunger is thereby with its upper end 20a through the through hole 30th passed through and reaches its upper end 20a in contact with the first leg 38 .

At the switch 10 " out 6 is also on the lower head 28 waived. Another difference to the switch 10 and 10 ' is by the switch 10 " the bimetal part 19th below the spring snap part 33 .

Although both heads 27 , 28 are missing, there is also no risk of the plunger 21st tilted or jammed because it is in the through hole 30th guided.

When the temperature of the bimetal part 19th If it increases beyond its transition temperature, the bimetal part jumps 19th from the in 6 into its other geometric configuration. It presses in the middle of the spring snap-in part 33 , which is thereby gradually bent up in its center until it suddenly snaps into its other geometrically stable configuration and together with the bimetal part 19th the plunger in 6 suddenly pushes upwards.

The spring part 17th is at the top 20a of the ram 21st on so that it opens the switch 10 " also here through the combined pressure of the bimetal part 19th and spring part 33 is pushed up very quickly.

When the switch is closed 10 " the bimetal part jumps 19th in his in 6 configuration shown. The spring part 17th now presses over the plunger 21st on the spring snap part 33 and pushes this where the plunger 21st attacks on it, down until it also enters its in 6 The other stable geometric configuration shown springs back.

Thereby the spring part 17th so not actively by the plunger 21st pulled down because of the head 27 out 1 is not provided here either. Nevertheless the switch opens 10 " not only faster than a switch without a spring snap-in part 33 , it can also close faster with the appropriate design. This faster closing results because the bimetal part 19th due to the snapping of the spring snap part 33 is moved down so quickly that it hits the plunger 21st no longer opposes any resistance when this is caused by the closing movement of the spring part 17th all the way back down into its in 6 position shown is moved.

At the switch 10 " so at least the opening speed is increased compared to a switch in which only one bimetal part 19th is provided.

Because at the switch 10 " on the head 27 is omitted, the assembly is easier than with the switch 10 from the 1 to 4th .

First is the insulator body 18th assembled so that the two connection plates 36 , 37 and the spring part 17th between the top 18a and lower part 18b be pinched.

After that, the ram 21st with its upper end 20a through the through hole 30th passed through and reaches its upper end 20a in contact with the first leg 38 . Then the spring snap part will be 33 and then the bimetal part 19th into the recess 53 inserted.

Claims (20)

Temperature-dependent switch (10, 10 ', 10 ") with a first and a second external connection (11, 12), a stationary contact part (15) which is electrically conductively connected to the first external connection (11), and a stationary contact part (15) which interacts with the stationary contact part (15) movable contact part (16) which is fastened to a spring part (17) which is electrically conductively connected to the second external connection (12) and which presses the movable contact part (16) against the stationary contact part (15), a bimetallic part (19 ) and a plunger (21) arranged between the bimetal part (19) and the spring part (17), the bimetal part (19) pressing the plunger (21) against the spring part (17) and thereby the movable contact part (16) when a switching temperature is exceeded ) lifts off from the stationary contact part (15) in order to effect a switching process in which the switch (10, 10 ', 10 ") is opened, characterized in that the switch (10, 10', 10") also has a spring snap part (33) a It presses the plunger (21) against the spring part (17) at least when the switching temperature is exceeded and, together with the bimetal part (19), exerts a combined pressure on the spring part (17) in order to increase the dynamics of the switching process. Temperature-dependent switch after Claim 1 , characterized in that the spring snap part (33) and the bimetallic part (19) are arranged at a first end (20b) of the plunger (21) and the spring part (17) are arranged at a second end (20a) of the plunger (21). Temperature-dependent switch after Claim 1 or 2 , characterized in that the spring snap part (33) and the bimetal part (19) are connected to the plunger (21) in such a way that they transmit compressive and tensile forces to the plunger (21). Temperature-dependent switch after Claim 2 or 3 , characterized in that the plunger (21) has a shaft (29) which, at its first end (20b), has a tapered section (31) which carries a head (28) that is wider than the tapered section (31), wherein on the tapered section (31) the bimetal part (19) and the spring snap part (33) with their respective through hole (55, 56) are arranged in such a way that the bimetal part (19) and the spring snap part (33) with play between the head (28 ) and the shaft (29). Temperature-dependent switch after one of the Claims 1 to 4th , characterized in that the bimetal part (19) is arranged between the plunger (21) and the spring snap part (33). Temperature-dependent switch after Claim 1 or 2 , characterized in that the spring snap part (33) is arranged between the plunger (21) and the bimetal part (19). Temperature-dependent switch after one of the Claims 1 to 6 , characterized in that the bimetal part (19) is designed as an elongated tongue which is arranged on its opposite narrow sides (22, 23) between two abutments (25, 26) which extend in the longitudinal direction (24) of the plunger (21) opposite. Temperature-dependent switch after one of the Claims 1 to 7th , characterized in that the spring snap part (33) is designed as an elongated tongue which is arranged on its opposite narrow sides (34, 35) between two abutments 25, 26) which are opposite in the longitudinal direction (24) of the plunger (21) . Temperature-dependent switch after one of the Claims 1 to 6 or 8th , characterized in that the bimetal part (19) is designed as a bimetal disc (47) which is arranged at its edge (51) between two abutments (25a, 54) which extend in the longitudinal direction (24) of the plunger (21) opposite. Temperature-dependent switch after one of the Claims 1 to 7th or 9 , characterized in that the spring snap part (33) is designed as a spring snap disk (48) which is arranged at its edge (52) between two abutments (25b, 54) which extend in the longitudinal direction (24) of the plunger (21) opposite. Temperature-dependent switch after one of the Claims 1 to 10 , characterized in that the first and second external connections (11 12) are fixed to an insulator body (18). Temperature-dependent switch after Claim 11 , characterized in that the first and the second external connection (11, 12) are designed as first and second connection plates (36, 37), the two connection plates (36, 37) protrude from the insulator body (18), and the insulator body ( 18) is arranged in a housing (43). Temperature-dependent switch after Claim 12 , characterized in that the spring part (17) has a first and a second leg (38, 39), the movable contact part (16) is attached to the first leg (38), the second leg (39) is electrically connected to the second connection plate (37) is connected, and the plunger (21) is arranged between the first leg (38) and the bimetal part (19). Temperature-dependent switch after Claim 12 or 13 , characterized in that the housing (42) has an upper side (43) and an underside (44) which are connected to one another via narrow sides (45), and the housing has an opening (46) on one of its narrow sides (45) and with this opening (46) is plugged onto the insulator body (18). Temperature-dependent switch after Claim 13 or 14th , characterized in that the two legs (38, 39) are bent apart by the plunger (21) in order to interrupt a conductive connection between the two connecting plates (36, 37). Temperature-dependent switch after one of the Claims 13 to 15th , characterized in that the second leg (39) rests against the second connection plate (37). Temperature-dependent switch after one of the Claims 12 to 16 , characterized in that the insulator body (18) is composed of two partial bodies (18a, 18b), and the two connecting plates (36, 37) lie between the two partial bodies (18a, 18b). Temperature-dependent switch after one of the Claims 11 to 17th , characterized in that the bimetal part (19) is arranged in a recess (53) on an outer side (18c) of the insulator body (18). Temperature-dependent switch after one of the Claims 11 to 18th , characterized in that the spring snap part (33) is arranged in a recess (53) on an outer side (18c) of the insulator body (18). Temperature-dependent switch after Claim 18 or 19th , characterized in that a ring (54) inserted from the outside is provided in the recess (53), which serves as an abutment for the spring snap part (33) and / or the bimetal part (19).

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