EP2282320A1 - Bimetallic snap disc - Google Patents

Abstract

The disc has an arched main element (1) whose arch extends in one direction and snaps in opposite direction under influence of temperature change. The main element is provided with heating element formed by electrical conductor (2) provided directly on main element. The electrical conductor is embedded in an insulting layer and in the form of conductor strip.

Description

The invention relates to a bimetallic snap disk according to the preamble of claim 1, with a curved main element whose curvature forms under the influence of temperature in the opposite direction. Furthermore, the invention relates to a switching element according to the preamble of claim 11, which has at least two switching contacts.

An abovementioned bimetallic snap disk is for example from EP 0 813 215 B1 known.

The known snap-action disc is installed in a temperature monitor and actuates a contact. The contact is actuated when the fixed temperature point of the bimetallic snap disk is reached, whereby it jumps from its convex shape to a concave shape.

It is also known to use bimetal domes as overcurrent release. That is, the bimetallic snap disk is used to open an electric circuit when the current in the circuit assumes an inadmissibly high value. For this purpose, a heating resistor is introduced into the circuit, which is usually arranged below the bimetallic snap disk. If an inadmissibly high current flows in the circuit, the heating resistor assumes a correspondingly high temperature, whereby the bimetallic snap disk is heated. By heating the bimetallic snap disk snaps from its convex shape into a concave shape, that is their curvature forms in the opposite direction. As a result, a regularly arranged at the highest point of the snap-action contact is moved, whereby the circuit is opened.

Bimetallic snap disk is understood to mean a metal disk consisting of two layers of different material, which is embossed in such a way that it has a curved curvature in different directions, which has a stable and a metastable state.

Although the known overcurrent shutdown also works substantially reliable, it still has the disadvantage that their structure is quite complex. Furthermore, the indirect heating of the snap disc their reaction is relatively sluggish.

It is an object of the invention to form an input called bimetallic snap disk and an input called switching element in such a way that they have improved properties with respect to current monitoring.

The solution of this problem arises from the features of the characterizing part of claim 1 and of claim 11. Advantageous developments of the invention will become apparent from the dependent claims.

According to the invention, a bimetallic snap-action disc with a curved main element, the curvature of which forms in the opposite direction under the influence of temperature, characterized in that a heating element designed as an electrical conductor is arranged on the main element.

Furthermore, according to the invention, a switching element having at least two switching contacts, characterized in that a switching contact on the main element of a bimetallic snap disk according to the invention is arranged.

Characterized in that on the main element designed as an electrical conductor heating element is arranged, the main element of the bimetallic snap disk no longer indirectly but directly heated. As a result, the reaction time of the bimetallic snap disk is significantly shortened. The reaction time of the bimetallic snap disk can be influenced by a suitable choice of material of the electrical conductor. Furthermore, by the direct arrangement of the electrical conductor on the main element of the bimetallic snap disk, the construction of a current monitor formed by means of a bimetallic snap disk is considerably simplified. In addition, the bimetallic snap disc is less sensitive to external influences, which has a very beneficial effect on the reliability of a particular overcurrent monitor. The direct mechanical connection of the electrical conductor to the main element of the bimetallic snap disk creates a compact element.

Advantageously, the electrical conductor is designed as a conductor track. As a result, the electrical conductor can be arranged in a simple manner on the main element of the bimetallic snap disk. The electrical conductor can be produced, for example, as a stamped part and fastened on the main part.

It is very advantageous if the electrical conductor is only then applied to the main element after it has already been embossed, that is, the curvature is already present. This has a very beneficial effect on the snap behavior of the snap disk. In particular, for example, the snap point can be set very precisely. The bimetallic snap disk may preferably be embossed by a special embossing process such as ring or dome embossing or single or multiple embossing so that as a result it has firmly defined snap temperatures T1 / T2. The temperatures result from the embossing process itself and the embossing depth and are specifically selectable for the respective desired application. On the already embossed disc, the electrical heating element is applied.

An embodiment of the invention in which the electrical conductor is embedded in a lacquer layer arranged on the main element is also very advantageous. By embedding the electrical conductor in the lacquer layer not only a reliable connection of the electrical conductor to the main element can be made in a simple manner, but also the electrical conductor is arranged on the main element electrically isolated. The insulation can also be done by means of an insulating film.

In particular, between the electrical conductor and the main element designed as a plastic film, polyimide film or aluminum foil insulating film which is connected, for example by means of an adhesive layer consisting of Pyraluxkleber firmly on the one hand firmly to the main element and on the other hand with the heating element. Alternatively, the insulation layer may consist of Meycoat bonded with acrylate adhesive or Dublocoll 384 TC Al foil. The connection of the insulating layer to the main element and the electrical conductor takes place in a special thermal process such that the layer structure under a pressure of about 2 tons to about 20 tons and a temperature of about 100 degrees Celsius to about 250 degrees Celsius are permanently interconnected ,

Due to the direct connection of the electrical conductor to the main element, there is a direct thermal coupling between the two elements. This results in an optimal and homogeneous heat transfer from the electrical conductor to the main element, resulting in a very rapid response in the event of an increase in current.

Particularly advantageous is an embodiment of the invention in which the electrical conductor extends over the region of the highest elevation of the main element and the resistance of the electrical conductor in the region of the highest elevation of the main element has its greatest value. This will achieve that the power loss of the electrical conductor in the region of the highest elevation of the main element has its greatest value, with the result that the heating of the main element in the region of its highest elevation is greatest. This has a very advantageous effect on the snap behavior of the main part.

The increase in the resistance of the electrical conductor in the region of the highest elevation of the main element can be achieved in a simple manner, for example, in that the cross section of the electrical conductor in the region of the highest elevation of the main element is less than outside the region of the highest elevation of the main element. Advantageously, the change in the cross section of the electrical conductor is effected by embossing or laser ablation.

Very advantageous in the latter embodiment, it is when the electrical conductor in the region of the highest elevation of the main element is annular, wherein the center of the ring is arranged on the highest elevation of the main element. As a result, the main element in the region of its highest elevation can be specifically heated symmetrically. This also has a very beneficial effect on the switching function of the bimetallic snap disk.

An embodiment of the invention has proved to be extremely advantageous in which the main element in plan view at least partially has the shape of two circular sections abutting one another with their chords, so that the chords of the circular sections extend in the direction of the greatest extent (length) of the main element form imaginary centerline of the main element. Such a shape, which is reminiscent of a biconvex lens, has the great advantage that it has a very good snap behavior when it is clamped at one end. For an arranged at the opposite end of the clamping switching contact leads when snapping the main element a relative large switching path, whereby the snap disk is well suited for opening a circuit.

Advantageously, the main element is flattened at the ends of its center line, whereby it has in plan view the shape of a barrel body in side view. This reduces the size of the main element, without this having a particularly adverse effect on the snap behavior of the main element.

Particularly advantageous is a bimetallic snap disk has been found in which the length of the main element from tip to tip is 1.4 to 3 times as large as the transverse to the center line of the main element extending width of the main element. In particular, the length of the main element is 2 to 2.75, preferably 2.5 times the width of the main element. If the main element is flattened at the ends of its center line, to calculate the length of the main element, the main element is theoretically supplemented by the omitted peaks and the length of the main element is then formed by the distance of the two imaginary tips.

Such a trained main element has the great advantage that distribute the material stresses in the main element very well, so that they have very little effect on the disposed on the main element electrical conductor.

In a further particular embodiment of the invention, it is provided that the main element has latching elements which, for example, protrude significantly beyond the shape of the previously described shaping. The locking elements are preferably symmetrical to the center line clearly on both sides of the main element. By locking elements can be achieved that the main element is prevented from snapping back snapping. For this purpose, the locking elements need only snap when snapping the main element with corresponding counter-elements, whereby the snap position of the main element is fixed. Such a bimetallic snap disk is very well suited for a so-called safety shutdown. Even after the main element has cooled down, the snap-action disc no longer assumes its original position.

The fact that in a switching element according to the invention, a switching contact is arranged on the main element of a bimetallic snap disk according to the invention, is achieved in an advantageous manner that a relatively fast interruption of a circuit can be achieved at overcurrent. Furthermore, the switching element according to the invention is designed very robust, which has a very advantageous effect on the reliability of the switching element.

Advantageously, arranged on the main element switching contact is connected to one end of the electrical conductor, wherein the other end of the electrical conductor forms the terminal of the switching contact. This achieves in a simple manner that the main element is heated by the current flowing through the switching contact. Since the electrical conductor is arranged isolated on the main element, no current flows through the bimetallic snap disk. A current flow and thus the heating of the main element is carried out exclusively by the electrical conductor, whereby the heating of the main element is controlled.

In a particular embodiment of the invention, a second heating element designed as an electrical resistor is arranged between the end of the electrical conductor forming the connection of the switching contact arranged on the main element and the switching contact not arranged on the main element. Since current only flows through the resistor when the switching element is open, the second resistor formed by the electrical resistance can Heating element serve to keep the main element at a temperature such that it does not snap back. In this way, similar to the locking elements, a permanent shutdown of the circuit can be achieved, but the main element snaps back when the power is turned off, that is, no current flows through the electrical resistance forming the second heating element.

In a further particular embodiment of the invention it is provided that the switching element is arranged in a housing which consists of a material insulated on at least one side, such as a plastic-coated sheet. As a result, a complete isolation of the switching element from the environment is achieved in a simple manner.

Advantageously, the housing is formed by folding a corresponding blank, wherein the edges of the blank are connected to each other by means of laser welding, for example. Such a housing can be very easily and thus produce cost. In particular, the housing is made waterproof in a simple manner.

Further details, features and advantages of the present invention will become apparent from the following description of a particular embodiment with reference to the drawings.

Fig. 1

eine erfindungsgemäß ausgebildete Bimetall-Schnappscheibe,

Fig. 2

eine Kontur der Draufsicht der in Figur 1 dargestellten Schnappscheibe,

Fig. 3

die in Figur 1 dargestellte Schnappscheibe von der Seite im Schnitt,

Fig. 4

ein erfindungsgemäß ausgebildetes Schaltelement in Seitenansicht im Schnitt,

Fig. 5

einen Schnitt durch das in Figur 4 dargestellte Schaltelement entlang der Schnittlinie A-A,

Fig. 6

eine zweite Ausführungsform einer erfindungsgemäß ausgebildeten Bimetall-Schnappscheibe,

Fig. 7

eine Kontur der Draufsicht, der in Figur 6 dargestellten Schnappschei- be,

Fig. 8

eine zweite Ausführungsform eines erfindungsgemäß ausgebildeten Schaltelements in Seitenansicht im Schnitt und

Fig. 9

einen Schnitt durch das in Figur 8 dargestellte Schaltelement entlang der Schnittlinie B-B.

It shows:

Fig. 1

an inventively designed bimetallic snap disk,

Fig. 2

a contour of the top view of FIG. 1 illustrated snap disk,

Fig. 3

in the FIG. 1 shown snap disk from the side in section,

Fig. 4

an inventively designed switching element in side view in section,

Fig. 5

a cut through the in FIG. 4 illustrated switching element along the section line AA,

Fig. 6

a second embodiment of an inventively designed bimetallic snap disk,

Fig. 7

a contour of the plan view, in FIG. 6 shown snippet,

Fig. 8

a second embodiment of an inventive design switching element in side view in section and

Fig. 9

a cut through the in FIG. 8 illustrated switching element along the section line BB.

As FIG. 1 can be removed, a bimetallic snap disk has a main element 1, which in plan view partially in the form of two with their tendons abutting circular sections, wherein the chords of the circular sections extending in the direction of the largest recess (length) of the main element 1 imaginary center line 1 'of the main element 1 form. The main element 1 is designed as a snap-action disc and has its highest elevation in the middle point 1c. At one end 1a of the main element 1, a tab 3 is connected to the main element 1 via a web 3b. The tab 3 has two openings 3b, for fixing the bimetallic snap disk.

On the main element 1 designed as a conductor electrical conductor 2 is arranged, which has a meandering course. The electrical conductor 2 has an annular portion 2 c, which encloses the highest elevation 1 c of the main element 1. The cross section of the electrical conductor 2 is reduced in the annular portion 2c, so that the resistance of the conductor 2 is greatest there.

At one end 2b of the electrical conductor 2, the electrical conductor 2 is connected to a switching contact 7, which is welded to the main element 1 and the one end 2b of the electrical conductor 2. The other end 2a of the electrical conductor 2 is formed as a tab and forms the electrical connection of the switching contact. 7

As FIG. 3 can be removed, a polyimide film 5 is disposed between the conductor 2 of the electrical conductor 2 and the main element 1, which is connected by means of a Pyraluxklebers 6 fixed to the main element 1. The conductor 2 is also connected by means of a Pyraluxklebers 6 fixed to the polyimide film 5.

The conductor track 2 can be applied to the main element in such a way that the material strip from which the main element 1 is separated and the material strip from which the conductor track 2 is separated, are guided in the blank and cleaned state into one and the same progressive compound tool. In addition, an insulating film provided with an adhesive layer on both sides is introduced into the progressive die. On the adhesive layers, a non-adhesive release film is applied in each case. The insulating film is applied to the material band from which the main element 1 is separated or to the main element 1. Before application, however, the main element 1 facing release film is peeled off the adhesive layer of the insulating film in question. When applying the insulating film to the main element is of the insulation film peeled off the second release film and then applied the conductor 2 to the insulation film. In an embossing station, the elements applied to one another are then connected to one another at a temperature of about 100 degrees Celsius to 250 degrees Celsius.

The conductor track 2 can also be embedded in a lacquer layer arranged on the main element 1. For this purpose, the main element 1 is coated in a preceding process by means of a lacquer. This layer serves exclusively as electrical separation. Another lacquer layer, which serves as a compound adhesive layer, is applied to this insulating layer in the wet state. Thereafter, the contour of the main element 1 from the strip material, from which the main elements are separated, separated.

The conductor 2 is produced in a corresponding manner. That is, the strip material of the electrical conductor is also coated in an upstream process by means of an insulating varnish. On this insulating varnish layer, a bonding adhesive layer is applied in the wet state. Thereafter, the contour of the trace of the electrical conductor is separated from the strip material.

In the tool in which the blanks take place, a module can be arranged which is thermally insulated from the rest of the tool. The module is heatable, so that the conductor of the electrical conductor in the module under a pressure of about 2 tons to 20 tons and a temperature of about 100 degrees Celsius to 250 degrees Celsius can be applied to the main element 1. The pressure depends on the area of the components to be pressed.

In both methods described above, a Nachheizstrecke and / or a UV irradiation can be performed. This has a very beneficial effect on the strength of the interconnected elements.

It has been found that the main element 1 has an optimum snap-action behavior when the width 1 "of the main element 1 is in a certain relation to the length of the main element 1. In order to calculate the ratio, in FIG. 2 extending in a radius, the side edges of the main element 1 continuously extended until the respective lines intersect. The extension is in FIG. 2 represented by dashed lines. The intersections of the extensions of the side lines form imaginary peaks 1a ', 1b'. The length of the main element 1 required for determining the ratio corresponds to the length of the center line 1 'from the imaginary tip 1a' to the imaginary tip 1b '. The length of the center line 1 ', that is, the theoretical length of the main element 1 required for calculating the ratio is 2.5 times as large as the width 1 "of the main element 1 extending transversely to the center line 1' of the main element.

Like that FIGS. 4 and 5 can be removed, the bimetallic snap disk with its tab 3 between an electrically non-conductive plastic existing elements 11 of a housing 10 a, 10 b is clamped. The housing 10a, 10b consists of a sheet 10a, which is coated on one side with plastic 10b. As a result, the housing 10a, 10b is electrically insulated on the outside. The housing 10a, 10b is produced by folding a corresponding blank and then preferably laser welding.

The plastic elements 11 are applied to the blank prior to folding the blank at the appropriate positions. They can be applied as separate parts to the blank or produced by injection molding at the relevant positions.

After the plastic elements 11 have been produced, the bimetallic snap disk is produced by means of an ultrasonic welding technique, clamping technology, embossing technique or pressing technique arranged on an element 11. By folding the housing, the bimetallic snap disk is then enclosed and, by virtue of the fact that the two plastic elements 11 face one another after folding, the bimetallic snap disk is pressed firmly against the housing. As a result, the bimetallic snap disk is extremely reliably fixed in position.

Between the connection of the arranged on the main element 1 switching contact 7 forming the other end 2a of the electrical conductor 2 and a housing attached to the switching contact 8, a resistor 9 is arranged, then flows through the current when the arranged on the main element 1 switching contact 7 not with the fixed to the housing switching contact 8 is in contact. In this case, the resistor 9 heats up, as a result of which the main element 1 is heated to such an extent that it remains in the position in which the two switching contacts 7, 8 are not in contact with one another.

In the FIG. 6 illustrated embodiment of a bimetallic snap disk according to the invention substantially corresponds to in FIG. 1 illustrated bimetallic snap disk. It differs only in that it has locking elements 4, which can be latched with retaining lugs 4 a, which are arranged in a housing of a switching element, as shown in FIG. 9 is shown. The locking elements 4 are arranged symmetrically to the center line 1 'of the main element 1 and are clearly visible from the main element 1. They are edge regions of the main element 1, which are created by a corresponding punching embossing. The retaining tabs 4a are connected to the plastic layer 10b of the housing and extend through an opening formed in the sheet 10a.

If the bimetallic snap disk heats up so that it changes its position, the locking elements 4 can latch with the retaining lugs 4a. This will prevent the bimetal snap-action disc from returning to its original position returns when she cools. The bimetal snap disc thus performs a one-time switching function corresponding to a fuse.

Since the bimetallic snap disk does not switch repeatedly, the switch contacts 7, 8 are riveted in the main element 1 or in the housing. This is possible FIG. 8 remove.

Like that FIGS. 8 and 9 can be removed, arranged on the housing switching contact 8 is arranged on a pedestal. The pedestal is made by stamping from the sheet metal wall 10a of the housing. Due to the height of the pedestal, the switching time of the switch formed by the arrangement can be adjusted.

Furthermore, the electrical conductor 2 extends almost over the entire surface of the main element 1 and is not meandering as in the first-mentioned embodiment. By required for the formation of the locking elements 4 sections of the main element and thus of the electrical conductor 2, the cross section of the electrical conductor 2 in the region of the locking elements 4, that is in the region of the highest elevation 1 c of the main element 1, whereby the resistance of the electrical conductor 2 is greatest there.

Claims (16)

Bimetallic snap-action disc with a domed main element (1), the curvature of which forms in the opposite direction under the influence of temperature,
characterized,
in that a first heating element designed as an electrical conductor (2) is arranged on the main element (1). Bimetallic snap disk according to claim 1,
characterized,
that the electrical conductor (2) is designed as a conductor track. Bimetallic snap disk according to claim 1,
characterized,
in that the electrical conductor (2) is embedded in an insulation layer arranged on the main element (1). Bimetallic snap disk according to claim 1 or 3,
characterized,
that the electrical conductor (2) extends over the region of the highest elevation (1 c) of the main element (1) and the resistance of the electrical conductor (2) in the region of the highest elevation (1 c) of the main element (1) its greatest value Has. Bimetallic snap disk according to one of claims 1 to 4,
characterized,
that the electrical conductor (2) has been applied to the main element (1) only after embossing of the curvature of the main element (1). Bimetallic snap disk according to claim 4 or 5,
characterized,
that the change in the resistance of the electrical conductor 2 is effected by embossing or laser ablation. Bimetallic snap-action disc according to one of claims 1 to 6,
characterized,
that the electrical conductor (2) in the region of the highest elevation (1c) of the main element (1) is annular, wherein the center of the ring (2c) on the highest elevation (1c) of the main element (1) is arranged. Bimetallic snap disk according to one of claims 1 to 7,
characterized,
that the main element (1) in plan view at least partially in the form of two with their tendons abutting circular sections, wherein the chords of the circular sections in the direction of the largest extension (length) of the main element (1) extending imaginary center line (1 ') of the main element (1) form. Bimetallic snap disk according to claim 8,
characterized,
in that the main element (1) is flattened at the ends (1a, 1b) of its center line (1 '), so that in plan view it has the shape of a barrel body in side view. Bimetallic snap disk according to claim 8 or 9,
characterized,
that the length of the main element (1) of possibly imaginary tip (1a ') to possibly imaginary tip (1b') 1.4 to 3, in particular 2 to 2.75, preferably 2.5 times as large as the transversely to the center line (1 ') extending width (1 ") of the main element (1). Bimetallic snap-action disc according to one of claims 1 to 10,
characterized,
that the main element (1) locking elements (4). Switching element which has at least two switching contacts (7, 8), characterized
in that a switching contact (7) is arranged on the main element (1) of a bimetallic snap disk according to one of Claims 1 to 9. Switching element according to claim 12,
characterized,
in that the switching contact (7) arranged on the main element (1) is connected to one end (2b) of the electrical conductor (2) and the other end (2a) of the electrical conductor (2) forms the connection of the switching contact (7). Switching element according to claim 13,
characterized,
in that a second heating element designed as an electrical resistor (9) is arranged between the other end (2a) of the electrical conductor (2) and the switching contact (8) not arranged on the main element (1). Switching element according to one of claims 12 to 14,
characterized,
in that it is arranged in a housing (10a, 10b) which consists of a metal sheet (10a) coated on at least one side with plastic (10b). Switching element according to claim 15,
characterized,
that the housing (10a, 10b) is formed by folding a respective blank and the edges of the blank by the laser welding are interconnected.

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