WO2010118842A1

WO2010118842A1 - Thermal tripping device and installation switch apparatus having a thermal tripping device

Info

Publication number: WO2010118842A1
Application number: PCT/EP2010/002228
Authority: WO
Inventors: Peter Pfirrmann; Ralf Weber; Alexander Orban
Original assignee: Abb Ag
Priority date: 2009-04-15
Filing date: 2010-04-09
Publication date: 2010-10-21
Also published as: CN102439679A; CN102439679B; DE102009017100A1; EP2419915A1; DE102009017100B4

Abstract

The invention relates to a thermal tripping device (1), particularly for an installation switch apparatus, comprising a thermo-mechanical converter (2) which has a current carrying heater band (3) wrapped around for indirect heating, and wherein the heater band (3) is held spaced from the thermo-mechanical converter (2). Thus the production is simplified and the variation of the thermal tripping current is diminished.

Description

Thermal release and service switching device with a thermal release

description

The invention relates to a thermal release, in particular for a service switching device, with a thermo-mechanical converter, which is wrapped for indirect heating with a current-carrying heating band.

Such thermal triggers are used in particular in circuit breakers or motor protection switches as overload triggers. When a certain, above a predetermined nominal current overcurrent occurs, the thermo-mechanical converter bends so strong that it acts on a rear derailleur so that the service switching device permanently turns off.

There are directly heated and indirectly heated thermal releases. In direct heating, the current flows through the thermo-mechanical converter itself, so that the thermo-mechanical converter lies directly in the main current path to be monitored.

If electrical isolation between the thermo-mechanical converter and the main current path is desired, indirect heating is used. In indirect heating, the thermo-mechanical converter is wound with a heating coil through which the current flows. Such an indirectly heated thermal release with a thermomechanical transducer made of bimetallic strip is shown for example in DE 100 02 773 A1 as a trigger of a motor protection switch. There, the heating element is wound as a wire on the bimetallic strip.

In order to achieve an effective heat transfer between the bimetallic strip and the heating conductor, it is known to punch the heating element as a heating band of sheet metal and to fold it around the bimetallic strip around and press against the bimetallic strip. The result is a surface contact between the bimetallic strip and the heating conductor, which causes a more efficient heat transfer than by a round heating wire on the bimetallic strip. Between the bimetallic strip and the heating tape is then an electrical insulation, usually in the form of an insulating film or an insulating braid surrounding the bimetallic strip or the sheet of heating coil and electrically isolate from each other over the entire contact surface between the bimetallic strip and the heating tape. Such a thermal release is shown for example in DE 10 2004 054 176 A1. The application of this insulation, for example in the form of a thin film or a thin tube, is expensive to install. The heat transfer from the heating tape to the bimetallic strip is carried out mainly by heat conduction through the electrical insulation layer and can therefore be limited. In particular, it can in the production of a large number of the same thermal triggers to an increased spread of the thermal tripping current and thus the tripping characteristic of different triggers come within a production lot, which is undesirable.

Nevertheless, a good and reproducible heat transfer between the

To reach bimetallic strip and the heating tape, the heating tape is pressed over a large area on the surrounded with insulation bimetallic strip. Because of the resulting large-area contact of the bimetallic strip with the heating band, the deflection of the bimetallic strip can be restricted or hindered, which is undesirable.

Based on the solutions known in the prior art, it is therefore desirable to provide an indirectly heated thermal release, which has a good heat transfer between the heating tape and the thermo-mechanical converter with a simple mounting option. It is a further object of the present invention to provide an improved service switching device.

The object of providing an improved indirectly heated thermal release is achieved by a thermal release with the features of claim 1. With respect to the service switching device, the object is achieved by an installation switching device according to claim 7. Further developments of the aforementioned objects are set forth in the subclaims.

According to the invention, therefore, the heating tape is kept at a distance from the thermo-mechanical converter.

The term thermomechanical transducer is used herein to generally refer to a transducer made of materials that under the influence of temperature Change shape. In addition to the known bimetals, which are formed from the combination of two metals, each with different coefficients of thermal expansion, shape memory alloys are also intended to fall under this term in particular. These are metals that change over from a certain temperature from a first mold to a second mold. In an advantageous embodiment, generic thermomechanical transducers are designed as metal strips clamped on one side, which consist, for example, of bimetallic strip or shape memory metal and bend perpendicular to their broad side when heated. There are also known thermomechanical transducer in the form of a snap disc, which consists of bimetallic strip or of a shape memory alloy, and which transforms when heated from a first stable mold layer via a dead center in a second stable mold position, wherein the forming when exceeding a certain critical Deformation can be said to occur very quickly, so that it can be said that there is a "snapping-in" between the two stable forming layers For the sake of simplicity, in this application, if a specific material is mentioned, instead of "bimetallic or shape memory metal" only Spoken "thermobimetal".

Thus, according to the invention, there is air between the heating tape and the thermo-mechanical converter, that is, for example, a bimetallic strip, the heating tape is not pressed onto the bimetallic strip. The heating tape is according to the invention rather pushed over more or less loosely over the bimetallic strip. The bending of the bimetallic strip is no longer limited by the heating tape. The heat transfer between the heating tape and the bimetallic strip is effected by convection, mainly by heat radiation, and to a lesser extent in still air via heat conduction.

In order to realize a compact structural unit of a thermal release, according to an advantageous embodiment of the invention, the thermomechanical transducer is designed as a cantilevered metal strip of bimetallic or shape memory metal and the heating tape is connected in the region of the clamping of the bimetallic strip with the bimetallic strip.

With regard to the spacing of the heating tape from the thermomechanical transducer, an advantageous embodiment of the invention is characterized in that coupled to the thermo-mechanical transducer at least one insulating support member against which the heating tape and by which the heating tape is kept spaced from the bimetallic strip. This is particularly advantageous if the heating tape itself has a low rigidity. The heating tape surrounds this Thermobimetal in the manner of a basket, which is why in the context of the invention is also spoken by a heating basket. The support member may for example be a plastic part, which is snapped onto the bimetallic strip and thereby fixed there, advantageously in the region of the free end of the bimetallic strip.

In order to achieve a good heat transfer between the heating band and the thermomechanical transducer, according to an advantageous embodiment of the invention, the opposing surfaces of the thermomechanical transducer, for example a strip of bimetallic strip, and the heating tape are painted. By a surface treatment such as painting, the heat transfer can be improved by thermal radiation between the side facing the bimetallic strip of the heating tape and the bimetallic strip. For example, the radiation emission coefficient of a painted metal surface is up to 20 times higher than a bare metal surface.

According to a further very advantageous embodiment of the invention, a very good heat transfer can also be achieved in that the opposing surfaces of the thermo-mechanical transducer, for example a strip of bimetallic strip, and the heating tape are coppered. The copper layer oxidizes when heated, which further supports the heat transfer. Also, a copper-plated and subsequently oxidized metal surface has a higher emission coefficient than a bare metal surface.

Of course, all further, in principle known surface treatment methods of the invention are also included, which lead to an increase of the radiation emission coefficient of the treated surface.

In order to reduce the heat loss to the outside, according to a further advantageous embodiment of the invention, the assembly comprising the thermo-mechanical converter and the heating band is surrounded by an insulating sheath, which is kept spaced from the heating tape.

An installation switching device according to the invention comprises at least one Verklin- kungsstelle and a thermal release, a thermomechanical transducer, for example, a cantilevered Thermobimetallstreifen comprises, which is wrapped for indirect heating with a current-carrying heating tape, wherein the heating tape from the thermo-mechanical converter, for example Bimetal strip is kept spaced, and which deflects when a certain current in the heating band is exceeded so that it thereby the Verklin- kung place unlatched.

Figures and description serve to better understand the subject. Articles or parts of objects which are substantially the same or similar may be given the same reference numerals. The figures are merely a schematic representation of an embodiment of the invention.

Showing:

1 schematically shows a first embodiment of a thermal release according to the invention with a heating tape wound around in a meandering manner, FIG. 1a schematically shows a second embodiment of a thermal release, with a heating band surrounding the bimetallic strip in a U-shape, FIG. see trigger, with a one-sided attached to the bimetallic strip

heating tape

Fig. 2 Schematically a second embodiment of a thermal release, Fig. 3 Schematically a third embodiment of a thermal release according to the invention, and Fig. 4 Schematically a fourth embodiment of a thermal release according to the invention.

Fig. 1 shows in a thermal release 1 with an elongated strip 2 of a bimetallic strip, it could also be a strip of shape memory alloy. At its one end 4, the strip 2 in the installed position in a service switching device, for example, in a circuit breaker or a motor protection switch, clamped, which is why this end is also referred to as clamping point. The bimetallic strip 2 is meander-like surrounded by a heating tape 3. The heating tape 3 is punched out of a flat, elongated metal sheet and wound around the band around the thermobimetal strip 2 in a meandering manner. The heating tape does not touch the bimetallic strip 2, it is spaced from him, there is air between the bimetallic strip 2 and the heater 3. At the clamping point 4 of the bimetallic strip 2 is connected to the heater 3 via a conductor piece 9. It could also be the heater 3 welded directly to the bimetallic strip 4 without the interposition of a conductor piece. In one For example, in an installation switching device, the current of the main current path flows on its way from the input terminal to the output terminal via the conductor piece 9 and the heating coil, whereby the heating coil is heated. The heat of the heating coil 3 passes mainly by radiation from the inside of the heating coil 3 on the bimetallic strip 2 and heats it. Due to the heating of this is perpendicular to its broad side, here in Fig. 1 So perpendicular to the plane bend, and indeed the stronger, the warmer it becomes. When exceeding a critical current, the deflection is so strong that the bimetallic strip 2 can unlatch with its operating end 6 a Verklinkungsstelle in a derailleur of the service switching device. The operating end 6 acts either directly on the Verklinkungsstelle, or it interacts with a lever or a lever system and thus indirectly affects the Verklinkungsstelle.

At the opposite end of the clamping free end of the bimetallic strip 2 is a support member 5, here a plastic sleeve 5, pushed onto the bimetallic strip on which the heating tape 3 is supported. The plastic sleeve 5 thus acts as an insulating support member. It ensures that the heating tape 3 and the bimetallic strip 2 remain kept at a distance from each other, even if the heating tape is a little less stiff. The assembly of the heating tape 3 and the support member 5 is also referred to as a heating basket, since it surrounds the bimetallic strip 2 in the manner of a basket. The support member 5 may be additionally latched to the bimetallic strip 2 or the heater 3 or pushed on pressing, so that it is held on the bimetallic strip and does not move even when bending the same.

The bimetallic strip 2 can bend unaffected by the heating tape 3, since the heating tape 3 is not pressed against the bimetallic strip. To improve the heat transfer between the heating tape 3 and the Thermobimet- tallstreifen 2, the facing surfaces of both elements are painted, for example, black or in another color, or copper and then oxidized, or otherwise surface treated. This increases the emissivity of the surfaces. The production of a thermal release according to the invention is simplified because it does not have an electrically insulating sheath more be applied to the bimetallic strip 2 or the heating tape 3. The electrical insulation of both parts is ensured by the spatial distance.

A variant of the embodiment of FIG. 1, Fig. 1a. Here, the wrapping of the bimetallic strip 2 with the heating tape 3 is achieved so that the heating tape 3 surrounds the bimetallic strip 2 in the manner of a unilaterally open envelope U-shaped.

A further variant of the embodiment according to FIG. 1 is shown in FIG. 1 b. Here, the wrapping of the bimetallic strip 2 with the heating tape 3 is achieved so that the heating tape 3 rests on one side of the bimetallic strip 2 spaced.

The embodiment of a thermal release according to the invention shown in FIG. 2 differs from that shown in FIG. 1 in that a thermally insulating sheath 7 is arranged around the assembly comprising the heating tape 3 and the support part 5. This keeps a distance from the heating tape 3 and the bimetallic strip 2, but it could also be applied close to the heating tape 3. The sheath 7 may be made of a plastic or of a ceramic foil or a thin ceramic tube, or of a textile or glass material, in solid or perforated execution, or other heat-insulating material or composite material. It increases the efficiency of heat transfer from the heating tape 3 to the bimetallic strip 2 by keeping the heat radiated outwardly from the heating tape 3 inside the heating basket.

The embodiment of a thermal release according to the invention shown in FIG. 3 differs from that shown in FIG. 1 in that an insulating sheath 8 is applied around the thermobimetal strip 2. This embodiment shows that a thermal release according to the invention can also be constructed with electrically insulated bimetallic strips. In addition, the electrically insulating sheath 8 may still have a high emission coefficient and therefore support the heat transfer from the heating tape 3 to the bimetallic strip. The embodiment shown in FIG. 4 of a thermal release 11 according to the invention differs from that shown in FIG. 1 in that a snap disk 41 is provided as a thermomechanical transducer, which consists of a bimetal or a shape memory alloy. It is held at their edges in clamping points 41. Schematically it is shown that the snap-action disc 21 is coupled to an actuating part 61, in this case a plunger, with which it interacts with the latching point of the service switching device in which it is fitted when it snaps over due to the heating. The snap disc 21 is shown in FIG. 4 in its first stable shaping position, in which the side coupled to the plunger 61 is concavely curved. If the current through the heating band 31 exceeds a predetermined value and the heating of the snap-action disc then a critical temperature, the snap disc 21 snaps into its second stable shape position in which the coupled to the plunger 61 side then convex, here in Fig. 4th to the left, will be arched. The plunger 61 is then pushed to the left and can interact with the Verklinkungsstelle the rear derailleur of the service switching device for permanent unlatching.

LIST OF REFERENCE NUMBERS

1 thermal release

2 bimetal strips

3 heating tape

4 clamping point

5 support part

6 actuation end

7 insulating sheath

8 insulation

9 conductor piece

11 Thermal release

21 snap disk

31 heating tape

41 clamping point

61 actuating part

Claims

claims

1. Thermal release (1), in particular for a service switching device, with a thermomechanical transducer (2), which is wrapped for indirect heating with a current-carrying heating tape (3), characterized in that the heating tape (3) of the thermo-mechanical converter (2 ) is kept at a distance.

2. Thermal release (1) according to claim 1, characterized in that the thermo-mechanical converter from a cantilevered metal strip

Bimetal or a shape memory alloy comprises and the heating tape (3) in the region of a clamping point (4) of the metal strip (2) with the thermo-mechanical converter (2) is connected.

3. Thermal release (1) according to claim 1, characterized in that with the thermo-mechanical converter (2) at least one insulating support member (5) is coupled to which the heating tape (3) is applied and by which the heating tape (3) of the thermomechanical transducer (2) is kept at a distance.

4. Thermal release (1) according to claim 1, characterized in that at least one of the opposing surfaces of the thermo-mechanical transducer (2) or the heating tape (3) is surface-treated to improve the heat transfer.

5. Thermal release (1) according to claim 4, characterized in that at least one of the opposing surfaces of the thermo-mechanical transducer (2) or the heating tape (3) is painted to improve the heat transfer.

6. Thermal release (1) according to claim 4, characterized in that at least one of the opposing surfaces of the Thermobimetallstrei- fens (2) or the heating tape (3) is copper plated to improve the heat transfer.

7. Thermal release (1) according to claim 1, characterized in that the assembly comprising the thermo-mechanical transducer (2) and the heating tape (3) with an insulating sheath (7) is surrounded.

8. Installation switching device with a Verklinkungsstelle and with a thermal release (1), which comprises a cantilevered thermo-mechanical converter (2) which is wrapped for indirect heating with a current-carrying heating tape (3), wherein the heating tape (3) of the thermomechanical see converter (2) is kept spaced, and which bends when a certain current in the heating band is exceeded, thereby unlatching the Verklinkungsstelle.

9. Installation switching device according to claim 8, wherein the thermal release is designed according to one of claims 2 to 6.