DE29816653U1 - Circuit breaker with thermal tripping - Google Patents

Description

Protective switching device with thermal release

The invention relates to a protective switching device with a thermal release for actuating a switch arranged in a conductor network.

Such a protective switching device is usually used to protect a conductor network and electrical devices connected to it against overload. A bimetal part through which the mains current flows is often used as a thermal release. The ohmic power converted by the mains current in the bimetal part causes the bimetal part to heat up. Due to the different coefficients of thermal expansion of the two metal components, this heating causes the bimetal to bend. The bimetal part is arranged in such a way with respect to the latch of a switch lock that, as a result of its deformation, which increases with temperature, it releases the latch at a specified release temperature. The release temperature corresponds to the nominal current specified by the device manufacturer, which is a measure of the triggering sensitivity of the protective switching device.

With small nominal currents, it is practically impossible to heat the bimetal part directly by the current flow, since the resistance required for the required heating is either impossible or difficult to achieve. It is therefore usual to indirectly heat the bimetal part with a thermal release with a small nominal current using an externally applied heating coil. The bimetal part must be separated from the heating coil by insulation. Such an indirectly heated bimetal part is complex in design and correspondingly costly.

98 G3704

A further disadvantage of a thermal release with a bimetal part is that the bimetal part must be provided with a relatively large deflection space in order to prevent the bimetal part from blocking over the entire possible temperature range. This temperature range extends from approximately -50 ⁰ C storage temperature to a trigger temperature of approximately 130 ⁰ C. If the bimetal part were to block on an adjacent part of the protective switching device, plastic deformation of the bimetal part would be expected, which would change the trigger temperature in an unacceptable manner. The deflection space required for this temperature range must be provided by the design and thus limits the space available for other functions.

It is also common practice to use a flexible cable to supply power to a bimetal part, especially an indirectly heated bimetal part, in order not to restrict the freedom of movement of the bimetal part. The use of a flexible cable is disadvantageously difficult to handle in terms of production technology and is also costly and susceptible to wear.

The invention is based on the object of creating a protective switching device with a structurally simple and space-saving thermal release, which is particularly suitable for a small nominal current.

This object is achieved according to the invention by a protective switching device with the features of claim 1. According to this, the trigger comprises a memory element which, when a predetermined triggering temperature is exceeded, forms from a normal position into a predetermined memory position. When formed, the memory element triggers the latching of a switch lock.

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In contrast to a bimetal part, which continuously deforms when the temperature changes, the memory element assumes a fixed memory position above the trigger temperature. If the temperature falls below the trigger temperature or bending back temperature again, the memory element either returns to its original position automatically (two-way effect) or can be brought back to a defined normal position using an external force (one-way effect). This process can be repeated as often as required.

The change in shape of the memory element when the temperature changes below or above the trigger temperature is, however, negligible. So-called memory metal is particularly suitable as a material for producing the memory element, as described, for example, in "Brockhaus, Natural Sciences and Technology", Volume 3, Brockhaus (1983) on page 244.

Due to the two defined positions of the memory element, the deflection space provided for it can be kept comparatively small, especially since blocking of the memory element is impossible. The thermal release is therefore advantageously designed to be particularly space-saving. Since the memory element is rigid in normal operation, a particularly simple design of the release relay is also possible.

Preferably, a heating element through which current flows is provided for heating the memory element. The heating element is connected to the memory element in a thermally conductive manner at a connecting surface. Such a heating element can be produced inexpensively. The heating element is expediently designed to be rigid, which results in a particularly simple and stable construction.

In a preferred further development, the memory element is designed as a memory strip which runs straight in the normal position and which in its memory position runs along a

GR 98 G 3704

Bending edge is angled. In this shape, the memory element is easy to implement and saves space. In addition, the strip shape is good for rapid heat transfer due to the large surface area with a relatively small thickness. This means that the memory strip has a particularly fast switching time. Rapid heat transfer is also supported by the fact that the memory element in the normal position rests against the heating element over its entire length.

A strip-shaped heating element made of a conventional resistance material is used to achieve good heat transfer to the memory element at low cost. By connecting the heating element to rigid electrical leads on both sides, a stable and low-wear construction is easily achieved.

In order to avoid a thermal influence of the supply line on the memory element, the connecting surface is expediently spaced away from the connection points of the supply lines. In particular, the connecting surface is arranged approximately in the middle between the contact points of the two supply lines.

If the memory element is designed in such a way that it exhibits the one-way effect described above, a return spring is preferably provided, which easily bends the memory element back into the normal position when the temperature falls below the trigger temperature. If a memory element exhibits the two-way effect is used, this return spring is not required, especially since the memory element automatically assumes the normal position.

An embodiment of the invention is explained in more detail below with reference to a drawing. In the drawing: 35

FIG 1 schematically shows a

Protective switching device with a thermal release

GR 98 G 3704 · .·· "..". .". .'

and with a switch lock and a switch, and

FIG 2 shows the thermal release according to FIG 1 in a schematic representation.
5

The protective switching device 1 shown in FIG 1 comprises a thermal release 2 which is connected to the current-carrying conductor L of a conductor network LN. In addition to the current-carrying conductor L, the conductor network LN comprises a neutral conductor N. The release 2 is connected to a switch lock 4 via a mechanical latch 3.

If the current I flowing through the conductor L - and thus through the release 2 - exceeds a predetermined trigger value, the release 2 releases the latch 3 of the switch mechanism 4. The triggering occurs at a trigger value of the current I that slightly exceeds the nominal current of the protective switching device 1 on which the dimensioning of the protective switching device 1 is based. After the latch 3 is released, the switch mechanism 4 actuates a switching mechanism 5, which in turn opens the switching contacts 6 of a switch 7 acting on the conductors L, N of the conductor network LN. The switch mechanism 4 is also provided with an externally accessible actuating element 8, e.g. a lever or a button, via which the switching mechanism 5 and the latch 3 can be operated manually.

According to FIG 2, the thermal trigger 2 comprises a strip-shaped heating element 10 made of a conventional resistance material. The heating element 10 has a contact point 11 and 12 for two electrical supply lines 13 and 14 at each of its longitudinal ends. The supply lines 13, 14 are part of the current-carrying conductor L of the conductor network LN. Approximately in the middle between the two contact points 11 and 12, the contact element 10 has a connecting surface 15, via which the heating element 10 is connected mechanically and thermally to a memory strip 16.

GR 98 G 3704 .; ." .*·..·'. ·"··!*■

In its normal position SN, the memory strip 16 lies flat against the heating element 10, so that there is surface contact between the memory strip 16 and the heating element 10 over the entire length of the memory strip 16. The memory strip 16 is provided with a holding means 18 on its free end 17 opposite the connecting surface 15. This holding means 18, which is designed as a nose-like projection in the manner of a latch or a locking hook, is in engagement with the latch 3 of the switch lock 4.

The current I flowing through the heating element 10 heats the heating element 10 to a temperature T due to its high ohmic resistance. Due to the close contact of the memory strip 16 with the heating element 10, and in particular due to the good heat-conducting connecting surface 15, the memory strip 16 takes on the temperature T of the heating element 10 with only a slight time delay. If the current I exceeds a predetermined trigger value, a corresponding trigger temperature is exceeded in the memory strip 16. At this trigger temperature, the memory strip 16 suddenly changes shape from the normal position SN to a predetermined memory position SM. In the memory position SM indicated by dashed lines, the memory strip 16 has an angled shape along a bending edge 19. The free end 17 is spread apart from the heating element 10 during the shaping process along the shaping path W. The holding means 18 is moved along with the spreading of the free end 17, whereby the latch 3 of the switching lock 4 is released.

The memory strip 16 shown functions according to the so-called one-way effect. The memory strip 16 loses its elastic dimensional stability when the temperature T falls below the trigger value or bending back value. The memory strip 16 therefore does not bend back automatically from the memory position SM to the normal position SN.

GR 98 G 3704 J ,*· /\ .**

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For this reason, the trigger 2 includes a schematically indicated return spring 20, which applies a spring force F to the free end 17 in the direction of the normal position SN. The spring force F is dimensioned in such a way that it causes the contact strip 16 to bend back into the normal position SN when the trigger temperature or a bending back temperature is undershot, without preventing the contact strip 16 from forming into the memory position SM when the trigger temperature is exceeded. Alternatively, a contact strip 16 that functions according to the so-called two-way effect can be used. The contact strip 16 bends back automatically when the bending back temperature is undershot. In this case, the return spring 20 is not required.

After resetting the contact strip 16 to the normal position SN, the protective switching device 1 can be switched on again manually. The switching contacts 6 of the switch 7 are closed. At the same time, the latch 3 of the switch lock 4 engages in the reset holding means 18. The protective switching device 1 is then ready for operation again.

Claims (8)

GR 98 G 3704 Protection claims 1. Protective switching device with a thermal release (2) for Actuation of a switch (7) arranged in a conductor network (LN), wherein the trigger (2) comprises a memory element (16) which, when a predetermined trigger temperature is exceeded, changes from a normal position (SN) to a predetermined memory position (SM) and thereby unlocks a switch lock (4) coupled to the switch (7). 2. Protective switching device according to claim 1, characterized by a heating element (10) through which current flows, which is thermally conductively connected to the memory element (16) at a connecting surface (15). 3. Protective switching device according to claim 1 or 2, characterized in that the memory element is designed as a memory strip (16) which runs straight in the normal position (SN) and which is angled along a bending edge (19) in its memory position (SM). 4. Protective switching device according to claim 2 or 3, characterized in that the heating element (10) is designed as a strip consisting of a resistance material, which is connected on both sides to rigid electrical supply lines (13, 14). 5. Protective switching device according to one of claims 2 to 4, characterized in that the memory element (16) is mechanically connected to the heating element (10) at the connecting surface (15). 6. Protective switching device according to claim 2 to 5, characterized in that the memory element (16) in the normal position (SN) rests against the heating element (10) over its entire length. GR 98 G 3704 .1 ♦" ·"::": 7. Protective switching device according to claim 4 or 5, characterized in that the connecting surface (15; from the contact points (11, 12) of the supply lines (13, 14) on the Heating element (10) is spaced apart. 8. Protective switching device according to one of claims 1 to 7, characterized by a return spring (20) counteracting the formation of the memory element (16) for bending the memory element (16) back into its normal position (SN) when the temperature falls below a bending temperature