DE19801258A1 - Temp. dependent magnetic snap system, pref. for use as a room temp. regulator - Google Patents

Abstract

The system has a bimetallic element (4') whose position is determined by the attractive force of a permanent magnet (7) and the room temp. The element is connected to a contact spring which adopts first heating and second heating off or cooling on electrical contact positions. The transition between the positions is by a snap action resulting from the magnet's attractive force. A magnet with a large attractive force for a small vol. is mounted directly on the bimetallic element at a small, adjustable distance from a ferromagnetic stop (8) on a mounting plate (2).

Description

The invention relates to a temperature-dependent magnet snap system in which the positions of a bimetal through the attraction of a permanent magnet and by the ever because room temperature acting on the bimetal is determined are, the bimetal in such a way with a contact spring is mechanically connected that it is about transverse to the contact spring to their longitudinal direction either in a first electrical Contact position "heating" or in a second contact position relocated, this second contact position alternatively "Heating off" or an electrical contact position "cooling can be a ". This is due to the attraction of the permanent magnet the transition from one to the other Contact position with snap action (generic term of the An saying 1). Such magnetic snap systems are preferred with room temperature controllers for bimetal-controlled two-point regulation used. Under the above Concept of Schnappwir kung becomes a sudden change in position of the contact spring understood from one contact position to the other. A Such a magnetic snap system is known from DE 44 45 928 A1. It is formed at the free end of the strip  ten bimetallic an arm made of ferrometal brings. At a certain distance from one side surface this arm, the permanent magnet is provided, while the free end of this arm over a driver with the con clock spring is in a mechanical driving connection. The Size of the distance between the arm and the permanent magnet can be changed by a cam disc, which is based on the Bimetal strips act. This magnetic snap system has has proven itself functionally. This is disadvantageous connected, relatively large space requirement, and that many individual Components are provided that not only to enlarge the Space requirements contribute, but also the manufacturing costs increase.

From DE 296 17 781 U1 a magnetic switch is known, the Permanent magnet, as in the case of DE 44 45 928 A1, is attached to the base plate of the associated housing. In the document DE 296 17 781 U1 it is stated as a task to create a magnet for a switch that at extremely small dimensions a very large actuation force is able to apply, and which is also very easy to use Housing can be stored. There is an embodiment for this of the permanent magnet provided such that on the contact surface of the associated anchor both a north and a south pole are trained. This is disadvantageous in two ways lig. On the one hand, the manufacture of such magnets is appropriate very expensive. On the other hand, it has to be exactly on the assembly make sure that the permanent magnet is mounted on the side becomes. It is also disadvantageous that in a further embodiment tion of DE 296 17 781 U1 on the permanent magnet molded projections must be provided, which inserted and given in recesses of the circuit board if glued. This also increases the manufacturing cost most. Otherwise there are essentially the same Disadvantages as described in DE 44 45 928 A1.

The task or problem of the invention is  in contrast, the same advantageous snap function and operating force of the known magnetic switch to achieve an arrangement that, in contrast, a little has less space and requires fewer components.

To solve this problem, starting from the beginning ge called preamble of claim 1, first according to the Invention provided that a permanent magnet with a high magnetic attraction with a relatively small volume an attachment side directly on the bimetal is brought, and that he with his to the attachment side opposite or opposite side a short distance from a stop from a ferro magnetic material located on a mounting plate is attached, and that the above Distance by adjusting the Stop is changeable. It is downsizing the space requirement of the magnet in connection with its Attachment to the bimetal an extremely small snap system created, whose magnetic actuating force Operating forces of the previously known arrangements. Due to the very small mass of the magnet, it can be used without Impeding or slowing the resilient movement of the Bimetal can be attached to this. This is a we significant difference compared to the above State of the art, in which the permanent magnet is always from the bime tall spatially decoupled is attached to the housing. This not only results in a larger space requirement, but conditionally, that the bimetal always with a ferromagnetic plate or arm must be extended in order to be separated from the Magne attached to the base plate of the housing to be able to work together.

Claim 2 includes a preferred embodiment of the Permanent magnets that have a particularly high magnetic attraction power with very little space required.

The features of claim 3 are also preferred  te because of the simplified design of the bimetal. With the Erfin As can be seen from the previous explanations shows an extension of the bimetallic strip a separate strip or plate of soft iron ver be avoided, which in the above-mentioned state of Technology were required.

Further details and advantages of the invention are the e.g. T. schematic drawing. Herein shows:

Fig. 1 is a plan view of the open housing of a temperature controller, which is designed according to the invention,

Fig. 2 shows a section according to line II-II in FIG. 1.

Fig. 1 shows the plan view of a here approximately square housing 1 having a base plate 3 and an edge 3 '. The associated lid is not shown.

On a mounting plate 2 provided in the housing, an elastic bimetallic strip 4 is attached according to number 15 by means of an adjusting lever 16 . The band-shaped design of the bimetal in cross section can be seen from the number 4 'in Fig. 2. The bimetal 4 leads according to number 4 'in Fig. 1 viewed upwards to end in an arm 4 '', which is angled by about 90 ° relative to the area 4 ' of the bimetal. This arm 4 '' is connected to the electrical contact spring 5 's. In this preferred embodiment of the invention, the bimetal 4 , starting with its attachment 15 on the adjusting lever 16 over the area 4 'to the outer end of the arm 4 ''is in one piece. It is therefore only necessary to have a one-piece bimetal strip on which the permanent magnet can be glued. Depending on the prevailing temperature, the regions 4 ′ and 4 ″ pivot in the direction of the arrow 6 to the left or right (based on the illustration in FIG. 1).

The permanent magnet 7 is very small, plate-shaped in this example and is made of a material that gives a very high magnetic tensile force with a relatively small volume. In a preferred embodiment of the invention, this can be cobalt samarium. The permanent magnet 7 (see FIG. 2) is attached with its one large-area side 7 'to the area 4 ' of the bimetal, while its opposite large-area side 7 '' faces away from it even closer to one another at a short distance a descriptive stop 8 is located. The aforementioned attachment of the permanent magnet 7 can be done by inserting it into a correspondingly shaped recess provided in the bimetal. The permanent magnet can, for. B. be fixed by gluing in the recess. The permanent magnetization of this magnet is such that the side 7 'one pole, z. B. the north pole, and the other side 7 '' the other pole, e.g. B. South Pole. Thus, it is not necessary to pay attention to which polarity of the magnet comes into contact with the bimetal during assembly or production, since this is indifferent to the result achieved. The arrangement described above is characterized by a very small space requirement, since no special space requirement is required for accommodating the magnet. The stop 8 explained below can also be placed in the space already present above the adjusting lever 16 .

A possible embodiment of the invention in the configuration of the contact spring and its different contact positions is explained below. This execution is also shown in the drawing. The function and the different positions of the elastic and sliding contact spring 5 which can be pivoted back and forth by means of the bimetal 4 ', 4 ''in the direction of arrow 9 (see FIG. 1) is closer to the schematic illustration of FIG. 2 drawn on an enlarged scale remove. A heating contact 10 and a cooling contact 11 are each attached to the mounting plate 2 . Depending on the position of the contact spring 5, they are electrically connected to either their counter heating contact 10 'or counter cooling contact 11 '. A contact between the contacts 10 and 10 'corresponds to the first electrical contact position "heating" mentioned at the beginning. Furthermore, the position of the contact spring 5 in which contact is made between the contacts 11 'and 11 corresponds to a second electrical contact position of the contact spring, specifically in the alternative "cooling on". The other end of the contact spring 5 is connected to a terminal 12 of the control circuit.

The circuit in this example is such that the control is set to "heating" when the contacts 10 , 10 'are in contact with one another, the magnet 7 being very close to the ferromagnetic stop 8 , the gap a between the magnet and the stop is very small. When the temperature rises, the bimetallic section 4 'attempts to move to the left in the illustration according to FIG. 1, 2. However, it is initially prevented from doing so by the magnetic force between the permanent magnet 7 and the stop 8 . If the temperature continues to rise, however, the bending force generated in the bimetal is greater than the holding force of the magnetic connection 7 , 8 . The magnetic holding force is overcome and the bimetal section 4 'is moved to the left in a snap. He takes the contact spring 5 to the left via the arm 4 ″ until its contact 11 ′ comes into contact with the cooling contact 11 . At the same time, the contact connection 10 , 10 'was suddenly interrupted and the heating was switched off. The electrical contact between the contacts 11 and 11 'causes the connection of a cooling, for example a fan, which blows warm air out of the room in question and / or cool air into it. If the room cools down accordingly, this results in a bending force on the bimetal section 4 'to the right (always in relation to the illustration). With this movement of the bimetallic section 4 'to the right, the distance a between the permanent magnet 7 and the stop 8 is reduced until the magnetic force becomes so great that the heating position is reached again like a snap. This heating position is defined by the contact of the contact 10 'on the contact 10 fixed to the housing.

In a simplified embodiment, in the second contact position, the connection of a cooling system, ie the contacts 11 ', 11 , can be dispensed with. In this case, the heating is switched on only by a corresponding low temperature by the contact between the contacts 10 and 10 '(first electrical contact position), which is interrupted for a certain time when the room and thus the bimetal are heated accordingly. During this time, the contact spring 5 is in the position of the second contact position "heating off", in which none of the above-mentioned electrical contacts are connected to one another (not shown in the drawing).

The peripheral surface 8 'of the stop 8 has to its longitudinal central axis 13 a course which deviates from the circular shape. So it runs eccentrically to its longitudinal central axis. It is thus possible to increase or decrease the distance a by rotating the stop 8 about its longitudinal central axis 13 . With this, the switching temperature difference can be set, which is equal to the maximum temperature difference between "heating" and "cooling".

There is thus a very simple adjustment by the stop 8 , which is formed on its circumference as a cam bolt or eccentric and is rotatable on its mounting plate (printed circuit board) 2 about its axis 13 . The rotation takes place by engagement of a tool in an internal hexagon 14 . The adjustment can be done from above in the factory. This is much easier than from the side, ie in the direction of the plane of the mounting plate 2 . The slope of the outer surface of this cam pin or the offset of the above eccentric can be designed so that a very sensitive adjustment is possible.

The abovementioned stop 8 consists of a ferromagnetic material. It can be designed as an extrusion. This allows a very precise tolerance of the eccentricity of its outer surface. A soft iron material is particularly suitable for this.

All features shown and described as well as their Combinations with one another are essential to the invention.

Claims (8)

1. Temperature-dependent magnetic snap system, in which the positions of a bimetal are determined by the attractive force of a permanent magnet and by the respective room temperature acting on the bimetal, the bimetal being mechanically connected to a contact spring in such a way that the contact spring either transversely to its longitudinal direction either in a first electrical contact position "heating" or in a second electrical contact position, wherein this second contact position can alternatively be "heating off" or an electrical contact position "cooling on", the transition from one to the other due to the attraction of the permanent magnet Contact position takes place under Schnappwir effect, characterized in that a permanent magnet net ( 7 ) with a high magnetic attraction force at a relatively small volume with an attachment side ( 7 ') is attached directly to the bimetal ( 4 '), and that it is attached to the attachment side opposite Now lying or facing side ( 7 '') is at a short distance (a) from a stop ( 8 ) made of a ferromagnetic material, which is attached to a mounting plate ( 2 ), and that the above distance by adjusting the Stop is changeable. 2. Magnetic snap system according to claim 1, characterized with a permanent magnet made of cobalt samarium. 3. Magnetic snap system according to claim 1 or 2, characterized in that the strip-shaped bimetal ( 4 , 4 ', 4 '') is in one piece and is from a fastening supply ( 15 ) on an adjusting lever ( 16 ) to a middle section ( 4 ') extends to which the permanent magnet ( 7 ) is attached and that at the end of this section Mittelab an arm ( 4 '') of the bimetallic strip is located, which is angled to the central section and is in a mechanical operative connection with the contact spring ( 5 ) . 4. Magnetic snap system according to claim 3, characterized in that the permanent magnet ( 7 ) in a section in the bimetal section ( 4 ') provided center and, for. B. is fixed by gluing. 5. Magnetic snap system according to one or more of claims 1 to 4, characterized in that the impact ( 8 ) is designed as an extrusion. 6. Magnetic snap system according to claim 5, characterized in that the stop ( 8 ) consists of soft iron. 7. Magnetic snap system according to one or more of claims 1 to 6, characterized in that the approximately round rod-shaped stop ( 8 ) has a lateral surface ( 8 ') which extends eccentrically to the longitudinal central axis ( 13 ) of the stop ( 8 ) and that one Adjustment ( 14 ) of the stop ( 8 ) about its central longitudinal axis ( 13 ) is provided such that the size of the distance (a) of this lateral surface ( 8 ') from the opposite permanent magnet ( 7 ) is adjustable. 8. Magnetic snap system according to one or more of the claims 1 to 7, characterized in that a mounting plate ( 2 ) is located within a housing ( 1 ), preferably attached to it, the carrier of the aforementioned components of the magnetic snap system, such as the stop ( 8 ) is the holding means of the bimetal ( 4 ) and the contacts.