EP0151226A1 - Thermostatic switch - Google Patents

Abstract

A temperature switch has an expansion element (7), which consists of a metal alloy, in which a martensitic structural transformation occurs in the work area, where the phases involved, austenite and martensite, ordered lattice structures and the smallest possible shape difference. The expansion element preferably has the shape of a helical compression spring which is supported on the one hand against a bottom surface (9) of the housing (1) of the temperature switch and on the other hand against a plunger (4). This plunger (4) is used to actuate a snap switch mechanism (3) by means of which a switch contact (5) can be moved against a fixed contact (6) or can be switched away from it.

Description

The invention relates to a temperature switch with an expansion element, which causes a change in path and force under the influence of a change in temperature, for actuating a switching contact.

Temperature switches of this type are required in technology for a very large number of applications, for example as control switches or warning switches, and are generally known. Wax is often used as an expansion element in a wax chamber sealed by a membrane. Such a design brings with it problems of tightness of the wax kettle and requires a very high uniformity of the membrane so that there are no falsifications of the measured values.

Temperature switches with thermal bimetal as an expansion element are also very common. Such temperature switches lead to adjustment and stability problems which are caused by the relatively small path changes of the thermal bimetal when the temperature changes. The invention has for its object to develop a temperature switch of the type mentioned, dpr is easy to manufacture and the expansion element deforms as much as possible under the influence of temperature.

This object is achieved according to the invention in that the expansion element consists of a metal alloy in which a martensitic structural transformation occurs in the working area, the phases - austenite and martensite - having ordered lattice structures and the smallest possible shape difference.

Such metal alloys have been known for some time under the term "homogeneous shape memory alloys" (MemoryMetall) and do ten times more work in the temperature range that is decisive for most applications than the expansion elements of the temperature switches currently in use. The main material of the expansion element according to the invention is usually copper. Due to structural changes, the shape of the expansion element is reversibly changed depending on the temperature. The orderly lattice structure of the material means that when the deformed martensite is heated, the atoms can only form the austenite phase through certain movements. This results in the restoration of the original high temperature form. Through targeted material treatment, a desired low-temperature shape can be specified and thus a reversible shape change behavior can be achieved.

Thanks to the use of such materials as an expansion element according to the invention, the problems encountered with previous temperature switches with wax or with a bimetal, in particular the sealing problem with wax and the adjustment and stability problem with bimetal tall, be avoided.

An advantageous embodiment of the invention is that the expansion element is supported against a plunger which bears against a snap switch mechanism which actuates the switch contact. Such an embodiment is particularly suitable as a control switch for large outputs. The snap mechanism and the plunger can be used unchanged from previous temperature switches with a wax kettle.

Particularly large changes in the travel of the expansion element in the event of a change in temperature are achieved if the expansion element is a helical compression spring which is fixed to the housing on the one hand and supported against the plunger on the other.

An alternative embodiment is that the expansion element has the shape of a leaf spring, which is supported on both ends of the housing, and rests on its opposite side between the support points against the plunger.

A particularly simply constructed temperature switch is produced when the expansion element is a material strip clamped on one side, which carries at its free end a switch contact that can be moved by bending the expansion element against a fixed contact.

A temperature switch which is very insensitive to impacts and which can be adjusted simply and precisely with regard to its switching point arises when the expansion element is held by a positioning spring against a stop which limits the open position of the temperature switch. Such temperature switches are particularly suitable for use in motor vehicles.

A particularly compact temperature switch is obtained when the expansion element bears against an axially displaceable contact carrier on which the switch contact movable against the fixed contact is provided.

The switching point of the temperature switch can be precisely adjusted in a simple manner if the temperature switch has the features specified in claim 9.

Due to the features specified in claim 10, the temperature switch is particularly simple in construction. Furthermore, it can be assembled very quickly.

• Figur 1 einen Längsschnitt durch eine erste Ausführungsform eines erfindungsgemäß gestalteten Temperaturschalters,
• Figur 2 einen Längsschnitt durch eine zweite Ausführungsform eines erfindungsgemäß gestalteten Temperaturschalters,
• Figur 3 einen Längsschnitt durch eine dritte Ausführungsform eines erfindungsgemäß gestalteten Temperaturschalters.

The invention allows numerous design options. To clarify its basic principle, three of them are shown in the drawing and are described below. Show it

• FIG. 1 shows a longitudinal section through a first embodiment of a temperature switch designed according to the invention,
• FIG. 2 shows a longitudinal section through a second embodiment of a temperature switch designed according to the invention,
• 3 shows a longitudinal section through a third embodiment of a temperature switch designed according to the invention.

The temperature switch shown in Figure 1 has a housing 1 which has an external thread 2 and can be screwed into a bore, not shown, with a thread. In the upper part of the housing 1 there is a snap switch mechanism 3 which can be actuated by a plunger 4 and through which a switch contact 5 can be moved against a fixed contact 6 or away from it.

The plunger 5 is moved by an expansion element which has the shape of a helical compression spring 7. This helical compression spring 7 is enclosed in a cylindrical working space 8 and is supported on the one hand against a bottom surface 9 of this working space 8 and on the other hand against the plunger 4.

Due to the rise in temperature, the helical compression spring 7 increases in height, so that the plunger 4 is raised and the snap switch mechanism 3 is actuated, which leads to the switching contact 5 being abruptly seated on the fixed contact 6. Sinks. Temperature again, then the helical compression spring 7 deforms back, so that a switching process takes place in the opposite direction.

The temperature switch according to FIG. 2 is similar to a thermal bimetal switch. Instead of a thermal bimetal, however, a material strip 10 is clamped on one side in the housing 11 of the temperature switch as the expansion element. This strip of material 10 carries at its free end a switch contact 12 which, when the strip of material 10 is deformed, can be moved against a fixed contact 13, which leads to the closing of a circuit. It is essential for the invention that the material strip 10 is held by a likewise leaf-shaped positioning spring 14 against a stop 15 fixed to the housing, which limits the open position of the temperature switch. By means of this positioning spring 14, which is clamped roughly like the material strip 10 on one side in the housing 11, the temperature switch is insensitive to shocks such as occur in vehicles.

In the embodiment according to FIG. 3, just like that according to FIG. 1, a helical compression spring 7 is provided as an expansion element in a housing 1. This is also seated on the bottom surface 9 of the housing 1, but is not supported on a plunger but on an axially displaceable contact carrier 16. This contact carrier 16 has a switching contact 17, which is electrically connected to the housing 1 via the contact carrier 16 and the helical compression spring 7.

A pin 18 is guided coaxially to the contact carrier 16 into the housing 1 and is held by an insulating body 19 so that it has no electrical connection to the housing 1. The lower end face of this pin 18 is designed as a fixed contact 21, against which the switching contact 17 can be moved by the helical compression spring 7.

A compression spring 20, which is supported against the insulating body 19 and the contact carrier 16 on the side opposite the helical compression spring 7, is used for the exact setting of the switching point.

The most important feature of the invention for all embodiments is that the expansion element consists of a material with reversible, temperature-dependent deformation behavior. In the two embodiments of the invention, the pressure of the expansion element resulting from expansion is used to actuate a switching mechanism. However, embodiments are also conceivable in which torsion or tension are used as the driving force.

Claims (10)

1. Temperature switch with an under the influence of a temperature change causing a displacement and force change expansion element for actuating a switching contact, characterized in that the expansion element (helical compression spring 7, material strip 10) consists of a metal alloy, in which a martensitic structural change occurs in the work area, wherein the phases involved - austenite and martensite - have ordered lattice structures and the smallest possible shape difference. 2. Temperature switch according to claim 1, characterized ^q ekenn- that the expansion element is supported against a plunger (4) which bears against a snap switch mechanism (3) actuating the switch contact (5). 3. Temperature switch according to claim 1 or one of the following, characterized in that the expansion element has the shape of a helical compression spring (7). 4. Temperature switch according to claim 1 or one of the following, characterized in that the helical compression spring (7) on the one hand fixed to the housing, on the other hand, is supported against the plunger (4). 5. Temperature switch according to claim 1, characterized in that the expansion element has the shape of a leaf spring which is supported with both ends fixed to the housing and bears on its opposite side between the support points against the plunger (4). 6. Temperature switch according to claim 1 or one of the following, characterized in that the expansion element is a material strip (10) clamped on one side, which carries at its free end a switching contact (12) movable by bending the expansion element against a fixed contact (13). 7.Temperature switch according to claim 6, characterized in that the expansion element is held by a positioning spring (14) against a stop (15) limiting the open position of the temperature switch. 8. Temperature switch according to claim 1, characterized in that the expansion element (helical compression spring 7) bears against an axially displaceable contact carrier (16) on which the switching contact (17) movable against the fixed contact (21) is provided. 9. Temperature switch according to claim 8, characterized in that on the opposite side of the helical compression spring (7) of the contact carrier (16) a compression spring (20) is supported, which on the other hand rests against the housing (1) of the temperature switch. 10. Temperature switch according to claim 9, characterized in that the fixed contact (21) is formed by a coaxial to the switching contact (17) in the housing (1) projecting relative to the housing (1) isolated pin (18).

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