DE2919208C2 - Thermostatic devices, in particular electric thermostatic switches - Google Patents

Description

The invention relates to a thermostatic device that works independently of the ambient pressure, in particular electrical thermostat switch, with the features of the preamble of claim 1 or of claim 4.

In a known thermostatic device of this type (DE-OS 22 11 126) is the first working space Enclosed by a corrugated pipe or the like, which is in a hermetically sealed, rigid-walled container its interior remaining outside of the corrugated pipe is arranged, the second working space forms. Since the end face of the corrugated pipe is not exposed to atmospheric pressure, one of Operation independent of this atmospheric pressure. Since the pressure in the first working space is below and the Pressure in the second working space is above atmospheric pressure and the spring against this is higher Pressure works, the actuating element moves to an end position corresponding to a maximum temperature, if the closed system leaks to the environment or to the second work area. In this end position a safety shutdown can be carried out.

This thermostatic device is dependent on the ambient temperature. Because since the Gas pressures in the first and second working space are at different levels, have an effect the same changes in the ambient temperature in the first and second working space due to different ones Pressure changes. Accordingly, the device works imprecisely.

It is also already known (GB-PS 10 89 926), the influence of the ambient temperature on a remote temperature display to be switched off by a working bellows connected to the sensor via a capillary tube on the side facing away from the display device with the movable end of a compensation bellows is connected, to which a capillary tube is connected, which runs next to the first-mentioned capillary tube.

The invention is based on the object of a thermostatic device of the type described at the outset Specify type that works largely independently of the ambient temperature.

In a first embodiment, this task is based on the features of the preamble of claim 1, solved by the features of the characterizing part of claim 1.

By using the additional adsorbent in the chamber of the closed system achieves that the steepness of the pressure-ambient temperature characteristic of the gas contained therein is amplified. This characteristic can therefore be compared to the characteristic in

second work space because of the prevailing there higher pressure is steeper. at The thermostatic device is also the same as that of the ambient temperature independent, i.e. only dependent on the sensor temperature.

Claims 2 and 3 are particularly advantageous Training for the chamber having the additional adsorbent.

In a second embodiment, based on the features of the preamble of Claim 4 solved by the features of the characterizing part of claim 4

The same advantages and the same function dependency apply to this as for the first exemplary embodiment. The only difference is that the actuating element is not in an upper temperature corresponding end position but moved into the end position corresponding to an undertemperature. This results in a Intrinsic safety for falling temperatures.

Claims 5 and 6 give preferred arrangements for receiving the additional adsorbent Chamber on.

There is a perfect match between the two slopes of the pressure-ambient temperature curves is only possible in a certain working point, but also in its closer environment the dependency from the ambient temperature is still so low that it can be allowed, one obtains by the Features of claim 7 a device which in its entire adjustment range of the ambient temperature is practically unaffected

The invention is explained in more detail below with reference to the drawings

F i g. 1 is a schematic representation of a device according to the invention Thermostat switch that is activated when a functional element breaks into an overtemperature condition corresponding end position goes

Fig.2 in a diagram the displacement of the Actuating element of Fig. 1 as a function of the sensor temperature at different ambient temperatures,

F i g. 3 to 5 other ways to accommodate the adsorbent,

F i g. 6 shows an alternative embodiment of one according to the invention Thermostat switch that is activated when a functional element breaks into a sub-temperature corresponding end position goes, and

F ί g. 7 shows another arrangement of the adsorbent.

In Fig. 1 illustrates a tub 1 with a bath 2 which is to be kept at a predetermined temperature T 1 by means of an electrical heating resistor 3. The actual bath temperature 7> is measured by a sensor 4. A microswitch 5 switches on the heating resistor 3 when the temperature falls _{below T 1} . It switches off the heating resistor 3 when this temperature is exceeded. An electrical thermostat switch 6 has a housing 7 with an actuating rod 8 which actuates the microswitch 5 with an arm 9 limited. The two pressure areas 10 and 14 are the same size. A coil spring 18 extending between the housing and the pressure surface 14 creates an upward force.

A coil spring 19 extending between the housing and a disk 21 adjustable by means of adjusting element 20 on the actuating rod extends, calls a downward force emerges and acts »Is

Range setting spring,

The sensor is filled with an adsorbent 22. An additional adsorbent 23 is located in the first working space 13, the sensor 4 and the working space 13 are connected to one another via a capillary tube 24

ίο and form a closed system, which also contains a superheated gas that is selected so that a pressure P \ prevails over the entire working range of the sensor temperature in the first working space 13, which is below the atmospheric pressure P _0. Active carbon is used as the adsorbent, Molecular sieves and the like come into consideration Low-boiling liquids such as carbonic acid, butane, ethane or the like come into consideration as the gas. The second working space 17 is filled with a gas, such as nitrogen, which has a pressure P ₂ above atmospheric pressure Po over the entire range of fluctuations in the ambient temperature T _u

The forces exerted on the actuating rod 8 by the springs 18 and 19, by the pressure P \ in the first working space 13 exerted on the pressure surface iO and by the pressure Pi in the second working space 17 acting on the pressure surface 14 result in an equilibrium position. This shifts over the distance s depending on the sensor temperature 7>. If the bath temperature rises, it shifts

jo actuating rod 8 upwards, if the bathing temperature falls, the actuating rod 8 shifts below.

With this construction not only the atmospheric pressure P _{0 has} no influence on the thermostat, but also the ambient temperature 7 " _L. If this ambient temperature rises, the pressure P ₂ in the second working space 17 increases more than the pressure P \ of the gas in the first Working space 13, if the additional adsorbent 23 were not present there.

This means that despite the lower pressure P \ in relation to the pressure P _2, the pressure increase, which is dependent on the ambient temperature, is approximately the same in both working spaces. This can be done for a specific temperature setpoint T _s

-) 5 pretty accurate by measuring the amount of additional adsorbent 23 reach.

In Fi g. 2, the bath temperature characterized by the sensor temperature 7} is plotted over the path s of the actuating member 8. The target value T ₅ can be adjusted within the range B. Three characteristics of the thermostat switch are plotted as a function of the ambient temperature T _11. The characteristic curve T ₁₁ \ corresponds to a room temperature of +20 ⁰ C, the characteristic line 71.2 to an elevated temperature of, for example +70 ⁰ C and the characteristic curve T _u j a very low temperature for example, -30 ° C. The amount of additional adsorbent * 23 is chosen so that these characteristics meet at switching point s 1 when the target temperature T i is exceeded

μ becomes. If the setpoint is adjusted within the range, all curves shift up or down, but the common point remains approximately in the range of switching point s 1. If the thermostat switch 6 is intended for a completely different area, it is expedient to provide a different amount of the additional adsorbent 23 from the outset.
In Figure 3 is a chamber 25 for receiving the

Adsorbent 23a is arranged in the capillary tube 24 in the vicinity of the working space 13. In FIG. 4, a chamber 26 for receiving the adsorbent 23b is connected to the working space 13 via a short connector 28. In Fig. 5, a chamber 27 for the adsorbent 23c is directly connected to the working space 13.

In Fig. 6 are the parts corresponding to FIG. 1 denoted by reference numerals increased by 100 in each case. It is essential here that the adsorbent 123 is located in the second working space 117 that in the first Working chamber 113 is overpressure and there is negative pressure in the second working chamber 117, and that consequently, if the corrugated pipe 111 or the corrugated pipe US breaks, the actuating rod 8 in that position goes, that of the lowest temperature

ι corresponds to. Here, too, are temperature-dependent Changes in pressure in the first working space 113 due to the use of the adsorbent 123 in the second Work area 117 compensated.

In the embodiment according to FIG. 7 is a

provided in chamber 127 for receiving the adsorbent 123a, which is directly attached to the second Work area 117 adjoins.

For this purpose 2 sheets of drawings

Claims (5)

Claims; \, A thermostatic device that works independently of the ambient pressure, in particular an electrical thermostat switch, with an actuating element that is actuated by a spring, through the pressure acting on a pressure surface in a first working space which, together with a sensor, forms a closed system containing an adsorbent, and through the pressure in a second working space, the pressure area of which has the same effective size as the pressure area of the first working space, is loaded, the filling of the sensor being selected so that the pressure in the first working space is below atmospheric pressure in the entire temperature working range of the sensor lies, and the second working space is filled with a gas that has a pressure above atmospheric pressure in the entire range of the ambient temperature, characterized in that the closed system apart from the? Adsorbent (27) located in the sensor (4) in a chamber (13, 25, 26, 27) exposed to the ambient temperature, additional adsorbent (23, 23a, 230, 23c) to adapt the steepness of the pressure-ambient temperature curve of the first working chamber to the steepness of the pressure Has ambient temperature curve of the second working space 2. Device according to claim 1, characterized marked m characterized in that the chamber the additional adsorbent (23) having formed by the first working space (13). 3. Device according to adjustment? Jch 1, characterized in that the V (25, 26, 27) having the additional adsorbent (23a, 236, 23c) is always arranged in the immediate vicinity of the first working space (13) 4. The thermostatic device that works independently of the ambient pressure, in particular an electrical thermostat switch, with an actuating element that is actuated by a spring, by the pressure acting on a pressure surface in a first working space which, together with a sensor, forms a closed system with an adsorbent forms, and is loaded by the pressure in a second work space, the pressure area of which has the same effective size as the pressure area of the first work space, characterized in that the filling of the sensor is chosen so that the pressure (Pi) in the first work space in the entire temperature working range of the sensor is above atmospheric pressure (Po) that the second working space (117) is filled with a gas that has a pressure (Pt) below atmospheric in the entire range of the ambient temperature (T ") Pressure (Po) has, and that in a connected to the second working space, exposed to the ambient temperature Ka Always (117, 127) additional adsorbent (123, 123a) is provided to adapt the slope of the pressure-ambient temperature curve of the second working space to the slope of the pressure-ambient temperature curve of the first working space (FIG. 6 and 7). 5. Apparatus according to claim 4, characterized in that the additional adsorbent (123) having chamber through the second Work space (117) is formed, 6, device according to claim 4, characterized in that that the additional adsorbent (J23aj having chamber (127) in the immediate Near the second working space (117) is arranged 7, device according to one of claims 1-6, characterized in that the amount of additional adsorbent (23) is chosen so that there is a complete adjustment of the slopes of the pressure ambient temperature approximately in the middle of the adjustment range (B) Curves results