NO812386L - THERMOSTAT. - Google Patents

Description

The present invention relates to a thermostat, and in particular a thermostat for use in mixer taps in sanitary installations, equipped with a practically rigid enclosure, in which is placed an expandable mass that acts on a pressure pin over a membrane r Thermostats of this type are previously known where the expandable mass is enclosed in a rigid, cup-shaped capsule. Here, the expandable mass has the shape of a cylinder, and thereby the mass has a relatively small surface in relation to its volume. As a result of this form of construction and due to the relatively unfavorable thermal conductivity of the expandable mass, such thermostats have a large thermal inertia, i.e. they only react after they have been exposed to a certain temperature for a relatively long time, and of this For this reason, such thermostatic elements are not very suitable for mixer taps in sanitary facilities.

In order to achieve improved sensitivity and less thermal inertia in such thermostats, it has already been proposed in Norwegian patent application no. 81*1052 that the expandable mass is placed in a hollow body which is limited by two cylindrical surfaces, one inner and one outer, which lie coaxially inside each other, thereby forming a hollow, thin-walled cylinder, and where the transition to the membrane is designed v.hj.a. passages that connect the rooms inside and outside the hollow body with each other. This construction will probably reduce the thermal inertia, but the production and filling of the capsule is difficult and expensive to carry out.

The purpose of the present invention is therefore to provide a thermostat with great sensitivity and a small time constant, i.e. small thermal inertia, combined with great rigidity and precise deflection of the pressure pin, and especially in such a construction that these conditions can be achieved without large production costs . This problem is solved by designing the thermostat in accordance with the patent claims set out below.

The most important advantages achieved by a thermostat according to the present invention is that a large contact surface is obtained in relation to the volume of the expandable mass, so that temperature changes in the area surrounding the sensor element are quickly transferred to the expandable mass. The thermostat construction exhibits particularly high rigidity in the face of volume changes, and thereby achieves that small volume changes in the expandable mass are accurately transferred to the pressure pin via the membrane. Due to the thermostat element's large "volume stiffness", it is also possible to achieve a large amount of the displacement force produced by the thermostat.

The thermostat according to the present invention can be produced in a simple way, whereby the capsule and the lifting element can be attached to each other by previously known and proven methods which are currently used in the construction of units which are connected, e.g. with flange. In particular, cylindrical shell constructions which are connected by a cover and a membrane placed between these parts are believed to be advantageous. The sensor element, which can be designed as a coiled elongated member, e.g. a tube or a hose, can be rolled or soldered to the base of the cylindrical capsule.

The rolled-up tube can act as a temperature-tolerant element and can preferably be shaped as a flat or elongated spiral, which makes it possible to place the capsule and the sensor element in the mixing valve in many different ways, and regardless of the construction of the mixing valve, it will be possible to adapt the thermostat so that the sensor element can easily be placed in the desired temperature monitoring area.

By adapting an intermediate tube between the capsule and the rolled-up sensor tube, it is also possible to choose an optimal location of the rolled-up detection tube so that it fits together with the area where there is ready-mixed water in the battery.

To provide a clearer understanding of the present invention, reference is made to the detailed description below of some design examples, as well as to the accompanying drawings, where:

- Fig. 1 shows a thermostat in longitudinal section,

- Fig. 2 shows a differently designed thermostat in side view, partially cut through, and

*- Fig. 3 shows a further thermostat construction seen from the side

side and partially cut through.

For the sake of simplicity, corresponding or identical elements in the various constructions are given the same reference number.

In the embodiment shown in fig. 1, the thermostat consists of a centrally placed capsule 1 and a rolled-up tube 2 which is shown arranged in a flat or flat spiral shape around the capsule. The open end part 20 of the rolled-up tube is soldered coaxially into the bottom of the capsule's cylindrical bottom plate 10, while the other end part 22 (see figures 2 and 3) is closed.

The cylindrical shell 10 of the capsule is approximately cup-shaped in shape and is provided with a cylindrical opening which cooperates with a sealing element consisting of the membrane 3 and the cover 11. In the cover 11, a tubular part or neck is centrally formed which preferably functions as a cylindrical guide tube , and this is mounted so as to allow a longitudinal displacement of the push pin 4 with a mounted washer 5 resting on a protruding portion of the diaphragm 3. The two parts which are soldered together, the cylindrical shell 10 of the capsule and the rolled tube 2 can easily manner is filled with an expandable mass, e.g. alcohol or wax. Then the cover with the membrane, the pressure pin 4 and the disk 5 can be inserted into the capsule's cylindrical shell 10 and can be fixed by conventional and proven technique, e.g. v.hj.a. flanges so that a seal is achieved by a suitably shaped flange edge 12. The thermostat is then ready for use.

Fig. 2 shows a differently designed thermostat, where the rolled-up tube 2 is still spiral-shaped, but now as a cylindrical spiral, and is placed coaxially with the capsule 1. With such a construction as shown in fig. 3, an intermediate pipe system 23 is placed between the spiral-shaped pipe 2 and the capsule 1, and thereby it is achieved that the rolled-up pipe 2 can be placed in any desired position in relation to the capsule 1, thus allowing an optimal design of the detection element in relation to the design of the mixing chamber in the mixer tap.

The construction examples described above can, for example* be attached by means of a threaded part (not shown) on the outside of the central neck of the cover 11 and can thereby be screwed into a valve housing or they can be attached with a sleeve nut that encloses the capsule 1 If temperature changes now take place in the area around the rolled-up tube 2 which constitutes the thermostat detector when this is placed in position, the corresponding volume changes are directly transferred to the expandable mass and lead to an almost instantaneous deflection of the membrane 3 in accordance with the temperature in question in the detector zone and will thereby, via the pressure pin 4, influence the correction variable parameter in question, such as e.g. can be the piston position in a valve.

Claims (4)

1.: Thermostat, particularly for use in mixer taps in sanitary facilities, with a practically rigid enclosure, in which one expandable mass is placed which acts on a pressure pin over a membrane, characterized in that the enclosure is a two-part construction and consists of a relatively flat cup-shaped capsule (1)., which encloses the diaphragm (3) and the pressure pin (4), as well as a tubular or hose-shaped elongated member (2) which communicates with the enclosure (1), and which is mainly constructed as a temperature-tolerant element. 2. Thermostat according to claim 1, characterized in that the elongated member (2) is spiral-shaped or helical-shaped, and that its open end (21) is inserted into the enclosure (1) and is permanently connected thereto, while the other end part (22 ). is sealed. 3. Thermostat according to claim 1 or 2, characterized in that the elongate body (2) is arranged coaxially in relation to the enclosure (1). 4. Thermostat according to claim 1 or 2, characterized in that the elongated body (2) is connected to the enclosure (1) by means of an intermediate pipe section (23) which is designed so that the elongated body (2) can be placed in which any desired position in relation to the enclosure (1).