SE502895C2 - temperature sensor - Google Patents

Abstract

A temperature sensing device adapted to bring about an actuating movement of a control valve, e.g. for a heating element. The device comprises a heat insulating housing (2) with a closed fluid chamber (5), which is filled with a fluid having a high coefficient of volume expansion and which is enclosed externally by a heat conducting casing (4) and internally by an elastically stretchable diaphragm (7). The diaphragm abuts a piston (9), which is displaceable in a sleeve body (6, 6') in the housing (2). The piston and the surrounding sleeve body (6, 6') form a continuous abutment surface for the diaphragm (7), wherein the central portion (7f) of the diaphragm (7) continuously abuts the end surface of the piston (9) and follows the movements of the piston while being stretched. The various parts of the device are preferably made of a polymer material.

Description

15 20 25 30 35 502 895 safety function at elevated temperatures and to enable environmentally friendly material choices.

The stated main object is achieved by means of a temperature sensing device designed in accordance with claim 1, while the stated secondary objects are achieved by devices according to claim 8 resp. claim 6.

By the design according to claim 1, an efficient and rapid heat transfer to the entire liquid volume, despite relatively small dimensions of the device as a whole, can be achieved and achieve a relatively large axial movement of the actuator, in the form of a piston, while the elastic extensibility of the membrane material is used in an advantageous manner.

The working area of the piston is in the vicinity of a gable end surface of a surrounding sleeve body, and the membrane is preferably stretched in different directions in resp. end position. The device thus has good temperature sensitivity, and furthermore the heat-insulating housing provides a good shielding against heat radiation and heat conduction from the nearby heating medium.

The design according to claim 2, with internal flanges, grooves or grooves on the inside of the cover, provides particularly good heat transfer and temperature sensitivity.

The device according to claim 6, with details of polymeric material, entails a low manufacturing cost for larger series and an environmentally friendly product.

The further development according to claim 8, with a sleeve biased by a safety spring, provides a good safety function, whereby the elongation of the membrane up to and including can be reduced as the sleeve shifts at elevated temperatures.

Further advantageous features will become apparent from the following detailed description of two embodiments of the invention, with reference to the accompanying drawings. Fig. 1 shows a central longitudinal section through a first embodiment of the temperature sensing device according to the invention; and Figs. 2a, 2b, 2c show central longitudinal sections through a second embodiment of the temperature sensing device according to the invention, the device being shown in three different positions corresponding to three different temperatures.

The temperature sensing device shown in Fig. 1 is intended to be placed on a control valve (not shown) for a heating medium, e.g. water in a heating radiator for regulated room heating.

It is assumed here that the control valve of the heating element is adjustable to the desired setpoint and is actuated by an operating rod 1 projecting axially from the temperature sensing device, the control valve (not shown) being arranged to actuate the control rod 1 with a spring force which seeks to push the control rod 1 into the temperature sensing device according to Fig. 1, the temperature sensing device comprises a solid, cylindrical housing 2 of polymeric material, from one end of which the control rod 1 projects axially from a central, cylindrical cavity 3 and whose other end connects to a cup-shaped cover 4 of heat-conducting polymeric material, for example a polyolefin, a closed chamber 5 being formed between the inside of the housing 4 and the solid, heat-insulating housing 2.

The housing 2 has a sleeve part 6 projecting axially in the direction of the inside of the housing 4, which is enclosed by a membrane 7 of an elastically stretchable material, in particular a thermoelastomer.

The membrane 7 is sealingly fitted at its radially outer part with a radially projecting flange 7a between a shoulder 4a and a ring 8 enclosing a sleeve part 6, likewise made of polymeric material. From the flange 7a and an adjoining lip 7b, which abuts against the inside of the housing 4, the diaphragm 7 extends radially inwards during abutment against the ring 8 and passes via a rounded portion to an axially extending portion 7c, which abuts 502 895 towards the outside of the sleeve part 6 of the housing 2 The housing part 6 has a rounded edge portion 6a, and the membrane follows this edge portion with a rounded portion 7d, which merges into a flat portion 7e with a central part 7f, which is kept abutting against the end surface 9a of a the cylindrical cavity 3 displaceable piston 9. The inner end 1a of the operating rod 1 is fitted in a central recess 9b in the opposite end of the piston 9.

As can be seen from Fig. 1, the closed chamber 5 thus consists of an annular part Sa radially outside the sleeve part 6 and the portion 7c of the membrane, and a central part 5b between the flat portion 7e, 7f of the membrane and the end portion 4b of the housing 4.

The closed chamber 5 is pre-filled with a wax-like material or a liquid, e.g. an organic ester, with a large coefficient of volume expansion, so that as the temperature of the ambient air outside the housing 4 increases, heat will be transferred through the heat-conducting material of the housing 4 to the liquid, which expands and exerts an increasing pressure on the membrane 7. central part 7f to displace the piston 9 and the control rod 1 to the left in Fig. 1, against the action of a spring force generated by the control valve (not shown). When the piston 9 is displaced to the left, the central part 7f of the diaphragm will reach the plane of the planar portion 7e of the diaphragm and then be stretched inwards into the cavity 3 while constantly abutting against the end surface 9a of the piston 9.

Since the central part 7f of the membrane 7 in the exemplary embodiment shown is extended in opposite directions in the initial stage, at low temperature, resp. in the final stage, at a higher temperature, the elongation capacity of the membrane material is utilized in the best possible way to achieve as great a stroke as possible of the piston 9, when this is displaced within its working range.

The heat transfer from the outside of the housing 4 to the wax or liquid in the chamber 5 is particularly good in that the housing 4 is provided on its inside with axially distributed, axially extending grooves 10, which considerably enlarge the effective area of the interface between the housing material and the wax or liquid. The grooves 10 can alternatively be designed as insertion grooves or flanges. The essential thing is that the inside of the cover has a large effective area. In the drawings, only one groove 10 is shown. In practice, a plurality of such grooves are distributed circumferentially.

In the manufacture of the temperature sensing device according to Fig. 1, the constituent details of polymeric material are injection molded, whereby the membrane 7 and the ring 8 can optionally be produced by double injection. Alternatively, the ring 8 and the membrane 7 are joined after the injection molding, e.g. by ultrasonic welding. The unit consisting of the membrane 7 and the ring 8 is then joined to the cover 4 in a suitable manner, e.g. by welding or gluing. Then the chamber 5 is filled with wax or liquid by inserting two fine needles through a pin 7g projecting axially through the ring 8. The liquid is supplied through one needle, while air is evacuated through the other. Then the holes for the needles are closed and the unit consisting of the ring 8, the membrane 7 and the cover 4 is joined to the housing 2, e.g. by gluing.

Finally, the piston 9 and the control rod 1 are inserted into the central cavity 3.

The second embodiment of the temperature sensing device according to the invention shown in Figs. 2a, 2b and 2c differs from that described above in that the sleeve portion 6 of the housing 2 is replaced by a separate sleeve 6 'axially displaceable in a widened central cavity 3', which controls internally the piston 9 and the control rod 1 in a manner corresponding to Fig. 1. The sleeve 6 'is biased towards the position shown in Fig. 2a by means of a strong compression spring 11, one end of which abuts the end wall of the housing 2 and the other end of which is inserted into an annular recess 12 in the sleeve 6 'and abuts against the bottom of the recess 12 in the vicinity of the end of the sleeve 6' abutting the membrane. A radially projecting flange 6'a abuts against a stop lug 8a on the ring 8 and thus holds the sleeve 6 'in a well-defined position according to Fig. 2a.

As the temperature rises and the wax or liquid in the chamber 5 expands, the diaphragm 7 will displace with its central part 7f the piston 9 and the control rod 1 to the left, as shown in Fig. 2b. In this case, the sleeve 6 'is still kept in its right end position under the influence of the strong spring 11. It can be seen that the central part 7f of the diaphragm 7 is in this case strongly stretched during abutment against the end surface of the piston 9, whereby the extended, central part 7f of the diaphragm becomes substantially thinner.

With further temperature increase, for example to temperatures around about 1OUC or more, the wax or liquid in the chamber 5 will expand further and act with great compressive force on the entire membrane 7. The possibility of the piston 9 moving further to the left is limited, and with increasing compressive force on the membrane 7, the sleeve 6 'will instead be displaced axially to the left against the action of the spring 11; Fig. 2c shows how the sleeve 6 'has been displaced to the left, the membrane 7 following under the influence of the liquid pressure in the chamber 5. Despite the increasing pressure, the elongation of the membrane 7 is reduced by the end face of the sleeve 6' coming closer to the cover 8 and the piston 9.

This second embodiment according to Figs. 2a, 2b and 2c thus has a built-in safety function, which ensures that the membrane 7 is kept intact even at sharply elevated temperatures.

The unit formed by the ring 8, the diaphragm 7 and the cover 4 is exactly the same in the two embodiments shown according to Figs. Fig. 2a - 2c.

Claims (9)

10 l5 20 25 30 35 502 895 PATENT REQUIREMENTS 1. l. Temperature sensing device arranged to effect an actuating movement of a control valve to a heating medium, comprising a housing (2) with a closed liquid chamber (5), which is filled with a liquid with a high coefficient of volume expansion and which is delimited externally by a thermally conductive cover (4 ) and inside of an elastically stretchable membrane (7), which abuts against an axially movable adjusting member (9, 1) to effect said adjusting movement under any temperature variations in the vicinity of the housing, characterized in that said housing (2) consists of heat insulating material, while said cover (4) consists of plastic material with good thermal conductivity, - said axially movable adjusting means (9,1) comprises a piston (9), which is displaceable in a sleeve body (6,6 ') in said housing ( 2), which sleeve body projects axially in the direction of said housing (4), - that said piston and surrounding sleeve body (6, 6 ') form a continuous abutment surface for said membrane (7), - that said piston (9) is tubular within a working area at the end face of the sleeve body (6, 6 '), which working area is limited by an inner end position located inside the end of the end, under the influence of the volume expansion of the liquid during normal temperature variations, the central part (7f) of the membrane (7) constantly abutting (9) end surface and accompanies the movements of the piston during stretching. Temperature sensing device according to claim 1, characterized in that the inside of the cover (4) has flanges, grooves or grooves (10) for enlarging the heat-transferring interface between the plastic material and the temperature-sensitive liquid. 10 l5 20 25 30 35 502 895 Temperature sensing device according to claim 1 or 2, that the radially outermost portion (7a, 7b) of the membrane (7) extends all the way to said cover known (4) and seals internally thereto. The temperature sensing device according to claim 3, that the radially outermost portion (7a) of the membrane (7) abuts against an annular body (8) surrounding the sensing body (6, 6 ') of said sleeve body. Temperature sensing device according to one of Claims 1 to 4, characterized in that (6a). that said sleeve body (6, 6 ') has a rounded edge portion Temperature sensing device according to any one of claims 1 - 5, characterized in that said housing (2), cover (4), sleeve body (6, ring body (8) and piston (9) consist of plastic material. Temperature sensing device according to any one of claims 1 - 6, characterized in that said sleeve body (6) is made in one piece with said housing (2). Temperature sensing device according to any one of claims 1 to 6, characterized in that said sleeve body consists of an axially movable sleeve (6 '), which is biased by a safety spring (11), the spring force of which is only overcome at elevated pressure in said liquid chamber. , said sleeve (6) being displaced axially while the piston (9) maintains its position. Temperature sensing device according to any one of the preceding claims, characterized in that the piston (9) acts on said control valve by means of a control rod (1), which is biased in the direction of the diaphragm (7).