DE29606702U1 - Arrangement with a protective tube for measuring at least one temperature, one or more parallel, elongated temperature sensors being arranged in the protective tube - Google Patents

Description

Arrangement with a protective tube for measuring at least one temperature, wherein one or more parallel, elongated temperature sensors are arranged in the protective tube.

The invention relates to an arrangement with a protective tube for measuring at least one temperature, wherein one or more parallel, elongated temperature sensors are arranged in the protective tube, according to the preamble of claim 1.

The arrangement is used, for example, in heating and/or air conditioning systems to measure different temperatures. A first and second elongated temperature sensor preferably each provide an actual temperature value for an electronic or mechanical temperature control circuit. The latter becomes effective, for example, if the former fails due to a defect. A third elongated temperature sensor is, for example, part of a temperature limiter which, for safety reasons, prevents the system from continuing to operate if a specified temperature is exceeded if the two temperature control circuits fail. The three elongated temperature sensors in this example are housed in a relatively short protective tube that is common to all temperature sensors and is exposed to the medium, e.g. water, whose temperature is to be recorded using the temperature sensors.

An arrangement of the type mentioned at the beginning is known in which several, e.g. four, cylindrical temperature sensors 1 (see Fig. 1) are each arranged in a coupling plate 2 associated with the relevant temperature sensor 1. The latter is bent parallel to the longitudinal direction of the associated temperature sensor 1. The coupling plates 2 are all arranged with their respective temperature sensors 1 in a common protective tube 3. The bent coupling plate 2 has a profile-shaped cross section and a side wall 2a facing the protective tube 3 and running parallel to its inner wall. In the arrangement shown in Fig. 1, the protective tube 3 has a circular cross section and the profile-shaped cross section of the coupling plate 2 has an external shape of a quarter-circle sector, i.e. two of the three side walls of the coupling plate 2 are arranged radially in the protective tube 3 and its third side wall 2a is arranged parallel to the inside of the protective tube 3. The third side wall 2a then has the shape of a quarter circle in cross section. The four temperature sensors 1 each touch tangentially the three side walls of the coupling plate 2 associated with them and have a large thermal time constant that is therefore unfavorable for control circuits, since one side wall of the coupling plate 2, namely its third side wall 2a, is arranged between the protective tube 3 and the temperature sensor 1 and must also be heated. This means that a larger mass has to be heated, which results in a larger thermal time constant due to the inertia. In addition, there is only a small coupling force between the protective tube 3 and the temperature sensors 1, which further increases the thermal time constant due to the poor thermal contact.

An arrangement is also known in which, for example, four temperature sensors 1 each have a quarter-circle sector-shaped cross-section and each completely fill a quarter of a protective tube 3 without a coupling plate (see Fig. 2). Two of the three side walls of the temperature sensors 1 are each arranged radially in the protective tube 3 and their third side wall la are each arranged parallel to the inner wall of the protective tube 3, which has a circular cross-section, with the third side wall la having more or less good contact with the protective tube 3. Since there is no coupling force between the protective tube 3 and the temperature sensors 1, the latter also have a large thermal time constant in this arrangement. They are also expensive and difficult to manufacture.

In addition, an arrangement is known in which several, e.g. three, cylindrical temperature sensors 1 each with a circular cross-section without a coupling plate are arranged in a protective tube 3 with a circular cross-section (see Fig. 3).

e.g. a single relatively complicated bent spring common to all temperature sensors 1 all temperature sensors 1 outwards against the inner wall of the protective tube 3. The spring production and spring assembly are relatively complicated and the assembly and disassembly of this arrangement relatively difficult, since the spring 4 remains in the protective tube 3 during disassembly. This is even more complicated and difficult if several springs are used instead of the one common spring 4, which is also possible

The invention is based on the object of realizing an arrangement of the type mentioned at the beginning with a short protective tube and a limited space, while solving the resulting space and assembly problems and ensuring easy assembly and disassembly of the arrangement, which has the following advantages:

- Good, safe and cheap, has a small thermal time constant, so that, among other things, the requirements of the DIN 3440 standard are met and

- with the

- pre-assembly in production,

- reuse of part of the assembly by simply replacing one or more temperature sensors, and

- in the event of a service call, interchangeability with the arrangements already known and available today

is possible without restrictions.
35

The above object is achieved according to the invention by the features specified in the characterizing part of claim 1. Advantageous embodiments of the invention emerge from the dependent claims.

Embodiments of the invention are illustrated in the drawing and are described in more detail below.
Shown are: Fig. 1 a cross section of a first variant of an inventive

Arrangement,

Fig. 2 shows a cross section of a first known arrangement, Fig. 3 shows a cross section of a second known arrangement, Fig. 4 shows a cross section of a third known arrangement, Fig. 5 shows a cross section of a quarter of a second variant of the

inventive arrangement, Fig. 6 a cross section of a third variant of the inventive

Arrangement,

Fig. 7 shows a cross section of a fourth variant of the arrangement according to the invention,

Fig. 8 shows a cross section of a fifth variant of the inventive

Arrangement and
Fig. 9 shows a cross section of a sixth variant of the inventive

Arrangement.
20

Figures 2 to 4 show the three known arrangements mentioned and described in the introduction to the description. Achieving a small thermal time constant with the known arrangements is relatively easy if very long temperature sensors 1 with a small diameter are housed in a very long protective tube 3. For practical reasons, however, the protective tube 3 is usually very short, e.g. approximately 100 mm long, and its diameter is relatively small, e.g. 20 mm, which on the one hand results in poor thermal time constants without countermeasures and on the other hand in space and/or assembly problems with countermeasures. For these reasons, the arrangement preferably has one of the structures according to the invention shown in Figures 1 and 5 to 9, in which the temperature sensors 1 all have an externally round cross-section.

In all six variants according to the invention (see Fig. 1 and 5 to Fig. 9), one or more parallel elongated temperature sensors 1 are arranged in the arrangement provided with a protective tube 3 for measuring at least one temperature in the protective tube, which are pressed against an inner wall of the protective tube 3 by means of one or more elongated coupling springs S. The coupling springs 5 are each bent parallel to the longitudinal axes of the temperature sensors 1 and their own longitudinal axes are each arranged parallel to the temperature sensors I. The temperature sensors

1 are arranged within one or more coupling plates 2 present in the protective tube 3, which are each bent parallel to the longitudinal axes of the temperature sensors 1 so that they each have a profile-shaped cross-section. The entirety of the coupling plates 2 has at least as many elongated openings parallel to the longitudinal axes of the temperature sensors 1 towards the inner wall of the protective tube 3 as there are temperature sensors 1 in the protective tube 3.

In the elongated openings, a part of an associated temperature sensor 1 is pressed against the inner wall of the protective tube 3. In the first five variants, the curved coupling plates 2 each have a side wall 2a (see Fig. 1 and 5 to Fig. 7) or 2 (see Fig. 8) facing the protective tube 3 and running parallel to its inner wall. 10

In the first three variants (see Fig. 1, 5 and Fig. 6), there is a coupling plate 2 belonging to the relevant temperature sensor 1 and a coupling spring 5 belonging to it in the protective tube 3 for each temperature sensor. The cross section of the bent coupling plate 2 then preferably has the external shape of a circular sector. If there are four temperature sensors 1 in the protective tube 3, the cross section of the bent coupling plate 2 has the external shape of a quarter-circle sector (see Fig. 1 and Fig. 5). If, on the other hand, there are only two temperature sensors 1 in the protective tube 3, the cross section of the bent coupling plate (2) has the external shape of a semi-circle sector (see Fig. 6). If there are three temperature sensors in the protective tube 3, the cross section of the bent coupling plate 2 preferably has the external shape of a third-circle sector. If there are several temperature sensors 1 in the protective tube 3, of which one temperature sensor 1 and, if present, its associated coupling plate 2 are shorter than the then longer coupling plates 2 of the other temperature sensors 1, there is a risk of the longer coupling plates 2 becoming jammed so that they are no longer pressed evenly against the inner wall of the protective tube 3, which would result in poor heat transfer and thus a large thermal time constant. In order to avoid this, preferably at least some of the longer coupling plates 2, namely those that are attached to the shorter temperature sensor 1 or shorter coupling plate 2, have a tab bent outwards on side walls that do not run parallel to the protective tube 3 as a stop to limit a longitudinal sliding movement of the shorter temperature sensor 1 or shorter coupling plate 2 along and/or parallel to the longitudinal axis of the protective tube 3. The tab is designed and arranged in such a way that, in the end position at the stop of the shorter temperature sensor 1 or shorter coupling plate 2, its longitudinal center is approximately at the level of the longitudinal centers of the other, longer coupling plates 2, so that the latter are pressed more or less evenly radially outwards against the inner wall of the protective tube 3.

In the fourth variant (see Fig. 7), four temperature sensors 1 and two coupling plates 2 are present in the protective tube 3, whereby the cross-section of the curved coupling plates 2 has the external shape of a semicircular sector and two associated temperature sensors 1 and an associated coupling spring 5 are arranged in the coupling plates 2. If a temperature sensor 1 is shorter than the longer, associated coupling plate 2, which e.g.

is the same length as the second temperature sensor L contained in it, then this coupling plate 2 preferably has an inwardly bent tab on its inner wall as a stop to limit a longitudinal sliding movement of the shorter temperature sensor 1. The tab is designed and arranged in such a way that, in the end position at the stop of the shorter temperature sensor 1, its longitudinal center is approximately at the height of the longitudinal center of the longer, associated coupling plate 2. If, however, one of the two coupling plates 2 is shorter than the other, the latter preferably has a tab bent outwards on a side wall that does not run parallel to the protective tube 3 as a stop for limiting a longitudinal sliding movement of the shorter coupling plate 2. The tab is designed and arranged in such a way that, in the end position at the stop of the shorter coupling plate 2, its longitudinal center is approximately at the height of the longitudinal center of the other, longer coupling plate 2.

The coupling plate 2 and the associated coupling spring 5 are either separate components (see Fig. 1, Fig. 6 to Fig. 9) or they both consist of a single bent part made using a resilient material (see Fig. 5). In the latter case, the coupling spring 5 preferably consists of tabs 5a and 5b of the associated coupling plate 2, which are designed and arranged in such a way that they act like a spring on each associated temperature sensor 1, so that the latter is pressed against the inner wall of the protective tube 3 through the associated elongated opening of the relevant coupling plate 2. Radial side walls of the coupling plate 2 then preferably also have the shape of tabs 2b and 2c for the purpose of generating a prestress of the coupling plate 2 within the protective tube 3.

In the fifth and sixth variants (see Fig. 8 and Fig. 9), a single common coupling plate 2 and a single common coupling spring 5 are present in the protective tube 3 for the temperature sensors 1. In the fifth variant (Fig. 8), the cross section of the curved single coupling plate 2 is circular. In the sixth variant (Fig. 9), the cross section of the curved single coupling plate 2 has the external shape of a triangle. In other variants not shown in the drawing, the cross section of the curved single coupling plate 2 has the external shape of a square, a rectangle or any regular or irregular polygon. In the presence of several temperature sensors 1 in the protective tube 3, of which one temperature sensor 1 is shorter than the longer one

Coupling plate 2, the latter has an inwardly bent tab on its inner wall as a stop to limit a longitudinal sliding movement of the shorter temperature sensor 1. The tab is designed and arranged such that, in the end position at the stop of the shorter temperature sensor 1, its longitudinal center is approximately at the height of the longitudinal center of the longer coupling plate 2.

Advantages of the arrangements according to the invention are:

- The thermal time constant is 40 to 50% smaller compared to the known solutions, which is advantageous when used in control loops.

- The temperature sensor production is simple, since only cylindrical temperature sensors 1 with an externally round cross-section are used.

- The coupling force between the temperature sensors 1 and the protective tube 3 is secured over the entire length of the temperature sensor.

- The known arrangements can be easily replaced by the arrangements according to the invention, e.g. in the case of servicing.

- Despite limited space in the protective tube 3, easy assembly and disassembly of the arrangement without special tools.

- Simplified material selection for the coupling plates 2, since good thermal conductivity is not required and thus cheap material can be used.

- Good and secure coupling force between the temperature sensors 1 and the short protection tube 3.

- Pre-assembly of the complete coupling plate 2 with associated temperature sensor 1 and associated coupling spring 5 in production is easily possible.

- Reuse of part of the arrangement, e.g. the complete

Coupling plate 2 with the coupling spring 5, with a simple replacement of one or more temperature sensors 1.

P2788DEg

Claims (19)

PROTECTION CLAIMS 1. Arrangement with a protective tube (3) for measuring at least one temperature, wherein one or more parallel, elongated temperature sensors (1) are arranged in the protective tube (3), which are pressed against an inner wall of the protective tube (3) by means of one or more elongated coupling springs (5), wherein the coupling springs (5) are each bent parallel to the longitudinal axes of the temperature sensors (1) and their own longitudinal axes are each arranged parallel to the temperature sensors (1), characterized in that the temperature sensors (1) are arranged within one or more coupling plates (2) present in the protective tube (3), which are each bent parallel to the longitudinal axes of the temperature sensors (1) in such a way that they each have a profile-shaped cross-section, wherein the entirety of the coupling plates (2) towards the inner wall of the protective tube (3) has at least as many coupling plates (2) parallel to the longitudinal axes of the temperature sensors (1) has elongated openings, such as temperature sensors (1) in the protective tube (3) and that a part of an associated temperature sensor is inserted through the elongated openings (1) is pressed against the inner wall of the protective tube (3). 2. Arrangement according to claim 1, characterized in that in the protective tube (3) for each temperature sensor (1) there is a coupling plate (2) belonging to the relevant temperature sensor (1) and a coupling spring (5) that also belongs to it. 3. Arrangement according to claim 2, characterized in that the cross section of the bent coupling plate (2) has an outer shape of a circular sector. 4. Arrangement according to claim 3, characterized in that four temperature sensors (1) in the Protective tube (3) is present and the cross-section of the bent coupling plate (2) has the external shape of a quarter-circle sector. 5. Arrangement according to claim 3, characterized in that two temperature sensors (1) are present in the protective tube (3) and the cross section of the bent coupling plate (2) in each case has the external shape of a semicircular sector. 6. Arrangement according to claim 3, characterized in that three temperature sensors are present in the protective tube (3) and the cross section of the bent coupling plate (2) has the outer shape of a third of a circle sector. 7. Arrangement according to one of claims 2 to 6, characterized in that in the presence of several temperature sensors (1) in the protective tube (3), of which one temperature sensor (1) and its associated coupling plate (2) are shorter than the then longer coupling plates P2786DEg ·»· ··'*··'*■·''··" ^: (2) of the other temperature sensors (1), at least some of the longer coupling plates (2) on side walls that do not run parallel to the protective tube (3) each have a tab bent outwards as a stop for limiting a longitudinal sliding movement of the shorter temperature sensor (1) or shorter coupling plate (2), and that the tab is designed and arranged in such a way that, in the end position at the stop of the shorter temperature sensor (1) or the shorter coupling plate (2), its longitudinal center is approximately at the level of the longitudinal centers of the other, longer coupling plates (2). 8. Arrangement according to claim 1, characterized in that four temperature sensors (1) are present in the protective tube (3) and the cross section of the bent coupling plate (2) in each case has the external shape of a semicircular sector, wherein two coupling plates (2) are present in each of which two associated temperature sensors (1) and an associated coupling spring (5) are arranged. 9. Arrangement according to claim 8, characterized in that if a temperature sensor (1) is shorter than the then longer, associated coupling plate (2), the latter has on its inner wall an inwardly bent tab as a stop for limiting a longitudinal sliding movement of the shorter temperature sensor (1), and that the tab is designed and arranged in such a way that, in the end position at the stop of the shorter temperature sensor (1), its longitudinal center is approximately at the height of the longitudinal center of the longer, associated coupling plate (2). 10. Arrangement according to claim 8, characterized in that if one of the two coupling plates (2) is shorter than the other, the latter is arranged on a non-parallel to the protective tube (3) extending side wall has an outwardly bent tab as a stop for limiting a longitudinal sliding movement of the shorter coupling plate (2), and that the tab is designed and arranged such that, in the end position at the stop of the shorter coupling plate (2), its longitudinal center lies approximately at the height of the longitudinal center of the other, longer coupling plate (2). 11. Arrangement according to one of claims 2 to 10, characterized in that the coupling plate (2) and the associated coupling spring (5) both together consist of a single bent part produced by means of a resilient material. 12. Arrangement according to claim 11, characterized in that the coupling spring (5) consists of tabs (5a, 5b) of the associated coupling plate (2), which are designed and arranged in such a way that they act like a spring on each associated temperature sensor (1), P2788DEg so that the latter is pressed against the inner wall of the protective tube (3) through the corresponding elongated opening of the respective coupling plate (2). 13. Arrangement according to claim 11 or 12, characterized in that radial side walls of the coupling plate (2) each have the shape of tabs (2b, 2c) for the purpose of generating a prestress of the coupling plate (2) within the protective tube (3). 14. Arrangement according to claim 1, characterized in that a single common coupling plate (2) and a single common coupling spring (5) are present in the protective tube (3) for the temperature sensors (1). 15. Arrangement according to claim 14, characterized in that the cross section of the curved single coupling plate (2) is circular. 16. Arrangement according to claim 14, characterized in that the cross section of the curved single coupling plate (2) has an external shape of a triangle. 17. Arrangement according to claim 14, characterized in that the cross section of the bent single coupling plate (2) has an external shape of a square or rectangle. 18. Arrangement according to claim 14, characterized in that the cross section of the curved single coupling plate (2) has an external shape of any regular or non-regular polygon. 19. Arrangement according to one of claims 14 to 18, characterized in that in the presence of several temperature sensors (1) in the protective tube (3), of which one temperature sensor (1) is shorter than the then longer coupling plate (2), the latter has on its inner wall a tab bent inwards as a stop for limiting a longitudinal sliding movement of the shorter temperature sensor (1), and that the tab is designed and arranged such that, in the end position at the stop of the shorter temperature sensor (1), its longitudinal center is approximately at the height of the longitudinal center of the longer coupling plate (2). P2768DEg