RU2811774C2 - Thermal control device and system - Google Patents

Abstract

FIELD: temperature control device.

SUBSTANCE: device is fixed on a surface to be thermally controlled, having at least one upper part, at least one lower part and at least one first thermally regulating element, and is in connection with an electrical contact. The upper part is located opposite the upper side of the first temperature control element, and the lower part is located opposite the lower side of the first temperature control element. The lower part is configured to engage the upper portion such that the upper part and the lower part provide surface pressure in a direction perpendicular to the upper side and the lower side of the first thermal control element to provide surface contact of the lower part with the surface to be thermally controlled. The temperature control device is configured to be longitudinally displaceable so that a change in the length of the temperature control device is absorbed in the longitudinal direction of the temperature control device.

EFFECT: creating an improved thermostatic device, which has a simple integral design and ensures effective heat transfer.

16 cl, 8 dwg

Description

The invention relates to a thermoregulatory device, primarily a resistive heating device, designed to be placed on a surface to be thermoregulated, having at least one upper part, at least one lower part and at least one first thermostatic element. The invention further relates to a system, in particular a distribution cabinet or electronics housing, with such a temperature control device.

Switch cabinets and electronic equipment enclosures must generally be thermally controlled in active or passive mode. Thanks to active heating or cooling of such a housing, the minimum temperature or maximum temperature of the electrical (electronic) components is ensured. Due to this, it is possible, for example, to prevent the formation of condensation moisture inside the housing or to prevent overheating of components. If the temperature in the control cabinet or electronics housing falls below a minimum threshold, the formation of condensation humidity can lead to short circuits in electrical circuits.

Typically, the components inside a distribution cabinet or electronics enclosure are arranged in a tightly packed structure as much as possible so that the required installation space can be minimized and a compact system unit can be obtained. Modules or components for targeted thermal control of a system unit generally take up additional installation space and at the same time must be able to provide reliable and efficient thermal control.

For heating distribution cabinets, etc. Primarily resistance heating systems can be used. The heating resistor as a structural element of a resistance heating system in its simplest design is a metal wire, also called a heating conductor. In most cases, a larger length of wire is required. Therefore, wires are often laid in turns or in a meander shape. Moreover, such an arrangement of the heating conductor in the form of turns or meanders requires a large installation space only for the actual heating components inside the distribution cabinet or electronic equipment housing.

In addition, there is the problem that effective heat transfer can only be achieved with sufficient surface contact. In this case, an increase in temperature leads to a relative linear elongation of the heating device or individual components and, consequently, to their protrusion. The necessary surface contact for proper heat transfer is in this case impossible. Such a protrusion can then manifest itself as a persistent deformation, so that the heat transfer is reduced and the function of the heating device is not fully ensured.

It is therefore an object of the invention to provide an improved thermal control device, especially for distribution cabinets and electronic equipment enclosures, which has a simple integral design, provides efficient heat transfer, allows for lower cost manufacturing, simplifies maintenance and repair, and also takes up minimal installation space.

This problem is solved thanks to a temperature control device according to claim 1 of the formula, as well as thanks to the system according to claim 15 of the formula. Preferred design options are presented in the dependent claims of the invention.

According to the present invention, there is provided a thermal control device, especially a resistive heating device, for placement on a surface to be thermally controlled, having at least one top portion, at least one bottom portion, and at least one temperature control element, especially a heating element. The upper part is located opposite the upper side of the first thermostatic element. The lower part is located opposite the lower side of the first thermostatic element. The lower part and the upper part are configured and engage with each other in such a way that they provide a surface pressure, especially a continuous surface pressure created in a perpendicular direction to the upper side and the lower side of the first temperature control element, on the upper side and the lower side of the temperature control element , and the lower part has the possibility of surface mating with the surface to be thermally controlled. In addition, the thermal control device can be mounted on the surface to be thermally controlled so as to be longitudinally displaceable so as to compensate for changes in the length of the thermal control device in the longitudinal direction of the thermal control device. For this purpose, the temperature control device has a first end closing element and a second end closing element, wherein the upper part, the first end closing element and the second end closing element are located on the lower part, and the second end closing element has a main part and a fastening clamp for fixing the main part on the underlying one. thermal regulation of the surface, wherein the fastening clamp is located in a recess in the main part with the ability to compensate for changes in the length of the thermal control device through elastic deformation of the fastening clamp.

The invention is based on the basic idea that a temperature control device provides a mechanical pre-clamp to ensure that the temperature control element or heating element, as well as the temperature control device, mates with the base or surface to be thermally controlled, for example the surface or wall plane of a distribution cabinet or electronic equipment enclosure, in incl. also in the case of relative linear elongation. Due to this, an effective temperature transfer can be achieved to the outer mating surface or the surface of the base in contact with the lower part (of the device).

Moreover, with the help of the temperature control device according to the invention, it is possible to provide a structure that takes up little space. First of all, the upper part and the lower part, as well as other components of the temperature control device, must be connected to each other or be able to be connected together in such a way that the installation space for the temperature control device can be reduced or is minimal.

In the context of the present invention, a thermoregulatory device is understood primarily as a heating device. In a preferred solution, the temperature control device is configured as an electric heating device, for example an electric resistance heating device. Alternatively, it is possible to provide a temperature control device with a temperature control element which includes a liquid circuit and which is supplied with liquid to provide a heating effect or a cooling effect.

According to the invention, the upper part is located opposite the upper side of the first thermostatic element or is directed in opposite directions, primarily along the mating surface of the upper part. The lower part is located opposite the lower side of the first thermostatic element or is directed in the opposite direction, primarily along the mating surface of the lower part. Thus, the temperature control element is flatly placed between the upper part and the lower part of the temperature control device and is wedged. First of all, the interface and heat exchange can be carried out through at least one significant part of the base surface of the at least one first thermostatic element.

The lower part is provided to engage with the upper part so that a surface pressure, preferably a continuous or uniform surface pressure, is provided by the upper part and the lower part in a direction perpendicular to the upper side and the lower side of the first temperature control element to provide surface interface of the lower part with the surface to be thermally controlled. Thus, double-sided or bidirectional surface jamming of the first thermal control element is provided, and an expedient coupling of the lower part (device) with the surface to be thermally controlled is also performed. The upper part and the lower part can be flexible or reversibly deformable to ensure expedient engagement with each other.

By surface pressure or surface jamming in the context of the present invention it is meant that opposing surfaces are mated to each other in order to minimize air or fluid clearances and optimize temperature transition. As the temperature increases and the associated linear elongation of the upper part, the first temperature control element and/or the lower part, an optimal mating of the opposing surfaces is also ensured. The efficiency of heat transfer to the base surface on which the lower part is exposed is optimized.

In addition, it is provided that the temperature control device is designed to be fixed on the surface to be thermally controlled with the possibility of longitudinal displacement so that a change in the length of the temperature control device is absorbed in the longitudinal direction of the temperature control device. First, the temperature control device may include a fastening mechanism for attaching the temperature control device to a surface to be temperature controlled, which allows a change in the length in the longitudinal direction of the temperature control device without transferring a deforming force to the temperature control device.

By fastening the thermostatic device with the possibility of longitudinal displacement in the context of the invention it should be understood that the change in the length of the thermostatic device is absorbed or compensated. In this way, an expedient coupling of the temperature control device, especially its lower part, with the surface or base to be thermally controlled can be ensured during operation of the temperature control device and, therefore, also in the case of relative linear elongation of the temperature control device due to temperature influences.

According to one preferred embodiment, the upper part includes at least one first clamping element which extends in the longitudinal direction of the upper part such that the upper part, when mutually engaged with the lower part, provides pre-clamping, in particular along the entire length of the lower part. parts.

At least one first clamping element may extend along the inner side of the upper part. In a preferred solution, first and one second clamping elements can be formed symmetrically on the inner side of the upper part and extend in the longitudinal direction of the upper part.

The at least one first clamping element can preferably be configured as a material cutout or as a material thinning along the upper part, in particular as a purposefully defined or effected material thinning. The rigidity or flexibility of the upper part is modifiable due to the design and location of the at least one first clamping element. The pre-clamping or pre-tensioning force, which in the assembled state of the thermostatic device is transmitted primarily from the upper part to the lower part, can be adjusted thanks to the at least one first clamping element.

In this context, due to the configuration of the upper part, the essentially present preload force on the side of the upper part can be reduced in this way by means of at least one first clamping element, which in a state corresponding to the use of the device, that is, in particular, in the range of the intended operating The temperature set is the flat plane of interface and heat transfer of the thermoregulatory device, passing along the lower part.

First of all, the upper part can be designed as an elastic element or a pressure spring to transfer a continuous clamping force or surface pressure to the temperature control element and the lower part. In this way, protrusion or lifting of the temperature control element and/or the lower part as the temperature rises can be prevented and surface contact for heat transfer can be ensured.

Due to the design of the clamping element in the longitudinal direction of the upper part, the temperature control device can have any overall length. Pre-clamping and heat transfer mating are provided along the entire length of the top and bottom.

In addition, the lower portion may include at least one specifically designed cutout of material to minimize deformation as temperature increases.

According to one preferred embodiment, the upper part has a surface structure, in particular a ribbed surface structure. In this way, an increase in effective surfaces for heat transfer or thermal control can be accomplished. In the context of the present invention, the top portion may have any surface structure along the outer side.

In a preferred solution, the top and/or bottom can be molded or formed as an extruded profile or extruded profile. EFFECT: simple and low-cost production of the upper part and/or the lower part.

According to another embodiment, the temperature control device has a grounding contact element, which is connected to the bottom side of the first temperature control element in such a way that a connection, in particular an electrothermal connection, is provided with the first temperature control element and the bottom part.

With the ground contact member making a surface electrical connection to the temperature control member, a reliable electrical ground or connection to ground can be ensured. First of all, a power cable or a connecting cable can be connected to the grounding contact element.

According to one embodiment, it is provided that the temperature control device has a temperature sensor or temperature switch, which is connected to the grounding contact element as a heat-conducting element.

In this context, the grounding contact element is an electrically conductive and thermally conductive element. The grounding contact element therefore performs a combined at least double function for the temperature control device according to the invention. By preferably electrothermally connecting the grounding contact element to the first temperature control element and the lower part, both electrical grounding and an advantageous temperature measurement along the grounding contact element can be ensured. A preferred, efficient installation of the temperature sensor is possible.

In a preferred embodiment, it is provided that at the lateral ends of the upper part and in the areas of the lateral ends of the lower part, first and second interpenetrating elements are respectively provided, which extend in the longitudinal direction of the upper part and in the longitudinal direction of the lower part, so that the upper part and the lower part are connected to each other or interpenetrate each other with force and/or geometric closure, primarily along their entire longitudinal extent. Alternatively, the interpenetrating elements may be provided along only one portion of the longitudinal extent of the top portion and/or bottom portion. In the context of the invention, the upper part and the lower part include first and second interpenetrating elements configured to respond to each other.

In a preferred solution, the upper part and/or the lower part are made so reversibly deformable or resilient that the upper part and the lower part are, as a result of temporary deformation, connected to and detached from each other. First of all, thanks to the first and second interpenetrating elements in combination with the first clamping element, a pre-clamping of the thermostatic device can be carried out for the purposeful mating of the internal thermostatic element, as well as the lower part, with the outer surface of the base or with the surface to be thermoregulated, for example with the surface of a distribution cabinet, etc. .P.

In a preferred solution, the upper part and the lower part can be connected to each other by a detachable connection in a spatial orientation. Thus, the upper part and the lower part can be moved relative to each other, respectively, in their longitudinal direction to establish or release a connection. In addition, the first and/or second interpenetrating elements can be connected to each other as a result of at least partial rotational movement.

As stated above, the temperature control device according to the invention has a first end closure element and a second end closure element, wherein the upper part, the first end closure element and the second end closure element are respectively located on the lower part and are primarily secured thereto.

The lower part is the central structural element of the temperature control device. The top portion, the first end closure, and/or the second end closure may be configured to engage the bottom portion as a central component. There is a complete design of the temperature control device.

End closures can be installed on the bottom before the top is mounted. Due to this, protection is provided against possible contact with live or electrically conductive structural elements when assembling the temperature control device. In addition, the lateral arrangement of the end closing elements on the lower part allows the temperature control device to be made arbitrarily long or large using the upper part and the lower part.

In addition, electrically conductive or live elements such as a ground contact element and/or a temperature sensor may also be placed in the lower portion.

According to another preferred embodiment, it is provided that the upper part and the lower part are located between the first and second end closing elements to form a housing for the first temperature control element.

The arrangement of the top, bottom, first end closure and second end closure in this plan defines a substantially closed hollow space for receiving and conveniently mating a thermostatic element or heating element. The temperature control device is essentially prefabricated or assembled in a modular manner.

According to one embodiment, the first end closure element includes at least a first locking element, the second end closure element includes at least a second locking element, and the lower part includes at least a first receiving element and at least a second receiving element, wherein the first locking element and the second locking element are respectively configured to respond to the first and second receiving elements for connection with the force and/or geometric closure of the lower part with the first and second end closing elements.

First of all, the first or second locking elements may be configured as a locking hook, a locking protrusion, or the like. for engaging with the first or second receiving element on the lower part. Moreover, the first locking element in combination with the first receiving element and the second locking element in combination with the second receiving element can be configured differently.

As stated above, the second end closure element has a main part and a fastening clamp for fixing the main part on the surface to be thermally controlled, wherein the fastening clamp is located in a recess in the main part so that the change in the length of the thermally regulating device, especially the upper part and/or the lower part , is compensated by elastic deformation of the fastening clamp.

Thus, the recess in the main part can be made larger than the fastening clamp or the thickness of the fastening clamp. In addition, the fastening clamp in the initial state of the temperature control device, that is, before using the temperature control device, can be positioned in the middle or at one end of the recess in the main part so that the relative linear elongation of the temperature control device in the operating state is absorbed or absorbed, primarily in the form of an elastic deformation of the fastening clamp. In operating condition, therefore, a smooth contact surface of the temperature control device can be ensured.

According to another design variant, at least one protruding element is made along the recess in the main part for transmitting the clamping force between the main part and the fastening clamp in the longitudinal direction of the temperature control device. First of all, two projecting elements can be arranged along the recess in the main part with a symmetrical distribution.

Thanks to the protruding element, when the length of the thermostatic device changes, especially when the thermostatic device elongates, the resulting clamping force can be transferred from the protruding elements to the fastening clamp and converted into elastic deformation of the fastening clamp. Likewise, the mounting clamp can absorb or compensate for changes in the length of the temperature control device, especially the upper part and/or the lower part.

In an aspect of the additional independent claim, there is provided a system, in particular a distribution cabinet or electronics housing, with a temperature control device according to one of the preceding claims.

In this context, the system may be, for example, a distribution cabinet with electrical or electronic components, which includes a temperature control device according to the invention to preferably ensure the lowest temperature or minimum temperature in the distribution cabinet. In this way, the formation of condensation moisture inside the switch cabinet can be prevented and the functionality of the switch cabinet components can be ensured. Preferred target temperature control is provided.

Below, with reference to the accompanying drawings, a more detailed explanation of the invention is given in terms of additional distinctive features.

Shown here:

Fig. 1 is a perspective view of the first example of the design of a thermoregulatory device according to the invention,

Fig. 2 is a perspective view of the internal components of a first example of the design of a thermostatic device according to the invention according to FIG. 1,

Fig. 3 is a perspective view of a first example of a design according to FIG. 1, in section,

Fig. 4 is a perspective view of a first example of a design according to FIG. 1, in section,

Fig. 5A is a perspective view of the detailing of a first embodiment example according to FIG. 1,

Fig. 5B is a further perspective view of the detailing of a first example of a structural embodiment according to FIG. 1,

Fig. 6 is a further axonometric detail view of the first embodiment example according to FIG. 1,

Fig. 7 is a perspective view of a second example of the design of a thermostatic device according to the invention,

Fig. 8 is a perspective view of a second embodiment example according to FIG. 7, sectional view.

In fig. 1 is a perspective view of a first embodiment example of a temperature control device 10 according to the invention.

The temperature control device 10 is shown with an upper part 12 and a lower part 14, which are located one above the other. At the ends of the longitudinal side of the upper part 12 or the lower part 14, a first end closure element 16 and a second end closure element 18 are located opposite each other. The upper part 12, the lower part 14, the first end closure element 16 and the second end closure element 18 form a substantially closed frame.

The first end cover 16 includes an upper part 16a and a lower part 16b, which are pushed onto each other and connected to each other. The first end closure element 16 may accommodate other components of the temperature control device 10, such as a ground contact element 26 or a temperature sensor 28. The second end closure element 18 according to FIG. 1 is also multi-part, primarily made with an additional plug-in fastening clamp 18a and a main part 18b. Alternatively, the second end closure element 18 can be made monolithic.

In addition, in the longitudinal direction of the temperature control device 10, an electrical cable or connecting cable 32 enters into the first end closure element 16. Thus, the temperature control device 10 can be supplied with electric current, for example when the temperature control device 10 according to the invention is configured as an electric resistance heating system. In this case, the first end closing element 16 and/or other structural elements of the temperature control device 10 can be designed in such a way that the connecting cable 32 can be relieved of tension.

In addition, the first and second end closure members 16, 18 are respectively provided with two counterbore mounting holes for mounting the temperature control device 10, for example, inside a distribution cabinet or electronics housing. Bored mounting holes may be provided in the fastening clamp 18a of the second end closing element 18. Bored mounting holes according to Fig. 1 can be made as longitudinally shaped grooves, respectively, in the corner of the temperature control device 10.

In a preferred solution, counterbored fastening holes can be made in at least one of the end closing elements 16, 18, transverse to the longitudinal extent of the temperature control device 10 and in the opposite end closing element 16, 18, in the longitudinal direction of the temperature control device 10, especially in a monolithic design the first and/or second end closure element 16, 18. Thus, the temperature control device 10 can be mounted so that it is longitudinally displaceable such that a change in its length is absorbed or compensated for.

In fig. 2 shows a perspective view of the internal components of a first embodiment example of a thermoregulatory device 10 according to the invention according to FIG. 1.

According to FIG. 2, the temperature control device 10 includes a temperature control element 20 with a top side 20a. The temperature control element 20 extends from the first end closing element 16 along the upper part 12 or along the lower part 14 with entry into the second end closing element 18.

On the lower part 16b of the first end closure element 16 is located a connecting cable 32 for electrical supply or connection, in particular the first temperature control element 20. In addition, on the first temperature control element 20 are provided a first electrical contact 24.1 and a second electrical contact 24.2 for electrical connection with the connecting cable 32. On the first temperature control element 20 there is also a grounding contact element 26, which is in connection with the power cable or connecting cable 32.

The lower part 16b of the first end closure element 16 includes two first locking elements 16.1. Two first locking members 16.1 extend to either side of the first temperature control member 20 from a lower portion 16b of the first end closure member 16 extending into the lower portion 14 to connect the first end closure member 16 to the lower portion 14. In addition, the second end closure member 18 includes two second locking elements 18.2 that extend from either side of the first temperature control element 20 into the lower part 14 to connect the second end closure element 18 to the lower part 14. Referring to FIG. 2, the first and second fixing elements 16.1, 18.2 are made identical.

In fig. 3 shows a perspective view of a first example of a design according to FIG. 1 in section.

The upper part 12 has a mating surface 12.5, and the lower part 14 has an opposite mating surface 14.5 for mating with the first thermoregulatory element 20. Between the mating surfaces 12.5, 14.5, at least one first thermoregulatory element or heating element 20 (on Fig. 3 not shown). The mating surfaces 12.5, 14.5 provide uniform continuous surface pressure or surface wedging along the length of a significant portion of the upper and lower surfaces 20a, 20b of the first temperature control element 20.

The upper part 12 of the temperature control device is connected with a force and/or geometric closure to the lower part 14. At the lateral ends of the upper part 12 there are first and second interpenetrating elements 12.1, 12.2, and in the areas of the lateral ends of the lower part 14 there are corresponding first and second interpenetrating elements 14.1, 14.2. The first interpenetrating elements 12.1, 14.1 and the second interpenetrating elements 12.2, 14.2 are respectively formed along the entire length of the upper and lower parts 12, 14 for engaging each other. (Thereby) a connection is formed that acts like a latch.

According to FIG. 3, the first and second interpenetrating elements 12.1, 12.2 of the upper part 12 are made identical to each other, primarily as the side ends bent inward at an angle of approximately 100 degrees relative to the horizontal. The corresponding first and second interpenetrating elements 14.1, 14.2 of the lower part 14 are also made identical, primarily as shoulder-shaped sections of the wall, which in relation to the lateral ends of the lower part 14 are inclined at an angle of approximately 100-110 degrees relative to the horizontal. Alignment relative to vertical or horizontal is indicated in relation to the representation in FIG. 3 and in appropriate use depends on the specific setting of the temperature control device 10.

In a preferred solution, the interpenetrating elements 12.1, 12.2, 14.1, 14.2 of the upper part 12 and the lower part 14 are designed in such a way that pre-clamping of the temperature control device 10 is possible. In this case, the upper part 12 and/or the lower part 14 can be at least partially reversibly deformable.

In addition, the upper part includes first and second clamping elements 12.3, 12.4 in the form of slot clamps 12.3, 12.4. Groove clamps 12.3, 12.4 are made on the sides of the mating surface 12.5 of the upper part 12 as targeted recesses in the material or thinning of the material. First of all, the clamping elements or groove clamps 12.3, 12.4 are made symmetrically in the form of a circular cutout in a sector of approximately 270 degrees and extend in the longitudinal direction of the upper part 12.

With the help of the first and second slot clamps 12.3, 12.4, when connecting the upper part 12 with the lower part 14, it is possible to create a specific clamping force, which mechanically pre-clamps the temperature control device 10. In this way, continuous surface pressure can be applied to the temperature control element or heating element 20 along the mating surfaces 12.5, 14.5.

The temperature control device 10 can also be pre-clamped in such a way that relative linear elongation with increasing temperature is compensated, and the lower side 14.6 of the lower part 14 is always mated to the base.

In addition, at least one part of the outer surface of the upper part 12 is provided with a surface structure. First of all, this structure is provided in the form of webs with side surfaces at a non-zero angle of installation, the webs extending in the longitudinal direction of the upper part 12. By this, the effective surface for heat transfer can advantageously be increased.

In fig. 4 shows a perspective view of a first embodiment example according to FIG. 1 in section.

The upper part 16a of the first end closure element 16 includes at least one trunnion element 16.3. The trunnion element 16.3 can be provided with a circular or polygonal cross-section. The lower part 16b is made with at least one corresponding receiving hole 16.2. First of all, the receiving opening 16.2 may have a polygonal, preferably hexagonal, cross-section. In this way, the trunnion element 16.3 can engage with the receiving hole 16.2 and an advantageous jamming occurs for forceful and/or positive engagement of the upper part 16a with the lower part 16b of the first end closure element 16.

In addition, the top portion 16a and the bottom portion 16b are flush with the top portion 12 and the bottom portion 14.

Also in FIG. 4 shows in detail one of the two first locking elements 16.1 of the first end closure element 16. The first locking element 16.1 is designed to engage a corresponding first lower part receiving element 14.3, primarily in the form of a locking hook. The first locking elements 16.1 are made monolithically with the lower part 16b of the first end closing element 16.

In a preferred solution, the first receiving element 14.3 of the lower part 14, as well as the second receiving element 14.4 in the form of a rectangular recess, can be molded into the lower part 14 as a result of a subsequent processing step. Thus, the lower part 14 as well as the upper part 12 can be formed in their basic form as an extruded profile or an extruded profile.

In fig. 5A is a perspective view of the detailing of a first embodiment example according to FIG. 1.

According to FIG. 5A, the second end closure member 18 includes second locking members 18.2. The second locking elements 18.2 are made identical to the first locking elements 16.1 of the first end closure element 16 and engage with the second receiving elements 14.4 of the lower part.

Moreover, the second end closure element 18 according to FIG. 5A can be made multi-part, in particular with an insertable or clampable fastening clamp 18a and a main part 18b. The mounting clamp 18a is provided with counterbored mounting holes for conveniently mounting the temperature control device 10 on the outer surface of the base.

The main part 18b of the second end closure 18 has a recess in it, in which the fastening clamp 18a is located or installed. In this case, the recess or niche in the main part 18b in the longitudinal direction of the temperature control device 10 is made in a shape larger than the mounting clamp 18a or the thickness of the mounting clamp 18a.

Thus, the relative linear elongation of the temperature control device 10, especially the upper part 12 or the lower part 14, can be compensated along the recess in the main part 18b, while the fastening clamp 18a ensures the fixation of the temperature control device 10 on the outer surface of the base or on the surface to be thermally controlled. The fastening clamp 18a, in combination with the recess in the main part 18b, constitutes a compensating component for the relative linear extension of the temperature control device 10, in particular the upper part 12 or the lower part 14.

In fig. 5B shows the following perspective view of the detailing of the first embodiment example according to FIG. 1.

First of all, in FIG. 5B shows the arrangement of the fastening clamp 18a in the recess of the end closure element 18. Along the recess in the end closure element 18 or its main part 18b are two projecting elements 18c, which extend in the direction of the fastening clamp 18a.

First of all, thanks to the protruding elements 18c, forces can be transmitted from the main part 18b to the fastening clamp 18a. As the relative linear elongation or change in the length of the temperature control device 10, especially the upper part 12 and/or the lower part 14, occurs, the protruding elements 18c transmit a force to the fastening clamp 18a in such a way that deformation of the fastening clamp 18a occurs. Due to this, the change in the length of the temperature control device 10 is absorbed or compensated.

In addition, the protruding elements 18c according to FIG. 5B are made in a semicircular shape and are located along the recess in the main part 18b symmetrically with respect to the longitudinal axis of the temperature control device 10.

In fig. 6 shows the following perspective view of the detail of the first embodiment example according to FIG. 1.

With the bottom side 20b of the first temperature control element 20 according to FIG. 6 is paired with a grounding contact element 26. The grounding contact element 26 protrudes in the form of a plate from under the first thermostatic element 20 and includes a connecting antenna for connection to the connecting cable 32. A temperature sensor or temperature relay 28 is also located on the grounding contact element 26. Therefore , the grounding contact element 26 is also used as a thermal conductive element for the temperature sensor 28 and in this sense performs a combined function.

The temperature control element 20 may have a multilayer structure. Moreover, in the context of the invention, several temperature control elements 20 may be provided, stacked on top of each other or located next to each other.

In addition, in FIG. 6, a mating surface 14.5 of the lower portion can be recognized as a wedged surface mate with the lower side 20b of the first thermal control element 20 to ensure optimal heat transfer.

In fig. 7 is a perspective view of a second embodiment example of a temperature control device 10 according to the invention.

The upper part 12 and the lower part 14 include first interpenetrating elements 12.1', 14.1' and second interpenetrating elements 12.2', 14.2', respectively responsive to each other. According to FIG. 7, the first interpenetrating elements 12.1', 14.1' are made in an L-shape in such a way that mutual engagement is possible. First of all, the first interpenetrating elements 12.1', 14.1', when performing a partially rotational movement or a purely translational movement across the longitudinal extent of the upper part 12 and the lower part 14, can be brought into mutual engagement.

The second interpenetrating element 14.2' in the lower part 14 is designed essentially as a U-shaped groove. A second interpenetrating element 12.2' in the upper part 12 with a rectangular cross-section can be inserted into the second interpenetrating element 14.2' in the lower part 14 and wedged there. Thanks to the V-shaped groove in the upper part 12, reversible deformation can be provided on the upper side of the second interpenetrating element 12.2' to jam the second interpenetrating elements 12.2', 14.2'.

Moreover, according to FIG. 7, it can be inferred that the top portion 12 along the mating surface 12.5 comes into contact with the top side 20a of the first temperature control element 20 to apply surface pressure to a substantial portion of the top side 20a of the first temperature control element 20. The same applies to the bottom mating surface 14.5 side 14 contacting the bottom side 20b of the temperature control element 20.

In addition, the upper part 12 along its outer side over almost its entire width has a surface structure in the form of alternating rising and falling fronts, which adjoin each other to form wide-angle edges.

In fig. 8 is a perspective view of a second embodiment example according to FIG. 7, sectional view.

According to FIG. 8, the second locking elements 18.2' of the second end closure element 18 are in the form of locking hooks which have a tongue or triangle cutout. First of all, the second locking elements 18.2' are formed integrally with the second end closure element 18. The lower part 14 is provided with a corresponding second receiving element 14.4' in the form of a triangular shaped protrusion for engagement with the second locking element 18.2'. In a preferred solution, the first locking elements (not shown in FIG. 8) and the second locking elements 18.2', as well as the first receiving elements (not shown in FIG. 8) and the second receiving elements 14.4' are made identical.

Thanks to the temperature control device 10 according to the invention, a complete structure with improved heat transfer can be achieved. While the assembled temperature control device 10 is in a pre-clamped state, continuous two-way surface pressure is provided to mate with the first heating element or temperature control element 20. In addition, the lower side 14.6 of the lower part 14 can be provided to mate with the outer surface of the base or with a surface subject to temperature control.

While the lower portion 14 is used as a central receiving unit for the other components of the temperature control device 10, a complete structure is achieved while saving installation space. In addition, the ground contact element 26 acts bifunctionally, namely as a ground connection and as a thermal conductive element for the temperature sensor 28.

Thus, thanks to the present invention, a temperature control device 10 is available that is optimized in terms of installation space, which also ensures efficient heat transfer during temperature increases.

List of reference designations:

10 thermostatic device

12 top part

12.1, 12.1' first interpenetrating element (upper part)

12.2, 12.2' second interpenetrating element (upper part)

12.3 first clamping element

12.4 second clamping element

12.5 mating surface (top)

14 bottom part

14.1, 14.1' first interpenetrating element (lower part)

14.2, 14.2' second interpenetrating element (lower part)

14.3 first receiving element (lower part)

14.4, 14.4' second receiving element (lower part)

14.5 mating surface (bottom)

14.6 bottom side of the bottom

16 first end closing element

16a upper part of the first end closure element

16b lower part of the first end closure element

16.1 first fixing element

16.2 receiving element

16.3 Trunnion element

18 second end closing element

18a mounting clamp

18b main part

18 with protruding element

18.2, 18.2' second fixing element

20 thermostatic element / heating element

20a upper side of the thermostatic element

20b bottom side of thermostatic element

24.1 first electrical contact

24.2 second electrical contact

26 ground contact element

28 temperature sensor

32 electrical cable/connection cable

Claims (20)

1. A temperature control device (10) for placement on a surface to be thermally controlled, having at least one upper part (12), at least one lower part (14) and at least one temperature control element (20), wherein: - the upper part (12) is located opposite the upper side (20a) of the thermostatic element (20), and the lower part (14) is located opposite the lower side (20b) of the thermostatic element (20), - the lower part (14) and the upper part (12) are made and engage with each other in such a way that they provide surface pressure on the upper side (20a) and the lower side (20b) of the temperature control element (20), and the lower part ( 14) has the ability to surface interface with the surface subject to thermal control, - the thermostatic device (10) has a first end closing element (16) and a second end closing element (18), wherein the upper part (12), the first end closing element (16) and the second end closing element (18) are located on the lower part ( 14), characterized in that the second end closing element (18) has a main part (18b) and a fastening clamp (18a) for fixing the main part (18b) on the surface to be thermally controlled, and the fastening clamp (18a) is located in a recess in the main part (18b) with the ability to compensate for changes in the length of the temperature control device (10) through elastic deformation of the mounting clamp (18a). 2. Thermostatic device (10) according to claim 1, characterized in that the upper part (12) includes at least one first clamping element (12.3, 12.4) which extends in the longitudinal direction of the upper part (12) so that that the upper part (12) when engaged in mutual engagement with the lower part (14) provides preliminary clamping. 3. Thermostatic device (10) according to claim 2, characterized in that the upper part (12) when entering into mutual engagement with the lower part (14) provides preliminary clamping along the entire length of the lower part (14). 4. Thermostatic device (10) according to one of the preceding paragraphs, characterized in that the upper part (12) has a surface structure. 5. Thermostatic device (10) according to claim 4, characterized in that the surface structure is ribbed. 6. The temperature control device (10) according to one of the preceding claims, characterized in that it has a grounding contact element (26) which is connectable to the bottom side (20b) of the temperature control element (20) in such a way that connection to the temperature control element is provided (20) and the bottom (14). 7. Thermostatic device (10) according to claim 6, characterized in that the connection to the thermostatic element (20) and the lower part (14) is electrothermal. 8. Thermostatic device (10) according to claim 6 or 7, characterized in that it has a temperature sensor (28), which is located on the grounding contact element (26) as a heat-conducting element. 9. Thermostatic device (10) according to one of the previous paragraphs, characterized in that at the lateral ends of the upper part (12) and in the areas of the lateral ends of the lower part (14) there are first and second interpenetrating elements (12.1, 12.1') made in response to each other ; 12.2, 12.2'; 14.1, 14.1'; 14.2, 14.2'), which extend in the longitudinal direction of the upper part (12) and in the longitudinal direction of the lower part (14) so that the upper part (12) and the lower part (14) are connected to each other with force and/or geometric closure. 10. Thermostatic device (10) according to one of the preceding claims, characterized in that the upper part (12) and the lower part (14) are located between the first and second end closing elements (16, 18) to form a housing for the thermostatic element (20) . 11. Thermostatic device (10) according to one of the preceding paragraphs, characterized in that the first end closing element (16) includes at least one first locking element (16.1), the second end closing element (18) includes at least at least one second locking element (18.2, 18.2'), and the lower part (14) includes at least one first receiving element (14.3) and at least one second receiving element (14.4, 14.4'), the first and second the fixing elements (16.1, 18.2, 18.2') are made corresponding to the first and second receiving elements (14.3, 14.4, 14.4') for connection with the force and/or geometric closure of the lower part (14) with the first and second end closing elements (16, 18). 12. Thermostatic device (10) according to one of the previous paragraphs, characterized in that the elastic deformation of the fastening clamp (18a) compensates for the change in the length of the upper part (12) and/or the lower part (14). 13. Thermostatic device (10) according to one of the previous paragraphs, characterized in that at least one protruding element (18c) is made along the recess in the main part (18b) to transmit the clamping force between the main part (18b) and the fastening clamp (18a ) in the longitudinal direction of the temperature control device (10). 14. Thermostatic device (10) according to one of the previous paragraphs, characterized in that it is made in the form of a resistive heating device, and the thermostatic element (20) is made in the form of a heating element. 15. Thermal control system containing a thermostatic device (10) according to one of the previous paragraphs. 16. The system according to claim 15, which is a distribution cabinet or electronic equipment housing.

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