WO2024156715A1 - Profile, profile arrangement and temperature control system - Google Patents

Abstract

The invention relates to a profile for receiving at least one conducting body which receives and conducts a cooling or heating medium. The profile has a component contact portion which is provided to cooperate in a holding manner with a component. The profile has a conducting body holding portion which is in thermal contact with the component contact portion. The conducting body holding portion is provided to receive and hold the conducting body. The conducting body holding portion has an insertion opening which is provided such that the conducting body can be inserted into the conducting body holding portion through said insertion opening.

Description

Profile, profile arrangement and tempering system

The invention relates to a profile, a profile arrangement and a temperature control system, each according to the respective preamble of the independent claims.

In particular, the invention relates to a profile for receiving at least one conductive body that receives and conducts a cooling or heating medium, wherein the profile has a component contact section that is intended to cooperate with a component in a holding manner, and the profile has a conductive body holding section that is in thermal contact with the component contact section, and the conductive body holding section is intended to receive and hold the conductive body, and the conductive body holding section has an insertion opening that is intended to allow the conductive body to be inserted into the conductive body holding section.

The profile described at the beginning is known, for example, from the European patent application EP 1 688 672. Here, the U-shaped line body holding section is located between two sections of the component contact section. The assembly of the (tubular or hose-shaped) line body takes place through the plane of the component contact section.

This structure works very well for the substructure described here, where the

Component contact section subsequently carries, for example, ceiling elements facing the room. However, this suggestion does not work if this profile is to be mounted on a heat storage unit, for example in the case of renovation on a concrete ceiling or solid facade in an existing building, or is used to transfer/introduce heat on a photovoltaic panel or a facade. This is because the component contact section then lies on the heat storage unit or the heat-emitting surface, e.g. a photovoltaic panel or a heat-absorbing container, and after the profile has been mounted, the insertion opening for the introduction of the cable body is no longer accessible.

A further disadvantage of this prior art proposal is that the line body, which carries the cooling or heating medium, rests on the bottom of the U-shaped line body holding section and is therefore relatively far away from the component contact section, via which the heat or cold is simultaneously transferred to the component. The thermal contact is not optimal.

In order to improve thermal contact over the lateral tangents and as a whole, the line bodies are pressed into U-shaped line body holding sections with great tension, sometimes with mechanical support. The deformation of the line body holding section that this creates is intentional in order to achieve tension on the pipe body via the restoring forces of the profile material. However, this always means that the component contact sections are no longer aligned with one another and parallel to a component plane. The U-shaped line body holding section is chaotically bent in practice on the construction site. Compensation by changing the angle of the component contact section to the legs of the line body sections is only possible to a limited extent due to the chaotic behavior. The effect is more serious the wider the profile and the more line bodies it contains. This deformation leads to a significant reduction in the form-fitting contact area and thus a reduction in the heat conduction from the component contact section into the component.

In this proposal, the component contact sections are also not in contact with the heat-emitting or heat-introducing surface over the entire profile width. In the area of the cable body holding section, a minimal contact could be made at most via the tangent of the cable body. With the known proposal, a loss of contact area of 10% to 20% must usually be accepted. It is therefore the object of the present invention to improve this state of the art and to propose a solution that enables flexible installation of the conductor body both in the case of room heating as a substructure of a heat-radiating ceiling, and as a heat coupling element, for example to an activatable mass storage device, such as a concrete ceiling storage device, a photovoltaic system or other heat-emitting surface, e.g. the wall of a corresponding container, but also in relation to the air or gas volume of a room.

At this point, it should be emphasized that the invention described here functions both for the purpose of heat transfer and cold transfer (heat dissipation/heat introduction). If only one application is discussed below, for example the transfer of heat, this does not exclude the other application, the transfer of cold (i.e. the dissipation of heat), but expressly includes it. Ultimately, in this case, only the energy or heat flows are reversed.

To achieve this object, the invention proposes that the line body holding section is at least partially designed to be resilient in such a way that the direction of action of this spring force is directed towards the component contact section and that the profile has a fastening section and the fastening section is oriented substantially at right angles to the longitudinal extension of the profile and the fastening section is provided to fasten the profile to a holding structure or the fastening section forms a substructure for fastening a ceiling or wall paneling or the like.

Usually, the line body holding section, seen in section, is adapted to the cut surface of the line body and often consists of round or rounded pieces. Such a design allows the line body to rest on the line body holding section over as large an area as possible, resulting in good heat transfer. The inventive proposal that the line body holding section is at least partially designed to be resilient in such a way that the direction of action of this spring force is directed towards the component contact section means that the line body inserted into the line body holding section is pressed by at least one resilient part of the line body holding section in the direction of the component contact section and thus exactly in the area in which the heat (or cold) is to pass from the cable body into the component contact section and then into the component. This results in an angled or lateral orientation or arrangement of the insertion opening, which remains accessible in both applications (profile as part of a substructure, in particular for holding a ceiling element and profile for mounting on a heat storage unit) when the assembly is carried out skillfully. In addition, the component contact section is not interrupted, which means that the full width of the profile is available as a contact surface, despite the fact that the cable body can be easily pressed in and removed again even after the profile has been mounted and still lies directly and maximally on the component contact section. The component contact section is also not deformed by pressing in cable bodies, the contact between the component contact section and the component is maintained at all times.

Furthermore, the invention proposes that the profile has a fastening section and the fastening section is oriented essentially at right angles to the longitudinal extension of the profile and the fastening section is intended to fasten the profile to a support structure or the fastening section forms a substructure for fastening a ceiling or wall paneling or the like. The profile according to the invention is therefore sufficiently stable and self-supporting. It does not require an additional support structure or support plate. The profile is therefore multifunctional, as it not only ensures optimal heat input and output, but at the same time forms a mechanically resilient fastening base, which leads to corresponding efficiency advantages when implemented.

A profile designed in this way therefore optimally solves the task set at the beginning.

The solution described at the beginning describes a one-piece profile. The invention is not limited to such a design, the object described at the beginning is also achieved by a profile arrangement for receiving at least one line body that receives and conducts a cooling or heating medium, wherein the profile arrangement consists of at least a first profile part and a second profile part, wherein the first profile part has a component contact section that is intended to cooperate with a component in a holding manner and the first profile part has a first part of a line body holding section that is in thermal contact with the component contact section, and the second profile part has a second part of the line body holding section, wherein the first and the second profile part can be releasably and firmly connected to one another in such a way that the two parts of the line body holding section, in the connected state of the two profile parts, form the line body holding section which is intended to receive and hold the line body, and the line body holding section has an insertion opening which is intended for the line body to be inserted into the line body holding section, in particular between the first and second parts of the line body holding section, and at least a part of the line body holding section is designed to be resilient in such a way that the direction of action of this spring force is directed towards the component contact section.

In the context of this application, "removably and firmly connectable" means that the elements to be connected to one another can be separated again without causing any damage. This includes, for example, clips or plug connections; this does not include, for example, welded connections.

In this embodiment, the line body is also held by the line body holding section. In the variant described here, the invention is designed in a multi-part profile arrangement and consists of at least two, possibly more than two, separate profile parts. In this variant, the function of the line body holding section is preferably divided into two, spatially or functionally separate parts and ideally assigned to one profile part each.

The first profile part has a component contact section and thus functions in a similar way to a base plate. A second profile part can then be removably mounted on this first profile part, which then serves to hold at least one cable body, or possibly several cable bodies.

Alternatively, the first profile part carries two second profile parts, which in turn are connected to the first profile part in a detachable and fixed manner. Each of these second profile parts is intended to carry one or more line bodies.

A detachable, fixed connection is understood as follows: If the two profile parts are firmly connected to each other, they are sufficiently stable to each other, which leads to For example, it is made using a form-fitting connection, a clip or screw connection or something similar. However, this connection can also be separated again without causing any damage, i.e. it can be removed.

A significant advantage of the two- or multi-part construction is that, for example, in a first step the first profile part is mounted or fastened, on or in which the line body(s) is/are then placed and then the second profile part is connected to the first profile part in the final step and thus, due to the resilient effect, the line body is optimally pressed in the direction of the component contact section into the line body holding section and thus a good thermal contact is formed between the line body and the line body holding section.

The profile arrangement according to the invention thus described ultimately provides a modular system that makes it possible to provide solutions for different installation situations with a small number of profile parts. For example, it is provided that the height of the second profile part is variable in different variants and can thus be adapted to different heights of a suspended ceiling.

The object described at the outset is also achieved by a profile that is or can be equipped with one or more additional elements. Therefore, the invention also includes a profile (or a profile system) with one or more conductor body holding means for receiving at least one conductor body that receives and conducts a cooling or heating medium, wherein the profile (or the profile of the profile system) has a component contact section that is intended to cooperate with a component in a holding manner and the profile has a conductor body holding section that is in thermal contact with the component contact section, and the conductor body holding section is intended to hold the conductor body, and the profile, at least in sections, carries at least one resilient conductor body holding means and the direction of action of the spring force or spring forces of this conductor body holding means is/are directed towards the component contact section.

According to the invention, it is provided that a plurality or a multiplicity of individual lead body holding means are provided, which are connected to the inventive Profile for holding the cable body. It is intended that these can also be detachably connected to the profile.

In this embodiment, the profile is provided with a particularly continuous feature that is intended to accommodate and hold the line body holding means. This feature can be designed as a rail or as a receiving recess, for example. It ideally extends over the entire length of the profile. It serves to position or fasten the line body holding means at different positions on the profile, in particular if the line body holding means is designed as a clamp and the line body is fastened with a plurality of these clamp-like line body holding means.

Alternatively, it is provided that the line body holding means itself is also designed in a profile-like or rail-like manner. The profile or profile system proposed here differs from the profile arrangement described above in that in the profile arrangement the second profile part takes on additional functions in addition to providing a force component due to a spring effect.

It has been found that the spring effect of a part of the line body holding section allows the line body to be positioned in an optimal manner. This clever feature of the invention results from the elastic design. This clever feature of the invention can also be used in other proposals that solve the problem set out at the beginning in the same way.

Therefore, a temperature control system described below also solves this problem. This temperature control system has a profile and a line body, wherein the line body receives and conducts a cooling or heating medium, and the profile has a component contact section which is intended to cooperate with a component in a holding manner, and the profile has a line body holding section with a first and a second part, and the line body holding section is in thermal contact with the component contact section, and the line body holding section is intended to receive and hold the line body, and the line body holding section has an insertion opening which is intended to allow the line body to be inserted into the line body holding section, and the The lead body is at least partially resilient in such a way that it rests against the second part of the lead body holding section facing away from the component contact section and against the first part of the lead body holding section facing the component contact section.

This inventive concept can now be implemented not only in a one-piece profile, but also in a tempering system in which the profile is made up of several parts. Therefore, the invention also includes a further temperature control system which has a profile arrangement (preferably as described here) and a line body, wherein the line body receives and conducts a cooling or heating medium, and the profile arrangement consists of at least a first profile part and a second profile part, wherein the first profile part has a component contact section which is intended to cooperate with a component in a holding manner and the first profile part has a first part of a line body holding section which is in thermal contact with the component contact section, and the second profile part has a second part of the line body holding section, wherein the first and the second profile parts can be releasably and firmly connected to one another in such a way that the two parts of the line body holding section form the line body holding section in the connected state of the two profile parts, which is intended to receive and hold the line body, and the line body holding section has an insertion opening which is intended for the line body to be inserted into the line body holding section, in particular between the first and second parts of the line body holding section. can be inserted or inserted, and the lead body is at least partially designed to be resilient such that it rests against the second part of the lead body holding section facing away from the component contact section and against the first part of the lead body holding section facing the component contact section.

In these two variants according to the invention, the elasticity of the hose-like line body is used, which is particularly advantageous for relatively rigid profiles or profile parts (if these are designed as extruded aluminum profiles, for example). It is intended that the elasticity, i.e. the springy effect of the line body, is used both in the one-piece design of the profile according to the invention and in the multi-part variant can be used in the profile arrangement according to the invention. Of course, the necessary opening, which is made possible and limited by the resilient effect of the one- or two-part profile, can be reduced by the elasticity and spring force of the pipe material and the contact pressure of the line body against the line body contact section can be increased in the interaction of both components. It was recognized that the contact pressure can be increased further if the line body is deformed when pressed in, also by mechanical deformation, so that its diameter between the line body contact section and the line body holding section increases.

These proposals include several variants. On the one hand, the elasticity of the cable body is used, but this can also be combined with the spring effect of the cable body section. Both variants are part of the invention.

The invention provides that the proposed profile (as well as the described profile arrangement or the temperature control system) accommodates one or more line bodies in which both a gaseous and a liquid cooling or heating medium is guided. The line body itself is designed, for example, as an (endless) hose or pipe. Frost-proof and temperature-resistant fluids are also proposed. In particular, if the invention is used to supply or remove heat from solar systems, such as photovoltaics or solar thermal systems. Thus, as was surprisingly discovered, the same invention can also be used according to its intended purpose for heat removal, cooling or defrosting systems, including photovoltaic or solar thermal systems, or fluid-holding containers, or even for absorbing solar heat. The latter case, it was surprisingly discovered, is predestined for the newly proposed system, since the component contact section is not interrupted and is available in its full width.

The material of the hose/pipe is characterized by a low coefficient of thermal expansion, which means that it can be used for both heating and cooling and provides heat transfer between the pipe body and the profile in every application. This advantageously results in the temperature control system according to the invention being usable with comparable efficiency for both heating and cooling. For example, PEX pipes (cross-linked polyethylene), composite pipes or copper pipes are preferred. According to the invention, it is provided that the component contact section of the profile cooperates with a component in a holding manner. The invention comprises two main implementation options. In the first, the component holds the profile, for example the concrete floor slab serving as a heat storage device (as a component) holds the heat-coupling profile. In the second variant, the profile holds, for example, a ceiling element (as a component) of a suspended ceiling.

If the component according to the invention is used in conjunction with a photovoltaic system, the latter can also be placed on the component. It was also discovered that the invention can also be used as a thermally active substructure with static properties relating to the construction of photovoltaic or solar systems.

The object described at the outset is also achieved by the following object. The proposed profile serves to accommodate at least two conductive conductor bodies, each of which accommodates a cooling or heating medium and conducts it, wherein the profile has a component contact section which is intended to cooperate with a component in a holding manner, and the profile has at least two conductor body holding sections which are in thermal contact with the component contact section, and the conductor body holding sections are intended to accommodate and hold the conductor body, and the conductor body holding sections each have an insertion opening which is intended so that the respective conductor body can be inserted into the conductor body holding section through these, and the respective insertion openings of the conductor body holding sections are arranged facing away from one another, and the conductor body holding sections are at least partially designed to be resilient in such a way that the direction of action of these spring forces is directed towards the component contact section.

Ideally, the two cable body holding sections run parallel to each other in the longitudinal direction of the profile. Since the respective insertion openings are arranged facing away from each other, the cable bodies can be inserted into the respective body holding sections after the profile has been mounted on a component (for example on the underside of a ceiling as a mass storage device) and are thus also accessible after assembly. Ideally, the profile according to the invention is designed to be self-supporting or inherently stable. In a variant of the invention, it can also be equipped with a separate fastening section for fastening other components such as wall or ceiling paneling, or this task can be performed by elements separate from the profile. Both equipment variants are part of the invention.

In a preferred embodiment of this variant of the invention, it is provided that the profile according to the invention has exactly two line body holding sections, into which the respective line body can be installed independently of one another by means of the proposed arrangement.

A further advantage of the invention is that the proposed profiles or profile arrangements according to the invention are intended for direct mounting on a component (for example a ceiling or similar) and thus, in contrast to the implementation in individual ceiling elements with a complex structure for heating or cooling, achieve a high level of efficiency during assembly and allow rapid implementation.

A key advantage of the inventive solutions presented here (be it as a profile, profile arrangement, as a temperature control system or as a component arrangement) is that in these different implementations of the invention, a room can be both effectively heated and, with the same proposal, optionally cooled as required. The invention is therefore not only limited to heating or cooling, but its design allows effective operation in both applications.

Furthermore, the proposal advantageously provides that the perpendicular bisector of the insertion opening with the profile transverse extension encloses an insertion angle a which lies between -20° and +75°.

The insertion opening is part of or is located on the line body holding section. Since this is incorporated (or realized) in the profile or the profile arrangement in particular in a channel-like manner, it extends along the profile or the profile arrangement. The insertion opening is limited by longitudinal edges, an upper and a lower edge. These two edges usually run parallel with a certain distance from each other. In section These two edges can be described as endpoints that can be connected by a connecting line. The perpendicular bisector is now at right angles to this connecting line, exactly in the middle, between these two endpoints.

The transverse profile extension is oriented at right angles to the longitudinal profile extension and is usually oriented parallel to the component contact section, which is preferably flat in order to provide the best possible heat transfer to the flat component adjacent thereto.

The notation of the insertion angle is chosen such that a parallel orientation of the perpendicular bisector to the profile transverse extension corresponds to an insertion angle a = 0° (the "horizontal"). In this case, the insertion opening is accessible from the side. However, the inventive design is not limited to this insertion angle; the inventive approach can be implemented in an angle interval, as stated, from -20° to +75°. According to the invention, it is also provided that the orientation of the perpendicular bisector is also possible below the horizontal, i.e. with a negative insertion angle.

An interval is specified for the insertion angle, which is described by an upper and lower limit. The following values are provided as the upper limit, for example: +75°, +70°, +65°, +60°, +55°, 50°, +45°, +40°, +35°, +30°, +25°, +20°, +15°, +10°.

The following values are considered lower limits: -20°, -15°, -10°, -5°, 0°, +5°, +10°, +15°, +20°, +25°.

The disclosure of this application includes the set of all intervals consisting of all possible, technically correct combinations (upper limit is greater than the lower limit) of the aforementioned upper and lower limits. All these intervals belong to the invention.

In particular, the object according to the invention is also achieved by the following profile, which is characterized in that it is provided for receiving at least one conducting body receiving and conducting a cooling or heating medium, wherein the profile has a component contact section which is provided for cooperating with a component in a holding manner and the profile has a conducting body holding section which is connected to the Component contact section is in thermal contact, and the lead body holding section is provided to receive and hold the lead body, and the lead body holding section has an insertion opening which is provided so that the lead body can be inserted into the lead body holding section, and the perpendicular bisector of the insertion opening encloses an insertion angle a with the profile transverse extension which lies between -20° and +75°.

Furthermore, the object according to the invention is also achieved by an alternative profile arrangement, which is characterized in that this profile arrangement is provided for receiving at least one line body that receives and conducts a cooling or heating medium, wherein the profile arrangement consists of at least a first profile part and a second profile part, wherein the first profile part has a component contact section that is intended to cooperate with a component in a holding manner and the first profile part has a first part of a line body holding section that is in thermal contact with the component contact section, and the second profile part has a second part of the line body holding section, wherein the first and the second profile parts can be releasably and firmly connected to one another in such a way that the two parts of the line body holding section, when the two profile parts are connected, form the line body holding section that is intended to receive and hold the line body, and the line body holding section has an insertion opening that is intended to allow the line body to be inserted into the line body holding section, in particular between the first and second parts of the line body holding section, and the perpendicular bisector of the insertion opening with the profile transverse extension encloses an insertion angle a which lies between -20° and +75°.

It should be noted that these two alternative solutions according to the invention can be combined with all the features of this description; all possible variants are part of the invention.

In a preferred embodiment of the proposal, it is provided that the component contact section has a connection region and the component contact section carries the lead body holding section at the connection region. The invention is very flexible in the design of this feature. Firstly, it is provided that the component contact section is formed in one piece, in particular in one material, with the line body holding section. Such an integral design also has a connecting region at which these two sections functionally abut one another.

Therefore, in a further preferred embodiment, it is provided that at least a partial region of the lead body holding section, in particular the first part of the lead body holding section, is integrated in the component contact section.

For example, it is provided that the profile or profile arrangement (also the profile or profile arrangement of the temperature control system) is designed as an extruded profile, where these two sections are integrated or arranged next to each other to save space. The invention is not restricted to the specific manufacturing method. Alternatively, it is provided that the connection area is a weld (for example roll welding) or an adhesive point where elements with the different functions are joined together. Preferably, a material with good heat conductivity is selected for the profile or profile arrangement, which is why, in addition to aluminum, steel sheets or metal in general can be used to implement the invention, but carbon-containing materials, e.g. mixtures of fibers, including plant fibers and graphite or plant charcoal and known adhesives, from lime/quark to plant resins, synthetic adhesives and much more, are also possible. It is also possible to realize the profile or the partial profiles as rolled components.

In a preferred embodiment, it is therefore provided that the first part of the line body holding section is designed as a longitudinal groove in the component contact section. This creates optimal thermal contact between the line body on the one hand and the component contact section on the other, since according to the various variants of the invention it is ensured that the line body is pressed into the first part of the line body holding section either by its elastic design or the elastic design of at least a part (for example the second part) of the line body holding section, in order to form a full, good thermal contact. Furthermore, it is provided that the profile has a fastening section and the fastening section is oriented essentially at right angles to the longitudinal extension of the profile. Depending on the intended use of the profile, profile arrangement or temperature control system proposed according to the invention, the fastening section has different functions. In the first application, the fastening section itself serves to fasten the profile, the profile arrangement or the temperature control system to a support structure. In the other application, the fastening section itself serves to form a substructure to which, for example, a ceiling or wall cladding, or solar energy system, etc., is fastened.

In particular, it is provided that the fastening section is also preferably oriented (essentially) at right angles to the transverse extension of the profile. "Essentially at right angles" here means that this also includes acute-angled arrangements. The arrangement is selected so that a certain distance is provided in the right-angled direction.

In an advantageous embodiment, the fastening section is formed by two L-shaped strips arranged symmetrically to one another. A first leg of the L extends at right angles to the longitudinal extension and defines through its length the distance of the substructure or the component contact section from the wall or ceiling, but also its static load-bearing capacity. The second leg adjoining this allows the engagement behind a corresponding holder, such as a cross connector or similar.

Cleverly, it is provided that a gap is provided between the fastening section, in particular the strip, and the line body holding section. The gap causes a thermal decoupling of the fastening section from the line body holding section or a considerable thermal resistance between these two elements and promotes the flow of thermal energy in the direction of the component contact section.

Advantageously, it is provided that the line body holding section is designed in section in such a way, in particular in sections oval-shaped, that the line body that can be inserted into the line body holding section is in close proximity to the Connection area rests on the cable body holding section. The term "oval-shaped" is to be understood in such a way that the cable body holding section is, for example, an ellipse in section, the special shape of which is of course also a circle. It is clear that since the cable body holding section also accommodates the insertion opening, at least the section is oval in sections. The proposed design of the cable body holding section is advantageously adapted to the cutting surface of the cable body in such a way that the cable body inserted into the cable body holding section rests as close as possible to the component contact section or the connection area rests on the cable body holding section and the heat can thus be transferred over short distances, which is beneficial to effectiveness.

Furthermore, the proposal advantageously provides that the insertion opening is arranged parallel to the longitudinal extension of the profile on the line body holding section.

In a preferred embodiment of the proposal, the area of the line body holding section is designed to be resilient and elastic at least on one side of the insertion opening. The line body holding section preferably consists of several parts, the first and second parts of the line body holding section, which face towards and away from the component contact section. The first part, facing the component contact section, is designed like a channel and forms a certain bed surface that serves as a heat exchange contact surface. Preferably, the second part of the line body holding section, facing away from the component contact section, is designed to be resilient and elastic, but the invention is not limited to this variant. The design described here can be found both in the profile according to the invention and in the profile arrangement consisting of at least two profile parts.

Furthermore, it is intended that the direction of action of the spring force is directed towards the connection area. The connection area describes the area in which the component contact section carries the line body holding section. It therefore belongs to the component contact section and specifies the direction of action of the spring force precisely to the area in which the heat absorbed by the line body (in the case of cooling) or released (in the case of heating) ultimately reaches the component contact section and thus the component via the line body holding section. It should be noted that the The direction of action of the spring force can be described in particular by a vector whose starting point is the contact point of the lead body on the part of the lead body holding section facing away from the component contact section and whose arrow direction (the front end of the vector) lies in the central region of the contact region of the lead body in the first part of the lead body holding section facing the component contact section.

In an advantageous embodiment, it is provided that the line body holding section has a longitudinal strip on at least one side of the insertion opening. This further development according to the invention ensures that the line body "snaps" into the channel-like line body holding section.

The arrangement of a strip as described has several advantages. Firstly, it specifies the point at which the resilient force acts on the lead body. This resilient force can result either from the elasticity of the lead body or the elasticity of the lead body holding section. The strip is preferably located on the part of the lead body holding section facing away from the component contact section. Since the insertion opening is preferably oriented at an angle, obtuse angle or parallel to the component contact section, the power body is located between the strip and the component contact section when assembled. In addition to the precisely defined introduction point (or line) of the holding force, the strip also forms a poor heat transfer between the lead body and this area of the lead body holding section, which is advantageous because the heat is therefore preferably distributed on the part facing the component contact section.

Line body holding section is replaced. It is clear that the arrangement of the strip, as described, can be implemented both in the one-part design of the invention in a profile and in the multi-part design of a profile arrangement and of course also in the temperature control system according to the invention.

In a further preferred embodiment, the outer diameter of the line body is approximately 1/10 to 2 mm, in particular 1 to 5/10 mm, preferably 1 to 2/10 mm larger than the width of the insertion opening. Such a geometric design leads to similar effects to the arrangement of a strip. The width of the insertion opening is defined by the distance between the opposite lower and upper edges that delimit the insertion opening. It is cleverly provided that the outer diameter of the line body is approximately 1 to 5/10 mm, preferably 1 to 2/10 mm larger than the inner diameter of the line body holding section or the average distance between the opposing first and second parts of the line body holding section.

The effect of this variant according to the invention is that the line body is squeezed into the line body holding section with a slight excess. This has two effects, depending on the design of the profile according to the invention or profile arrangement or temperature control system:

If the profile or profile arrangement or the profile or profile arrangement of the temperature control system is relatively rigid (for example because it is made of an aluminum extruded material), the line body will deform elastically during assembly in the line body holding section. The resulting spring force positions and presses the line body in the line body holding section to the desired location, as described above.

If the profile or profile arrangement or the profile or profile arrangement of the temperature control system is relatively soft (for example because it consists of a folded metal sheet made of steel or iron), the line body holding section will deform elastically when the line body is mounted in the line body holding section. The resulting spring force also positions and presses the line body in the line body holding section to the desired location, as described above.

The line body is usually cylindrical, with a round base, but the design of the line body is not determined by this. The line body holding section that holds the line body is also (ideally) round, in particular circular. Their size relationships to one another can therefore be described by comparing the respective diameters. However, if the geometry deviates from a round shape, the geometry relevant here is described by the average distance between the opposing first and second parts of the line body holding section. The average distance is the arithmetic mean of the distances between the opposing first and second parts of the lead body holding section in the region of the lead body holding section.

The same effect as with the aforementioned feature is also achieved with the following advantageous embodiment. The profile, profile arrangement or temperature control system are characterized in that the outer diameter of the line body is approximately 1/10 to 2 mm, in particular 1 to 5/10 mm, preferably 1 to 2/10 mm larger than the width of the insertion opening.

Furthermore, it is advantageously provided that the first or second profile part has at least one connecting element which can be firmly but detachably connected to a connecting means of the second or first profile part. Such a design, which can be implemented for example by a clamping tongue and groove connection or a clip connection, but also quite classically with a screw connection, provides a detachably fixed connection between the first and second profile parts.

Advantageously, the fastening section is part of the first or the second profile part. Such a variant according to the invention relates in particular to the profile arrangement or the temperature control system according to the invention. This proposal distinguishes the flexibility of the invention, since either the first or the second profile part can carry the fastening section.

Furthermore, it is advantageously provided that the ratio of the distance of the bed surface of the lead body holding section from the contact surface of the component contact section to the average thickness of the component contact section is in a range of approximately 0.3 to 10, in particular from 0.4 to 6, particularly preferably from 0.4 to 3.

The bed surface of the lead body holding section is the surface on which the lead body mounted in the lead body holding section rests on the lead body holding section, i.e. touches it. This contact represents a very good thermal contact. The bed surface is an area of the lead body holding section. The contact surface of the component contact section is on the side of the profile or profile part facing away from the cable body holding section. The component lies as tightly and as completely as possible on the contact surface in order to form good thermal contact.

The contact surface is usually flat. The bed surface is typically adapted to the outer contour of the line body and corresponds more to the surface of the shell of a cylinder with a round or elliptical base. Typically, the bed surface is therefore not oriented parallel to the contact surface. In order to determine the distance between the bed surface and the contact surface, the bed surface is first determined. The various points on the bed surface now have different distances from the contact surface. The distance is the shortest distance between these two surfaces. From this, the arithmetic mean is determined, which corresponds to the distance in the sense of this disclosure.

The feature proposed in this preferred embodiment is based on the fact that the heat transported by the conductor body (in the heating case) reaches the component via a short path. In the cooling case, the heat flow is reversed.

An interval is specified for the distance, which is described by an upper and lower limit. The following values are provided as upper limits, for example: 26; 25; 24; 23; 22; 21; 20; 19; 18; 17; 16; 15; 14; 13; 12; 11; 10; 9; 8; 7; 6; 5; 4; 3; 2.5; 2; 1.5; 1; 0.8.

The following values are considered as lower limits: 0.3; 0.35; 0.4; 0.5; 0.6; 0.7; 0.8; 0.9; 1; 1.2; 1.4; 1.6; 1.8; 2; 2.3; 2.6; 3; 3.3; 3.6; 4.

The disclosure of this application covers the set of all intervals consisting of all possible, technically correct combinations (upper limit is greater than the lower limit) of the aforementioned upper and lower limits.

In a preferred variant, it is provided that a bed surface of the cable body holding section facing the cable body to be inserted or inserted is smooth. In particular, it is also alternatively provided that the inner surface of the component contact section, of which the bed surface is a part, is smooth, in particular in the region of the component contact section or the connection region.

In this context, "smoothly formed" means that the surface, which is in particular continuously curved, has no elevations, depressions, beads, cracks or similar. This smooth surface allows the pipe body inserted into the pipe body holding section to always lie as flatly and snugly as possible in the pipe body holding section, essentially regardless of the temperature of the medium flowing in it (water or air, cold or warm), thus providing the best possible thermal transition.

Furthermore, it is advantageously provided that the profile has two line body holding sections which run longitudinally with the profile and whose respective insertion openings are arranged facing away from one another.

This means that the cable body sections remain accessible from the side when the profile or profile arrangement is assembled. Such a design allows the respective cable bodies to be assembled independently of one another without hindering one another.

The object of the invention described at the outset is also advantageously achieved by a component arrangement. This consists of a component, such as a preferably solid wall or ceiling component used to store thermal energy or a wall or ceiling paneling used in particular to regulate the temperature in a room, and a profile, a profile arrangement or a temperature control system, as described, wherein the component has a contact surface which interacts with the component contact section of the profile or profile arrangement and the line body holding section, which is accessible laterally through the insertion opening, accommodates the line body, through whose conducted cooling or heating medium the component can be temperature controlled.

All of the aforementioned advantages also become apparent in the component arrangement proposed here according to the invention. The interaction of the contact surface of the component with the component contact section is characterized by the fact that either the component holds the profile, the profile arrangement or the temperature control system or vice versa, i.e. the temperature control system, the profile arrangement or the profile supports the component.

"Temperature control" means heating or cooling the component, but also charging or activating the building mass storage (as a component). A building mass storage is, for example, a floor made of concrete or an internal or external wall.

The design of the profile or profile arrangement according to the invention results in a surprising additional assembly advantage in the component arrangement also proposed according to the invention, as described below. The component arrangement is characterized in this improved design in that it has at least two profiles or profile arrangements, and at least one continuous line body is provided and the line body is led out of the laterally open line body holding section of the first profile or the first profile arrangement and is introduced into the likewise laterally open line body holding section of the second profile or the second profile arrangement.

In the proposals according to the state of the art, the cable bodies are led out of the profile at the front. This means that the profile must be mounted on the ceiling at a corresponding distance from a wall in order to have sufficient space to connect or attach the cable body outside the profile. Ultimately, this circumstance results in a reduced area that can be tempered using the profile. Installation in the narrow edge area is also cumbersome and complex. These disadvantages are avoided and overcome by the advantageous design described above. The cable bodies that emerge from the side of the profile or profile arrangement can be connected more easily because more space is available. This also results in faster installation with greater utilization of the temperable area on the component. It was also surprisingly found that this also enables non-rectangular connections to room enclosures or other tempered ceiling areas and also does not lead to any thermal loss areas in the transition area. In particular, this design also makes it easier to lay several differently controlled pipe body strands. For example, it is intended that different pipe body strands are supplied by different heat sources. Since the individual pipe bodies are led out laterally on the profile or profile arrangement, they can be laid without any problems and without hindering each other. Overall, the lateral insertion of the pipe bodies leads to significantly greater flexibility, which is also reflected in the placement of supply points for the inflow/return of the fluid in the pipe body and the associated architecture. The pipes can be fed out of the profile and into the inflow/return at any point in the system.

It is clear that this advantage exists in both the single-piece profile and the multi-piece profile arrangement, since in both arrangements the line body holding section is laterally accessible.

Furthermore, the proposal advantageously provides that at least the area of the line body holding section facing the component contact section is formed at least partially parallel to the line body resting thereon. With this advantageous design of the component arrangement, the heat conveyed or dissipated in the line body (in the case of cooling) has an optimal heat transfer to the component contact section facing the component. This therefore proposes not only a linear contact, but also a flat contact of the line body on the line body holding section.

The object described at the outset is further achieved by a method for assembling a component arrangement, wherein firstly the profile is fastened with its component contact section to the surface of a component, in particular a solid wall or ceiling component, or the profile is fastened to the substructure supporting the profile, and then the cable body is inserted laterally through the insertion opening into the cable body holding section, wherein the insertion direction of the cable body into the cable body holding section is substantially parallel to the surface of the component. Also part of the invention and the disclosure of this invention is a method for assembling a component arrangement, wherein firstly the first profile part of the profile arrangement is fastened to the surface of a component, in particular a solid wall or ceiling component, or the first profile part is fastened to the substructure supporting the first profile part, then the second profile part is connected to the first profile part and then the cable body is inserted laterally through the insertion opening into the cable body holding section, wherein the insertion direction of the cable body into the cable body holding section is substantially parallel to the surface of the component.

Furthermore, the invention and the disclosure of this invention include a method for assembling a component arrangement, wherein firstly the first profile part of the profile arrangement is fastened to the surface of a component, in particular a solid wall or ceiling component, or the first profile part is fastened to the substructure supporting the first profile part, then the cable body is placed on the first part of a cable body holding section of the first profile part and then the second profile part is connected to the first profile part. By connecting the second profile part to the first profile part, the cable body, which is arranged between the two parts of the cable body holding section, is also fixed or clamped.

The methods proposed according to the invention are characterized on the one hand by the fact that they can be used in the same way for the various applications, i.e. assembly concepts, and thus make them easier to handle in principle. The sequence of steps is the same whether the profile or temperature control system according to the invention or the profile arrangement is supported by a component (for example the floor) or itself supports one or more components (for example the ceiling elements of a suspended ceiling). The assembly of the cable bodies in the cable body holding sections arranged on the side is also easier because the cable body holding section already supports and holds the cable body when it is inserted.

In this context, it is particularly pointed out that all features and properties described in relation to the device, i.e. the profile, the profile arrangement or the tempering system, but also procedures, are also transferable with regard to the formulation of the method according to the invention and in the sense of the invention can be used and are considered to be included in the disclosure. The same applies in the opposite direction, i.e. structural features mentioned only in relation to the method, i.e. features relating to the device, can also be taken into account and claimed within the scope of the device claims, in relation to the claimed profile, the profile arrangement, the temperature control system or the component arrangement and are also included in the disclosure.

Further features, details and advantages of the invention emerge from the wording of the claims and from the following description of embodiments with reference to the drawings. They show:

Fig. la, lb, lc each show in a sectional view various embodiments of the profile according to the invention

Fig. 2 shows a sectional view of an embodiment of the profile arrangement according to the invention

Fig. 3a, 3b, 3c, 5, 6 each show in a sectional view details of a profile according to the invention

Fig. 4a, 4b, 4c each show in a sectional view various embodiments of the component arrangement according to the invention

In the figures, identical or corresponding elements are each designated with the same reference numerals and are therefore not described again unless expedient. The disclosures contained in the entire description are transferable mutatis mutandis to identical parts with the same reference numerals or the same component designations. The position information chosen in the description, such as top, bottom, side, etc., also refers to the figure directly described and shown and, if the position changes, is to be transferred mutatis mutandis to the new position. Furthermore, individual features or combinations of features from the different embodiments shown and described can represent independent, inventive or inventive solutions in themselves. Figure 1a shows a first embodiment of the profile 1 according to the invention. It consists of a flat, strip-like component contact section 3, which has a flat, or minimally concave, flat contact surface 31 on its underside. The contact surface 31 serves as a heat exchanger surface for a component not shown here. The longitudinal extension of the profile is perpendicular to the plane of the drawing, the transverse extension of the profile is marked with the double arrow 10, perpendicular to the longitudinal extension of the profile.

The fastening section 5 is arranged at right angles to the longitudinal extension of the profile and the transverse extension 10 of the profile in the middle of the component contact section 3, above the upper side 32. The fastening section 5 is formed by two symmetrically arranged, L-shaped strips 50a, 50b.

In the embodiment shown in Figure 1a, the two L-shaped strips 50a, 50b are oriented towards each other. In general, it is of course also possible for the respective short legs of the two L-shaped strips 50a, 50b to be arranged facing away from each other. For example, a profile 1 according to the invention can be fastened to the elements of the fastening section 5 on a substructure of any design through openings in the component contact section 3 (not shown here).

Furthermore, it is (generally) provided that the L-shaped strips 50 a and 50 b interact with a holding element or profile to be fastened to the ceiling / wall, which is arranged between the two L-shaped strips 50 a and 50 b or interacts with it.

To the left and right of the strips 50a, 50b, on the upper side 32 of the component contact section 3 facing away from the contact surface 31, there is a line body holding section 4, 4a, 4b. The left line body holding section 4a is located on the left side of the left strip 50a. The right line body holding section 4b is located on the right side of the right strip 50b. The two line body holding sections 4a, 4b are arranged symmetrically on the component contact section 3.

However, the profile 1 according to the invention is not limited to such a symmetrical arrangement, the line body holding sections 4 can also be arranged asymmetrically on the Component contact section 3 can be arranged. The invention also includes solutions in which the profile 1 has only one or more than two line body holding sections 4.

In the embodiment shown here, there is a connection region 30 between the line body holding sections 4, 4a, 4b and the component contact section 3. The connection region 30 is designed here, for example, as an adhesive connection or welded connection, but without limiting the invention to the physical presence of the connection region 30, as is shown and described in particular in Figures 1b, 1c.

The line body holding sections 4a, 4b are constructed in the same way. The line body holding section 4, 4a, 4b is, seen in section, at least partially elliptical, oval or even round, with an insertion opening 40 on the side facing away from the fastening section 5. The insertion opening 40 extends on the profile 1 over the entire length of the profile. The insertion opening 40 is delimited by longitudinal edges 48a and 48b. The line body holding section 4 has at least two parts, the first part 41, which faces the component contact section 3, and the second part 42, which faces away from the component contact section 3.

The two parts 41, 42 have the edges 48a and 48b at their respective open ends, wherein the upper edge 48a is assigned to the second part 42 facing away from the component contact section 3 and the lower edge 48b is assigned to the first part 41 facing the component contact section 3.

These parts 41, 42 also have different functions. In the embodiment shown in Figure 1a, the second part 42 facing away from the component contact section 3 is designed to be elastic and springy, whereas the first part 41 facing the component contact section 3 functions more like a bed.

The insertion opening 40 serves to push or press the preferably hose-like line body 2 into the line body holding section 4. This takes place along the insertion movement 20, which in the embodiment shown here is essentially parallel or at an acute angle to the profile transverse extension 10. On the left side of Figure 1a it is shown how the line body 2 is already inserted into the left line body- holding section 4a is inserted. Now the inner diameter r in the line body holding section 4 is slightly smaller than the outer diameter 21 of the line body 2 to be inserted into it. The line body 2 is forced into the line body holding section 4 by the insertion movement 20, which leads to the elastic second part 42 of the line body holding section 4 being elastically bent back (upwards) and thus a force is developed, the direction of action F of which presses or presses the inserted line body 2 in the direction of the component contact section 3 into the bed-like first part 41 of the line body holding section 4. The elasticity of the second part 42 of the line body holding section 4 in this embodiment arises from the material of the line body holding section 4, which is designed, for example, as spring steel or similar elastic material, or has a springy effect due to its construction and geometry.

The embodiment according to Figure 1b is very similar to the embodiment according to Figure 1a, which is why only the differences will be discussed below.

The embodiment according to Figure 1b is, for example, designed as an extruded aluminum profile. With a profile 1 that is manufactured using such a process, a much more compact design of the profile 1 is possible. In particular, the fastening section 5 is not as high. The strips 50a, 50b are designed to be integrated with the respective line body holding sections 4. In particular, the long leg 51a, 51b is used multifunctionally. The long leg 51a, 51b essentially stands at a right angle above the component contact section 3. It therefore also forms an area of the line body holding section 4. At the upper end facing away from the component contact section 3 is the short leg 52a, 52b, which bends inwards at a right angle. The short legs 52a, 52b are extended outwards and form the second part 42 of the line body holding section facing away from the component contact section 3. Seen in section, the short leg 52a, 52b is essentially rectangular, just like in Figure 1a. A reduction in the height towards the centre of the profile can be just as advantageous for better fastening as the formation of a bevel or upstand to increase the statics. A connecting element engaging the substructure can also be better secured against pulling out if necessary. The profile 1 shown in Figure 1b is designed as an extruded profile. In particular, the second part 42 of the line body holding section 2 facing away from the component contact section 3 is too stiff and not elastic enough, which is why the radial elasticity of the hose-like line body 2 is used in this embodiment for the secure, full pressing of the line body 2 into the first part 41 of the power body holding section 4 designed as a groove 41a. Not shown, but also possible in the design, is the achievement of a constructive spring force in which the legs 50a, 51a; 50b, 51b extend in their full height up to approximately the material thickness of the contact surface 31, or penetrate into it.

In order to further enhance this effect, a strip 43 is provided in the cable body holding section 4 on the inside of the second part 42 of the cable body holding section 4 facing away from the component contact section 3. This strip 43 reduces the clear width in the cable body holding section 4, thus making it narrower. The cable body 2 pressed into this cable body holding section 4 (see arrow 20) is then supported linearly on the top of the strip 43 in the assembled state (see Figure 1b left area). The effective direction F of this spring force is directed in the direction of the component contact section 3. As a result, the cable body 2 is pressed over a large area onto the bed surface 41' of the first part 41 of the cable body holding section 4. A relatively large temperature exchange surface is created on the bed surface 41', via which the component contact section 3, which is located immediately below, is supplied with heat over a short distance, or via which heat is dissipated in the case of cooling.

The first part 41 of the lead body holding section 4 is designed as a groove 41a and almost extends into the material thickness of the component contact section 3. The functional connection area 30 between the lead body holding section 4 and the component contact section 3 is located in this area.

The proposal according to the invention is characterized in that the distances between the line body 2 and the contact surface 31 of the component contact section serving as a heat exchanger surface are as short as possible. This is achieved by the ratio of the distance a of the bed surface 41' of the line body holding section 4 from the contact surface 31 of the component contact section 3 to the average thickness d of the component contact section 3, in a

Range from 0.3 to 10, in particular from 0.4 to 6, particularly preferably from 0.4 to 3.

In the embodiment shown in Figure 1b, this ratio a/d is approximately 1.35.

In contrast, the ratio a/d in Figure 1c is approximately 0.8. It should be noted that the different thicknesses dl and d2 must be arithmetically averaged in order to determine the mean thickness d.

The embodiment according to Figure lc is very similar to the embodiments according to Figures la and lb, which is why only the differences will be discussed below.

The value of the ratio a/d achieved in this embodiment results from the fact that the first part 41 of the line body holding section 4 facing the component contact section 3 extends into the material thickness of the component contact section 3. The groove 41a extends into the component contact section 3. Nevertheless, the connection area 30 is located directly below the groove 41a.

In contrast to the embodiments according to Figures la and lb, the short leg 52a, 52b in Figure lc is also varied. Seen in section, the legs 52a, 52b are triangles, with the tips of the triangles pointing towards each other.

In Figure 2, the profile arrangement 1' according to the invention is shown as an embodiment. The structure of the profile arrangement 1' is similar in terms of height to the proposal according to Figure 1c. The characteristic of the profile arrangement 1' is that the profile arrangement 1' consists of several profile parts 11, 12.

The first profile part 11 has the function of a base plate 13. It provides the component contact section 3 and has the contact surface 31 on its underside, which, as already described, interacts with the component in a variety of ways. On the upper side 32, in the middle area of the base plate 13, a groove 14a is provided as a connecting element 14. The groove 14a is oriented parallel to the contact surface 31 and extends longitudinally over the entire profile part 11. The connecting element 14 is provided with a Connecting means 15 of the second profile part 12. The connecting means 15 is provided on the second profile part 12 as a spring 15a. The connection of the two profile parts 11, 12 is achieved by the spring 15a of the second profile part 12 being inserted into the groove 14a of the first profile part 11 in a clamping or clipping manner (for example by means of a positive fit).

The second profile part 12 also provides various functions. The spring 15a protrudes at a right angle from a main web 16. This main web 16 corresponds, among other things, to the long leg 51a of the fastening section 5, which has the short leg 52a at its end opposite the spring 15a, protruding at a right angle therefrom. The short leg 52a and the spring 15a protrude on opposite sides of the main web 16. On the same side as the spring 15a, the main web 16 carries the strip-like second part 42 of the line body holding section 4. This second part 42 extends essentially parallel to the spring 15a, but is longer than the spring 15a.

The function of the cable body holding section 4 is divided between the two profile parts 11, 12 in the embodiment according to Figure 2. The first profile part 11, the base plate 13, carries the first part 41 of the cable body holding section 4, which is designed as a groove 41a. The groove 41a is embedded in the material thickness of the component contact section 3, comparable to the embodiment according to Figure 1c. The second part 42 of the cable body holding section 4 has (as does the embodiment according to Figure 1c) a curve 42a on the side facing the upper side 32, in order to better fix the cable body 2 to be inserted.

The line body 2 (which is not shown in Figure 2) is inserted into the space between the curve 42a and the groove 41a. If the profile arrangement 1' is not rigid enough, the second part 42 of the line body holding section 4 is elastically bent and its springback causes a spring force which presses the line body 2 into the groove 41a and thus clamps it (as in Figure 1a, for example). If the rigidity of the profile arrangement 1', in particular of the second profile part 12, is too great, the inserted line body 2 is elastically deformed and this elastic deformation then results in the clamping force, as has already been described, for example, in the embodiment according to Figure 1b. It is clear that both in the one-piece design of the profile 1 according to the invention and in the design of the profile arrangement 1' according to the invention, both the second part 42 of the line body holding section 4 and the line body 2 are elastically deformed at the same time. How high the respective proportions of the elastic spring effect are ultimately depends on their material or construction details.

It is also clear that, alternatively, the second part 42 of the line body holding section 4 can also carry a (downward) projecting strip 43, as is shown, for example, in Figure 1b.

The embodiment shown in Figure 2 is particularly characterized by its symmetrical structure of the profile arrangement 1'. It has two parallel, symmetrically arranged second profile parts 12a, 12b. In this respect, the embodiment shown in Figure 2 is a variant of the profile arrangement 1' with a total of three profile parts. The fastening section 5 is formed by a clever interaction of the two second profile parts 12a, 12b. The respective short legs 52a, 52b are aligned with each other, as shown in Figure 1b.

A clever feature of the invention is that the insertion opening 40 is accessible from the side. Figures 3a, 3b and 3c show various embodiments for the arrangement and orientation of the insertion opening 40. The orientation of the insertion opening 40, which extends between the upper edge 48a and the lower edge 48b, is described by the inclination of the perpendicular bisector 49, which encloses the insertion angle a with the profile transverse extension 10. The notation of the insertion angle is chosen such that a parallel orientation of the perpendicular bisector to the profile transverse extension corresponds to an insertion angle a = 0° (the "horizontal"). This arrangement is shown in Figure 3a.

Figure 3b shows a negative insertion angle a, i.e. an insertion angle a < 0°. According to the invention, the insertion angle can be up to -20°. If the upper line body holding section or the line body, or both together, are made more flexible, the insertion angle can be further reduced. In this embodiment, the line body must be forced under the upper edge 48a. when it is pushed into the insertion opening 40. This results in a secure fit of the lead body 2 in the lead body holding section 4.

Figure 3c shows a positive insertion angle a (insertion angle a > 0°). According to the invention, this can be up to +75°. This angle could also be chosen to be somewhat steeper, depending on the spring effect of the material.

Figure 4a shows a first embodiment of the component arrangement according to the invention. The component 9 is implemented here as a ceiling component 90. The profile 1 according to the invention is mounted under the essentially horizontally oriented ceiling 90 in such a way that its contact surface 31 at the top lies snugly against the surface of the ceiling component 90 and thus forms good thermal contact between the component contact section 3 and the ceiling component 90. In the embodiment shown here, the component 9 carries the profile 1. It can be seen from the drawing that a slightly concave design of the component contact section 3 and a positive fastening in the middle area of the profile with the component leads to a higher contact pressure of the component contact section on the component 9. Such a design can also increase the tension of the line body sections on the line body. Such a design is expressly possible, if required with the development according to the invention, and is disclosed for all of the applications and designs mentioned, even if this is not shown separately.

Figure 4b shows the reverse application, namely that the profile 1 supports the component 9. The profile 1 is attached with its fastening section 5 to a substructure (not shown in detail) and the component 9 designed as a ceiling element 91 is attached to the contact surface 31 of the component contact section 3 with fastening means 92, for example screws. It is easy to see that the profile 1 is not yet completely covered by the ceiling elements 91, but is only partially installed. The right-hand area of the profile 1, in particular the right-hand cable body holding section 4b, is still accessible and the cable body 2 has just been pushed in from the side. In the subsequent assembly step (not shown), the right-hand profile part would then also be covered by a ceiling element. Figure 4c shows a similar structure to Figure 4b, but here the ceiling elements 90 are not screwed against the contact surface 31 of the component contact section 3, but are loosely placed on the lateral projections 33a and 33b, which adjoin the component contact section 3 on the outside of the line body holding section 4. In this embodiment, the contact surface 31 is not covered by a component 9, but faces directly towards the room 99 and can regulate its temperature accordingly. This suggestion is also part of the invention. A special feature of this design is the combination with a heat-insulating ceiling element 91. On the one hand, the thermal performance of the profile compared to the room is not reduced, and on the other hand, the insulation of the ceiling cavity and any component above it that is used as a heat storage device is very effective. An additional part of the profile, 33a and 33b, is insulated with the ceiling element 91. The effect can be further enhanced if this ceiling element 91 is equipped with a coating that reflects IR radiation for the ceiling cavity and the heat storage unit above it. Such a ceiling element 91 can consist of a wide variety of materials, be equipped with various other functions, e.g. acoustics, fire protection, etc., and is expressly disclosed in conjunction with the profile according to the invention.

It should be noted that the variants shown in Figures 4a, 4b and 4c are of course also possible with a profile arrangement 1' according to the invention.

Figure 5 shows the detail of another variant of the profile 1 according to the invention. It shows the right half of the profile 1 with the right strip 50b of the fastening section 5.

This proposal is characterized in that the profile 1, at least in sections, carries at least one resilient line body holding means 44. For this purpose, a longitudinal, in particular rail-like receiving recess 45 is provided in the profile 1. This is T-shaped or hammerhead-like in section. The line body holding means 44 can be inserted into this in a longitudinally movable manner. It is provided that a rail-like line body holding means 44 or several clamp-like line body holding means 44 are used. Alternatively, it is also provided that the clamp-like line body holding means 44 can be suspended in the receiving recess 45 at any point and can be fixed sufficiently firmly. The receptacle 45 can alternatively also by any other connection, e.g. locking into raised edges and punchings. The type of connection is not decisive for the effect of the spring force on the line body and the line body section described according to the invention. The direction of action F of the spring force or the directions of action of the spring forces of this/these line body holding means 44 is/are directed towards the component contact section (3). The deflected line body holding means 44' can be seen in dashed lines in Figure 5, the spring force (see arrow F) of which presses the line body 2', also shown in dashed lines, downwards into the bed-like first part 41 of the line body holding section 4.

The proposal according to the invention is characterized in that the profile or the parts of the profile arrangement can be manufactured using different manufacturing processes. The embodiment variant according to Figure la shows a combination of a relatively solid element, which comprises the component contact section 3 and the fastening section 5, with line body holding sections 4, preferably made of resilient material, which are welded or glued to one another.

The profiles or profile parts shown in the variants according to Figures lb, lc and 2 are made using the extrusion process, e.g. as extruded aluminum profiles. But carbon and fiber materials and much more are also possible.

Figure 6 shows a further alternative method of manufacturing the profile 1 according to the invention or a profile part of the profile arrangement 1'. In Figure 6, the right-hand line body holding section 4b is shown as a detail, enlarged, in an application, with component 9 mounted underneath. The striking feature of this embodiment is that the profile or profile part is designed as a rolled, edged and/or folded metal profile. The starting material for this proposal is therefore a metal or steel sheet with a relatively low thickness, which is then folded, edged and/or rolled accordingly in a large number of processing steps in order to achieve the desired shape. This proposal is characterized by the fact that the material thickness is relatively low, so the profile absorbs little heat and heat can therefore be transferred very quickly.

The sections of the rolled or folded component shown in Figure 6

Line body holding section 4, are from inside to outside as follows: In the application, the inner piece 400 runs parallel to the surface of the component 9 and functionally also takes over the task of the component contact section 3.

This is followed by a first arched area 401, which projects upwards at an acute angle and describes an approximately right-angled arc.

This is then followed by a 180° deflection 402, which simultaneously forms the upper edge 48 of the insertion opening 40.

After the deflection 402 there is a first inner bend 403 which, in the application case, interacts at least partially with the line body 2. This first inner bend 403 also describes approximately a right angle.

The first curved region 401, the deflection 402 and the first inner curve 403 form the second part 42 of the line body holding section 4 (facing away from the component contact section 3). Due to the springy, elastic property of the material of the second part 42, a spring-back characteristic is formed here when the second part 42 is deflected upwards, counterclockwise, by the inserted line body 2.

This first inner arc 403 is then followed by the second inner arc 404. The second inner arc 404 describes an arc of approximately 180°. The vertex 405 of the second inner arc 404 is positioned such that it also rests on the component 9 in the application case. It therefore represents part of the component contact section 3.

The apex 405 is embedded in the integrally integrated connection region 30 between the lead body holding section 4 and the component contact section 3.

The apex 405 is part of the bed surface 41' on which the inserted line body 2 acts due to the resilient effect of the first part 41 of the line body holding section 4. The second inner arc 404 ends in the outer deflection 406, which also simultaneously describes the lower edge 48 b of the insertion opening 40. The outer deflection 406 also describes a

Arc of approx. 180°.

The outer deflection 406 is then followed by the outer arc piece 407, which describes an approximately rectangular arc.

The second inner bend 404, the outer deflection 406 and the outer bend piece 407 form the first part 41 (facing the component contact section 3) of the line body holding section 4.

The outer piece 408, which in turn belongs to the component contact section 3, is then connected to the outside of the outer arc piece 407.

To increase performance, the doubled areas of the profile can be filled with heat-conducting fillers or treated with adhesive. In a preferred variant, this is achieved with specially coated sheets.

It is clear that the other areas of the profile or profile part can also be manufactured in the same way using these manufacturing processes, namely, for example, the fastening section 5. For example, it is provided that this folded profile is either followed by a folded fastening section 5, or the inner and outer pieces (400, 408) are placed/fastened/welded onto a profile holding plate (not shown here) and this profile holding plate holds the fastening section.

The invention is not limited to one of the embodiments described above, but can be modified in many ways.

All features and advantages arising from the claims, the description and the drawings, including structural details, spatial arrangements and method steps, can be essential to the invention both individually and in a wide variety of combinations. Reference number:

1 profile

1 ' Profile arrangement

10 Profile cross-section

11 first profile part

12 second profile part

13 Base plate

14 Connecting element

14a Connecting element

15 connecting devices

15a Spring

16 Main jetty

2 line bodies

20 Insertion movement

21 outer diameter

3 Component contact section

30 Connection area

31 Contact surface

32 Top

33a, 33b Overhang

4, 4a, 4b Line body holding section

40 Insertion opening

41 first part of the cable body holding section

41a gutter

41 ' bed area

42 second part of the line body holding section

42a Rounding

43 Bar

44 Line body retaining means

45 Recess

48a upper edge of the insertion opening

48b lower edge of the insertion opening

49 Bisecting lines 400 inner piece

401 Arch area

402 Redirection

403 first inner arch

404 second inner arch

405 Vertex

406 External deflection

407 outer arch pieces

408 Exterior

5 Mounting section

50a, 50b bar

51a, 51b Leg

52a, 52b legs

9 Component

90 Wall or ceiling component

91 Ceiling element

92 fasteners

99 Space a Insertion angle a Distance d Thickness

F spring force r inner diameter

Claims

Patent claims

1. Profile for receiving at least one conductive line body (2) that receives and conducts a cooling or heating medium, wherein the profile (1) has a component contact section (3) that is intended to cooperate with a component (9) in a holding manner, and the profile (1) has a line body holding section (4) that is in thermal contact with the component contact section (3), and the line body holding section (4) is intended to receive and hold the line body (2), and the line body holding section (4) has an insertion opening (40) that is intended to allow the line body (2) to be inserted into the line body holding section (4), the profile (1) has a fastening section (5) and the fastening section (5) is oriented essentially at right angles to the longitudinal extension of the profile (1), and the fastening section (5) is intended to fix the profile

(I) to be fastened to a support structure or the fastening section (5) forms a substructure for fastening a ceiling or wall covering or the like and the line body holding section (4) is at least partially designed to be resilient in such a way that the direction of action (F) of this spring force is directed towards the component contact section (3).

2. Profile arrangement for receiving at least one conducting body (2) receiving and conducting a cooling or heating medium, wherein the profile arrangement (1') consists of at least a first profile part (11) and a second profile part (12), wherein the first profile part (11) has a component contact section (3) which is intended to cooperate with a component (9) in a holding manner and the first profile part

(II) has a first part (41) of a lead body holding section (4) which is in thermal contact with the component contact section (3), and the second profile part (12) has a second part (42) of the lead body holding section (4), wherein the first and the second profile part (11, 12) can be releasably and firmly connected to one another in such a way that the two parts (41, 42) of the lead body holding section (4) form the lead body holding section (4) in the connected state of the two profile parts (11, 12), which is intended to receive and hold the lead body (2), and the lead body holding section (4) has an insertion opening (40) which is provided so that the lead body (2) can be inserted into the lead body holding section (4), in particular between the first (41) and second part (42) of the lead body holding section (4), and at least one part (41, 42) of the lead body holding section (4) is designed to be resilient such that the direction of action (F) of this spring force is directed towards the component contact section (3).

3. Profile for receiving at least one conductive line body (2) that receives a cooling or heating medium and conducts it, wherein the profile (1) has a component contact section (3) that is intended to cooperate with a component (9) in a holding manner, and the profile (1) has a line body holding section (4) that is in thermal contact with the component contact section (3), and the line body holding section (4) is intended to hold the line body (2), and the profile (1), at least in sections, carries at least one resilient line body holding means (44), and the direction of action (F) of the spring force or the directions of action of the spring forces of this/these line body holding means (44) is/are directed towards the component contact section (3).

4. Temperature control system which has a profile (1), in particular according to claim 1, and a line body (2), wherein the line body (2) receives and conducts a cooling or heating medium, and the profile (1) has a component contact section (3) which is intended to cooperate with a component (9) in a holding manner, and the profile (1) has a line body holding section (4) with a first (41) and a second (42) part, and the line body holding section (4) is in thermal contact with the component contact section (3), and the line body holding section (4) is intended to receive and hold the line body (2), and the line body holding section (4) has an insertion opening (40) which is intended for the line body (2) to be insertable into the line body holding section (4), and the line body (2) is at least partially designed to be resilient in such a way that it is supported on the side facing away from the component contact section (3). second part (42) of the line body holding section (4) supporting the first part (41) of the lead body holding section (4) facing the component contact section (3).

5. Temperature control system which has a profile arrangement (1'), in particular according to claim 2, and a line body (2), wherein the line body (2) receives and conducts a cooling or heating medium, and the profile arrangement (1') consists of at least a first profile part (11) and a second profile part (12), wherein the first profile part (11) has a component contact section (3) which is intended to cooperate with a component (9) in a holding manner and the first profile part (11) has a first part (41) of a line body holding section (4) which is in thermal contact with the component contact section (3), and the second profile part (12) has a second part (42) of the line body holding section (4), wherein the first and the second profile parts (11, 12) can be releasably and firmly connected to one another in such a way that the two parts (41, 42) of the line body holding section (4) in the connected state of the two profile parts (11,12) form the lead body holding section (4), which is intended to receive and hold the lead body (2), and the lead body holding section (4) has an insertion opening (40) which is intended for the lead body (2) to be insertable or inserted into the lead body holding section (4), in particular between the first (41) and second part (42) of the lead body holding section (4), and the lead body (2) is at least partially designed to be resilient in such a way that it rests against the second part (42) of the lead body holding section (4) facing away from the component contact section (3) and supports it against the first part (41) of the lead body holding section (4) facing the component contact section (3).

6. Profile for receiving at least two conductive conductor bodies (2), each of which receives a cooling or heating medium, wherein the profile (1) has a component contact section (3) which is intended to cooperate with a component (9) in a holding manner and the profile (1) has at least two conductor body holding sections (4, 4a, 4b) which are in thermal contact with the component contact section (3), and the conductor body holding sections (4, 4a, 4b) are provided to receive and hold the lead body (2), and the lead body holding sections (4, 4a, 4b) each have an insertion opening (40) which is provided so that the respective lead body (2) can be inserted into the lead body holding section (4, 4a, 4b), and the respective insertion openings (40) of the lead body holding sections (4, 4a, 4b) are arranged facing away from one another, and the lead body holding sections (4, 4a, 4b) are at least partially designed to be resilient in such a way that the direction of action (F) of these spring forces is directed towards the component contact section (3).

7. Profile, profile arrangement or tempering system according to one of the preceding claims, characterized in that the perpendicular bisector (49) of the insertion opening (40) with the profile transverse extension (10) encloses an insertion angle a, which is preferably between -20° and +75°.

8. Profile, profile arrangement or temperature control system according to one of the preceding claims, characterized in that the component contact section (3) has a connection region (30) and the component contact section (3) carries the line body holding section (4) on the connection region (30), wherein the line body holding section (4) is designed in section, in particular in sectionally oval, such that the line body (2) which can be inserted into the line body holding section (4) rests on the line body holding section (4) in close proximity to the connection region (30) and/or the direction of action (F) of the spring force is directed towards the connection region (30).

9. Profile, profile arrangement or tempering system according to one of the preceding claims, characterized in that the profile (1) has a fastening section (5) and the fastening section (5) is oriented substantially at right angles to the longitudinal extension of the profile (1).

10. Profile, profile arrangement or temperature control system according to one of the preceding claims, characterized in that the region of the line body holding section (4) is designed to be resilient, elastic at least on one side of the insertion opening (40) and/or the line body holding section (4) has a longitudinal strip (43) at least on one side of the insertion opening (40).

11. Profile, profile arrangement or temperature control system according to one of the preceding claims, characterized in that the outer diameter of the line body (2) is approximately 2 to approximately 1/10 mm, preferably approximately 1 to 2/10 mm larger than the inner diameter of the line body holding section, or the average distance between the opposing first (41) and second (42) parts of the line body holding section (4) and / or the outer diameter of the line body (2) is approximately 1/10 to approximately 2 mm, in particular 1 to 5/10 mm, preferably approximately 1 to 2/10 mm larger than the width of the insertion opening in its minimum width (40).

12. Profile, profile arrangement or temperature control system according to one of the preceding claims, characterized in that a bed surface (41) of the line body holding section (4) facing the line body to be inserted or inserted (2) is smooth.

13. Profile, profile arrangement or temperature control system according to one of the preceding claims, characterized in that the profile (1) has two line body holding sections (4, 4a, 4b) which run longitudinally with the profile (1), the respective insertion openings (40) of which are arranged facing away from one another.

14. Component arrangement, consisting of a component (9), such as a preferably solid wall or ceiling component (90) serving to store thermal energy or a wall or ceiling component serving in particular to control the temperature of the room. Ceiling covering (91, 92), and a profile (1), a profile arrangement (1') or a temperature control system according to one of the preceding claims, wherein the component has a contact surface which interacts with the component contact section (3) of the profile (1) or the profile arrangement (1') and the line body holding section (4) which is accessible laterally through the insertion opening (40) receives the line body (2), by means of whose conducted cooling or heating medium the component can be temperature controlled.

15. Method for assembling a component arrangement according to one of claims 18 to 19, wherein firstly the profile with its component contact section (3) is fastened to the surface of a component, in particular a solid wall or ceiling component or the profile (1) is fastened to the substructure supporting the profile (1), and then the line body (2) is inserted laterally through the insertion opening (40) into the line body holding section (4), wherein the insertion direction of the line body (2) into the line body holding section (4) is substantially parallel to the surface of the component.