NL7901881A - HEATING TUBE. - Google Patents

Description

• ·. * ”^ Τ

Artus Feist, in Bergisch Gladbach, Federal Republic of Germany Heating pipe ·

The invention relates to a heating pipe of a flexible, heat-resistant and conductive plastic material.

Such heating pipes are used in floor, wall and ceiling heating systems. Hot water flows through these pipes, so that the pipes serve for heating spaces. Optionally and if necessary, the tubes can also be used for cooling or generally controlling the climate in rooms, in which case cold water or a coolant flows through them. They can also be laid outside in 10 concreted or asphalted bottom surfaces. This may include airports, traffic or other surfaces that must be kept ice-free. The heating tubes, using the tube-mounting mounts, clamping brackets and the like in the form of loops, reciprocating arcs, and the like, are laid on the supporting bottom structure, and then poured closed with a screed, a concrete or other bottom covering. Such a floor covering is then, if it concerns the bottom of a room, still covered with plastic plates and the like.

The heat transfer from the heating pipes to the screed, concrete and the like enclosing these pipes takes place by heat conduction. The same applies when the heating pipes are used for cooling purposes. The extent of the heat transfer is primarily dependent on the thermal conductivity of the plastic material used for the heating pipes.

25 The thermal conductivity of plastic is limited and only reaches * 7901881 * 2 low values. In the present case, in addition, the plastic material is primarily adjusted or must be adjusted in view of high flexibility, which facilitates laying, and in view of long life and aging resistance. As a result, the heat transfer from the heating pipes into the screed, concrete or other material enclosing the pipes does not reach the high value by heat conduction, which should be pursued from a technical viewpoint. Furthermore, it must be taken into account that the screed, concrete and the like is heated very strongly in the direct vicinity of the heating pipes.

By adding means for increasing the heat conductivity to the screed, or the concrete, the heat dissipation is improved. In spite of this, the temperatures in screed or concrete directly next to the heating pipes are higher than the average temperature in screed or concrete. The resulting temperature drop leads to tensions. These stresses can cause cracks. These cracks run in screed or concrete above and next to the heating pipes.

Based on this, the object of the invention is to provide a heating tube with a better heat transfer in its environment and also to provide means which counteract the formation of cracks. The solution to this problem has been provided with a heating pipe of the type described in the preamble according to the invention, in that metal fins lie on the top of the heating pipe and extend laterally from the heating pipe. Metals generally have a high thermal conductivity, which is above that of plastic. The heat flowing from the plastic material of the heating pipes into the fins is thus quickly dissipated in the fins and transferred to the screed, concrete and the like surrounding these fins * Due to the intimate, direct contact between the plastic material of the heating pipe and the fins directly on top of it, the heat flows directly and quickly from the heating tube into the fins. As explained above, the heat is then guided away from the slats laterally and transferred into the screed, 7901881 3 * concrete and the like. When the heating pipe consisting of the plastic material with the fins lying thereon is technically considered to be a one-piece whole, the fins not only increase the heat conductivity of the heating pipe, but also the surface thereof. With the resulting better heat dissipation, temperature peaks in the direct vicinity of the heating pipes are avoided, and the bottom is heated more regularly.

Reducing or the complete absence of temperature peaks also reduces or completely eliminates the risk of cracking. However, a cracking which is still possible from thermal technical grounds is then eliminated with the present heating pipe, because the slats running in the screed, concrete and the like reinforce or reinforce this. In this regard, the slats perform the same effect as the steel inserts 15 or reinforcing iron in reinforced concrete construction. According to the invention, the particularly unpleasant cracking as regards the consequences thereof is combated and eliminated on two sides.

It is preferred that the slats not only lie on the top of the heating tube, but are attached thereto. There are a number of options for this, which are explained in more detail below.

In a preferred embodiment it is provided that the fins in the longitudinal direction of the heating tube have a distance corresponding to the width thereof. The internal bond in screed or concrete is not broken with a number of such mutually spaced slats. The formation of nests or bags in screed or concrete is also avoided, which nests or bags could form under large-area slats.

The fins advantageously extend to either side of the heating pipe. In order to simplify attachment thereof to the heating pipe, it is provided in a preferred embodiment that the slats extending to either side are formed in one piece with a central body and extend therefrom, which central body is corresponding to the circular shape of the heating pipe bent, on top of the heating pipe and connected to it.

7901881 j Λ α if

This slat center body is a simple punching part. It is made from metal sheet. A smaller or larger number of slats is thus connected via the middle body. Thus, this number of fins can be placed on the heating pipe in a single operation and connected to it. The close contact of the middle body with the heating pipe and the resulting good heat transfer is favored, because the middle body is bent in the circular shape of the heating pipe. The middle body advantageously encloses an arc of 180 °. Thus, the mid-body encloses half the circumference of the heating tube. In a further effective embodiment, the middle body encloses an arc of more than 180 °. In this embodiment, the middle body is slid over it with some pressure and with light compression of the heating tube. In the end position thereof, the middle body snaps, clamping it onto the heating tube.

Preferably, the slats extending from either side of the middle body alternate in sequence or are on openings.

A slat on one side therefore always faces a free space on the other side of the slat. This preserves the internal dressing in screed, concrete and the like. This also simplifies manufacture. In a single operation, a number of raid bodies can be punched with their slats in a single operation without loss, whereby the slats of a middle body come to lie in the openings or spaces between the slats of the neighboring middle body.

According to the invention, bonding, welding or pressing or pressing is available for attaching the middle body to the heating pipe.

The number of slats connected to each other via a middle body is in fact not limited. However, for simplifying manufacture and mounting, it is highly preferred that an outline placed around the center body and slats be in the shape of a square.

The middle body and the slats consist of a metal with a high thermal conductivity. Silver and copper as metals with 7901881

I 5 have a particularly high conductivity due to cost. Therefore, aluminum or an aluminum alloy presents itself as effective.

Depending on the local conditions on the construction site or the laying site, it depends on whether the central webs with the fins are placed on the heating pipes already laid or lying and connected or whether they are already pre-attached to the heating pipe, with the pipe on a drum or the like are wound, and in this way brought to the laying place as a one-piece construction part.

The invention is further elucidated with reference to the drawing, in which: fig. 1 is a spatial view of a piece of heating tube with a central body with fins attached to it, fig. 2 is a top view of this piece of heating tube, fig. 3 is a cross-section according to line III-III in fig. 2, fig. b is a cross section similar to fig. 3, in which the central body encloses an arc of more than 1800, fig. 5 is a spatial view of laid and heating pipes mounted with moldings and clamping brackets with fins attached thereto, fig. 6 is a section of a bottom according to fig. 5, heating pipes already prayed in screed, and fig. 7 is a spatial view, partly broken open and partly in section, of a bottom with heating pipes lying in screed and slats.

Figures 1-k show a piece of heating pipe 12 with the blades 14 running laterally therefrom and the middle body 16. The 30 blades 1 * f and the middle body 16 form a single construction part. The central body 16 is bent according to the circular shape of the heating tube 12. In the embodiment of Figures 1-3, the middle body encloses an arc of 180 °. Thus, the middle body lies on the top half of the heating pipe 12. In the embodiment 35 according to figure k, the middle body 16 is pulled further down »7901881

Claims (11)

Heating pipe made of a flexible, heat-resistant and conductive plastic material, characterized in that metal fins (1 * 0 lie on the top of the heating pipe (12) and run sideways from here. Heating tube according to claim 1, characterized in that the lamellae (1 * 0) are mounted on the top side of the heating tube (12). Heating pipe according to claims 1 and 2, characterized in that the fins (1 * 0 in the longitudinal direction of the heating pipe (12) have a distance adapted to their width. * F. Heating pipe according to claims 1-3, with characterized in that the fins (1 * 0 extend to either side of the heating pipe (12) 790 1 8 8 1 r. Heating pipe according to claim 4, characterized in that the slats 04) extending on either side are formed in one piece with a central body (16) and extend from here, which central body corresponds to the circular shape of the heating pipe (12). ) is bent, lies on the heating pipe and is connected to it. Heating pipe according to claim 5, characterized in that the central body (16) encloses an arc of more than ΐ8θ ° and is clamped on the heating pipe (12). Heating pipe according to claim 5 and é, characterized in that the slats (14) emerging from either side of the middle body (16) are alternate or have openings in their order. Heating pipe according to claims 1-7, characterized in that the central body (16) is glued to the heating pipe (12). Heating pipe according to claims 1-7, characterized in that the central body (16) is welded to the heating pipe (12). Heating pipe according to claims 1-7, characterized in that the central body (-16) is pressed onto the heating pipe (12). Heating pipe according to Claims 1 to 10, characterized in that a periphery placed around the central body (16) and the slats (14) has the shape of a square. Heating pipe according to claims 1-11, characterized in that the central body (16) and the fins (14) consist of a metal with a high thermal conductivity, such as aluminum or an aluminum alloy. 15. Heating tube substantially as described in the description and shown in the drawing. 7901881