NL7903898A - FLOOR HEAT TRANSFER SYSTEM. - Google Patents

Description

«I X

Ρ & c W 5596-1 Ned.

Thermoval Fussbodehheizungen, Entwicklungs- und Forschungsgesellschaft m.b.H. in Vienna, Austria

Heat transfer system for floors

The invention relates to a heat transfer system consisting of plastic pipes arranged in a hardbar and hardened medium, the position of which is fixed relative to the subfloor by holders.

Heat transfer systems of this kind are already known.

Such heat transfer systems, also referred to as large area heat transfer systems, are used, for example, together with low temperature heating systems, in particular for underfloor heating. In these heat transfer systems, in general, a heat insulation layer is applied to a subfloor, for instance rough concrete, on which containers are fixed by means of strips of metal or the like, for receiving plastic pipes. After arranging the plastic pipes or an endless plastic pipe in the associated holders, these pipes are embedded together with the holders in a floor, for instance a cement floor. The tubes are generally made of propylene or polyethylene with a smooth surface and are placed in a tubular, zigzag or spiral shape on the heat insulation by means of the holders. The tubes used so far have in principle a circular cross section.

The described heat transfer systems have various drawbacks. During the hardening of the floor, air gaps can arise between the plastic pipes and the floor, which significantly reduce the heat transfer from the pipe to the floor, resulting in a lower efficiency. This drawback is particularly evident in heating systems operating at a low input temperature and which require a higher heat capacity, ie a higher input temperature, in the event of poor heat transfer. Low temperature heating systems are also often used in combination with heat pumps so that the lower efficiency cannot be compensated by larger heat & energy.

30 The air gaps that occur between the plastic pipes and the floor also prevent a connection between the floor and the pipe that is closed by the shape and / or by forces acting, so that • the different expansion coefficients of the floor material and / / 790 3 8 98 ' 2 '. * * J t - 2 - plastic material of the pipes, when switching on and off the heat transfer system, as well as with controls, a repeated displacement of the pipe with respect to the floor is possible, which over time can lead to breakage or damage of the tube or 5 tubes.

The object of the invention is to provide a heat transfer system in which the above-mentioned drawbacks and difficulties are avoided.

This is achieved according to the invention in that the tubes 10 have a substantially oval or elliptical cross section.

The substantially elliptical or oval cross-sectional shape of the plastic pipes. in operation of the heat transfer system, pressures the inner wall of the tube through the heat transfer medium passed through the tubes, which pressure causes a deformation of the elliptical cross-section. The internal pressure of the heat transfer medium, which causes the deformation of the elliptical tube section, in particular in that part of the tube which has the greatest radius of curvature, causes a deformation such that the respective tube wall completely and closes against the associated wall of the paved floor. Since this pipe section with a large radius of curvature forms the major part of the pipe circumference, an important improvement in the heat transfer between the pipe and the floor is achieved. This also results in a connection between the floor and the pipes obtained by a pressing force, whereby an uncontrolled and continuous movement of the pipe in the floor as a result of the different heat expansion coefficients of the floor and plastic material prevents heating. Moreover, by arranging ridges distributed over the tube lengthwise, the displacement effect of the tubes can be counteracted even further.

Placing the pipes in the floor such that the long axis of the pipe cross-section is perpendicular to the subfloor facilitates bending of the pipes when placing them before applying the floor material. The placement of the pipes with the long axis of the cross-section parallel to the subfloor may result in a reduction of the construction height or. the floor height of the heat transfer system, which may be beneficial. Due to the improved heat transfer between the pipe and the floor, a high efficiency is achieved, ie that in contrast to the known underfloor heating systems with plastic pipes with a circular cross section, the same surface temperature of the floor is obtained at a lower temperature. input temperature of the heat transfer medium. In addition, a uniform surface temperature of the floor and of the floor covering present thereon is achieved, especially when the pipes are very close to the heat insulation layer.

The use of a standing oval tube has the following advantage: the dent of the heating medium on the inner surface of the tube causes the tube diameter 10 to become smaller at the location of the two tops of the tube and an air gap is formed with the floor while air gaps are formed. the parts of the pipe with the greatest radius of curvature are prevented from being caused by the pipe expansion in this area. This achieves a better, more uniform heat radiation, namely a better heat transfer between the floor and the pipe surfaces with the largest radius of curvature than hitherto possible, which in this area leads to a higher surface temperature, while the heat radiation on the tips of the pipe upwards and downwards through the air gaps formed therein, which leads to a decrease in the temperature in the floor surface at the location of the pipe tops, where otherwise a higher surface temperature was measured.

The large surface area heat transfer system according to the invention is particularly suitable for underfloor heating systems, so-called low temperature underfloor heating systems, which operate with a low input temperature in combination with a conventional heating system or with 25 heat pumps.

The invention will be explained in more detail below with reference to the drawing, in which some exemplary embodiments of the device according to the invention are shown.

Fig. 1 is a vertical section through a first embodiment of the system.

Fig. 2 shows a corresponding section as FIG. 1 of a second embodiment.

Fig. 3 schematically shows a length of pipe at its bend.

FIG. 4 is a section according to IV-IV of FIG. 3.

Fig. 5 is a plan view of a portion of a seeded frame.

> t * - 4 - tube with holders.

Fig. 6 shows a preferred embodiment of a tube.

Fig. 7 is a sectional view along VII-VII of FIG. 6.

With reference to Figures 1 and 2, the basic construction of a heat transfer system as used for underfloor heating is now described. A heat insulation layer 2 of any heat-insulating material, preferably Styropor, is applied to a subfloor 1, for instance of rough concrete. On the insulating layer 2, according to a certain pattern and at a certain distance from each other, mounting strips 3 are placed, which for instance consist of metal and are adapted to receive holders 4. The holders 4 can have any shape and serve to fix pipes 5 of plastic prior to the application of a floor layer 6. The tubes 5 are herein preferably clampedly received by the holders or holder elements 4, so that before the application of the floor layer 5, for example, the pipe profile shown in Fig. 5 is created. Fig. 5 is only an example of a possible arrangement of the tubes 5, which may consist of individual tube pieces or of an endless tube as required. The placement of the holders 4 is also only shown as an example. After application.

20 of the floor layer 6 and the hardening of the floor, an arbitrary floor covering 7 is placed on its surface. The structure of the heat transfer system described so far is known.

In the exemplary embodiment shown in Fig. 1, the tubes 5 with an elliptical cross-section are placed in the holders 4 such that the long axis of the tube cross-section is perpendicular to the surface of the subfloor, ie, perpendicular to the placement surface of the tubes 5. As a result the pipes 5 extend over their straight part (indicated by A in fig. 5) in such a way over the heat insulation layer 2 that in the region A the long axis of the pipe cross section is always perpendicular to the subfloor 1. Also in the bending part B, the long axis of the pipe section extends perpendicular to the subfloor. 1. In this way of placing, the bending in the area B is by placing the elliptical tube with the long axis perpendicular to the subfloor 1, relative to the subfloor. of the usual arrangement of pipes of circular cross section, more convenient. While hitherto the tubes of circular cross-section have been heated upon installation according to Fig. 5, for example by passing heated water, J 790 3 8 98 r Μ; In order to be able to bend in the area B, the elliptical tube can be laid in the installation mode according to Fig. 1 without or with only slight heating.

Fig. 2 shows a different embodiment of the heat transfer system with respect to FIG. 1, in which case the pattern can also be according to FIG. In the straight part A of the pipe 5, the long axis of the pipe section lies substantially parallel to the subfloor 1, while in the bending part B the pipe 5 is rotated such that at the location S of the unbent part B the: long axis is perpendicular to 10 the subfloor. In this way the narrowing shown in Fig. 5 is obtained in the plan view in the apex or reversal point S.

Fig. 3 schematically shows the course of the elliptical tube for the embodiment of Fig. 2 in the area B, while Fig. 4 is a sectional view of the tube, seen from the top S, along line IV-IV. of fig. 3.

The holders 4 shown in Figs. 1 and 2, which each fix the tube 5 to the frames 3, clamp the tube 5 with arms 4a, 4b and hold the tube 5 against the base 4c of the container. The containers are shown by way of example only and they can be replaced by any other container. In the embodiment according to Fig. 1, holders of smaller width than the embodiment in Fig. 2 are required due to the long axis of the tube perpendicular to the mounting surface. It is clear that after the application and hardening of the floor 6, the holders 4 no longer have any function and only serve to hold the tubes 5 or the tube 5 on the heat insulation layer 2 before the application of the floor 6.

By the arrangement according to fig. 2 of the elliptical tube 5 with the long axis parallel to the subfloor 1, the construction height of the heating system, ie of the floor 6, can be reduced by the difference between the long and the short axis of the elliptical tube section. As far as a small construction height is desired, the embodiment according to Fig. 2 is preferred.

Fig. 6 and 7 show another embodiment of the tube 5. This tube has circumferential rings or ridges 8 spaced in the direction of the tube centerline 8 which, preferably as parts 790 3 8 98

Claims (10)

Preferably, the ends of the tubes 5 transition into a circular cross-section or are converted into a circular cross-section only after placement in the holders 4 with suitable tools, so that the. connection of the otherwise elliptical cross-section pipes to distributors, etc. is easier. 10 Heat transfer system, in particular for underfloor heating, consisting of plastic pipes arranged in a hard hair or hardening medium, the position of which is fixed with respect to the subfloor 15 by holders, characterized in that the pipes (5) are at least most have an oval or elliptical cross section. System according to claim 1, characterized in that the long axis of the elliptical pipe section is perpendicular to the surface of the subfloor (1} v System according to claim 1, characterized in that the long axis of the elliptical tube section is parallel to the surface of the subfloor (1). System according to claim 1, characterized in that each tube (5) has at least a first part (B), in which the long axis is perpendicular to the surface of the subfloor (1), and at least one second part ( A); in which the. long axis · parallel to the surface of the subfloor (l) (fig. 3, 4, 5). System according to claim 1 or 4, characterized in that at the location of the bends (B) of the tubes (5) the long axis is perpendicular to the surface of the. subfloor (1) and at the location of substantially straight parts (A) the long axis of the pipe runs parallel to the surface of the subfloor. System according to any one of the preceding claims, characterized in that the tubes consist of a single endless tube. System according to one of the preceding claims, characterized in that the transition at the end of the pipes (5) to a ƒ ....... ..... -... .. 790 3 8 98 - 7 Λ fc. circular cross section is formed. System according to any one of the preceding claims, characterized in that the tubes (5) are provided with circumferential rings (8) which are spaced apart. System according to claim 8, characterized in that the rings (8) are formed on the tubes (5). System according to any one of the preceding claims, characterized in that the tubes (5) have an elliptical or oval cross-section at least in most of their length. \ / 4 7903 8 98