NL9201319A - Device for controlling the temperature of spaces in a building - Google Patents

Abstract

A device to control the temperature for spaces of a building having facade walls which comprise a metal frame of struts and rails and which are provided with facade elements and optionally window areas substantially free from thermal bridges, has a temperature control device which is mounted on the frame in the interior of the space. This temperature control device includes a conduit system which is added to the struts and/or rails. The conduit system has a heat transfer fluid flowing through it and comprises heat transfer profiles which are joined to the conduit system to provide direct heat transfer. To reduce the volume of the heat transfer fluid flowing in the conduit system, the heat transfer profiles are joined integrally (in one piece) to the conduits added thereto and consist of aluminium.

Description

Title: Device for controlling the temperature of rooms in a building.

The invention relates to a device for controlling the temperature of rooms of a building with facade walls, comprising a metal frame of posts and rails, to which facade elements and possibly window surfaces are arranged substantially free of heat bridges, with a temperature control device attached to the frame is disposed in the interior of the space, the device comprising a piping system added to the uprights and / or rails with a heat transport liquid flowing therein, and with heat transfer profiles which are directly connected to the pipeline system in a heat transfer manner.

Such an apparatus is known from German Offenlegungsschrift 2621186. The posts and lines are herein designed as hollow posts and hollow lines, which have a flow connection with one another in a predetermined manner and which conduct a heat transport liquid between a pre-run and a return flow. Due to the relatively large hollow cross-section, the flow-through channel of the heat transport liquid through the hollow profiled metal frame requires a large amount of circulating heat transport liquid, so that the temperature of the room of a building can only be controlled with a certain inertia.

The object of the invention is to considerably reduce the volume of the heat transport liquid flowing in the pipeline system without changing the heat transfer properties. This object can be achieved according to the invention in that the heat transfer profiles are connected in one piece to the pipelines added to them and consist of aluminum.

An important advantage of the device according to the invention is that, on the basis of the heat-formed profiles and pipelines made of aluminum, the flow cross-section for the heat transport liquid and thus the total volume through the pipeline system is greatly reduced on the one hand and the heat-transferring surfaces on the other hand. of the heat transfer profiles can be made optimally large without in principle changing the heat transfer properties.

If the pipelines in the added greenhouse-shaped closed heat transfer profiles leave additional recesses open laterally in the interior thereof, these recesses can be provided on both sides of the pipelines or can be arranged laterally in the added heat transfer profiles and leave a recess, considerable material savings can be achieved without affecting the good properties of the temperature control device and the heat transfer itself. Moreover, this leaves sufficient free space in the interior of the box-like closed heat transfer profiles for accommodating further construction parts or other pipes.

Moreover, a considerable advantage is noticeable in the fact that the aluminum heat transfer profiles connected to the pipelines can also be designed as a load-bearing part of the frame.

Another object of the invention is to provide a device indicated in the preamble, which is designed in such a way that the space in the cabinet profiles, which is left open in a simple manner without additional costs, due to the substantial reduction in volume of the heat transport liquid flowing into the pipeline system. space requirement allows a supply of temperature-controlled fresh air. According to the invention, the free spaces in the box-like closed heat transfer profiles of the posts are designed for this purpose as parts of an additional air supply system, which is led through adjacent storey ceilings of a building.

In this embodiment, the supplied air is brought to the temperature of the heat transport liquid immediately upon passage through the uprights, so that the heat transport liquid and the supply air when entering the room have the same temperature and can therefore have their own control for the temperature of the supplied air. fall away.

It is noted that German Offenlegungsschrift 1802320 discloses a building element in the form of a hollow profile, which can also be used for fixing parapet panels and window elements, whereby a built-in heat transfer medium is provided, while the remaining hollow profile provides air. can be fed. However, with this known building element, a heat transfer unintentionally takes place between the heat transfer agent and the outer wall of the building element and only via the air which is passed through. The known building element in the form of the hollow profile is thus not directly connected to the heat transfer agent in a heat-transferring manner.

German Offenlegungsschrift 2534140 furthermore discloses a device for the temperature control of rooms of a building, which device has a metal frame provided with posts and rules and a rules-arranged separated heat transfer system (corrugated pipe), in which the rules with the separated heat transfer system air flows. This known heat transfer system serves exclusively for the temperature control of the air flowing through and is not directly connected with the rules arranged around it.

On the other hand, the preferred device according to the invention provides for a direct heat transfer between the heat transport liquid and the posts, which are simultaneously used for the conduction of supply air over several floors of a building and its temperature control.

The invention will now be explained in more detail with reference to the figures, in which exemplary embodiments are shown.

Figure 1a shows a detail of a temperature control device in horizontal section through the wall of a building.

Figure 1b shows the placement of the temperature control device according to Figure 1a at a corner connection of a building.

Figure 1c shows a detail corresponding significantly with figure 1a of a temperature control device with another embodiment of the heat transfer profile.

Figure 2 shows a vertical section through adjoining storey ceilings with associated temperature control devices, which are additionally provided with an air supply system which is guided through the adjacent storey ceilings.

Figure 3 shows a side view according to Figure 2 over two storey ceilings.

Figure 4 shows a horizontal section along the line M-M through the wall on the floor side according to Figure 3

The horizontal section shown in Figure 1a through a part of a wall or facade of a building shows part 1 of the temperature control device with a single tube connected in one piece with a heat transfer profile 51. In addition, in the interior of the heat transfer profile 51, sideways next to the tube, extra recesses 52 are left open. The box-shaped closed transfer profile 51 is arranged directly on the added frame part and the glass panes 5, with an insulation 3 placed between the frame part and the heat transfer profile.

Figure 1b shows the embodiment of a temperature control device according to figure 1a in an angular connection. An aluminum connecting corner 53 connects the two heat transfer profiles 51 at an angle to each other, thereby forming a heat bridge to improve the heat transfer properties.

In the embodiment according to figure 1c, the pipeline is arranged laterally in the heat transfer profile 51. As a result, a relatively wide internal recess 54 is created, so that sufficient internal free space is provided for the accommodation of other construction or fastening parts, for example screws.

Figures 2 to 4 show the air supply system 60 formed by the box-like closed transfer profiles 51 of the posts and the heat transfer profiles 56 of the blocks. The heat transfer profiles 51 of the posts serve for the supply of supply air through adjacent storey ceilings, while the heat transfer profiles 56 of the rails, which are arranged on the side of the floor in each storey, have longitudinally extending air slots 55 ( see figure 4) through which temperature-controlled air enters the interior of the room.

During operation, supply air is supplied from the outside to the ceiling side in the top floor of a building, as shown by arrow W in figure 2. The supply air introduced from above then enters the posts 51 and flows downwards in the direction of the arrows 6 parallel to the heat transport liquid, whereby a heat transfer between the heat transport liquid and the supply air takes place in direct current or in counter current.

Within reach of the floor of each floor, a part of the supply air is diverted in the direction of the arrows Y and this air flows in the line 56 and from there through the air slots 55 into the interior of the room, as in Figures 3 and 4 is indicated with the arrows X.

Between adjacent storey ceilings, part of the vertically flowing supply air is directed downwards to deeper storeys according to arrows 6. For this purpose, throttling devices are arranged between the adjacent floors, which reduce the flow rate of the supply air between adjacent floors by half.

Claims (10)

1. Device for controlling the temperature of rooms of a building with facade walls, comprising a metal frame of posts and rails, to which facade elements and possibly window surfaces are arranged substantially free of thermal bridges, with a temperature control device attached to the frame in the interior of the space, which device contains a pipeline system added to the uprights and / or rails with a heat transport liquid flowing therein, and with heat transfer profiles which are directly connected to the pipeline system in a heat transfer manner, characterized in that the heat transfer profiles are connected in one piece to the added pipelines and consist of aluminum. Device according to claim 1, characterized in that the pipelines in the added box-shaped closed heat transfer profiles (51) leave open laterally in the internal additional recesses (52). Device according to claim 2, characterized in that recesses (52) are provided on both sides of the pipelines. Device according to claim 2, characterized in that the pipelines are arranged laterally in the associated heat transfer profiles and leave a recess (54) open (figure 1a). Device according to claim 1, characterized in that the free spaces in the box-like closed heat transfer profiles (51) of the posts are designed as parts of an additional air supply system, which is led through adjoining storey ceilings of a building. Device according to claim 5, characterized in that the air supply system (60) has a single structural outside air supply (W). Device according to claim 6, characterized in that the architectural outside air supply (W) is arranged on the side of the ceiling in the top floor of a building. Device according to any one of claims 5 to 7, characterized in that throttling devices are arranged between individual adjacent floors, which reduce the airflow velocity between adjacent floors by half. Device according to any one of claims 5 to 8, characterized in that the outlets for the air supply flow (X) are arranged essentially on the side of a storey floor. 10. Device according to claim 9, characterized in that transverse rails (56) with air slots (55) for the discharge of supply air are arranged in the interior of the space.