CH702645A1 - Thermally active insulator. - Google Patents

Abstract

A thermally active insulator (1) contains two surfaces, between which a plurality of Peltier elements are arranged. The Peltier elements are supplied by a control device (9) with an electric current. They allow the heat transfer from one surface to the other surface or in the opposite direction. They also allow the suppression of heat transfer, which can be used for example in a heat exchanger to prevent the normally occurring exchange of heat between two media of different temperature.

Description

The invention relates to a thermally active insulator and a method for operating a heat exchanger with such insulators.

Heat exchangers are used, for example, to exchange heat between the exhaust air discharged from a room and the fresh air supplied to the room. In winter, when the exhaust air is warmer than the fresh air, the heat contained in the exhaust air is transferred to the fresh air, so that it must be heated less. In summer, when the exhaust air is colder during the day than the fresh air, then heat contained in the fresh air is transferred to the exhaust air, i. the fresh air cooled. During the summer nights, however, it is often the case that the fresh air is colder than the exhaust air. In this case, however, no heat exchange between the fresh air and the exhaust air should be done so that the room in the morning, when the day begins, has a pleasant coolness. To make this possible, the fresh air or the exhaust air is passed through a bypass on the heat exchanger during the summer during the summer operation.

The invention has for its object to develop a solution without a bypass.

The invention is characterized in claim 1. An advantageous use of the invention results from claim 2.

The invention will be explained in more detail with reference to an embodiment and with reference to the drawing. <Tb> FIG. 1, 2 <sep> show in plan view and in cross section a thermally active insulator with Peltier elements, <Tb> FIG. 3 <sep> shows a wiring scheme of the Peltier elements, and <Tb> FIG. 4 <sep> shows a heat exchanger.

Fig. 1 shows a thermally active insulator 1 in plan view, Fig. 2 shows the insulator 1 in a preferred embodiment in cross-section, i. perpendicular to the drawing plane of Fig. 1. The insulator 1 has a flat shape, i. its dimensions in two dimensions are at least a factor of 100 greater than its dimension in the direction perpendicular to said dimensions. For example, the insulator 1 has the shape of a thin rectangular plate as shown. The insulator 1 may also have the shape of any two-dimensional surface. The insulator 1 includes a plurality of Peltier elements 2.

Peltier elements 2 are thermoelectric transducers which enable electrical energy to be used to transport heat from one surface 3 of the insulator 1 to the opposite surface 4, or vice versa. either to cool the surface 3 or the surface 4.

From Fig. 2 it can be seen that the insulator 1 comprises two mutually parallel support 5, between which the Peltier elements 2 are arranged. The carriers 5 form the two surfaces 3 and 4. They are, for example, foils which are provided with electrical conductor tracks 6 in order to electrically connect the Peltier elements 2. In each case a plurality of Peltier elements 2 are electrically connected in series. The Peltier elements 2 are thin layers which consist of a material with an n-doping or with a p-doping. The direction of the DC current flowing during operation through the Peltier elements 2 depends on the doping of the Peltier elements 2. The n-doped Peltier elements 2 and the p-doped Peltier elements 2 are therefore wired to the conductor tracks 6 in such a way that the direction of the technical electrical current passes through the n-doped Peltier elements 2 is opposite to the direction through the p-doped Peltier elements 2, so that in operation all Peltier elements 2 transport heat in the same direction. The interstices between the Peltier elements 2 are advantageously at least partially filled with a foam-like, electrically insulating material 7, which prevents the air circulation within the interstices and thus acts as a thermally passive insulator. The Peltier elements 2 can be applied to the carrier 5, for example, by vapor deposition or sputtering. The thermally active insulator 1 can be bent and bent almost as desired.

The thermally active insulator 1 has at least two electrical terminals 8, to which a control device 9 can be connected to supply the Peltier elements 2 with an electric current. The control device 9 can also be mounted inside or on the insulator 1.

Fig. 3 shows an embodiment of the electrical wiring of the Peltier elements 2. The Peltier elements 2 are fed by the control device 9 with electrical energy, for example by applying an electric current. In this example, several of the Peltier elements 2 are combined electrically into a block 10, wherein the blocks 10 are supplied individually by the control device 9 with electrical energy. In the example, eight Peltier elements 2 are combined into one block 10 and a total of five blocks 10 are present. However, the number of Peltier elements 2 per block 10 and the number of blocks 10 is not limited to these example values. Arrows indicate the direction of the current flowing from the controller 9 to each of the blocks 10, through the Peltier elements 2 of the block 10, and back to the controller 9. Accordingly, in this embodiment, ten terminals 8 are provided, via which the insulator 1 is connected to the control device 9.

Fig. 4 shows in cross section a heat exchanger 11 for the exchange of heat between a first medium and a second medium. By the term "medium" is meant a gas, e.g. Air, or to understand a liquid. Such a medium is also referred to as fluid.

The heat exchanger comprises first exchange spaces 12, through which the first medium can be passed, and second exchange spaces 13, through which the second medium can be passed, and heat exchanging, spaced parallel to one another thermally active insulators 1, wherein each of the thermally active insulators 1 separates one of the first exchange spaces 12 from one of the second exchange rooms 13. For reasons of clarity of drawing, the isolators 1 are shown to be wider than they are in reality. The flow direction of the two media is perpendicular to the plane, with advantage the two media flow in the opposite direction. In the example, two exchange spaces 12 for the first medium and three exchange spaces 13 for the second medium are present, but the number of exchange spaces 12, 13 is usually larger. The exchange spaces 12 facing surfaces of the insulators 1 are designated by the reference numeral 3, the exchange spaces 13 facing surfaces by the reference numeral 4 and the control device 9 and the insulators 1 are wired accordingly.

A common control device 9 for all thermally active insulators 1 is adapted to operate the thermally active insulators 1 of the heat exchanger 11 in different operating modes, of which the most important are listed below. It is assumed that fresh air supplied to a room flows through the exchange rooms 12 and exhaust air from the room through the exchange rooms 13. The heat exchanger 11 is usually a part of a device for conditioning the supply air to be supplied to a room, the control device preferably a part this device is and is supplied with temperature signals from corresponding temperature sensors.

Operating mode 1

This operating mode corresponds to winter operation, in which the fresh air is colder than the exhaust air. The control device 9 controls the current flowing through the Peltier elements 2 such that heat is transported from the surface 4 to the surface 3 of the insulators 1. The Peltier elements 2 thus support the transfer of heat from the exhaust air to the fresh air.

Operating mode 2

This mode of operation corresponds to the summer operation during the times during which the exhaust air is colder than the fresh air, which is especially the case during the morning until the evening and night hours the case. The control device 9 controls the current flowing through the Peltier elements 2 such that heat is transported from the surface 3 to the surface 4 of the insulators 1. The Peltier elements 2 thus support the cooling of the fresh air through the exhaust air.

Operating mode 3

This mode of operation corresponds to the summer operation during the times during which the fresh air is colder than the exhaust air, which can be the case, especially in the hours after midnight to the morning hours. The control device 9 controls the current flowing through the Peltier elements 2 such that no heat transfer from the surface 4 to the surface 3 of the insulators 1 takes place. In other words, this means that the Peltier elements 2 completely or approximately completely compensate for the heat transfer which would take place when the Peltier elements 2 were switched off from the exhaust air to the fresh air. The insulators 1 are then thermally 100% insulating.

Operating mode 4

This operating mode is based on the operating mode 3. It is used when the fresh air is colder than the exhaust air, but not cold enough to cool the room during the night by the coolness of the fresh air alone to the desired temperature. The control device 9 controls the current flowing through the Peltier elements 2 such that heat is transported from the surface 3 to the surface 4 of the insulators 1, so that the fresh air is cooled and the extracted heat and the waste heat of the Peltier elements 2 is removed with the exhaust air.

Claims (2)

1. A thermally active insulator (1), with two surfaces (3, 4), between which a plurality of Peltier elements (2) are arranged, which can be supplied by a control device (9) with an electric current. 2. A method for operating a heat exchanger (11) having first exchange spaces (12) and second exchange spaces (13), which are separated by thermally active insulators (1) according to claim 1, characterized in that the by the Peltier elements (2) flowing current is controlled so that no heat transfer from the one surface (4) to the other surface (3) of the insulators (1) takes place.