AT512905A4 - Heat exchange element - Google Patents

Abstract

Heat exchange element comprising a filling body (1), a through the filler (1) guided fluid channel (2), through which fluid channel (2) a fluid is conductive, so that the fluid can be heated by a force acting on a first surface (3) of the heat exchange element energy or is coolable, wherein the heat exchange element in the vicinity of the first surface (3) has a parallel to the first surface (3) extending, a glass granule (5) comprising layer and / or the fluid channel (2) in a horizontal plane and in a vertical plane is serpentine.

Description

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This invention relates to a heat exchange element comprising a filling body, a fluid channel guided through the filling body, through which fluid channel a fluid can be conducted, so that the fluid can be heated or cooled by an energy acting on a first surface of the heat exchange element.

There are known in the art floor heating systems or wall heating systems. In this case, a heated liquid is passed through a arranged in a portion of the wall or the floor fluid channel, so that the wall or the floor and thus the surrounding space is heated.

In a reverse manner, a heated by solar radiation, for example, heat wall.

The existing heating systems or cooling systems according to the prior art have at a heating of the fluid at an energy input from the outside an unsatisfactory efficiency. Only a small portion of the energy radiating onto the first surface can be converted into heat energy of the fluid. The invention discussed in the following has the object to provide a heat exchange element which is characterized by a higher efficiency than systems according to the prior art. The heat exchange element disclosed below can also be coupled with existing systems.

According to the invention this is achieved in that the heat exchange element in the vicinity of the first surface has a parallel to the first surface extending, comprising a glass granule layer, and / or the fluid channel is serpentine in a horizontal plane and in a vertical plane.

The energy input can be effected for example by a solar radiation, which is directed to the first surface of the heat exchange element according to the invention. -1 - ·········································· ········ · · · · · 1 * ♦ ···

Preferably, the glass granules have a property according to the prior art, which bundles the energy radiating onto the first surface. The bundling of the incident energy has the effect that only certain areas of the heat exchange element heating energy is supplied. Preferably, the bundled energy is directed to areas of the heat exchange element, through which the fluid to be heated is passed.

The glass granules also have the advantage that the first surface can be designed arbitrarily by methods according to the prior art.

For an energy input in the form of solar energy, the glass granules may for example have a shape, so that the sun's rays are bundled by an optical effect according to the prior art (magnifying effect). For this purpose, the glass granules can have a means of refraction or a bowl shape arranged in the interior of the glass granules. Bowl-shaped glass granules are preferably sufficiently large that upon application of the glass granules to the packing, the glass granules are properly aligned by the process of application.

The Giasgranulat must by no means necessarily be made of a glass material. A similar effect can be achieved, for example, with the use of plastic granules, which has a similar refractive property.

A serpentine arrangement of the fluid channel extending in two planes has the advantage over a serpentine one in a plane that the length of the fluid channel is a multiple. In the case of a same throughput speed, which is determined essentially by downstream heating systems and cooling systems, the residence time of the fluid passing through the fluid channel is longer, so that the fluid can be heated over a longer period of time.

The heat exchange element according to the invention can be designed such that an arc of the serpentine-shaped fluid channel close to the first surface can be bent in the direction -2- * * Ι ······································································. It is arranged in a partial region of the heat exchange element in which partial region a high concentration of the energy through the glass granules is effected ,

An arc arranged in a partial region has a greater length of the fluid channel than a fluid channel running straight through this partial region. For this reason, it is advantageous to arrange a sheet in a partial area with a high energy input.

In the vicinity of the second surface of the heat exchange element according to the invention, which second surface of the first surface is arranged opposite, can be arranged parallel to the second surface extending thermal barrier coating.

The heat-insulating layer prevents the dissipation of heat energy on the surfaces facing away from the place of energy input.

In the vicinity of the second surface, a film with heat-reflecting properties may be arranged, which film extends parallel to the second surface.

At least one carrier grate may be arranged in the filler body, through which the fluid channel is guided in a serpentine shape. When guiding the fluid channel in two levels snake-shaped, the arrangement of two mutually parallel, objected carrier grids makes sense.

The fluid channel can be guided around the bars of the carrier grates, so that the serpentine arrangement of the fluid channel is predetermined by the carrier grates.

The support grid can be a reinforcing element for the concrete or clay filling body.

The filler may comprise a material having a property which results in an increase in the temperature of the filler when the energy is applied to the first surface. There are known in the prior art so-called Thermoputze, which at an energy input to the first surface -3- »· * ·» M > · · «· · · · · · · · · · · · · · · # · + ·» # · · · ♦

Have a particularly favorable temporal course of the temperature of the filling body have ".

The requirement of increasing the temperature is in no way limited to an optionally short-term increase in the temperature. The filler may, for example, have a high heat storage capacity, so that the filler has a higher temperature even after completion of the energy input, so that after completion of the energy input, the fluid passing the filler can be heated.

The fluid channel may be in fluid communication with a reservoir, so that the fluid that is in the fluid channel is only part of the fluid of the heating system or cooling system of which the heat exchange element of the invention is part.

The heat exchange element may be part of a facade, a roof or a component lying on a substrate.

FIG. 1 shows a section through a possible embodiment of the instantaneous heat detection element.

Figure 2 shows a table and a graph on the heating of a heat exchange element.

Figure 3 shows a table and a graph on the heating of a fluid by means of the heat exchange element according to the invention.

In the figures, the following elements are indicated by the reference numerals presented. 1 filler 2 fluid channel 3 first surface 4 second surface 5 glass granules 6 thermal barrier coating -4- ♦ 4 44 * 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 4 Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie 7 8 Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Folie Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen Sonnen bundled sunbeams 12 bows 13 bars

The heat exchange element shown in FIG. 1 by means of a sectional view comprises a filling body 1 and a fluid channel 2 guided through the filling body 1. A fluid is passed through the fluid channel 2, so that the fluid can be heated or cooled by a solar beam 10 acting on a first surface 3 of the heat exchange element ,

The filling body 1 has a property which has an increase in the temperature of the filling body 1 with an energy input to the first surface 3 result. The filler 1 has a high heat storage capacity.

The fluid channel 2 is serpentine in a plane parallel to the viewing plane and not serpentine in a plane perpendicular to the viewing plane. Between the snake-shaped fluid channels arranged parallel to the viewing plane, connecting elements 9 are arranged, which connecting elements are oriented perpendicular to the viewing plane.

The heat exchange element comprises on the first surface 3 a layer extending parallel to the first surface 3 and comprising a grass granulate 5. The glass granules 5 have a property which bundles the energy acting on the first surface 3. In essence, the incident sunbeams 10 are broken by the glass granules 5.

The bundled solar beams 11 act on a defined portion of the fluid channel 2, through which the fluid to be heated is passed. -5- • I «« llft »» II «* ♦ · 9» · · · Μ I ··· »9 9 · 19 9 9 I I · 1 · 999 ·

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An arc 12 of the serpentine-shaped fluid channel 2 is arranged near the first surface 3 in that subregion of the heat exchange element, in which subregion a high concentration of the energy through the glass granulate 5 is effected. For reasons of clarity, only one such subarea is shown in FIG.

The heating of the fluid is also influenced by the thermal conductivity is also influenced by the thermal conductivity of the grass granules and the packing. For this reason, the sun's rays are bundled into subregions in which the fluid channel 1 of the first surface 3 as close as possible to the location of the energy input.

On a second surface 4 of the heat exchange element according to the invention, which second surface 4 of the first surface 3 is arranged opposite, a parallel to the second surface 4 extending thermal barrier coating 6 is arranged. The heat-insulating layer prevents a flow of heat energy stored in the filling body 1 to the environment.

It is further arranged on the second surface 4 a film 7 with heat-reflecting properties, which film 7 extends parallel to the second surface 4.

The filling body 1 comprises a support grid 8 with rods 13 arranged parallel to the viewing plane and perpendicular to it, around which the fluid channel 2 is guided in a serpentine shape. The fluid channel 2 is to facilitate the manufacture of the heat exchange element according to the invention, attached to points of the rods 13.

FIG. 2 gives a tabular overview of the heating of two-with the exception of the difference mentioned below-identical heat exchange elements according to the invention and the heating of a fluid conducted through the heat exchange elements.

As indicated in the table, unlike the other plate, one plate comprises an addition of glass granules which, according to claim 3, has the additive disclosed herein.

Invention is arranged. The glass granules causes a slightly faster heating of the plate.

The fluid is passed through the plate without added glass granules by means of a 16.0mm diameter tube while the glass granule plate comprises a 4.0mm diameter tube.

It will be appreciated that despite the smaller diameter, the fluid passed through the glass granule plate will reach substantially the same temperature as the fluid passing through the large diameter tube.

Claims (10)

· * ·· * ··· «i« • * * · «« * ··· • · · ♦ * I ········································································· 1. A heat exchange element comprising a filling body (1), a fluid channel (2) guided through the filling body (1), through which fluid channel (2) a fluid can be conducted, so that the fluid flows through one a first surface (3) of the heat exchange element acting energy can be heated or cooled, characterized in that the heat exchange element in the vicinity of the first surface (3) has a parallel to the first surface (3) extending, a glass granules (5) comprising layer , and / or the fluid channel (2) is serpentine in a horizontal plane and in a vertical plane 2. Heat exchange element according to claim 1, characterized in that the glass granules (5) has a property which bundles the energy acting on the first surface (3). 3. Heat exchange element according to one of claims 1 to 2, characterized in that an arc of the serpentine guided fluid channel (2) near the first surface (3) is arranged in a partial region of the heat exchange element, in which part of a high concentration of energy through the glass granules (5) is effected. 4. Heat exchange element according to one of claims 1 to 3, characterized in that in the vicinity of the second surface (4) of the heat exchange element according to the invention, which second surface (4) of the first surface (3) is arranged opposite one another parallel to the second Surface (4) extending thermal barrier coating (6) is arranged. 5. Heat exchange element according to one of claims 1 to 4, characterized in that in the vicinity of the second surface (4) a film (7) is arranged with heat-reflecting properties, which film (7) extends parallel to the second surface (4) , -9- 6. Heat exchange element according to one of claims 1 to 5, characterized in that in the filling body (1) at least one support grid (8) is arranged, through which the fluid channel (2) is guided serpentine. 7. Heat exchange element according to one of claims 1 to 6, characterized in that the filling body (1) has a property which have an increase in the temperature of the filling body (1) at an energy input to the first surface (3) result. 8. Heat exchange element according to one of claims 1 to 7, characterized in that the fluid channel (2) is in fluid communication with a storage reservoir. 9. Heat exchange element according to claim 8, characterized in that the heat exchange element is part of a heating system and / or cooling system. 10. Heat exchange element according to one of claims 1 to 9, characterized in that the heat exchange element is part of a facade, a roof or a lying on a substrate component. Vienna, on | 3, Aug. 2012 Joachim Hengl Michael Hengl represented by Häupl & Ellmeyer KG