CH708158A1 - Stiller heat absorber. - Google Patents

Abstract

The silent heat absorber can replace the conventional heat absorber of an air-to-water heat pump or a brine-to-water heat pump when the appropriate area is reached. This eliminates the additional installation of an air heat absorber and, consequently, the power requirement for the air fan and associated sound emissions. The silent heat absorber represents both the heat absorber for the heat pump as well as a fall protection or area limitation (railing) and thus integrates aesthetically inconspicuous and beautiful in the building.

Description

Technical area:

The invention provides a building aesthetic opportunity to absorb heat from the air and supply it to a heat pump.

State of the art:

Nowadays, air-water heat pumps are provided on the primary side as far as possible with conventional finned heat exchangers, wherein the air is transported by a fan through the heat exchanger. This fan can consume up to 15% of the total output of the heat pump system and typically produces noise levels of up to 75 dB (A). As the air flows through the heat exchanger, the air is cooled and the extracted energy is supplied to the heat pump on the side of the primary circuit. There are air-to-water heat pumps in which the finned heat exchanger on the cooling medium side flows through either directly with the coolant or with a brine (frost-proof medium).

Presentation of the invention:

The silent heat absorber substitutes a conventional heat absorber in the form of a heat exchanger which is shown as an air-brine heat exchanger or optionally by a ground probe. At the same time, the silent heat absorber combines the feature with a railing commonly used today with panel coater as fall protection or area limitation. The heat absorber panels can be made of transparent glass (typical term glass railing) or with non-transparent materials such as aluminum or stainless steel.

Especially in studios and terraced houses (list not completed) large areas spanning railing are used. These form in this respect a suitable possibility with a silent heat absorber which today required (modern building standard assumed) to absorb heat quantities silently and economically for a heat pump heating.

The advantages of the silent heat absorber are: <tb> • <SEP> No separate component is needed as a heat absorber (space saving and aesthetics of the environment) <tb> • <SEP> There are no noise emissions from the air fan (quiet operation) <tb> • <SEP> Energy consumption for the air fan is eliminated (energy saving) <tb> • <SEP> The heat absorber panels can be constructed of glass and with colored heat transfer medium adapted to the optical claim of the owner <tb> • <SEP> Opaque materials such as aluminum or stainless steel are of course also possible, but at the same time offer the opportunity to increase efficiency through ribbing.

Brief description of the drawings:

The invention is explained in more detail below with reference to exemplary embodiments with reference to the accompanying drawings. The features disclosed here can also be essential to the invention individually or in combinations other than those shown. Show it: <Tb> FIG. 1 <SEP> Overall view of the silent heat absorber <Tb> FIG. 2 <SEP> Structure and section through an absorber panel of the silent heat absorber <Tb> FIG. 3 <SEP> Installation system for the silent heat absorber

Ways to carry out the invention:

It is an object of the present invention to provide a silent and aesthetically to be integrated into the building heat absorber. The silent heat absorber is primarily composed of the three parts inner glass (1), outer glass (2) and the frame (3) by waterproof gluing together. Aluminum sheets or other materials may be used instead of the glasses. The upper end (4) formed as a U-profile forms an aesthetic conclusion of the upper edge, which substitutes a handrail and at the same time secures the fixation of the absorber panels.

The by the sticking together of the components (1), (2) and (3) resulting cavity is flooded by the frost-proof heat transfer medium (M) and transported so transferred from the glass surfaces via convection heat to the return (RL). The heat transfer medium (M) is transported by a circulation pump in the heat pump from the flow (VL) to the return (RL). The circulation by the heat pump does not form part of the invention.

The frame (3) we constructed from the distribution bar (I) the collecting bar (II) and the side profiles (III) similar to an insulating glass. The uniform flow with the heat transfer medium (M) is achieved by appropriate holes (VII) on the inside of the distribution bar (I) and collecting bar (II). The complete heat absorber is constructed in individual modules the so-called absorber panels, which are connected to the connecting pieces (V) with a connecting sleeve (VI). The assembled absorber panels are assembled using the supports (5) which are mounted in the panel spacing. Thereafter, the lower U profiles (6) which are provided with drainage facilities for accumulated water are mounted on the supports (5). Now the absorber panels (consisting of 1, 2 and 3) can be placed in the lower U-profiles (6) and connected laterally with the connecting sleeves (VI). The upper end (4) finally fixes the absorber panels by with the upper end (4) and the clamping plate (7) to the supports (5) are screwed. This type of mounting ensures a stress-free installation with the possibility of free temperature-related linear expansion.

LIST OF REFERENCE NUMBERS

[0010] <tb> <SEP> Absorber Panels bending from: 1-3 <tb> 1 <SEP> Inner glass (possibly metallic sheet) <tb> 2 <SEP> Outer glass (possibly metallic sheet) <tb> 3 <SEP> Frame expanded from the parts <Tb> <September> I <September> Verteilbalken <Tb> <September> II <September> Chromos bar <Tb> <September> III <September> Page Profiles <Tb> <September> V <September> connection piece <Tb> <September> VI <September> connecting sleeve <tb> 4 <SEP> Upper degree <Tb> 5 <September> support <tb> 6 <SEP> Lower U profile <Tb> 7 <September> clamp <tb> M <SEP> Heat transfer medium (brine, or water-glycol mixture)

Claims (5)

1. A still heat absorber (1) for a heat pump, characterized by the property of the connection of a heat absorber for a heat pump with the use point as fall protection or area limitation (railing). 2. Stiller heat absorber according to claim 1, characterized in that the absorber surfaces are made transparent and the cavity formed by the structure (3) with a heat transfer medium (M) is flooded. 3. Stiller heat absorber according to claim 1, characterized in that the absorber surfaces are not made transparent and by the structure (3) shaped cavity with a heat transfer medium (M) is flooded. 4. The silent heat absorber according to claim 1, characterized in that the air is circulated by the pure natural movement such as wind or convection and thereby can be dispensed with an air fan. 5. The mounting system for the silent heat absorber according to claim 1, 2 or 3, characterized in that the absorber panels in the mounting system their temperature-related length expansions are not hindered both horizontally and vertically.