DE20311784U1 - Solar collector has trough-shaped base and highly-transparent lid which is thermally insulating or incorporates thermally-insulating layer - Google Patents

Abstract

Solar collector has a trough-shaped base (12) and a highly-transparent lid (14). The lid is thermally insulating or incorporates a thermally-insulating layer.

Description

The invention relates to a heat collector for warming of liquids and / or a heat storage device for storing and keeping liquids warm, especially of Process water for use in a household or in a business unit.

heat collectors for domestic water heating by means of radiation from warming Sunlight is known in different configurations. at So-called flat-plate collectors become liquid - as a rule, process water or a suitable thermal conductor or transmission fluid such as glycol or a glycol-water solution for one Household or business unit - by relatively large, that Areas absorbing sunlight heated and over a circuit to a heat accumulator transported inside the house, where the heat is transferred to a heat store becomes. Such systems are common on house roofs or mounted on racks and in the direction of maximum sunlight or the maximum irradiation time. These well-known Systems are relatively efficient, but complex to build and operate and therefore also relatively expensive.

A known simple embodiment of heat collectors consists of a light-absorbing container that is filled with water and can be exposed to the sun. As such light absorbing container For example, black-colored drums, for example made of metal or plastic, are suitable. Such heat collectors are mostly self-made, which are inexpensive and simple but not are very efficient. They are not suitable for heat storage because the containers only single-walled and therefore the heat stored in the water in the absence of sunlight or with cooler ones Release temperatures quickly to the outside.

So-called semi-transparent storage collectors are also used known in which water can be heated and stored. This Storage collectors are common relatively large and usually have a slant stand up lid. The size is typically approx. 300 liters. The weird standing lid is due to the relatively low position of the sun in central and Northern Europe necessary. The size and the Contour of the container has the consequence that these containers are relatively difficult to transport to let. you need also a relatively large stacking space during storage.

An object of the present invention is seen in an efficient, inexpensive and easy to transport heat collector for water heating and / or heat storage to disposal to deliver.

This object of the invention is achieved with the subject of the independent Claim reached. Features of advantageous developments of the invention result from the dependent Claims.

The heat collector according to the invention comprises one well-shaped Container, in the water or a suitable heat transfer or conduction fluid is located and that by means of a highly transparent for Sonnenlich Cover is provided. The cover can also be covered by another cover, for example made of transparent plastic or mineral glass and thus be protected against mechanical influences. The container itself is there preferably made of plastic, for example polypropylene, polyamide, ABS or the like. As a heat transfer fluid or as heat Conductive fluid comes, for example, glycol or a solution of glycol and water in question.

The cover preferably has two flexible layers on top of each other, but not are interconnected. The first layer expediently consists from a highly transparent film, for example from ETFE (ethylene-terflour-ethylene), while the second layer consists of a transparent and heat-insulating material. The second layer can in particular have a honeycomb structure and consist, for example, of cellulose acetate. The first layer can be one material thickness for example between approx. 30 and 100 μm have while the second layer has a material thickness of approximately 30 to 80 mm can. Between the first and second layer or within the honeycomb structure the second layer is provided with an air cushion that blocks the water or heat conduction fluid content of the collector additionally before cooling off protect can.

The trough-shaped container is preferably double-shelled executed with an inner and an outer shell each with a heat insulating Coating can be provided. A surrounding stabilizing frame serves as a connection between the two containers.

Preferably both shells are container each thermoformed or injection molded from plastic. Both shells of the container can for example, also be produced by means of a blow molding process. With This method can also be used inside and outside outdoor tub in one piece and with a defined distance between them. To increase the mechanical stability and dimensional stability the containers show in use according to one embodiment stiffening ribs of the invention. These can be easily bring in the manufacture without the need for increased manufacturing effort would.

Since there is also a very high demand for hot water in the Mediterranean region and south of it, but the sun intensity is not very high in the colder seasons, an efficient system with high efficiency for heating domestic water is required there. Because in these regions the technical and financial possibilities of the population are often not as great as here in the country, the system still has to be simple and inexpensive. Since central production in Central or Northern Europe should be possible, for example in Germany, the system must also be easy to transport and stack. It is desirable to have as little space as possible when storing and stacking the containers according to the invention or their individual parts.

A container with a capacity of typically about 50 to 300 liters, preferably about 150 liters, brings the advantage of better portability and one lower price with it. The additional profiling of the side walls increases the rigidity and thereby facilitates use and transport. The opposite to known systems horizontally closing lid is the higher position of the sun in southern countries customized. Moreover the storage collectors can be stacked better in this way. The one in southern countries less night cooling because of the transparent insulation layer thinner selected what under these circumstances still sufficiently isolated and better optical efficiency guaranteed. Improved sealing technology prevents condensation like higher ones Reduced temperatures. The increased ratio of aperture area to water content elevated the rate at which water heats up.

The heat collector according to the invention is extremely inexpensive and easy-to-implement method to generate useful heat from solar energy. The installation is very simple. It just has to be ensured be that there is sufficient sunlight. For installation only an inlet, an outlet and possibly an overflow must be connected become. There is no additional to operate the system electrical energy necessary. It only has to be the required Water pressure available be put as well as for the upheaval of the warmed Water or heat transfer fluids (Glycol, glycol-water solution or similar) be taken care of.

An additional welcome effect can be the disinfecting effect of water heating because at temperatures from above 60 ° C one disinfectant effect occurs and the correspondingly heated water thus becomes drinkable.

The system can be modified also for fresh water or drinking water from salt water.

Another advantage of the system according to the invention is the decalcifying effect achieved by flocculation. The collector system according to the invention deprives the heated Water dissolved in it Lime that deposits on the absorber. Due to the easy opening thanks to the removable cover, it can be easily lime scale be solved Agents cleaned and then be put back into operation. Other water heaters like e.g. Electric boilers are mostly due to the lime deposited in them no longer usable after several years.

Other characteristics, goals and advantages of the present invention will become apparent from the following detailed Description of a preferred embodiment of the invention, the as non-limiting Serves as an example and refers to the accompanying drawings, in which:

1 2 shows a perspective illustration of a container of a heat collector according to the invention,

2 a schematic side view of the container,

3 a schematic partial sectional view,

4 a perspective schematic representation of the open container,

5 a perspective view of an outer tub of the container,

6 a perspective view of an inner tub,

7 2 shows a perspective schematic representation of the transparent cover that can be placed on the container,

8th a perspective exploded view of the heat collector according to the invention and

9 is a schematic partial sectional view of a cover closing the container.

The 1 and 2 show a heat collector according to the invention in a perspective schematic representation ( 1 ) or in side view ( 2 ) and in assembled condition. The heat collector 10 comprises a trough-shaped container 12 with a largely flat lid 14 , The container 12 has a rectangular contour with a flat bottom 121 and flat, all-round edge 24 on which the lid 14 with a lid rim that preferably fits flush with it 141 can rest. In the container 12 an inlet opens to the side 20 as well as an expiry 22 , each of which is designed as a connecting piece to which a line or hose section of a water line system (not shown) can be connected.

As already with the 1 and 2 the container is clear 12 as well as the lid 14 each have ribs in the form of slightly raised transverse or longitudinal ribs. These ribs are explained in more detail with reference to the following figures. The ribbing leads to an increase in the stiffness of the container parts, which preferably consist of relatively thin, deep-drawn, blow-molded or injection-molded plastic. The ribs are regularly formed and each preferably have a depth that does not account for more than 5% of the total height of the components. The ribbing can thus correspond approximately to the wall thickness of the components or something be more trained.

The container 12 includes an outer tub 16 as well as an inner tub that can be firmly connected 18 what based on the 3 is clarified in more detail. The inner tub 18 can be filled with a liquid to be heated. The inlet is for this purpose 20 as well as the process 22 provided, each with the inner tub 18 connected and through the outer tub 16 of the container 12 are passed through.

3 shows the arrangement of the inner tub 18 inside the outer tub 16 , The connection of the two tubs is over the peripheral edge 24 formed, which can optionally be reinforced with a circumferential profile piece. This profile piece can in particular consist of a metal profile part or the like.

The inner tub 18 is not visible from the outside and can, for example, consist of transparent or non-transparent plastic. Between inner tub 18 and outer tub 16 is preferably an insulating layer 28 introduced, which ensures that the heat collector 10 releases as little stored heat as possible. The insulation layer 28 envelops the inner tub 18 from all sides and prevents direct incidence of light, so that the inner tub can optionally be made of almost any choice of transparent or non-transparent materials.

The container 12 consists preferably of non-transparent plastic such as polyamide, polypropylene, ABS or the like. The lid 14 consists of highly transparent and possibly heat-insulating plastic such as polyamide, polypropylene, PVC, ABS or the like.

4 shows the inner tub again in perspective. On the ground 181 the inner tub 18 For example, a fill level measuring device (not shown) can be arranged, which supplies its signals to a control device. Furthermore, a temperature measuring device (not shown) can be arranged there, which also supplies its signals to the control device. The transverse or longitudinal ribbing is clearly recognizable 38 . 40 the inner tub 18 as well as the ribs 34 . 36 the outer tub 16 , each for the increased stiffness of the tubs 16 and 18 to care.

5 shows the outer tub 16 in perspective, the ribs here 34 . 36 are made particularly clear. It becomes apparent that there are cross ribs 36 from the top of the container 24 over the side walls and the tub floor 161 extend to the opposite side of the top edge. Other ribs are as longitudinal ribs 34 attached to the narrow sides and each end on the floor 161 , but spaced apart from the cross ribs 36 ,

6 illustrates the inner tub 18 in a schematic representation from above. Here it becomes clear that similar cross ribbing 40 and longitudinal ribbing 38 are provided, which, as in the exemplary embodiment shown, are narrower than in the outer tub 16 can be arranged, but can also be designed as in this.

7 illustrates that on the container 12 attachable lid 14 , which has a slightly curved contour with cross ribbing 142 having. The lid 14 can be tight with the container 12 be connected, for example by a circumferential elastomer seal between the container edge 24 and lid rim 141 is used. Between the edge of the lid 141 and container rim 24 is preferably a heat-insulating and highly transparent cover that can be removed in 7 not shown, but to avoid condensation in the lid 14 can be useful. Water or other heat transfer fluid gets into the container 12 , the film floats on it. There is a highly transparent thermal insulation on the film, which allows incident light to pass through, but prevents heat from escaping.

8th illustrates once again the structure and assembly of the container 12 , the heat collector according to the invention in the fully assembled state 10 forms. In the outer tub 16 will be the insulation layer first 28 introduced, which can consist, for example, of styrofoam plates or the like. The profile piece 26 to stiffen the edge 24 is inserted between the inner and outer tub before the inner tub 18 is used. The inflow 20 and the process 22 are in this assembled state of the two tubs 16 and 18 preferably already used. On the surrounding edge 24 the inner tub 18 will continue to be a seal 42 hung up before the lid 14 sealed and placed on the container 12 is fixed.

A level measuring device is only indicated 30 which, according to the exemplary embodiment shown, can have a float switch or the like for level regulation. Optionally, the level measuring device 30 but also have a different measuring principle.

The schematic partial sectional view of the 9 illustrates that on the inner tub 18 overlying two-layer cover 50 that from a first layer 52 made of highly transparent film material and a second layer on top of it 54 consists of transparent and heat-insulating material. As the first layer 52 an ETFE film with a layer thickness between 30 and 100 μm is particularly suitable, which is particularly temperature-resistant and translucent. The temperature resistance of over 200 ° C is particularly important when no water is available and the collector can reach temperature peaks of up to 180 ° C in so-called dry running. The transparency of such a film for light is approximately 96%. The film also has the advantage that it is food-safe and no connections with other substances and materials, which makes the collector suitable for the intended purpose of drinking water preparation.

Because the first layer 52 the second layer is above it and cannot provide thermal insulation 54 , which can consist in particular of a honeycomb structure made of cellulose acetate or cellulose triacetate (CA) with a layer thickness of approximately 30 to 80 mm. The woven film has a thickness of approx. 30 μm. This creates a structure similar to a honeycomb, which has transparent walls. The resulting tubular cells have a cross section of approx. 1 cm².

The second layer 54 lies on the film of the first layer 52 , which in turn sags loosely and thus on the water in the inner tub 18 floats. The two layers 52 and 54 are not connected. Inside the honeycomb structure of the second layer 54 there is an air cushion layer that prevents the collector content from cooling too quickly. The transparency for sunlight of this second layer is approximately 70 to 90%. The insulation effect can reach a so-called k-value of approx. 0.8 to 0.9. How the cover works 50 can be called a light trap.

The inner tub 18 can optionally be provided with a food-safe coating, which seals the tub surface and thus drinking water preparation and heating in the container 12 allowed. The coating (not shown) can also enable heat absorption and, for this reason, preferably has a dark color. The coating can be applied subsequently, for example, and by a melting process with the inner tub 18 be connected and seal them at the same time. The coating of the inner tub 18 also ensures that the plastic is UV-resistant and protects it from aging too quickly due to the continuous sun exposure.

In principle, however, such a coating is not necessary, since food safety can also be achieved by appropriate admixtures in the plastic granulate to be processed. The required resistance to UV components in sunlight can be achieved in the same way. These admixtures allow the container to be manufactured much more cheaply than a coating to be applied subsequently. A corresponding UV-resistant coating or admixture of the plastic can also be on the outer tub 16 be provided, but at least on the outside.

The lid 14 must have at least sufficient mechanical stability to withstand snow, hail and wind loads. In addition to the wall thickness, this is due to the ribbing 142 of the lid 14 reached. PMMA (polymer methyl methacrylate) or PA (polyamide) is particularly suitable as the material.

Claims (25)

Heat collector ( 10 ) for heating industrial water or heat transfer fluid by solar radiation and / or for storing tempered water or heat transfer fluid, comprising a trough-shaped container ( 12 ) made of plastic, which can be filled with water to be heated or with heat transfer fluid to be heated, and the open top of which is a cover which is highly transparent to sunlight ( 50 ), characterized in that the cover ( 50 ) is heat-insulating and / or a heat-insulating layer ( 54 ) having. Heat collector according to claim 1, characterized in that the cover ( 50 ) at least two layers ( 52 . 54 ) having. Heat collector according to claim 1 or 2, characterized in that a first layer ( 52 ) the cover ( 50 ) consists of a highly transparent film. Heat collector according to claim 3, characterized in that the film of the first layer ( 52 ) consists of ETFE (ethylene-terflour-ethylene). Heat collector according to one of the preceding claims, characterized in that a second layer ( 54 ) the cover ( 50 ) consists of a transparent and heat-insulating or heat-insulating material. Heat collector according to claim 5, characterized in that the second layer ( 54 ) has a honeycomb structure and consists of CA (cellulose acetate). Heat collector according to one of the preceding claims, characterized in that between the first layer ( 52 ) and second layer ( 54 ) or within the second layer ( 54 ) an air cushion is formed. Heat collector according to one of the preceding claims, characterized in that the trough-shaped container ( 12 ) two, at least partially nested, tub parts ( 16 . 18 ) includes. Heat collector according to one of the preceding claims, characterized in that an inner trough ( 18 ) spaced from an outer tub ( 16 ) is arranged. Heat collector according to one of the preceding claims, characterized in that between the inner and outer tub ( 18 . 16 ) a heat-insulating layer ( 28 ) is inserted. Heat collector according to one of the preceding claims, characterized in that the inner tub ( 18 ) and outer tub ( 16 ) at an upper edge ( 24 ) are firmly connected. Heat collector according to one of the preceding claims, characterized in that the inner and outer tub ( 18 . 16 ) at the top ( 24 ) surrounding stabilizing frame are fixed together. Heat collector according to one of the preceding claims, characterized in that the peripheral edge ( 24 ) consists of a metal frame or has one. Heat collector according to one of the preceding claims, characterized in that at least the outer trough ( 16 ) stiffening ribs ( 34 . 36 ) having. Heat collector according to one of the preceding claims, characterized in that the inner and outer tub ( 18 . 16 ) stiffening ribs ( 34 . 36 . 38 . 40 ) exhibit. Heat collector according to one of the preceding claims, characterized in that an inner surface of the inner trough ( 18 ) has a heat absorbing coating. Heat collector according to one of the preceding claims, characterized in that the coating of the inner tub ( 18 ) sealing the tub ( 18 ) causes. Heat collector according to one of the preceding claims, characterized in that the inner and / or the outer tub ( 18 . 16 ) each consist of plastic. Heat collector according to one of the preceding claims, characterized in that the inner and / or the outer tub ( 18 . 16 ) each consist of deep-drawn plastic such as polypropylene, polyamide, PVC, ABS or the like. Heat collector according to one of the preceding claims, characterized in that the container ( 12 ) covering layer ( 50 ) made of plastic on the peripheral edge ( 24 ) is fixed and sealed against it. Heat collector according to one of the preceding claims, characterized in that the cover ( 50 ) is flexible and with an empty container ( 12 ) sags inside. Heat collector according to one of the preceding claims, characterized in that over the transparent cover ( 50 ) a highly transparent seal or a cover ( 14 ) made of plastic and / or mineral glass. Heat collector according to one of the preceding claims, characterized in that the container ( 12 ) has a capacity between 50 and 300 liters. Heat collector according to one of the preceding claims, characterized in that the transparent heat-insulating cover ( 50 ) has a layer thickness of approx. 3 to 8 cm. Heat collector according to one of the preceding claims, characterized in that the top of the container ( 12 ) largely parallel to the floor ( 121 ), and that both are arranged horizontally.