DE3017727A1 - Solar heating system absorber grid - has black surface with strips carrying glass tubes connected to collector tubes by resilient adaptors - Google Patents

Abstract

The solar heating system using absorbers through which water can trickle, uses glass or transparent plastics tubes (3a,3b) to form a grid for an absorber. These tubes can be similar to the tubes used for fluorescent lamps, and two suitable lengths can be joined by a resilient connector sleeve (4). Their outer ends (5,7) can be fitted with adaptors (16,19) to enable collector tubes (6,8) to be connected to these ends to complete the grid. The tubes are supported by longitudinal strips with hooked attachments to grip round them, and mounted on a block surface. The adaptors have large flanges (5) to fit the glass tubes and small flanges (20a) to fit inside the collector tubes, joined by necks (21). Throttling valves (17) can be fitted to the adaptors (16) from the discharge tubes (6).

Description

Solar grid

The invention relates to a solar grid in the manner of a solar collector for the use of solar warmth by means of liquid that can be passed through the grid.

Various solar collector constructions are known and on the market, which, however, are material-intensive, expensive and often heavy. The cost-benefit effect this collector is relatively unfavorable, so that systems equipped with it and he threshold of profitability work. These facts are no reason why Solar technology is reluctant to introduce itself despite today's high energy costs and can enforce.

The present invention was based on the object of a solar grid to create that solar energy is not available in a particularly simple and economical way With the help of a heat transfer medium flowing through it, e.g.

Water, usable at night, inden the heat transfer medium stored in it Energy to any heat receiver, such as a swimming pool, a heat store, an underfloor heating system, a service water system, a greenhouse or the like. Transport can. Another object of the present invention is the solar grid partly from already for others Purposes used to produce components and relatively easy assembly and maintenance of the solar grid to enable, so that this can also be offered as a kit for self-assembly can.

According to the invention this is achieved in that the solar grid of individual closed transparent ones arranged next to one another and / or one above the other There is glass or plastic tubes as absorber tubes.

One such from prefabricated individual elements, namely glass or Plastic tubes, assemblable solar grid is relatively easy to assemble, since the individual elements are only light in weight and therefore easy to handle are.

The previously known solar collectors put expertise for the Assembly in advance, are usually heavy and unwieldy and can often be carried out without assembly aids, such as scaffolding or cranes are not assembled. Furthermore, the often large-scale and heavy collectors covered with glass, a really flat roof or a roof level installation surface ahead, they should not be at risk of breakage, even by occurring Wind forces.

It is advantageous if the solar grid according to the invention of the liquid heat carrier is flows through pressurized chlorine, so that the sealing problems between the individual components can be reduced to a minimum.

Furthermore, it can be advantageous if the Abrorberrohre from the heat carrier, like water, only partially filled resp. are sprinkled by these. This results in Although there is a lower liquid throughput, the amount collected in the drain pipe is The liquid is considerably warmer because it is in the gloss or plastic absorber tubes trapped still air cannot circulate, causing heat to build up in the Absorber tubes are created, the additional burden of the trickling through the absorber tubes Releases heat transfer medium.

A further development of the invention is the length of the absorber tubes of the solar grid by joining pipes with standard lengths according to the Modular principle can be varied. This allows the solar grid to be attached to the available Surfaces are adapted so that any roof of any size and any shape or the installation or wall area can be optimally occupied or hung for the best possible Use of solar energy.

It can be particularly advantageous if the absorber tubes or the tubes forming the absorber tubes with standard lengths of fluorescent tube bulbs are made of glass, as these are machined in different lengths and are subject to international standards and are therefore inexpensive. Furthermore are their tubular shape makes them relatively stiff and suitable as a load-bearing element.

The joining of the individual ones that form the absorber tubes Pipes, can be done through a plug connection. It is particularly advantageous if the pipes with standard lengths are fitted with connecting pieces that can be plugged on at their ends, such as grommets made of an elastic material, such as rubber or plastic, to one accordingly Erwunechten long absorber tube can be connected.

In the same way, between the drain pipe and the absorber pipes and between the inlet pipe and the absorber tubes of the solar grid connectors elastic material, such as rubber or plastic, can be provided in the absorber tubes can be plugged in or out of the absorber tubes. The connecting pieces be glued onto the inlet pipe and / or the outlet pipe, or else on this be attached by a plug connection.

It can be seen that a solar grid constructed in this way by simple Plugging pipes together can be assembled and no specialist knowledge is required are necessary, as is the case with the currently

constructions on the market is the case.

It is useful if the solar grid is attached to a substructure which can be constructed from metal or plastic profiles, with the Profiles are provided with fastening holes for fastening, e.g. by means of Clamps, the inlet and outlet pipes and the absorber pipes. Particularly useful is included when all components are made of plastic or gloss, so that no corrosion can occur and the system is therefore maintenance-free in terms of corrosion.

The substructure can expediently by means of a corresponding connection of the profiles that form it according to the modular principle to the various absorber pipe lengths be adapted or adapted to the available roof or structure flat will.

It is particularly useful if the absorber tubes are used as load-bearing Element to be included in the overall construction, so that the total weight the construction is thereby reduced.

In particular, the fluorescent tube bulbs made of glass are inherently stiff Construction elements, which, as soon as they are e.g. with pipe clamps on the substructure are attached, stiffen the overall structure, which is a statically expensive heavy sub-bou can be dispensed with.

It is also possible to use several grids to form a unit Connecting pieces, e.g.

a deer antler distribution system.

According to an advantageous development of the invention are between Inlet pipe and absorber pipes, resp.

Absorber pipes and drain pipe adjustable throttles provided so that the amount of heat transfer medium flowing through the individual absorber tubes can be adjusted.

It is advantageous if the solar grid is over a black area mounted, e.g. a dark pan roof or a black cardboard roof. It is but also possible to color the absorber pipes themselves black on their underside, e.g. by sticking a black foil. The resulting heat reflection increases the efficiency of the solar grid.

Another way to improve the efficiency of the solar grid consists in the absorber tubes on their underside with a selectively absorbing To be provided with a layer, e.g. with a selective varnish. This layer absorbs the Sun rays almost one hundred percent, like a normal black surface. You prevented however, in contrast to these, the losses resulting from heat radiation.

A particularly favorable one that increases the efficiency of the solar grid Measure consists in covering the underside of the absorber tubes with a reflective layer to be provided, e.g. by gluing with an aluminum foil, and the top of the To provide absorber pipes with a selectively solar-absorbing layer.

The solar radiation can selectively fall into the absorber tubes and taken up by heat transfer medium, the one on the back normally emitted part of the radiation is reflected back into the heat transfer medium and the upper selective layer largely prevents radiation from escaping upwards can.

Even with solar grids, the orientation of the system to the sunny side brings about a better utilization of solar energy, result in the invention Solar grid further efficiency improvements by using of round absorber pipes, as these have a larger surface than the one required for this Have mounting surface, so that for solar radiation, especially when diffuse Irradiation, there is a larger impact surface than is the case with flat surfaces would be the case. Furthermore, due to the round cross-section of the absorber tubes the sun's rays optimally on the absorber pipes during the entire duration of the sunshine hit, which is particularly beneficial for the efficiency.

It is advantageous if the absorber pipes and the inlet and outlet pipes of the solar grid close to one another, or with a narrow pitch, on a pre-assembled one Substructure made of e.g. wood, plastic or metal can be attached or mounted. A such a substructure can e.g.

be arranged flat on a roof or some other free space. Advantageous it is there when the Gesout construction is inclined towards the sun. However can they can also be installed on a flat roof or a small amount of space is sufficient, and the flow of the heat transfer fluid, such as water, through the solar grid is safe to deliver.

Because in the solar grid the water flows from the higher inlet to the lower one When the drain pipe is lying down, the inclination of the solar grid determines the water flow rate and with it the amount.

To a more intensive warming of the water by the solar radiation a throttle screw is provided e.g. at the inlet, with the help of which the water flow rate as a function of the slope of the Solar grid can be adjusted.

As with all high-performance solar systems, the solar grid should also The water flow through the absorber pipes only takes place when there is sufficient solar heat or diffuse light is offered to heat the water. This should go through a temperature reference controller, as already offered on the market will. A collector sensor should be placed directly in one of the absorber pipes and with the existing temperature, e.g. in the floating pool water or the heat storage tank or heating system can be compared by a reference sensor attached there. If there is enough heat, either the feed pump is switched on directly or a notoriously or electromagnetically controlled switching valve operated so the water circulation can occur.

If the heat supply has become insufficient, the control device switches the water cycle flowing over the solar grid, so that the solar grid automatically Empty air and no risk of frost for the absorber pipes in the event of a sudden change in weather exists so that the solar grid does not need to be dismantled in winter.

Further useful refinements result from the subclaims.

The invention is explained in more detail using the figures.

Figure 1 shows the arrangement and the basic structure of a solar grid according to the invention.

Figure 2 details of the connections between absorber tubes and Inlet and outlet pipe.

Figure 3 shows the arrangement and structure of a solar grid receiving Plastic box and an alternative embodiment of the invention.

FIGS. 4 to 6 show a further alternative embodiment of the invention.

In Figure 1 ibt partially shown a solar grid 1, which on a Roof 2a of a building 2 is arranged obliquely towards the sunny side. The roof 2a is expediently designed in black in order to improve the efficiency of the To achieve overall system.

The grid 1 consists of absorber tubes arranged next to one another 3, which in turn consist of two or several in a row connected tubes 3a and 3b exist, which have one on one of their ends plug-on grommet 4, made of e.g. soft PVC, rubber or the like, with one another are connected.

The absorber pipes 3 are at one of their ends 5 with an inlet pipe 6 and with the other end 7 with a. Drain pipe 8 connected by a plug connection.

To hold the individual absorber tubes together, are these fastened with clamps 10 on a structure formed by profiles 11. Included the absorber pipes are included as a supporting element in the overall construction.

The heat transfer medium such as water flowing through the grille is by means of a pump, not shown, via a line 12, the feed pipe 6 fed and via a. Return line 13 from drain pipe 8 of grille 1, e.g. to a swimming pool not shown in detail, drained0 In Figure 2 is again an absorber tube 3 can be seen, which is supported by two fluorescent tubes 3a and 3b A grommet 4 is formed on the end 14 of the tube 3a and 15 of the tube 3b plugged in and connects them. The connection of the Abiorber tube 3 to the Inlet pipe 6 takes place by means of a connection piece 16 which is glued onto the inlet pipe 6, e.g. and can be inserted into the end 5 of the tube 3b. To the water flow rate To be able to adjust through the absorber tube 3, the connection piece 16 has a throttle screw 17, which shows the cross section of the channel 18 between the inlet pipe 6 and the absorber pipe 3 can change.

At the end 7 of the tube 3b, a connection piece 19 is also provided, which is attached to one end 7 and can be glued. The connector 19 protrudes with a region 20 through an opening 21 of the drain pipe 8 into the latter and connects the absorber pipe 3 to the drain pipe 8 via a channel 22.

The area 20 of the connecting piece 19 forms a bead 20a, which engages behind the opening 21 in the interior of the run-up pipe 8 and thus a fixed one Button connection and at the same time ensures the seal. It can be seen that by such an assembly of the individual tubes 3a and 3b, 6 and 8 the Pipes 3a and 3b in their elastic plug connection 4, 16, 19 so much freedom of movement recovered that they can also be individually exchanged and the manufacturing tolerances of the components and allow expansion of all parts as a result of heating.

In a further embodiment of the invention according to FIG the solar grid pre-assembled in a prefabricated box and as a closed one Unit applied to any sloping roof or building surface and attached.

The substructure 40 is formed by a plastic film deformed in the deep-drawing process, which is stiffened by beads 41. This is a metallized one by welding or gluing Foil 42 deformed in this way in the division of the arranged absorber tubes 3a and 3b arranged that this serves as a reflector. The cover is made by a transparent, again deformed in the form of corrugated sheet metal in the division of the absorber tubes 3a and 3b and this stiffened, also deep-drawn plastic film as a hood 43. The hood 43 can be screwed or riveted to the reflector 42 and the sub construction 40 must be connected at the points of contact 44 and 45. Through these arrangements cavities 46 arise, which like an additional insulating effect and heat build-up cause an insulating glass pane and heat dissipating air movements from the Keep away from absorber tubes 3a and 3b through which a heat transfer fluid has flown. In addition, this protected arrangement means that the absorber tubes 3a and 3b are in front of the outside Damage, e.g.

better protected from hailstorms.

In a third embodiment of the invention according to FIGS. 5 and 6 the structure was chosen so that the inlet and outlet system and the connection of the assembly units for the assembly and maintenance of the solar grid mostly Easier to reach lower edge of the solar thing or the construction area provided are. Only the profiles 11 and the clamps 10 for fastening the absorber pipes 30 and 3b must be outside of the Grundoufboues and before the assembly of all absorber pipes 3 can be fastened once to the roof or construction area.

This embodiment of the invention is illustrated with reference to FIGS. 4, 5 and 6 explained in more detail.

Part 23 is a manifold or base body, in which the inlet and Distributor pipe 6 is held centrally, which is glued, welded, or buttoned Has pre-divider connection 24. The manifold 23 is through cover 25 and 26 closed, which is sealed by a sealing ring 27 or by gluing or Welding to the pipe 23 are firmly connected.

Both cover plates 25 and 26 contain a through hole for the inlet and distributor pipe 6 and a connection hole for the outlet pipe 8, wherein through the two protruding pipe ends on one side Sealing caps 28 are closed, which are removed again when a further solar grid is connected can be.

The drain pipe 8 is at the lowest point of the collecting pipe 23 through Gluing, welding or screwing attached. Depending on the length, this can be Inlet and distributor pipe 6 at a suitable point or several times through a clamp 29 be supported with support screws 30 to prevent deflection of the fluid-filled To avoid inlet and distributor pipe 6.

The central arrangement of the inlet and distributor pipe 6 in the base body 23 allows the absorber tubes 3a and 3b in any desired angular position, that corresponds to the roof pitch or that of the installation surface, and still of the drain pipe 8 by fitting the pivotable cover 25 accordingly and 26 to be arranged at the lowest point of discharge of the flowing heat transfer medium, e.g. water, because the base body 23 also serves as a collector for the reflux.

In the base body 23 there are bores 31 in the division of the distributor nozzle 24 introduced, each receiving and centering an absorber tube 3. Every absorber pipe 3a is closed at its upper end by a lid 32 that has a circulation the included Air in the cavity 33 prevents and for one Heat and fawn build-up ensures.

One is placed concentrically on each of the distributor stubs 24 in the absorber tubes 3 held black, grooved riser pipe 34 attached and through a sealing ring 35 sealed or connected by another suitable plug connection. The centering the riser pipes 34 in the absorber pipes 3 are carried out by centering rings 36, e.g. an annular wire spiral which is formed so that they simultaneously one Permits reflux of the heat transfer fluid.

Each riser pipe fills up to its uppermost edge 37, air then over and the heat transfer fluid can ouf the underside of the sloping or vertically positioned absorber tubes 3a and 3b flow back into the base body 23, which is connected to the return valve 8.

The flow rate of the heat transfer fluid, e.g.

Water is supplied through a nozzle which can be inserted into the distributor connection 24 38 determined and regulated, whereby an adjustment to the existing pump capacity becomes possible. It may well be possible, depending on the size or retrofitting, nozzles 38 of different bores within a solar grid to use. The nozzles 38 can also be replaced by adjusting throttles.

If there are leaks on one of the absorber pipes 3a or 3b, e.g. due to broken glass, or a sputore retrofitting or a gradual If expansion of the solar grid is planned, a blind plug can be used instead of the DUse 38 (Nozzle head without a through-hole) and thus the heat transfer medium flow to it. Manifold nozzles are interrupted without the rest of the solar system until the repair having to shut down. If there is a throttle screw, the Wörmetrögerfluss can use it also be cordoned off.

The third embodiment of the invention described above has the following additional advantages: It is to be expected that when the warming Sun rays through the crystal clear absorber tubes 3 and when they hit perpendicularly on the black riser pipe 34 by the radiation collecting effect of the glass tube 3 the Heat transfer fluid, e.g. water, already warms up considerably in the riser pipe 34, before they go to the overflow 37 through the absorber tubes 3a and 3b and through the dormant Air 33 flows back into the base body 23, with heat dissipating through the heat build-up had resulted and the heat transfer fluid is heated again. It results So-a greater heating effect for the heat transfer fluid with the same large solar grid area than previously described.

Because the supply and distribution line 6 'with the base body 23 and the return, which flows into the return line 8 ', form a unit, The solar grid can also be expanded at a later date by arranging it as required many absorber tubes 3a and 3b one above the other with simultaneous extension of the Riser pipe 34 by plug-in couplings or sleeves 39 in height and by being connected in series several base bodies 23 and by connecting the nozzle 40 for the inlet and Distributor pipe 6 'and the connector 41 for the drain pipe 8' in the width possible. In order to a universal possibility of expansion of the solar grid is achieved without further supply lines 6 'and discharge lines 8' must be laid.

The assembly and maintenance of the solar grid is simplified and made easier, because most of the connection parts come from the lower edge of the roof surface or lower near the ground Can be installed and serviced at the edge of a set-up area. This is the The system can be easily expanded and expanded and is easy to maintain in the event of malfunctions.

The solar grid can be tilted at a small angle and also steeply set up and operate is largely independent of the angle of inclination. Self if for reasons of space a vertical arrangement of the solar grid necessary can be expected with a useful efficiency, because the heat transfer fluid speed, e.g. water, only flows through the black riser pipe 34 and warms up before it past the heated walls of the absorber tubes 3a and 3b into the base body 23 riesolt.

The last-described embodiment of the invention also allows one problem-free and independent idling of all absorber tubes 3 and lines from the heat transfer fluid, e.g. water, when the solar grid is shut down should, e.g. if there is a risk of frost.

It is intended for all individual parts made of plastic of the solar grid to use W-bonded plastic.

L e r s e i t e

Claims (23)

Claims 1. Solar grid for the use of solar heat by means of a liquid which can be passed through a grid, characterized in that it doses from individual side by side and / or one above the other, closed at the top, transparent glass or plastic tubes (3a, 3b) as absorber tubes (3). 2. Solar grid according to claim 1, characterized in that the liquid Heat transfer medium, such as water, flows through or trickles through the solar grid (1) without pressure. 3) solar grid according to claim 1 and 2, characterized g.-indicates that the length of the absorber tubes (3) the solar grid (1) by joining one behind the other Pipes (3a, 3b) with standard lengths is variable. 4) solar grid still one of claims 1 to 3 characterized, that the absorber tubes (3) are formed by glass bulbs, as they are for fluorescent tubes Find use. 5. Solar grid according to one of the preceding claims, characterized in that that several tubes (3a, 3b) through connectors that can be plugged on at their ends (14,15) (4) (TUllen) made of an elastic material, such as Guzei, can be connected. 6) solar grid according to one of claims 1 - 5, characterized in that that the substructure for the grid is made of metal or plastic profiles (11) with fastening holes for fastening, e.g. by means of clamps (10) are provided. 7) solar grid according to claim 6, characterized in that the substructure by corresponding connection of the profiles (11) according to the modular principle to different Absorber tube lengths can be adjusted. 8) solar grid according to claim 6 or 7, characterized in that the absorber pipes (3) are included as a supporting element in the overall Fit construction are. 9) solar grid according to one of the preceding claims, characterized in that that the absorber tubes (3) over an underlying blackened surface (2a) are mounted. 90. Solar grid according to one of the preceding claims, characterized in that that the absorber tubes (3) colored black on their underside, or with a selectively solar absorbing layer are provided. 11) solar grid according to at least one of the preceding claims, characterized in that a control unit is provided, which it the help of a Collector sensor and a reference sensor provided on a hot water receiver controls the flow of liquid through the absorber tubes (3) or switches it on or off. 12) solar grid according to one of claims 1-11, characterized in that that the absorber tubes (3a, 3b) in a. closed box are arranged, whose Substructure made of a deep-drawn plastic film (40) and beaded (41) is stiffened, contains a preformed reflector (42) made of metallized plastic and by means of a also deformed in absorber pipe division and in the deep-drawing process, transparent hood (43) is covered, whereby heat-insulating cavities (46) arise. 13. Solar grid still one of claims 1 - 5, characterized in that that the absorber pipes (3) can be connected with one of their ends (5) to a supply pipe (8) are. 14. Solar grid according to one of the preceding claims, characterized in that that between the drain pipe (8) and absorber pipes (3) and between the inlet pipe (6) and Absorber pipes (3) connecting pieces (16, 19) made of elastic material, such as Gu11i, are provided that are inserted into the absorber tubes (3) or onto the absorber tubes (3) are attachable. 15. Solar grid according to claim 14, characterized in that connecting pieces (16, 19) are glued onto the inlet pipe (6) and / or the outlet pipe (8). 16. Solar grid according to claim 14, characterized in that the Connections to the inlet pipe (6) and / or the outlet pipe (8) by means of a plug connection are attached. 17. Solar grid according to one of the preceding claim che, characterized characterized in that between the inlet pipe (6) and absorber pipes (3) or between Absorber pipes (3) and drain pipe (8) adjustable throttles (17, 18) are provided are. 18. Solar grid after a. of claims 1 - 14, characterized by that as a feed to each absorber tube (3) a concentric held in the absorber tube Riser pipe (34) is provided with a. Pre-air and distribution pipe (6) connected is. 19. Solar grid according to claim 18, characterized in that the Flow and distribution pipe (6) into a return pipe forming the absorber pipes connected manifold (23) is arranged. 20. Solar grid according to claims 18 and 19, characterized in that doß on the riser pipes (34) one or more spiral wire rings (36) applied are that center the riser pipe (34) in the absorber pipes (3a, 3b) without the To hinder the return flow of the heat transfer fluid, e.g. water. 21. Solar grid according to claims 18-20, characterized in that that the absorber tubes at their end facing away from the collecting tube (23) by closure caps (32) are closed. 22. Solar grid according to claims 18-21, characterized in that that between the flow and distribution pipe (6) and the riser pipes (34) cans (38) to regulate the heat transfer fluid flowing through the riser pipes (34), e.g. water. 23. Solar grid according to claims 18-22, characterized in that that the inlet and distributor pipe (6) centrally in the rotatably mounted manifold (23) and the drain pipe (8) eccentrically to a cover plate (25, 26) of the collecting pipe (23) is held.