DE2508339A1 - Hollow cylindrical type solar cell - in which complicated assembly of lenses and mirrors is eliminated - Google Patents

Abstract

Solar cell comprises a hollow cylinder (1) which is closed at both ends and either evacuated or filled with gas of low heat conductivity, and housed in the cylinder a flat hollow absorption body (5) through which flows a heat-conducting medium. The absorption part comprises a glass body with absorption means, and with a width (B) only slightly less than the inner dia. (D) of the cylinder (e.g. B = 4/5 D). The absorption means comprises a coating (6) which absorbs solar radiation but emits IR radiation, and which is applied to the outside wall of the glass body or to the inside wall of a body which transmits IR radiation. The drawing also shows a glass base (4) which includes inlet and outlet openings (2, 3) and which rigidly connects the cylinder to the absorption body.

Description

Solar oil motor The invention relates to a solar oil motor (a Device for the absorption of solar radiation), consisting of a closed at both ends evacuated or filled with a poorly thermally conductive gas hollow cylinder and an approximately equal length, accommodated in the hollow cylinder, the solar radiation absorbent hollow body (absorption body), which is used by a for heat dissipation Medium is flowing through.

In a known solar collector of this type (cf. z.3.

USA Pat. 3 125 091) consists of a transparent plastic hollow cylinder accommodated absorption body from a coaxial or parallel to the longitudinal axis of the Hollow cylinder running, heat-resistant, if necessary blackened plastic tube (Absorption tube) with a small luro knife in relation to the hollow cylinder diameter. The inside of the hollow cylinder is on the side facing the solar radiation designed so refractive that most of the incident solar radiation focused on the side surface of the absorption tube facing the solar radiation falls.

But also the solar radiation that does not hit the absorption tube is nooh effectively exploited and indeed because it is from the - in the direction of the imagination the solar radiation - part of the inside located next to or behind the absorption tube of the hollow cylinder, which is provided with offset mirror surfaces is also directed to the absorption tube. Even if the efficiency of a Such solar collectors should be good - but there are no measurement results before - so is the structural design of such a solar collector with the numerous lens and mirror systems required on the inside of the Hollow cylinder very complicated and expensive, r kali iloht be ovakulort.

In contrast, the invention is based on the object of a solar oil motor to sohaffen that is simple in construction and in production.

According to the invention, this object is achieved in that the one in the hollow cylinder accommodated absorption body as a flat, provided with absorbents Glass body is formed, the width of which is only slightly less than the inner diameter of the hollow cylinder. The distance between the absorption body and the hollow cylinder only needs to be as large as it can avoid significant heat conduction losses required by gas residues.

Such a solar oil motor thus has a very simple structure, for which no complicated parts are required.

Advantageously, the absorbent is a solar heat absorbing, in particular selective covering either on or in the absorption body. The attachment in the absorption body has the advantage that no gas release of the Absorbent can be done in the vacuum.

However, it is also possible to insert a thin layer into the absorption body, the Liohten width of the absorption body largely adapted to the solar radiation insert strongly absorbent body from the heat-dissipating medium is flowed around and also with guides for the medium used for heat dissipation can be provided. The attachment inside the absorption body has the advantage that the heat transfer to the liquid is improved.

But it can also be advantageous to use the absorbent layer first on a bolie,. made of copper, which in turn is applied to the absorption body, e.g. by gluing. But it is also possible to use the absorbent Schioht, e.g. as a paint, to be applied directly to the absorption body. In In all cases it is advantageous if the absorption body is exposed to solar radiation facing side is flat. So that the sun's radiation turned towards it Side of the absorption body in each case perpendicular to the direction of incidence of the solar radiation stands, the hollow cylinder firmly connected to the absorption body can around its The longitudinal axis can be designed to be pivotable.

Around the medium used to dissipate heat, which may consist of water, for example can, under as many places as possible on the covering that absorbs solar radiation To allow the absorption body to flow through it as effectively as possible contain a canal system in the pavement. Advantageously, this canal system be formed from the glass of the absorbent body; but it can also, for example, consist of a additional U-shaped bent pipe with transverse walls exist.

Further details and advantages of the invention will become apparent with reference to FIG discussed several embodiments. 1 and 2 show a complete one Sun Oollector according to the invention (with an absorption body) in plan view and on average; 3 and 4 an absorption body according to the invention before application the absorption material, in plan view and in section; Egg £. 5 one according to the invention Absorbent body with a different channel system; 6 and 7 show one according to the invention Absorbent body prior to application of the Absorbsohioht, with one of a U-shaped bent pipe formed channel system, in plan view and in section; Figs. 8, 9 and 10 shows a device for producing the transverse walls in an absorbent body Fig. 3.

The solar collector .naoh Figs. 1 and 2 consists of a hollow cylinder 1 made of glass, which has a glass base provided with input and output openings 2, 3 4 is firmly connected to the absorption body 5, which is also made of glass.

Because these three parts are made of glass, they are otherwise when using metal and glass possible sealing problems with the necessary evacuation of the hollow cylinder avoided. To that of the sun's rays facing side of the absorption body 5 is the heat-absorbing covering 6 applied. The absorption body 5 has glass stones, for example in the case of a of 1 mm and a prong of 6 mm a length of 200 cm for one Width of 8 cm and is housed in a cylinder about 10 cm long.

At its end of the absorption body 5 facing away from the base 4 At least one support 7 is provided to support the free end on the hollow cylinder 1. The medium used for heat dissipation flows through the openings 2, 3, e.g. from and to a heat accumulator, not shown.

The firmly connected to the absorption body 5 by the base 4 Hollow cylinder 1 can pivot about its longitudinal axis in a manner not shown be around the side of the absorption body 5 facing the solar radiation to be able to adjust perpendicular to the direction of incidence of solar radiation.

3 and 4 show an absorption body 8 (in plan view and in section) before applying the absorption coating and before connecting with the associated hollow cylinder.

In these two figures there is one below which is absorbing solar radiation The channel system for the medium used to dissipate heat can be seen. This channel system is advantageously made from the glass of the absorption body 8.

The channels 9, which, for example, are explained in more detail in FIG. 8 Can be formed, run back and forth from the openings 2, 3 roughly meandering, so that largely all places under which the sun's rays absorbent covering can be reached by the heat-dissipating medium. As 4 is the side of the absorption body facing the solar radiation 8 as flat as possible, whereby the application of the absorption layer by gluing or spreading is facilitated. The side of the Absorbent body is shaped and wavy for the purpose of forming the channel system the points 10 firmly connected with the flat side. To those facing away from solar radiation Page can also be a layer or a film in the manner not shown low heat radiation, see B. a mirror layer or a reflective metal foil, be provided.

The channel system in the absorption body can also be used in other ways such as shown in FIG. The exit opening 12 can in this version lie approximately in the middle of the base. Essential is with all Designs that the inlet and outlet openings are always on the same side of the Solar collectors are located in order to avoid undesirable tension in the absorption body.

Another example embodiment of the absorption body can be seen from FIG. 6. The associated glass body 13 consists of a U-shaped bent tube in which the medium used to dissipate heat is transverse to the direction of flow Transverse walls 14 are provided, the sohmale Durohflussöffnungen in their upper part 15 have. By these own places it is achieved that air bubbles, the sioh could have formed due to the warming and in the higher-lying part of the canal have risen to be carried away with the current. The PlieB direction of the medium is again indicated by arrows.

The channel system required in the absorption body is advantageous from the glass of the absorption body 3 and 4 from a tube 16 (Fig. 8, 9 and 10) start at a Side is closed and on the other side two thinner tubes 17, 18 as one and an outlet for the medium serving for heat dissipation. This pipe is on a Die 19 with protruding steel strips 20 (corresponding to the channel walls 10 in Fig. 3) placed, loaded with a plate 21, heated and then compressed, the protruding strips 20 press into the glass and the opposite ones Walls of the glass tube fuse together, resulting in the partition walls between the Channels are formed. To promote the bulging of the canals, one closes during the deformation process the pipe intermittently; in the end it is advantageous open so that the partition walls between the channels can be well formed. This The easiest way to achieve temporary closing is to use one of the two Feed pipes e.g. 17 close from the beginning, the other 18 in a fine capillary looks like. This capillary can be conveniently passed through by local heating Break open.

After this production of the glass part of the absorption body is the absorbent covering applied, including in particular a selectively absorbent Layer is used that absorbs solar radiation strongly, but infrared Little emitted radiation. The covering can be on the inside or outside of the absorption body be attached. It is advantageous to first apply the selective view to a film e.g. made of copper, to be applied and then this film to be applied to the absorption body, e.g. stick on. But it is also possible to apply the selective layer, e.g. as a paint, apply directly to the absorption body.

Another possibility is that as an absorbent in the cavity of the absorption body a thin, the inside width of the absorption body Largely adapted bleach that strongly absorbs solar radiation has been incorporated is that on its side facing away from the solar radiation with guides for the for heat dissipation serving medium (approximately in the manner of Fig. 3 or 5) is provided.

Then apply the absorbent covering to the absorbent body at least one support (e.g. 3.7 according to FIG. 2) is attached to the absorption body, around this body only fastened to the base at its free end on the outer hollow cylinder to be able to support. Then the absorption body is in the outer hollow cylinder pushed and fused to the base. The hollow cylinder, which was initially attached to a Side is open, the open side is finally requested, evacuated and melted down.

Claims (26)

Claims (1. Solar collector (device for the absorption of solar radiation), consisting of from an evacuated one closed at both ends or with a poorly thermally conductive one Gas-filled hollow cylinder and a hollow cylinder about the same length housed in the hollow cylinder the solar radiation absorbing hollow body (absorption body) by a for heat dissipation serving medium is flowed through, characterized in that the absorption body (5) accommodated in the hollow cylinder (1) as being flat, with Absorbent provided glass body is formed, the width (B) only is slightly smaller than the inner diameter (D) of the hollow cylinder (e.g. B = 4/5 D). 2. Sun collector according to claim 1, characterized in that that the absorbent is a solar heat absorbing covering (6) on the absorbent body (5) is attached. 3. Sun collector according to claim 2, characterized in that that the covering consists of a selective layer that largely absorbs solar radiation absorbs, but emits little infrared radiation. 4. Sun collector according to claim 2 or 3, characterized in that that the absorbent covering is attached to the outer wall of the absorbent body is. 5. Sun collector according to claim 2 or 3, characterized in that that the absorbent coating on the inner wall is good for infrared radiation permeable absorbent body is attached. 6. Sun collector according to claim 1, characterized in that that as an absorbent in the cavity of the absorbent body a thin, in its width largely adapted to the inside width of the absorption body, the Solar radiation strongly absorbing body is inserted, from which the heat discharging medium is flowed around. 7. Sun collector according to claim 6, characterized in that that the inserted into the cavity of the absorption body with guides is provided for the medium used to dissipate heat. 8. Sun collector according to claim 4, characterized in that that the selective layer is applied to a foil, for example made of copper, which in turn applied to the absorption body, e.g. glued on. 9. Sun collector according to claims 4 and 8, characterized in that that the absorption body is flat on its side facing the solar radiation is trained. 10. Sun collector according to claims 4 or 5, characterized in that that the selective layer, e.g. as a paint, directly on the absorption body is upset. 11. Sun collector according to claims 1 to 10, characterized in that that the hollow cylinder (1) and the absorption body (5) each through at one end a connecting body, also made of glass, similar to a base (4) are connected to each other. 12. Sun collector according to claim 11, characterized in that that the base (4) input and output openings (2, 3) for the heat dissipation has serving medium and can be inserted into a holder. 13. Sun collector according to claims 1 to 12, characterized in that that the hollow cylinder firmly connected to the absorption body about its longitudinal axis is designed to be pivotable, so that the solar radiation absorbing surface of the absorption body perpendicular to the direction of incidence of the solar radiation is adjustable. 14. Sun collector according to claims 1 to 13, characterized in that that the side of the absorption body facing away from solar radiation has a layer low heat radiation, e.g. a mirror coating. 15. Sun collector according to claims 1 to 13, characterized in that that on the side of the absorption body facing away from the solar radiation, a film low heat radiation, e.g. a reflective metal foil. 16. Sun collector according to claims 1 to 15, characterized in that that a channel system is provided under the covering of the absorption body in which the medium used to dissipate heat under as many places as possible of the solar heat absorbent coating can flow. 17. Sun collector according to claim 16, characterized in that that the channel system is formed from the glass of the absorbent body. 18. Sun collector according to claims 16 or 17, thereby characterized in that the medium used to dissipate heat is in the operating position of the collector's lower flank of the absorption body into the channel system is initiated. 19. Sun collector according to claim 18, characterized t, that the channel system is designed so that the cooler medium in the near The channels located at the edge of the absorption body flows. 20. Sun collector according to claims 16 or 17, thereby characterized in that in the channel system transversely to the flow direction of the heat dissipation serving medium transverse walls (14) are provided, which the flow essentially let through only in the upper part of the channel (Fig. 6). 21. A method for producing the absorption body according to claim 1, that one or more glass tubes are flattened will. 22. A method for producing the absorption body according to claim 21, characterized in that in the flattened tube (16) by a die (19) the walls to form the channel system are created (Fig. 8, 9, 10). 23. Absorbent body according to claim 21, characterized in that that the glass tube used to manufacture the absorption body is bent into a U-shape is. 24. Absorbent body according to claim 21, characterized in that that the glass tube used to manufacture the absorption body is a curved one Tube with more than one reciprocating section each. 25. Absorbent body according to claim 21, d a d u r c h g e k It is noted that the one used to manufacture the absorbent body Glass tube is closed at one end and at the other end in two thinner tubes empties. 26. The method according to claim 21, characterized in that one or more of the glass tubes used to manufacture the absorption body are completely closed at times during the deformation process. L e r s e i t e