WO2014122229A1 - Solar plant - Google Patents

Abstract

The invention relates to a solar plant (1) having at least one solar collector (2) which can be guided about at least one axis and which comprises a linear focusing optical element (3), in the focal line of which a receiver (10) is mounted. The receiver (10) comprises at least two sub-receivers (11, 11'), each having an elongate transparent hollow profile (12); the hollow profile (12) in each sub-receiver (11, 11') is mounted in a transparent protective tube (13), and the hollow profiles (12) and protective tubes (13) of each sub-receiver (11, 11') are hermetically joined to each other at both ends. The sub-receivers (11, 11') are also joined in such a way that the hollow profiles (12) are hermetically joined to each other to form a continuous interior (14), and for the hollow profile (12) and/or the protective tube (13) at least one length compensator (30) is provided, which is a solid body and is designed to compensate, by way of its own elasticity, for a difference in thermal expansion between the protective tube (13) and the hollow profile (12).

Description

 solar system

The invention relates to a solar system with at least ei ^¬ nem solar collector tracking at least one axis comprising a line-focusing optical Ele ^¬ ment, in the focal line, a receiver is arranged.

In the prior art solar collectors are known in which incident solar radiation using optical elements - such as, for example, elongated Fresnel lenses or parabolic troughs - are focused on a linear focus. Along the focal line thus generated, an absorber tube is then arranged, which is heated by the bundled solar radiation ^¬ . The heat energy thus obtained can be removed by a heat transfer fluid flowing through the absorber tube and used as useful energy.

The invention is based on the object, a solar system comprising at least one solar collector with a linear focusing optical element and a in the

Focus line arranged to provide receiver, which is improved over the prior art.

The problem is solved by a solar system according to the main claim. Advantageous developments are the subject of the dependent claims.

Accordingly, the invention relates to a solar plant with Wenig ^¬ lecturer least one trackable at least one axis Solarkol- comprising a linearly focusing optical Element in the focal line of a receiver is arranged, wherein the receiver comprises at least two partial receivers, each having an elongated transparent hollow profile, wherein the hollow profile of each Teilreceivers is arranged in a transparent cladding tube and the Hohlpro ^¬ fil and the cladding tube of each Teilreceivers in each case being hermetically sealed to one another at both ends, and wherein the partial receivers are connected to one another such that their hollow profiles are hermetically sealed to form a continuous inner space, and at least one length compensator is provided for the hollow profile and / or the cladding tube , which is a solid body and which is designed so that it compensated for a thermal expansion difference between cladding tube and hollow profile by its own elasticity.

By solid state is meant a force-transmitting structure consisting of a rigid material, such as metal or glass. Not covered by the term solids fall plastic structures, such as those gebil ^¬ det liquid from (tough) adhesive, silicone or similar plastic materials.

Since the hollow profile of a subreceiver is hermetically connected to the cladding tube of the same subreceiver and the subreceivers are also connected to one another, a transparent receiver is produced having a length combined with the length of the subreceiver and having a number adjacent to one another corresponding to the number of subreceivers Gaps between the ducts and hollow sections of the respective subreceiver. The interior of the entire receiver extends through the hollow profiles of all partial receivers. By the Intermediate spaces heat losses from the hollow profile of a partial receiver to the environment, in particular due to convection, can be reduced. Practically usable these advantages but only, as the invention has recognized, by a special device (the length compensator) to compensate for the different thermal expansion (meaning in particular the change in length, but may alternatively or additionally also refer to expansion in the radial direction) of cladding and hollow profile. Without such on the one hand good and safe and on the other hand robust and produced in a controlled manner balancing device would not allow permanent operation of the solar system. It is in the nature of things that the ther ^¬ mix under the load - is highly intense solar radiation, and, moreover, at least in the - desired se

 Day / night rhythm is present as an alternating load. This places great demands on the connection between the cladding tube and the hollow profile, so that it remains intact even under this high thermal cycling and an intrusion of undesirable foreign bodies and gases into the walls

Interspace prevents, so in short, remains tight. With known only plastic compounds (DE 20 2009 0150505 Ul), such as those using silicone adhesives, this is not permanently possible because of the diffusion of gas molecules through the compound.

Furthermore, length compensators designed as solid bodies have the advantage that, depending on the design, they can also compensate for quite large linear expansions. Especially if they are made of glass or metal, an excellent gas-tightness is an advantage. In addition, they are thermally stable for a long time even under strong Solar radiation. Advantageously, the length compensator is designed as a glass-metal connection.

Preferably, the length compensator is corrugated in a w-shaped manner, at least in one region, in particular as a bellows. It is preferably arranged on at least one end of the hollow profile, between cladding tube and hollow profile. It is, but can also be provided at both ends.

The interior of the entire receiver can be designed for the passage of heat transfer fluid, wherein the hollow sections of the partial receiver itself can form the passage for the heat transfer fluid. In the interior, as an alternative or in addition to a passage for heat transfer fluid, solar cells or other arrangements for converting solar radiation into usable energy can also be arranged.

It has been found that improvements are achieved by the connection according to the invention of the cladding tube and the hollow profile of each partial resonator as well as due to the inventive transparency of both the cladding tubes and the hollow profiles over the prior art. In particular, in the case of a solar installation according to the invention, only a slight loss of efficiency occurs compared with a system of the prior art. This is achieved on the one hand by the interspaces described above and the associated possible reduction of convective heat losses. A further improvement of the efficiency is achieved in that the inventive compound of transparent cladding with the transparent hollow sections of the subreceiver and the subreceiver with each other thanks to the length compensator to save space and at least partially can be made transparent, so that it comes only to ge ^¬ ringem extent to the efficiency-reducing shading of the hollow profile in said Verbindungsbe ^¬ rich.

The length of the receiver is given by the sum of the County ^¬ gen that part receiver. It is possible, according to the invention, to connect more than two subreceivers in order to achieve an arbitrary total receiver length. For reasons of clarity, however, the following statements refer to receivers with two sub-receivers. However, a limitation to such embodiments is not associated therewith. The material for the cladding tube preferably has a much ^higher coefficient of the thermal expansion coefficient than the material for the hollow profile. This is based on the Detects ^¬ nis that heats up during operation, the inner hollow profile much Staer ^¬ ker than the comparatively cool tubular permanent envelope. By a seemingly absurd choice of a higher coefficient of expansion, an approximation of the actual extent at the respective temperatures during operation is thus achieved. It is particularly expedient that the multiple be chosen so that at operating temperature, the difference of the amount thermal

Extension of cladding on the one hand and hollow profile on the other hand is minimized.

It is preferred if at least one clamping element is provided for the connection of two partial receivers, which is arranged on the egg ^¬ nander facing ends of the partial receiver and the partial receiver in the longitudinal direction against each other, preferably between the end faces of Teilreceiver. ver at least one sealing ring is arranged. This results in a higher load capacity and greater tightness than in a closure in the circumference of the cladding tube. Further, the part of the receiver may each have a flange at their facing ends at least, and the Wenig ^¬ least one clamping element engages the flanges and ver ^¬ spans the part of the receiver such that the at least one sealing ring seals the area between the part receivers hermetically, bringing then gives a hermetically sealed connection of the hollow sections of the partial receiver to form a continuous interior. The clamping elements may be metal clamps or clamping screws. The flanges may extend over the entire circumference of the partial receivers, or a plurality of flanges may be arranged distributed over the circumference of the partial receivers. By the clamping elements, a sufficient sealing effect over the entire circumference of the partial receiver can be achieved in both cases. It is particularly useful when the clamping element a

Clamp and a hoop comprises. Here, a de ^¬ En of the tension bow is mounted via a hinge on the clamping hoop pivotable so that a folding of the two receivers is allowed to each other. The other end of the clamping bracket is by means of a clamping strap against the clamping ^¬ ripe for clamping and can be locked in the cocked position. In this case, the tension of the partial receiver in the hinge is ensured by this itself. The effect of the clamping strap can be limited to the rest of the sub-receiver. Preferably, the hinge is made detachable and the clamping strap is separable. Thus, the two partial ceiver easily separated from each other or easily assembled.

Alternatively, it is possible for at least one sealing ring to be arranged between two partial receivers, the partial receivers each having a thread at the ends facing each other, and a connecting element having mating threads matching the threads of the partial receivers being provided, into which the two partial receivers are screwed are that the at least one sealing ring seals off the region between the two part receivers hermetically, wherein the connecting element from another Ma ^¬ TERIAL exists as part of the thread of the receiver. Preference ^¬ example, in a thread made of glass, the connection ^¬ element made of metal.

It is preferred if the connecting element between the mating threads, in which engage the threads of the Teilreceiver, a bellows or other elastic deformation region. A corresponding bellows or deformation region allows compensation for the thermal expansion of the partial receivers and / or other components of the solar system. It is also possible to provide a connecting element which hermetically rests against a first partial receiver and at a second partial receiver and thus connects the two partial receivers hermetically sealed together. The corresponding connecting element can be connected via press fit, bonding and / or fixation with pipe clamps hermetically sealed, each with a partial receiver. Preferably, the connecting element between the Be ^¬ rich, in which it is hermetically sealed to the Teilreceivern rests on a bellows or other elastic deformation area. A corresponding bellows or deformation region allows compensation for the thermal expansion of the partial receivers and / or other components of the solar system.

It is preferred if the at least one sealing ring flexi ^¬ bel, transparent and / or sun-resistant. Due to the flexibility of the at least one sealing ring and / or the connecting element stresses in the individual elements of the solar system, which could arise, for example due to thermal expansion, can be reduced. The solar resistance of the at least one sealing ring

and / or the connecting element allows a long life of the solar system according to the invention. The preferred transparency of the sealing ring and / or the connecting element reduces the heating of the connecting elements and the shading, which can reduce the efficiency. It is preferred if the at least one sealing ring is made of transparent silicone or transparent fluoropolymers. These materials are sun ^resistant materials. Due to its transparency, the efficiency loss in the area of the transition between two partial receivers can be further reduced.

Conveniently, the at least one sealing ring and / or the connecting element are provided at least on their radiating ^¬ facing side with a radiation protection. It is preferably designed as a mirrored or opaque covering. Thus, a protection of the material for the sealing ring or the connecting ^element before Strahlenbelas ^¬ tion, in particular against UV radiation, can be achieved. The gap between the hollow profile and the jacket tube of a Teilreceivers can be evacuated. As a result, a good thermal insulation of the hollow profile is achieved. In particular, in connection with a vacuum in the space between the hollow profile and cladding tube, but also in other embodiments ^¬ forms, it is preferred if the hollow profile and / or the cladding tube of a Teilreceivers is made of glass. A vacuum in said gap can be permanently preserved. In addition, glass is corrosion resistant to many substances and in particular many heat transfer fluids. It can also be provided that the gap is filled with inert gas. For this purpose, gas connections are preferably arranged at both ends of the cladding tube. They allow a simple and efficient flushing with inert gas, wherein flushing ^¬ losses are minimized.

It is also possible that the intermediate space between the hollow profile and the cladding tube of a partial receiver is at least partially filled with an airgel, wherein the aerosol is transparent to the hollow profiles at least in the region of the expected beam path of the solar radiation. Due to the pore structure of aerogels, the convection in said space, which leads to heat losses, reduced or almost completely avoided.

It is particularly preferred when the inner and Außenwan ^¬ compounds of the hollow profile and / or of the cladding tube are coated, with one or more of the following have coatings is:

The radiation-side surfaces with an anti-reflection layer to increase the transmission; the radiation facing away from the inner wall of the cladding tube with a reflective layer to capture radiation that has missed the tube and to reflect heat radiation from the heat transfer tube and / or

- The entire outer wall of the hollow profile with a coating, which reduces the heat radiation (low-e coating).

 The coatings thus increase the efficiency in terms of energy yield.

Preferably, it may further be provided to provide highly insulating aerogels with embedded IR opacifiers on the side of a receiver tube facing away from the radiation. While the aerogels minimize the back losses due to heat conduction and convection, the reflectors of the IR turbidity substances throw the heat radiation back onto the heat transfer tube. A storage of the aerogels between the cladding tube and the hollow profile has proven to be useful. In particular, in the cases in which a heat transfer fluid is di ^¬ rectly passed through the hollow sections of the partial receiver or through the continuous interior of the entire receiver, the heat transfer fluid is preferably a calcium chloride solution, the calcium chloride solution is preferably mixed with a dark absorber. If another heat transfer fluid is used, it can preferably be radiation-absorbing and / or mixed with a dark absorber.

It is preferable if the solar array a Stirling Mo- tor, an Organic Rankine Cycle (ORC) system or a thermal refrigerating machine comprises which is operated with the receiver, he ^¬ wärmtem heat carrier fluid. The solar collector of the solar system is preferably uniaxial (in terms of elevation) or biaxial (in terms of elevation and azimuth) of the sun trackable.

This ensures that the receiver is in the focus line of the line-shaped focusing optical element during the course of the day.

If a solar system has two solar panels or more and these are out for heating of heat transfer fluid, the receiver of the individual solar collectors may preferably parallel - eg. With a Tichelmann circuit - be connected. As a result, a more uniform temperature of the heat transfer fluid can be achieved.

The invention will now be described by way of exemplary embodiments with reference to the accompanying drawings by way of example. Show it:

1 shows a first embodiment of a solar system according to the invention;

FIG. 2 shows a detail section of the receiver of the solar system from FIG. 1 in a first embodiment variant; FIG. 3 shows a detail section of the receiver of the solar system from FIG. 1 in a second embodiment variant;

Figure 4 is a detail section of the receiver of the solar system of Figure 1 in a third embodiment;

Figure 5 is a detail section of the receiver of the solar system of Figure 1 in a fourth embodiment; FIG. 6 shows a detail section of an alternative connection of the partial receivers;

Figure 7 is a detail section to the junction between see two Teilreceivern and their protection; and

Figure 8 shows a cross section through cladding tube and hollow profile of a Teilreceivers. 1 shows a solar plant 1 of the invention is Darge ^¬ provides. The solar system 1 comprises a collector unit 2 with a line-focusing element 3 and an elongated receiver 10. The receiver 10 is arranged along the focal line of the linear focusing element 3 and is held there by means of support arms 4. The linear focusing element 3 is a semi-paraboloidal mirror groove.

In the illustrated embodiment, the receiver 10 is designed for the passage of heat transfer fluid. The supply and discharge lines for the heat transfer fluid to and from the Re ^¬ ceiver 10 are not shown for reasons of clarity. The collector unit 2, comprising the line-shaped focusing element 3 and the receiver 10, is around one

Swivel axis 5 pivotally mounted, wherein the pivot axis 5 along one edge of the linear focusing element 3 extends. Via a drive element 6, the collector unit 2 can be pivoted about the pivot axis 5. The collector unit 2 can thus be tracked in terms of elevation the state of the sun. The collector unit 2 is further arranged on a slewing gear 7. By means of this slewing gear 7, the collector unit 2 can be about an axis 8 perpendicular to the

Turn swivel axle 5 of collector unit 2. By pivoting the collector unit 2 on the one hand and the Dre ^¬ hen the same about the axis of rotation 8 of the slewing 7 other ^¬ a two-axis tracking is achieved, namely with regard to the elevation and the azimuth. The receiver 10 of the solar system 1 of Figure 1 comprises part ^¬ receiver 11, 11 ^λ . The partial receivers 11, 11 ^λ each have an elongated transparent hollow profile 12. The hollow section 12 of a partial receiver 11, 11 ^λ is in each case arranged in a transparent cladding tube 13, wherein the hollow profile 12 and the cladding tube 13 of a partial receiver 11, 11 ^{λ are} each hermetically sealed to each other at both ends. The two partial receivers 11, 11 ^λ are in turn connected to each other such that the hollow sections 12 of the two partial receivers 11, 11 ^λ are hermetically sealed together to form a continuous interior 14. The interior 14 of the receiver 10 thus extends through the hollow sections 12 of all partial receivers 11, 11 ^λ .

The receiver 10 has one of the length of the part of receiver 11, 11 ^λ total combined length, wherein along the Ge ^¬ total length to the number of part of receiver 11, 11 ^λ corresponding number of adjacent spaces 14 ^λ between the cladding tubes 12 and hollow sections 13 of the respective part of the receiver 11 , 11 ^{λ is} present.

The cladding tubes 12 and hollow sections 13 of the partial receivers 11, 11 ^λ are each made of glass. To the inventive sealing ^¬ seal at the respective ends of a Teilreceivers 11, 11 to reach ^λ , the cladding tubes 12 and hollow sections 13 are fused together in these areas.

The connection of the two partial receivers 11, 11 ^λ of Figure 1 will now be explained in more detail with reference to the embodiments in Figures 2 to 5. The figures mentioned show a

Sectional view of the connection area of the two Teilre ^¬ ceiver 11, 11 ^λ of the receiver 10 of Figure 1. The connection variants nachfol ^¬ quietly explained for the part receivers 11, 11 ^λ can thereby be combined with the following be ^¬ signed embodiments of the spaces 14 ^λ.

FIG. 2 shows a first embodiment variant of the connection region between the two partial receivers 11, 11 ^{λ of} the receiver 10 from FIG. 1 in section.

As seen from Figure 2, the hollow section 12 and the cladding tube 13 of the receiver part 11, 11 ^λ of the hermetically sealed together in the figure, the end of each 2 are shown. A corresponding compound of Hohlprofi ^¬ le 12 and sheaths 13 is also provided at the ends of the subreceiver 11, 11 ^λ , not shown. The two partial receivers 11, 11 ^λ each have flanges 16 at their ends facing each other. On these flanges 16 clamping elements 17 engage in the form of clamps made of spring steel and clamp the part of receiver 11, 11 ^λ such that the ^λ between the sub-receivers 11, 11 angeordne- te sealing ring 15, the two part receivers 11, 11 ^λ relative to the environment so hermetically seals, a continuous interior 14 through both partial receivers 11, 11 ^λ and thus the receiver 10 is formed. In the embodiment in Figure 2, the gap 14 is ^λ between the hollow section 12 and the cladding tube 13 of each Teilreceivers 11, 11 ^λ evacuated. By a vacuum in these spaces 14 ^λ a good thermal insulation of the hollow sections 12 is achieved. But it can also be provided a filling with inert gas. For this purpose expediently Gasan ^¬ circuits 32 are provided at both ends of the receiver 10 so as to allow effective rinsing.

In the embodiment in Figure 3 is between the two part receivers 11, 11 provided ^λ a hinge 18, a folding down of the two receivers 11, 11 ^λ to one another allows, for example for transport. Over the remaining periphery of the receiver part 11, 11 respectively ^λ flanges 16 are provided at the ends facing each other, where - as in the embodiment variant according to FIG 2 - the clamping elements 17 engage. Between the sub-receivers 11, 11 ^λ, a sealing ring 15 is arranged so that when the hollow sections Verspannun- gene by the clamping elements 17 12 are connected to Bil ^¬ dung a continuous internal space 14 is hermetically sealed to each other.

As with the embodiment of Figure 2 the intermediate are the spaces between 14 ^λ evacuated.

In the embodiment according to Figure 4, the Teilre ^¬ ceiver 11, 11 ^λ at the mutually facing ends of each thread 19. In each case, connecting elements 20 engage with corresponding counter-threads 21 in these threads 19.

The two part receivers 11, 11 ^λ can be connected in such a manner using the connecting element 20 that the interim rule ^¬ the two part receivers 11, 11 arranged sealing ^λ ring 15 hermetically seals the continuous interior 14 from the environment.

The connecting element 20 for the two partial receivers 11, 11 ^λ has a bellows 22 between the mating threads 21, with which the connecting element 20 engages the threads 19 on the Teilreceivern 11, 11 ^λ . With this Fal ^¬ tenbalg 22 thermal expansion of the two part receiver 11 can be compensated ^λ 11.

The intermediate space 14 ^λ between the cladding tubes 13 and hollow sections 12 of the partial receivers 11, 11 ^λ is filled in the embodiment of Figure 4 with an airgel 30, which is transparent to the hollow section 12 at least in the region of the expected beam path of the sun's rays.

Due to the airgel 30, heat losses due to convection in the intermediate spaces 14 ^{λ can be} reduced.

In the embodiment in Figure 5, the two partial receivers 11, 11 ^λ mitei ^¬ each other mitei ^¬ connected via a connecting element 20, which hermetically sealingly abuts the two Teilreceivern 11, 11 ^λ . For this purpose, the Verbindungsele ^¬ element 20 is glued to the one part receiver 11 ^λ while it is pressed by means of a pipe clamp 24 hermetically sealed to the other Teilreceiver 11. The connection ^¬ element 20 also includes the area between the end faces of the part receiver 11 11 ^λ a deformation area 23, ^λ can be compensated with the different thermal expansions of the Teilre ^¬ ceiver 11,. 11 The deformation portion 23 is characterized by recesses in the connecting element 20, allow an elastic deformation of the Verbin ^¬-making element 20 in precisely this area. In the embodiment in Figure 6 is similar to the embodiment according to FIG 3 between the two part receivers 11, 11 provided ^λ a hinge. Similar parts are provided with the same reference numerals, and it is to that extent for further explanation on the above statements to Fig. 3 referenced. The clamping element is in this embodiment in the manner of a clip closure ^¬ forms and comprises a clamping bracket 26 which is fixedly arranged at the end of a Teilreceivers 11, and a

Tensioning 27, which is arranged at the facing end of the other Teilreceivers 11 '. The in Fig. 6 upper ends of clamping bracket 26 and clamping ring 27 are formed as a hinge 28. The hinge 28 is detachable, in which the hook-shaped executed upper end of the tension bracket is unhooked from the upper region of the tensioning rim 27. Thanks to the hinge 28 of a partial receiver 11 can be folded from the other Teilreceiver 11 ', and if necessary even by Unhook the hinge and remove it.

At the other, in the representation lower end of clamping bracket 26 and clamping ring 27 a clamping strap 29 is ausgebil ^¬ det. It has an actuating handle 29 'with which, by moving in the direction of the arrow shown, the clamping lug 29 engages the lower end of the tensioning bow 26 against the

Spannreif 27 pulls and finally locked (the Verrie ^¬ gelung can be done in a very simple manner by moving the operating handle 29 'beyond a dead center - an independent provision is blocked with it).

On the front side of the subreceiver 11, 11 'is in each case a compensator 30 between the cladding tube 13 and hollow section 12 is arranged. With his W-shaped bellows area 26 he is despite radial arrangement capable, even in the axial direction acting changes in length, in particular by different ^¬ cal thermal expansion of cladding tube 13 and hollow section 12, record. The sealing ring 15 is not executed as in Figure 3 as an O-ring, but as an X-ring. This offers the advantage that its surfaces facing the end faces of the partial receivers 11, 11 'have recesses which provide sufficient space for accommodating the bellows region 31 of the compensator 30.

In the embodiment shown in Figure 7, the connecting element 20 is designed as a bond. It surrounds the sealing ring 15, which is arranged between the end faces of the partial receivers 11, 11 'as described in the preceding embodiment variants. To protect the bond and / or the sealing ring 15 is a curved over the connecting element arching radiation protection 25 is provided. It is mirrored or made of opaque material. In both cases, harmful effects of solar radiation are prevented.

Furthermore, the partial receiver 11 'has a length compensator 30 at its end shown in FIG. It is made of metal material and has a sleeve-like basic shape. In its central region 31, it is W-shaped. He thus additionally has a shape-related elasticity, since the W-shaped shape acts like a bellows bellows ^¬ and thus allows a length compensation. Fer ^¬ ner can be adjusted by the bellows portion 31, a bias, so that the hollow section 12 is always supported without play in the cladding tube 13. The intermediate space 14 ^λ between the hollow section 12 and the cladding tube 13 of each Teilreceivers 11, 11 ^λ is filled with inert gas. In the above embodiments, the Teilre- ceiver 11, 11 gefer ^¬ Untitled ^λ completely transparent and made of glass. The heat transfer fluid can be passed directly through the hollow sections 12 of the part receivers 11, 11 ^λ or through the continuous interior 14 of the total receiver 10. So that in this case the incident on the receiver 10 solar radiation can be absorbed, the heat transfer fluid is radiation absorbing or at least offset with absorber materials. Basically, a calcium chloride solution which is preferably mixed with dark absorber substances is preferred as heat carrier fluid.

In Figure 8, various coatings for the Teilre ^¬ ceiver 11, 11 'are shown. It can be seen the structure with cladding tube 13 outside and hollow profile 12 inside. There are at eye STATEMENTS- as both inner wall of the casing tube 13 as well as the hollow profile 12 are each made an anti-reflection coating 33 on ^¬. It can be completely circumferential or only partially applied. On the outer wall of the hollow profile 12, a low-E coating 34 is further applied to reduce heat radiation. At the radiation-remote inner wall of the cladding tube 13, a reflective coating 36 is also applied, which serves to Rückwer ^¬ fen of leakage radiation.

Claims

 claims

Solar installation (1) with at least one trackable at least ei ^¬ ne axis solar collector (2) comprising a linearly focusing optical element (3), in the focal line, a receiver (10) is arranged, characterized in that

the receiver (10) at least two part receivers (11, ^λ 11), each having an elongated trans ^¬ parentes hollow profile (12), said hollow section ^¬ fil (12) of each part receiver (11, 11 ^λ) in a trans ^¬ Parenten cladding tube (13) is arranged and the Hohlpro ^¬ fil (12) and the cladding tube (13) of each Teilreceivers

(11, 11 ^λ ) are each hermetically sealed together at both ends, and wherein the Teilreceiver

(11, 11 ^λ ) are connected to one another in such a way that their hollow profiles (12) are hermetically sealed to form a continuous inner space (14), at least one length compensator (30) for the hollow profile (12) and / or the cladding tube (12). is pre see 13) ^¬, which is a solid and is formed so that it (a thermal expansion difference between the envelope tube (13) and the hollow section 12) is compensated by its own elasticity.

Solar system according to claim 1,

 characterized in that

 the length compensator (30) is corrugated in a w-shaped manner at least in one region, preferably in the form of a bellows (31).

3. Solar system according to claim 1 or 2,

characterized in that the material of the cladding tube (13) has a multiple of the thermal expansion coefficient as the material for the hollow profile (12), wherein preferably the multiple is selected so that at operating temperature the difference in the absolute value of thermal

Expansion is minimized.

Solar installation according to one of the preceding claims, characterized in that

for connecting two partial receivers (11, 11 ^λ ) at least one clamping element (17) is provided, which at the mutually facing ends of the Teilreceiver (11, 11 ^λ ) is arranged and clamped in the longitudinal direction against each other, preferably a sealing ring (15) between the end faces of the two partial receivers (11, 11 ^λ ) is arranged.

Solar system according to claim 4,

 characterized in that

the part receiver (11, 11 ^λ) each have at least one flange at the mutually facing ends (16), and the at least one clamping element (17) engages the Flan ^¬ rule (16) and the part receiver (11, 11 ^λ) such braced in that the at least one sealing ring (15) hermetically seals the area between the two partial receivers (11, 11 ^λ ).

6. Solar system according to claim 4 or 5,

 characterized in that

 the tensioning element (17) on the two partial receivers (11,

11 ^λ ) comprises a clamping ring (27) and a clamping bracket (26), wherein one end of the clamping bracket (26) via a hinge (28) on the clamping ring (27) pivotally is mounted so that a folding down of the two sub-receivers (11, 11 ^λ ) is allowed to each other, and the other end of the tensioning bow (26) by means of a clamping ^¬ tab (29) against the clamping ring (27) pulling and locking is gelbar.

7. Solar system according to claim 6,

 characterized in that

 the hinge (28) is made detachable and the

 Clamping tab (29) is separable.

Solar system according to claim 1,

 characterized in that

between the part receivers (11, 11 ^λ) at the end faces of at least one sealing ring (15) is arranged, the part receiver (11, 11 ^λ) at the ends facing each other each having a thread (19) and Wenig ^¬ least one connecting element (20) is provided with the threads (19) of the part receiver (11, 11 ^λ) matching mating threads (21), in which the two part receivers (11, 11 ^λ) are screwed such that the at least one sealing ring (15) the region between the two part receivers (11, 11 ^λ) hermetically seals, wherein the connecting element (20) consisting of a resistors ^¬ ren material than the thread (19) of the Teilre ^¬ ceiver (11, 11 ') _/ preferably of metal with a thread made of glass.

9. Solar system according to claim 8,

 characterized in that

the connecting element (20) between the mating threads (21) has a bellows (22) or another elastic having a deformation area.

Solar system according to one of claims 1 to 7,

 characterized in that

a connecting element (20) is provided, which hermetically rests against a first partial receiver (11) and at a second partial receiver (11 ^λ ), and hermetically connects the two partial receivers (11, 11 ^λ ) to each other.

Solar system according to claim 10,

 characterized in that

the connecting element (20) via interference fit, reduct ^¬ advertising and / or fixing with clamps, each having a hermetically sealed part receiver (11, 11 ^λ) is the verbun ^¬.

12. Solar system according to claim 10 or 11,

 characterized in that

the connecting element (20) between the areas in which it is hermetically sealed against the Teilreceivern (11, 11 ^λ ), a bellows or other deformation region (23). 13. Solar system according to one of claims 2 to 12,

 characterized in that

 the at least one sealing ring (15) and / or the connecting element (20) is flexible, transparent and / or solar resistant, preferably made of transparent silicone or transparent fluoropolymers.

Solar installation according to one of claims 4 to 13, characterized in that are provided at least one sealing ring (15) and / or the connecting element (20) at least on the radiating face towards ^¬ th page with an anti-irradiation (25) which is preferably designed as a mirror or OPA ke covering.

15. Solar system according to one of the preceding claims, characterized in that

the intermediate space (14 ^λ ) between the hollow profile (12) and the cladding tube (13) of a Teilreceivers (11, 11 ^λ ) is evacuated and / or filled with inert gas, where ^¬ at preferably provided at both ends gas connections (32) for rinsing are more preferably, the intermediate space (14 ') between the hollow profile (12) and the cladding tube (13) of a Teilreceivers (11, 11 ^λ ) at least partially filled with an airgel (30).

Solar installation according to one of the preceding claims, characterized in that

 one or more of the following coatings are provided:

 - Antireflection coating (33) on the inner and / or outer wall of the hollow profile (12) and / or the cladding tube (13);

 - A coating of low emissivity (34) (low-e coating) on an outer wall of the hollow profile

(12); and or

 a reflective coating (36) on a region of the inner wall of the cladding tube (13) facing away from the radiation.