ES2393742A1 - Thermal solar collector - Google Patents

Abstract

The invention relates to a solar collector (11) including a first set of parallel pipes (13), in which a first end of the set of pipes of the collector is connected to an inlet distributor (12) and a second end of the first set of pipes (13) of the collector is connected to an outlet distributor (14), both of which are transverse to the pipes (31), such that the inlet distributor (12) supplies a fluid to the first set of parallel pipes (13) and said fluid is discharged to the outlet distributor (14).

Description

Solar thermal collector

OBJECT OF THE INVENTION

[0001] The present invention relates, in general, to a thermal solar collector of thermal radiation collection safely for the structure itself.

STATE OF THE TECHNIQUE

[0002] A solar collector comprises a set of conduits through which a fluid circulates that will receive part of the solar thermal energy that affects the collector. The fluid circulates from an inlet distributor to another outlet distributor. The collector also contains other elements that favor the capture of solar thermal energy and the thermal exchange between these surfaces and the fluid.

[0003] The conduits through which the fluid circulates in the collector are normally made of metal, such as copper

or similar, good thermal conductor, so that the thermal energy collected in the collection elements can be easily transferred to the fluid that circulates inside, since in them the solar radiation affects surfaces outside the receiving fluid. This makes the panel result in a high weight and, consequently, its handling during assembly is complex.

[0004] Also, it is normal for the collectors to incorporate a glass cover that allows the passage of solar thermal energy, in addition to protecting against external actions to the set of ducts and the collector system, it also allows reducing the losses of the thermal energy captured .

[0005] Consequently, the incorporation of the glass cover, also, makes the collector result in a high weight and, consequently, the handling thereof during assembly is complex.

[0006] It is known in the state of the art that the temperature that is reached inside the solar thermal collection must be limited to avoid its destruction when the demand for sanitary hot water is reduced or zero for long periods of time. The aforementioned situation occurs during the summer in some regions of the earth.

[0007] Generally, some type of system to limit the maximum operating temperature of the circulating fluid is included within the solar thermal collector.

CHARACTERIZATION OF THE INVENTION

[0008] The present invention seeks to solve or reduce one or more of the drawbacks set forth above by means of a solar thermal collector as claimed in claim 1. Embodiments of the invention are set forth in the dependent claims.

[0009] An object of the invention is to incorporate into a solar thermal collector that includes a set of conduits transparent to the incident radiation so that it reaches the interior thereof thus improving the transmission to the fluid of the corresponding thermal energy.

[0010] Another object of the invention is to limit the temperature of the circulating fluid inside the solar thermal collector to extend the useful life of the solar thermal energy installation, reduce the risk of failure of any of its components and materials of the solar energy system .

[0011] Still another object of the invention is to provide a solar thermal collector element with a large active surface for exchanging thermal energy radiated by the sun and the fluid flowing inside the ducts of the solar thermal collector.

[0012] Another object of the invention is to provide a solar thermal collector element of reduced weight.

[0013] Still another object of the invention is to provide a solar thermal collector element with a temperature limiting module that is reached within it simple and economical manufacturing, so that the whole solar thermal collector is also of Simple and economical

[0014] Another object of the invention is to provide a collector element of simple installation and, therefore, of reduced cost.

[0015] Still another object of the invention is to increase the performance of the solar thermal collector element.

BRIEF STATEMENT OF THE FIGURES

[0016] A more detailed explanation of the invention is given in the following description and based on the attached figures:

[0017] Figure 1 shows in an elevation section a solar thermal collector element according to the invention,

[0018] Figure 2 shows in an elevation section a first set of ducts according to the invention,

[0019] Figure 3 shows a set of suspended particles in the fluid circulating through the first set of ducts according to the invention,

[0020] Figure 4 shows in an elevation section another embodiment of the solar thermal collector element according to the invention,

[0021] Figure 5 shows in a raised section a new embodiment of the solar thermal collector element according to the invention,

[0022] Figure 6 shows in elevation the installation, in unfolded mode, of two sections of adjacent sheets of the absorbent material according to the invention,

[0023] Figure 7 shows in a plan view two adjacent grooved sections of sheet according to the invention,

[0024] Figure 8 shows an installation of an insulating material according to the invention,

[0025] Figure 9 shows the inclusion of an inlet and an outlet tank within the body of the solar thermal collector according to the invention, and

[0026] Figure 10 shows an embodiment according to the invention.

DESCRIPTION OF THE INVENTION

[0027] Next, with reference to Figure 1, a solar collector element (11) comprising a first set of parallel ducts (13) is illustrated.

[0028] A first end of the first set (13) of manifold ducts (11) is connected to a distributor (12) transverse inlet thereto and a second end of the first set of ducts (13) of the manifold (11) is connected to an outlet distributor (14), also, transverse thereto, so that the inlet distributor (12) supplies a fluid to circulate inside the first (13) set of parallel ducts, being evacuated to the distributor (14) output.

[0029] In relation now to Figure 2, the first set (13) of ducts is delimited by a first panel (21), front panel, of solar radiation transparent material and a second panel (22), rear panel, both front (21) and rear (22) panels being separated by a first set of partitions (23).

[0030] Each conduit (13) delimited by the first front panel (21), the first rear panel (22) and the first partitions (23) is hermetic to avoid losses of the fluid radiated by the solar radiation flowing through each conduit ( 13). In summary, the solar collector (11) can be configured as a first reticular profile comprising the first (13) set of ducts or first row of ducts.

[0031] It should be noted that both the first (21) panel and the second (22) panel and the partitions (23) that separate both panels (21), (22) can be made of the same radiation-transparent material solar or they can be of different material, not having to be the partitions (23) and the second (22) panel, which forms the bottom of the first ducts (13), of the same material as the first (21) panel, by For example, the partitions (23) and the second (22) panel do not have to be made of a material transparent to solar radiation.

[0032] For example, the material used for the realization of both panels (21), (22) and partitions (23) defining the first (13) set of ducts can be a plastic material such as polycarbonate, or the first

(twenty-one)

 front panel can be made of a radiation-transparent plastic material and partitions (23) and the second

(22)

 panel can be made with a material not transparent to solar radiation.

[0033] For example, in the case of using polycarbonate, it would have an environment thickness equal to or greater than 1.8 mm to withstand the thermal stresses, stagnation temperature of 120 ° C, and mechanical ones to which the collector could be subjected (11 ).

[0034] In any case, the collector (11) will be constructed with lightweight materials to generate a lightweight solar collector element (11) and said materials do not have to be thermally good thermal conductive materials, while the function of the The same is not to transmit the captured solar radiation through conduction through its walls and transmit it to the circulating fluid through the first set of conduits (13).

[0035] For example, in relation now to Figure 8, the manufacture of the manifold (11) could include longitudinal cellular profiles to house a thermal insulation material (81), (82) and a back panel. A base panel may incorporate a material to provide at least UVA protection on the outer face thereof.

[0036] The rear panel provides rigidity to the solar collector assembly (11), in turn, can support the rear thermal insulation.

[0037] The rear panel should be the same length as the base panel and its width may be somewhat smaller than that of the base panel. Both panels are jointly joined, for example, via a resin cord, projected polyurethane foam, etc., which provides protection against solids and liquid tightness, minimum IP 64.

[0038] The plates are joined at the edges, both of the base panel and the back panel, by ultrasonic welding or by friction, for example.

[0039] Each closure assembly, one for the lower edge and one for the upper edge, comprises a plate and a cover. The closure assembly can be coated by a thermal insulating material such as projected polyurethane foam, etc.

[0040] The cross section of each conduit (13) can be rectangular, circular or similar.

[0041] In relation to Figure 3, as mentioned above, solar radiation passes through the first (21) front panel being trapped / absorbed by an absorbent material (51) in the form of appropriate particles that are suspended within the circulating fluid, said particles being immiscible in the circulating liquid, made of a material of density substantially greater than the density of the circulating liquid, of suitable geometry such as spherical, for example, to facilitate the circulating liquid moving and / or dragging them the inside of the solar collector.

[0042] Said absorbent material (51) in the form of particles can be generated by fractionating a solid material, for example, black plastic material, such as black polyester tape, propylene; a metal such as black anodized aluminum, copper with black coating; black glass or similar. The material used has the physical characteristic that its coefficient of absorption of solar radiation is high, as well as that its coefficient of thermal transmission is also high. To generate a correct substantially homogeneous distribution of said absorbent material (51) in the form of particles inside the set of ducts (13) that connect the inlet (12) and outlet (14) manifold distributors (11), the particles they have a spherical predetermined shape, for example, and the amount of absorbent material (51) in the form of particles (51) that are displaced by the circulating fluid is a function of the desired thermal efficiency.

[0043] Once the received solar radiation is absorbed by the absorbent material (51) in the form of suspended particles, it is transmitted to the fluid surrounding them by convection and conduction, so that the fluid, for example, water , an antifreeze or similar solution is heated.

[0044] Therefore, the reticular solar collector (11) is manufactured with a material / s whose thermal insulation coefficient is high based on the desired target performance.

[0045] In relation to Figure 4 now, in order to increase the thermal insulation of the solar collector (11) and, consequently, decrease the conduction and convection losses, a third panel is added by the outer face of the first front panel (21) (31) transparent to solar radiation, hermetically joined by a few second partitions (32) to the first front panel (21), analogously defining a second multilayer or sandwich reticular panel.

[0046] Therefore, between the first front panel (21), the third front panel (31) and the second partitions (32) a second set of conduits (33) are defined parallel and superimposed on the first set of conduits

(13) through which circulating fluid flows.

[0047] To increase the thermal insulation provided by said second set of ducts (33), a vacuum of a predetermined degree is carried out in each of them, that is, the air is extracted therefrom.

[0048] Obviously, it should be noted that the first set of ducts (13) and the second set of ducts (33) need not have the same number of ducts. And, in addition, the first panel (21), the third panel (31), the first set of partitions (23) and the second set of partitions (33) can be made of the same material, for example, from a material that can be extruded configured as a reticular profile.

[0049] Likewise, a layer of thermal insulating material can be installed on the outer front face of the second panel (31) to avoid conduction and convection losses, not shown in Figure 4.

[0050] According to Figure 5, similarly, in order to avoid conduction and convection losses through the rear exterior face of the second panel (22) another fourth panel (41), not necessarily transparent to solar radiation, can be installed, tightly connected by means of third partitions (42) to the second rear panel (22), defining a third multilayer or sandwich reticular panel.

[0051] Therefore, between the second rear panel (22), the fourth panel (41) and the third partitions (42) a third set of ducts (43) parallel to the first set of ducts (13) is defined.

[0052] In order to increase the thermal insulation provided by said third set of ducts (43), it is possible to choose to maintain these with air or other gas, as an air chamber or in each of them a vacuum of a predetermined degree, it is say, the air is extracted from them.

[0053] Obviously, it should be noted that the first set of ducts (13) and the second set of ducts (33) and the third set of ducts (43) do not have to have the same number of ducts, being parallel and overlapping . And, in addition, the set of all panels and partitions can be made with the same material, for example, from a material that can be extruded configured as a reticular profile.

[0054] Also, in order to avoid radiation losses from the first set of ducts (13), the fourth set of ducts (33), a fourth set of transparent ducts as a whole and of similar characteristics to the previous one, in the that each duct is sealed containing inside a gas that increases the greenhouse effect of the previous set (33), not shown in the figures.

[0055] Obviously, it should be noted that the first set of ducts (13), the second set of ducts (33), the third set of ducts (43) and the fourth set of ducts need not have the same number of ducts And, in addition, the set of all panels and partitions can be made with the same material, for example, from a material that can be extruded configured as a reticular profile.

[0056] In another embodiment, said radiation absorbing material (51) may not be divided into particles, being a continuous sheet, for example, a natural or synthetic textile material absorbing solar radiation such as a silk ribbon. Said absorbent material (51) in the form of sheets is introduced into each of the ducts (13) of the first set according to the direction of the longitudinal axis of the duct (13) with a predetermined thickness and a predetermined cross section that provides a surface of reception of high solar radiation and high heat exchange with the circulating fluid that contours said sheet, not shown in the figures.

[0057] In another embodiment, the absorbent material (51) in the form of radiation absorbing sheets may be deposited on a face of the second panel (22), which forms the bottom of the first set of ducts (13), and partially or totally on the partitions (23) thereof.

[0058] In this case, the heat receptor fluid bathes the faces of the absorbent material (51) in the form of radiation-absorbing sheets that are not in contact with the second panel (22) and the partitions (23), receiving the thermal radiation of the absorbent material (51) in the form of radiation absorbing sheets.

[0059] In another embodiment, the walls (23) and the panel (22) are made of materials, colors and surface finishes absorbing solar radiation.

[0060] In this case, the heat receiving fluid bathes the inner faces of the ducts receiving heat from the thermal radiation absorbed by them from the partitions (23) and the bottom panel (22).

[0061] In another embodiment, in the second panel (22), it has a predetermined thickness, so that a series of continuous and parallel emptyings can be defined, so that, once the first panel (21) is installed on the second panel (22) and tightly joined, the set of conduits through which the fluid flows is defined. In summary, the second panel (22) integrates the first set of partitions (23) into a single piece.

[0062] In relation to Figure 6, when the consumption of hot sanitary water is reduced or zero, the water stored in the solar thermal collector (11) can reach a high and dangerous temperature for the solar installation itself.

[0063] During the aforementioned periods in which the consumption is reduced and to limit the temperature of the water stored therein, an extension module (61) of the absorbent material (51) of the sheet, tape or similar type has been arranged.

[0064] The extender module or drag head of a section of absorbent material (51) in the form of sheets of said upper absorbent material to a consecutive lower section, where the absorbent material

(51) in the form of a sheet (51) could have some type of insert so that said assembly has an average density greater than that of the fluid such as water contained in the solar collector (11).

[0065] While there is a demand for hot sanitary water, the fluid contained in the solar collector (11) circulates from the lower tank (12) to the upper tank (14) via the ducts (13).

[0066] The fluid returns to the inlet tank (12) from the outlet tank (14) via a return duct, when it has transferred its caloric power to the sanitary water via a heat exchanger, for example, arranged for that purpose.

[0067] In the aforementioned mode of operation, the extender (62) placed at a distal end of a second section of absorbent material (51) in sheet form (51), that is, at the end of the sheet (51) of the Absorbent material closest to the outlet tank (14) is physically connected to an extender (62) such as a device that, due to its physical construction, can be dragged by the circulating fluid, namely a float.

[0068] Consequently, when there is no demand for hot sanitary water or consumption is reduced, the absorbent material (51) in the form of a sheet (51) is in a fully or partially retracted position because it is folded on itself. That is, the absorbent material (51) in sheet form (51) has a length less than the total length of a duct (13).

[0069] That is, the absorbent material (51) in sheet form (51) comprises at least a first and second section of sheet (51) of the absorbent material mechanically crimped so that in extended mode, the sum of the lengths of each sheet section adds approximately the total length of the duct (13), in extended mode.

[0070] The absorbent material (51) in sheet form (51) comprises several sections, at least two, so that the length of sheet (51) of the absorbing material that absorbs radiation is a function of the volume of flow flowing through the conduit (13).

[0071] The proximal end of the sheet (51), closest to the lower reservoir (12), is mechanically fixed at the beginning of the duct (13), so as not to occlude the inner diameter of the duct (13), that is, the mechanical joint (61) that holds the proximal end at the beginning of the duct (13) to prevent it from being displaced, however, allows the passage of the liquid flowing through it.

[0072] Also, the float (62) placed at the distal end of the sheet-shaped absorbent material (51) allows the circulation of the liquid contained in the solar collector (11).

[0073] It is to be understood that the arrangement of the different parts into which the sheet (51) of the absorbent material and the fixing mechanism (61) which fix the lower end of the sheet (51) of the absorbent material as the mechanism is divided (62) extendable slide that moves or retracts together with the upper end of the sheet along the duct (13) are assembled and positioned in such a way as to prevent their entry (51), (61), ( 62) at the entrance depot (12) and / or at the exit depot (14).

[0074] The mechanical joining of two sections of sheet (51) of the absorbent material can be carried out, for example, by bending on itself the upper end of a first section of sheet (51) of the lower absorbent material to the lower end of a second sheet section (51) of the upper absorbent material consecutive to the first sheet section (51). That is, the upper end of a lower section can be folded

or curved, presented a "J" type shape, towards the inner bottom face of the duct (13) and the lower end of the adjacent section can be folded or curved, presented a "J" shape, toward the inner top side of the duct ( 13) in such a way that when the float (62) is displaced by the circulating liquid, both "J" bent parts will come into physical contact by the curved part thereof.

[0075] It should be noted that the higher the consumption of hot sanitary water the more quickly the ends of several sections of sheet come into contact (51).

[0076] In relation now to Figure 7, another way of making a sliding mechanical joint between two sections of sheet (51) of the adjacent absorbent material can be performed in the center of each section of sheet

(51) of the absorbent material a longitudinal longitudinal channel (71) or narrow longitudinal groove, section of sheet (51) of the corrugated absorbent material, installing a through piece (72), by the grooves of two adjacent sections of corrugated sheets (51), in the form of horizontal "H" type.

[0077] The through piece (72) allows the passage of liquid flowing through the conduit (13).

[0078] The lower part of the sheet (51) of the absorbent material is fixed at any instant of operation.

[0079] It should be noted that depending on the expected operating regime of the solar thermal collector

(11) a set of sections of sheets (51) and associated mechanisms such as fixator (61) and float (62) will be installed in a predetermined number of ducts (13) of the manifold (11).

[0080] In summary, the control of the internal temperature of the collector (11) is done by increasing or decreasing absorbing material (51) deployed inside the ducts (13) depending on the consumption of existing hot sanitary water in a Given moment.

[0081] That is, a greater consumption of hot sanitary water implies a greater number of lengths of sheets of sheet (51) of the absorbent material deployed. If there is no consumption of hot water, there is no liquid circulating and the sections of sheet (51) of the absorbent material retract on themselves. Therefore, the absorbed radiation is reduced and the temperature of the liquid is lower than if the absorber material were permanently deployed, for example, because it was attached internally and permanently to the ducts (13).

[0082] In relation now to Figure 9, in order to reduce the number of elements that could be included in the described solar collector (11), the pieces called cover could be eliminated, their function being performed by the deposit of inlet (12) and outlet tank (14) adapted to perform the functions of the suppressed covers.

[0083] The dimensions of the distributors (12), (14) integrated in the manifold body (11) will be such that the passage section is equal to that assigned to the parts called covers. And, for example, the entry and exit of the fluid from the distributors will be made on the rear walls by means of a welded tube in the plane of the wall of the base panel of the collector (11).

[0084] In relation to Figure 10, from the use of distributors (12), (14) integrated in the base panel of the manifold (11), the options of upper and lower closures can be several, for example, by welding of non-perforated plates, filling the channels (13) by silicone, molten material, or other materials of easy application, low cost and sufficient adhesion to the material of the base panel, such that it resists the internal pressure and the aging process at that the solar collector (11) will be subjected; bending and welding of front walls that have been left with sufficient length in the process of machining the side walls.

[0085] If using base panels of two or three rows of cells, those that are not fluid closure could be sealed with silicone or other filler material.

[0086] In connection with Figure 5, the need to insulate the back of the collector base panel

(11) to reduce heat losses, it can be performed by incorporating one or two rows of additional cells, of size and materials not necessarily equal to the cell containing the fluid. These cells would be coextruded with the cell that contains the fluid so that they will form a compact block of

10 sufficient structural strength so that the collector does not need structural reinforcement.

[0087] The process of extruded the set of fluid circulation cells with those of isolation and even with the filling insulation material, could be carried out jointly so that the manipulation of the manifold (11) given is minimized its general dimensions

[0088] The embodiment and example set forth herein is presented as the best explanation of the

The present invention and its practical application and thus allow a person skilled in the art to practice and use the invention. However, the person skilled in the art will recognize that the above description and example has been presented for the purpose of illustration and only as an example.

Claims (17)

one.

Solar thermal collector of material transparent to solar radiation comprising an inlet distributor (12) and an outlet distributor (14) connected via a first set of conduits (13); characterized in that at least one conduit of the first set of conduits (13) includes in its interior a material (51) absorbing solar radiation adapted to be extended along the conduit (13) via an extension means (62), the extension means (62) inside the conduit (13) due to the movement of fluid circulation contained in the solar collector (11).

2.

Solar collector according to claim 2; characterized in that the fluid flows from the inlet distributor (12) to the outlet distributor (14) as a function of the temperature reached by said liquid within the solar thermal collector (11).

3.

Solar collector according to claim 2; characterized in that the solar radiation absorbing material (51) folds back on itself when the fluid stops circulating inside the first set of ducts (13).

Four.

Solar collector according to claim 3; characterized in that the absorbent material (51) has an elongated sheet-like shape divided into at least a first and a second section of sheet, so that the sum of the linear length of both first and second section of sheet (51) is less than the linear length between both inlet (12) and outlet (14) distributors of the first set of ducts (13).

5.

Solar collector according to claim 4; characterized in that the proximal end of the first section of sheet (51) of said absorbent material is mechanically fixed to the inner part of the duct (13) close to the inlet reservoir (12) via a mechanical joining means (61) so as to allow the passage of fluid through the inside of the duct (13) and avoid the longitudinal displacement of said fixator (61).

6.

Solar collector according to claim 5; characterized in that the second section of sheet (51) of the absorbent material consecutive to the first section of sheet (51), moves longitudinally towards the outlet tank (14), dragged by the extender (62), until the upper end of the first sheet section (51) mechanically contacts the lower end of the second section of upper sheet (51).

7.

Solar collector according to claim 6; characterized in that both upper and lower ends of the first and second section of sheet (51) respectively are curved on each other adopting a "J" type shape.

8.

Solar collector according to claim 1; characterized in that the absorbent material (51) is obtained from a black material such as a synthetic, natural fabric; plastic, glass, a metal such as copper, aluminum whose density is different from the circulating liquid and substantially higher than that of the referred liquid.

9.

Solar collector according to claim 8; characterized in that each section of the absorbent material (51) has a geometric shape adapted to slide through the interior of the duct (13) depending on the volume of fluid circulating between the inlet reservoir (12) and the outlet reservoir (14).

10.

Solar collector according to claim 9; characterized in that the absorbent material (51) is configured as a continuous tape of a black material such as a natural, synthetic textile material that is adapted to be extended along each duct (13).

eleven.

Solar collector according to claim 1; characterized in that the solar collector (11) has the form of a first reticular profile like that of the first row of conduits (13), these conduits being flowing through the fluid, of walls and bottom absorbing thermal radiation.

12.

Solar collector according to claim 12; characterized in that the solar collector (11) is in the form of a first reticular profile such as that which includes the first row of ducts (13) through which the fluid flows from walls and bottom absorbed by thermal radiation and a second row of ducts flows (33) transparent superimposed on the first row of ducts (13).

13.

Solar collector according to claim 12; characterized in that in the second row of ducts

(33) Overlaps a vacuum has been made with a predetermined degree of vacuum.

14.

Solar collector according to claim 12; characterized in that it comprises a fourth set of transparent ducts between the first set of ducts (13) and the second set of ducts (33), in which each duct is sealed containing in its interior a gas that increases the effect

5 greenhouse of the second set of ducts (33). 15. Solar collector according to claim 12; characterized in that it comprises a third set of ducts (43) parallel to the first set of ducts (13), separated by third partitions (42) from the second rear panel (22). 16. Solar collector according to any of the preceding claims; characterized in that the solar collector (11) is manufactured by an extrudable plastic material such as polycarbonate. SPANISH OFFICE OF THE PATENTS AND BRAND Application no .: 201090038 SPAIN Date of submission of the application: 04.12.2008 Priority Date: REPORT ON THE STATE OF THE TECHNIQUE 51 Int. Cl.: F24J2 / 40 (2006.01) RELEVANT DOCUMENTS

Category

56 Documents cited Claims Affected

TO

US 4282856 A (STEHL OTTO et al.) 11.08.1981, column 5, line 5 - column 6, line 6; Figures 1-3. one

TO

DE 2846178 A1 (MESSERSCHMITT BOELKOW BLOHM) 30.04.1980, summary [online] [retrieved on 05.12.2012] Recovered from WPI DATABASE in POQUE & DE 2846178 A1 (MESSERSCHMITT BOELKOW BLOHM) 30.04.1980, figures. one

TO

US 4220139 A (RAMSDEN JAMES B) 02.09.1980, the whole document. one

TO

US 3981294 A (DEMINET CZESLAW et al.) 21.09.1976, column 4, lines 36-66; figure 10. one

Category of the documents cited X: of particular relevance Y: of particular relevance combined with other / s of the same category A: reflects the state of the art O: refers to unwritten disclosure P: published between the priority date and the date of priority submission of the application E: previous document, but published after the date of submission of the application

This report has been prepared • for all claims • for claims no:

Date of realization of the report 05.12.2012

Examiner J. Merello Arvilla Page 1/4

REPORT OF THE STATE OF THE TECHNIQUE Application number: 201090038 Minimum documentation searched (classification system followed by classification symbols) F24J Electronic databases consulted during the search (name of the database and, if possible, terms of search used) INVENES, EPODOC, WPI State of the Art Report Page 2/4  WRITTEN OPINION Application number: 201090038 Date of Written Opinion: 05.12.2012 Statement

Novelty (Art. 6.1 LP 11/1986)

Claims Claims 1-16 IF NOT

Inventive activity (Art. 8.1 LP11 / 1986)

Claims Claims 1-16 IF NOT

The application is considered to comply with the industrial application requirement. This requirement was evaluated during the formal and technical examination phase of the application (Article 31.2 Law 11/1986).  Opinion Base.- This opinion has been made on the basis of the patent application as published. State of the Art Report Page 3/4  WRITTEN OPINION Application number: 201090038  1. Documents considered.- The documents belonging to the state of the art taken into consideration for the realization of this opinion are listed below.

Document

Publication or Identification Number publication date

D01

US 4282856 A (STEHL OTTO et al.) 11.08.1981

 2. Statement motivated according to articles 29.6 and 29.7 of the Regulations for the execution of Law 11/1986, of March 20, on Patents on novelty and inventive activity; quotes and explanations in support of this statement Document D01 is considered the closest in the state of the art to the invention according to claims 1 to 16 of the patent application object of this Written Opinion. The numerical references used are relative to document D01. Hereinafter, the same terminology as the claims of the patent application under study will be used. Document D01 presents a solar thermal collector of material transparent to solar radiation comprising an inlet distributor (16) and an outlet distributor (17) connected via a first set of conduits (11) which includes in its interior a material ( 12) solar radiation absorber (D01, column 5, lines 63-65) adapted to be extended along the conduits (11). The difference between D01 and the first claim of the patent application under study lies in the fact that the latter proposes that the solar radiation absorbing material be extended along the conduit thanks to an extension means that travels through the conduit due to the movement of fluid circulation contained in the solar collector; on the contrary the absorbent material disclosed in D01 is fixed. This difference gives rise to a solar collector different from those found in the state of the art, so the invention according to the first claim of the patent application is new (Law 11/1986, Art.6.1.). At the same time, it is not considered obvious for a person skilled in the art that starts from the invention according to D01 to provide the radiation-absorbing material (12) with an extender that causes it to move in the ducts (11), taking advantage of the movement of the fluid contained in the collector to give rise to the solar collector proposed in the first claim under study; therefore it is considered that said first claim has inventive activity (Law 11/1986, Art.8.1). Since the first claim counts with novelty and inventive activity, the dependent claims thereof, that is, claims 2 to 16, in turn have novelty (Law 11/1986, Art.6.1) and inventive activity (Law 11/1986, Art.8.1). State of the Art Report Page 4/4