NL1027032C2 - Solar collector for storing solar energy in liquid medium, has flat plate which fixed along edges on underside of collecting plate, and space between plates where profile defining zigzag form of space is arranged in at least one of plates - Google Patents

Abstract

A solar collector, comprises first flat plate for collecting solar energy; second flat plate which fixed along edges (31, 32, 33) on underside of first plate; space between the two plates; an inlet for feeding a liquid to space; and outlet for discharging liquid from space. The liquid can flow from inlet to outlet. The space between the plates is formed in that a profile defining zigzag form of space is arranged in at least one of plates. Independent claims are also included for: (A) a method for manufacturing a solar collector, comprising manufacturing plates for an upper side and an underside of the solar collector; arranging a profile comprising edges and ribs in at least one of the plates, which profile, after assembly of the heat exchanger, defines a space on the inside of the heat exchanger, which space has a zigzag form for allowing a fluid to flow; and fixing the plates to each other along the ribs and edges by laser welding; (B) a storage container for a liquid, comprising an inner wall and an outer wall, each comprising a bottom wall for the storage container, which are molded from a plastic; a closing cover for closing the container which is also double-walled and filled with a foaming insulating mechanism; passage openings for passage of supply and discharge conduits for the liquid; passage openings for passage of supply and a discharge for a heat exchanger; and an insulating unit such as PUR foam which fills the space between the inner wall and the outer wall by foaming during or after introduction between the inner wall and the outer wall; (C) a system comprising a solar collector; a storage container; and conduits for transporting a liquid from the storage container to the collector and vice versa; and a pump for driving the liquid through the conduits; (D) a method for manufacturing a storage container for a liquid, comprising introducing a liquid curable plastic into a mold defining an outer wall, an inner wall and a connection; rotating the mold such that the plastic is distributed over the whole surface of the mold; curing the plastic; and arranging a foaming, heat-insulating plastic in the space between the inner wall and outer wall, where the plastic fills the whole space between the inner wall and the outer wall; (E) a sun following system for optimizing the orientation of a solar collector relative to the sun during the course of a day, comprising a support; a first rotation frame which is arranged in the frame and which is mounted about a first rotation axis on the support frame; a second rotation frame which is arranged in the first rotation frame by a second rotation axis for mounting of a solar collector; drive unit for driving the first and second rotation frames for movement; and a controller for controlling the drive unit; and (F) a method for orienting a collector in a direction considered optimal relative to incident solar radiation by device, comprising determining the direction of incident solar radiation, rotating the solar collector in a first direction to this direction, and rotating the solar collector in a second direction to this direction.

Description

METHOD FOR MANUFACTURING A HEAT EXCHANGER, A SOLAR COLLECTOR, STORAGE CONTAINER AND A SYSTEM CONTAINING A

SUN COLLECTOR

The present invention relates to a method for manufacturing a heat exchanger, a solar collector, a storage vessel, a system comprising a solar collector and a method for manufacturing a storage vessel for a liquid.

10 Solar energy is increasingly being used to replace the use of fossil fuels. An application of solar energy is the storage of the energy in a liquid medium by means of a heat exchanger.

Such systems are known per se, for example from the publication of the international patent application of the same inventor as this application, WO 01/77590 A1. A flat plate collector is described in this document. This collector already offers a relatively high efficiency; however, it is relatively expensive to manufacture.

In order to obviate the above-mentioned drawback and to provide an improved device for exchanging heat, the present invention provides a method for manufacturing a heat exchanger, comprising steps for: - manufacturing plates for an upper side and a lower side of the heat exchanger, - arranging a profile comprising edges and ribs in at least one of the plates, which profile, after assembling the heat exchanger, defines a space on the inside of the heat exchanger, which space has a zigzag shape for passing through it flowing a 1027032 2 fluid; ~ - fixing the plates together along the edges and ribs.

An advantage of an embodiment according to the present invention is that the space for allowing the fluid to flow through can be realized relatively advantageously by providing the profile in at least one of the plates.

According to an embodiment the profile is provided in the plate by means of deep drawing. This allows a profile 10 in a plate to be arranged in one go in a plate.

Furthermore, it is possible to arrange the profile by means of a roller on which the desired profile is applied to the surface.

The plates preferably comprise stainless steel or another durable metal. The use of stainless steel is very well achievable in such a heat exchanger, since there is direct contact between the liquid medium and the metal, whereby a very high efficiency can be achieved despite the somewhat lower conductivity with respect to, for example, copper.

The plates are preferably welded together for fixing. Furthermore, it is advantageous if the plates are provided with a coating for increasing the absorption capacity of the surface and optionally for reducing the emission capacity at operational temperatures.

Furthermore, the above-mentioned method preferably comprises steps for arranging in at least one of the plates at least one turbulence member for causing turbulence in the flow of the fluid. This turbulence is helpful in spreading the collected heat through the entire fluid volume. For example, water is known to have relatively low thermal conductivity.

1G2fU32 3

A further aspect of the present invention relates to a solar collector, comprising: - a first plate for collecting solar energy, - a second plate which is fixed at least substantially along the edges on the underside of the first plate, - a space between the two plates, - an inlet for supplying a liquid to the space, - an outlet for discharging the liquid from the space with a zigzag shape through which the liquid can flow from the inlet to the outlet wherein the space between the plates is formed in that at least one of the plates is provided with a profile which defines the zigzag shape of the space.

Such a collector has advantages such as. described above. Manufacturing this is relatively advantageous in that a profile is provided in the metal plate 20, which profile forms the space for the liquid that serves as a heat transfer medium. The profile is preferably manufactured by deep-drawing or, for example, rolling.

In a further embodiment, the solar collector comprises turbulence members for causing swirls in the liquid in the space. An optimum heat distribution in the liquid is hereby realized when the liquid is pushed through the zigzag channels. These turbulence members comprise, for example, oblique ribs which, viewed in the flow direction, narrow the flow channel by 50 to 90 percent.

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In a further preferred embodiment the solar collector comprises a housing for placing the plate assembly, comprising: - a bottom wall, comprising a plastic and a frame for supporting the plate assembly and a cover plate, in one piece, - an insulating layer arranged on the bottom wall within a framework for supporting the plate assembly, - a cover plate with both radiation-accepting properties and insulating properties. An advantage of this embodiment is that with a minimum number of parts a maximum efficiency of the solar collector can be realized. Furthermore, this collector can easily be placed at the location where it is to function. Furthermore, such a solar collector is easy to assemble and, in assembled form, relatively easy to handle and transport.

The solar collector as described above preferably comprises a mounting profile which extends around the circumference of the plate assembly. An advantage of such a profile is that the possibly somewhat rough edge of the plate assembly is shielded from the frame within which the plate assembly is placed.

Furthermore, with a suitable choice of material, such a profile functions as a damping member for vibrations and / or sounds produced by the flow of liquid in the plate assembly.

A further aspect of the present invention relates to a storage vessel for a liquid, comprising: - an inner wall and an outer wall, each comprising a bottom wall for the storage vessel, which are cast from a plastic, 1027032 - a closing lid for closing the vessel that is also double-walled and filled with a foaming insulating agent, - a number of passage openings for the passage of at least supply and discharge pipes for the liquid, - a number of passage openings for the passage of at least one inlet and a discharge for a heat exchanger, and - an insulating agent such as PUR foam which foams the space between the inner wall and the outer wall during foaming or after its insertion between the inner wall and the outer wall.

An advantage of such an embodiment is that a storage vessel can be manufactured in a relatively simple manner. The storage vessel is very light, durable and well-insulated. It is an open vessel through which the entire collector system can be pressureless.

Preferably, a per se known, for example spiral, heat exchanger 20 is provided in the vessel. Hot water stored in the vessel, for example tap water or heating water, is passed through this heat exchanger. Further openings which can be provided in the storage vessel serve, for example, for a probe or for an overflow.

Preferably, the inner wall and the outer wall are molded as a whole from a plastic. For this purpose, for example, a technique such as rotational molding is applied.

For the sake of insulation, the sealing cover preferably encloses a part of the wall of the vessel in the position of use in the vertical direction.

A further aspect of the present invention relates to a solar collector as described in the foregoing, which is manufactured with the aid of a method 1027032 6 as described in the foregoing, as well as a storage vessel as described in the foregoing, and: - pipes for transporting of a liquid from the storage vessel to the collector and vice versa, 5 - a pump for driving the liquid through the pipes. Advantages of such a system are similar to the advantages described above.

A further aspect of the present invention relates to a method for manufacturing a storage vessel for a liquid, comprising steps for: - introducing a liquid curable plastic into a mold that defines an outer wall, an inner wall and a connection between them, rotating the mold so that the plastic is distributed over the entire surface of the mold, - curing the plastic, - applying a foaming, heat-insulating plastic in the space between the inner wall and the outer wall, the plastic fills the entire space between the inner wall and the outer wall. An advantage of such a method is that a highly insulating storage vessel can be obtained in a relatively simple and advantageous manner. Such storage vessels are applicable in situations where an insulating effect is desired.

Further advantages, features and details of the present invention will be further described with reference to a few embodiments which will be described with reference to the appended figures, in which: figure 1 is a top view of a first embodiment according to the present invention; Figures 2, 3, 4 and 9 are cross-sections of the embodiment of Figure 1; 1027032 7 - Figure 5 is an exploded perspective view of a further embodiment comprising the embodiment of Figure 1; figure 6 is a cross-sectional view of a detail of figure 4; figure 7 is a cross-sectional view of a detail of figure 4; figure 8 is a cross-sectional view of a detail of figure 9; Figure 10 is a plan view of a further embodiment of the present invention; figure 11 is a perspective view of a detail of figure 10; figure 12 is a cross-sectional and partly side view 15 of a further embodiment according to the present invention.

A first embodiment (Figure 10) relates to a flat plate collector 1. This is shown in Figure 10 from the top. The lower plate (not visible) is flat in this embodiment. A profile of channels and vertebral ribs 11, 13 is arranged in the upper plate. The channels are formed by edges 7, 8, 9, 10 as well as channel ribs 3, 5. A heat medium such as water flows through the channels which are designed in a zigzag shape. The water enters the collector on one side at inlet 2 and exits at the outlet 4 on the other side of the collector.

The lower corner near the water inlet 2 is shown in greater detail in perspective in figure 11. The flat plate collector 1 comprises a bottom plate 16 which in this embodiment is flat and an upper plate 17 in which a profile is arranged by deep-drawing. In an alternative embodiment, both plates are provided with 1027032 8 a profile. The two plates are welded together along the broken lines 88, for example by means of laser welding. Between the two plates there is a space through which the heat transfer medium water flows from the inlet 2 to the outlet 4. The channels are formed by the channel ribs 3, which are bounded by channel walls 86 and 87. On the side, the collector is bounded by wall 85.

In order to improve the heat transfer from the upper plate 17 to the water, vertebral ribs or turbulence ribs 11, 13 are arranged in the upper plate 10. These extend at an angle from one side of the channel to the next side of the channel. The turbulence rib 11 is formed by two walls 81 and 82 in V-shape relative to each other. The turbulence rib 13 is formed by two walls 83 and 84 in V-shape relative to each other. The turbulence ribs 11 and 13 close the part of the flow channel in the vertical direction, creating swirls in the flowing water. Swirls also arise through the angle at which the turbulence ribs are arranged in the channels. Depending on the use of the collector, the height of the ribs and the angle thereof can be varied. More or fewer ribs can also be provided per channel.

Furthermore, the top side of the collector plate 17; 25 can be provided with a suitable coating for better absorption of the sun's rays. Depending on the amount of solar radiation and ambient temperature at the location of the use of the collector, an optimum coating can be applied which, for example, optimizes the ratio between the absorption properties and the radiation properties.

Stainless steel plates 16, 17 are particularly suitable for use in this embodiment. Such a metal offers a very long service life and is relatively advantageous. Furthermore, relatively thin plate material such as, for example, between 0.1 and 1 millimeter will suffice. A consequence of this is that solar collectors can be manufactured with a low weight of between 10 and 20 kilograms per m2. A further advantage of the construction of this embodiment is that when water is used as a heat medium, the addition of antifreeze is not necessary.

Figure 5 shows an assembly of a built-in plate 50, insulating material 51, collector 1, mounting profile 52 and cover plate 53 in an exploded perspective view. The mounting plate 50 is made of a plastic, for example by injection molding from, for example, polyethylene. This plate has a relatively complex profile with a number of advantages. This will be explained in more detail below with reference to Figures 2-9.

The cover plate 53 is preferably made of perspex. This material has the advantage that it has electrostatic properties, is dirt-repellent and can be cleaned in a simple manner by means of water. For fixing, the plate is provided with clamping lugs 54. These are clamped around a protrusion (Figure 8) of an edge of the mounting plate (Figure 8). Alternatively, a (hardened) glass plate can be used as a cover plate.

An insulation plate 51 is provided directly on the mounting plate 50. This is located directly or at some distance below the collector 1. The collector 1 is held in place under the cover plate 53 by means of a mounting strip. In an embodiment (not shown) there is a groove in the mounting strip 52 in which the edge of the collector 1 can be placed. In the embodiment shown, 1027032 the collector is placed on the insulation layer, after which the mounting strip is placed on the edge of the collector.

The embodiment of the mounting plate 50 is particularly suitable for placement on pitched roofs instead of the existing roof tiles. For this purpose, a recess 28 is provided on the underside for support on a so-called pan batten.

There are two edges 26, 27 for guiding rainwater on either side of the mounting plate 50. This prevents rainwater from flowing sideways. At the top of the mounting plate 50, at least seen in the mounting position, there is a mounting strip or mounting ramp 25.

In the representation in figure 1 a number of cross-sections 15 are indicated which are shown in cross-section in the respective figures 2, 3, 4, 9.

Figure 1 furthermore shows reinforcement ribs 21 and 22 which are located in the central region of the mounting plate 50. Near the edges of the mounting plate 50 are shown profile edges 31, 32, 33, 34 which will be shown in detail in the cross-sectional views. . Collector plate supports 24 are located on the inside of the corners of the profile edges 31, 32, 33, 34.

Figure 2 shows the section II-II of Figure 1 in greater detail. It can be seen that the insulation plate 51 is located between the bottom of the mounting plate 50 and the collector 1.

Figure 3 shows the section III-III of Figure 1 in greater detail. The section VIII of profile edge 32 is shown in greater detail in Figure 8. Furthermore, in the representation of figure 3, profile edge 34 is shown as well as the insulation plate on the mounting plate 50 on which the collector 1 is located. Above this is the cover plate 53. Along the 1027032 11 profile edges 32 and 34 there is mounting profile 52 between the collector and the cover plate for keeping the collector plate positioned below and at some distance from the cover plate 53.

In addition to the parts shown in Figs. 2 and 3, Fig. 4 shows a further section of the assembly along the section line IV-IV of Fig. 1. The cross-section of the profile edge 33 and the adjacent pan slat support is shown in greater detail in Figure 6. The profile edge 31 and the adjacent mounting strip are shown in greater detail in Figure 7.

In figure 9 the profile edge 32, which is shown in greater detail in figure 8, is shown. This profile edge 32 comprises a snap cam at the location for snap-fitting of the cover plate. Profile edge 34 also includes snap cams.

Figure 6 shows in detail a section of profile edge 33. This is located in the bottom mounting position of the collector. The profile edge 33 is formed by a wall 61 which rises from the bottom of the mounting plate 50 and which merges into horizontal wall 62, after which it again extends downwards by means of downward wall 63. At the bottom side of this downward wall 63 sideways wall portion 64 of 25 which serves as a support on a tile batten. As shown in Fig. 1, this pan batten support 64 extends over the entire width of the mounting plate 50. This makes it possible to place this pan batten support on a pan batten extending to both sides.

In Figure 7 the top side of the mounting plate is shown in section in the mounting position. The mounting plate 50 extends upwards from its bottom through wall 71 which merges into horizontal wall 72 and 1027032 12 from there again downwards through wall 73. From the underside of wall 73 the mounting plate extends through horizontal wall 74 which mounting edge 25.

In figure 8, mounting profile 32 of mounting plate 50 is shown in cross-section at the line IX-IX of figure 1, which detail is also indicated by VIII in figure 9. The mounting plate 50 extends upwards from its bottom by means of wall 81. This wall 81 overflows into horizontal top wall 82 which subsequently extends into arc wall 83 which forms the snap cam for attaching the cover plate 53. This curved part 83 extends into vertical part 84 of the profile 32. By means of some undulations the wall continues in the downward direction to the vertical part 85. From the vertical wall part 85, the mounting plate extends sideways by means of side flap 28. This side flap 28 is provided with water barriers 26, 27. These water barriers 26, 27 must prevent water from draining sideways.

Furthermore, Figure 8 clearly shows the mutual positioning of the insulation 51, the plate assembly 1 and the mounting strip 52 under the cover plate 53.

Figure 12 shows a further embodiment according to the present invention. A storage vessel 111 serves to store heated water or another suitable liquid through the collector plate. The storage vessel 111 comprises a double-walled bucket-shaped holder and a lid fitting thereto. The holder is formed by inner wall 113 and outer wall 112, inner bottom 116 and outer bottom 115 and top wall 114. Such a holder is manufactured in a particularly advantageous manner from a piece of plastic, for example by means of rotational molding. Subsequently, through a suitable opening (not shown), preferably in the outer bottom 115, a foamed 1027032 13 insulation material is introduced which foams the entire space 120 of the container during or after insertion. The lid is manufactured in a similar manner. The cover comprises upper wall 127, lower wall 125 and side wall 129. These walls enclose the insulated inner space 126. A highly insulating foaming plastic is preferably also arranged in this inner space. For a good connection to the holder, the lid is provided with annular notch 130 where the upper part of the hollow wall of the holder fits. Furthermore, the slot between the holder and the lid can be closed further by means of suitable insulating material. For this purpose, for example, one or more annular elements can be used. The water from the solar collector is introduced into the storage vessel through a conduit 122 which in this embodiment is led through the cover. The cold water is supplied to the collector by means of line 121, which drains the colder water at the bottom of the collector vessel. This conduit 121 is preferably insulated in order to isolate the cold water during transport thereof to the top of the container from the relatively warm water present there. Furthermore, a heat exchanger 126 is located in the holder. This heat exchanger preferably extends into the relatively warm part of the collector vessel water. This, for example spiral, heat exchanger is connected to the outside world by means of pipes 123 and 124 which in this embodiment pass through the cover of the storage vessel.

The present invention has been described with reference to a few embodiments, the various aspects of which can be freely varied by a person skilled in the art within the understanding of the present invention. The requested rights are determined by the appended claims.

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Claims (15)

Method for manufacturing a heat exchanger, comprising steps for: 5. manufacturing plates for an upper side and a lower side of the heat exchanger, - applying a profile comprising edges and ribs in at least one of the plates, which profile after assembling the heat exchanger, defines a space on the inside of the heat exchanger, which space has a zigzag shape for flowing a fluid through it, fixing the plates together along the ribs and edges. Method according to claim 1, wherein the plates comprise metal and the profile is provided in the plate by deep-drawing. 3. Method as claimed in claim 1 or 2, wherein the plates preferably comprise stainless steel or another durable metal. 4. Method in which the plates are welded together for fixing. 5. Method as claimed in one or more of the foregoing claims, comprising steps for arranging in at least one of the plates at least one turbulence member for causing turbulence in the flow. 6. Solar collector, comprising: - a first plate for collecting solar energy, 30. a second plate which is fixed at the bottom of the first plate at least substantially along the edges, - a space between the two plates, 1027032 - an inlet for supplying a liquid to the space, - an outlet for discharging the liquid from the space with a zigzag shape through which the liquid can flow from the inlet to the outlet, wherein - the space between the plates is formed in that at least one of the plates is provided with a profile which defines the zigzag shape of the space. 7. Solar collector according to claim 6, comprising turbulence members for causing swirls in the liquid in the space. 8. Solar collector according to one or more of the preceding claims, comprising a housing for placing the plate assembly, comprising: 15. a bottom wall, comprising a plastic and a frame for supporting the plate assembly and a cover plate, in one piece, - an insulating layer which is arranged on the bottom wall within a framework for supporting the plate assembly, - a cover plate with both radiation-accepting properties and insulating properties. 9. Solar collector according to claim 9, comprising a mounting profile which extends around the circumference of the plate assembly. 10. Solar collector according to claim 8 or 9, wherein the cover plate is a slightly curved plastic plate. 11. Storage vessel for a liquid, comprising: - an inner wall and an outer wall, each comprising a bottom wall for the storage vessel, which are molded from a plastic, 1027032 - a closing lid for closing the vessel which is also double-walled and filled with a foaming insulating means is filled, - a number of feed-through openings for feeding through at least supply and discharge lines for the liquid, - a number of feed-through openings for feeding through at least one feed and a discharge for a heat exchanger, and - an insulating means such as PUR- foam which, during foaming or after insertion thereof between the inner wall and the outer wall, fills the space between the inner wall and the outer wall. 12. Storage vessel according to claim 11, wherein the inner wall and the outer wall are molded as a whole from a plastic. A storage vessel according to claim 11 or 12, wherein, in the position of use, viewed in the vertical direction, the closure lid encloses a part of the wall of the vessel. 14. System comprising a solar collector according to one or more of claims 6-10 or which is manufactured with a method according to claims 1-5, a storage vessel according to one or more of claims 11-13, and: - pipes for transporting of a liquid from the storage vessel to the collector and vice-versa, 25. a pump for driving the liquid through the lines. 15. Method for manufacturing a liquid storage vessel, comprising steps for: - introducing a liquid curable plastic into a mold that defines an outer wall, an inner wall and a connection between them, - rotating the mold so that the plastic is distributed over the entire surface of the mold, 1027031 - curing of the plastic, - applying a foaming, heat-insulating plastic in the space between the inner wall and the outer wall, the plastic covering the entire space between the inner wall and fills the outside wall. 1027032