KR20150049757A - High concentrating photovoltaic module for easily arraying lens plate - Google Patents

Abstract

The present invention relates to a high concentrating photovoltaic module, more specifically to a high concentrating photovoltaic module which increases the generation efficiency of a solar battery module made of multiple solar batteries and lens plates by arraying the lens plates at exact locations, and improves the function of radiating heat and assembling by a simple composition. The high concentrating photovoltaic module according to the present invention comprises: a frame having a side plate and an under plate; a solar battery assembly equipped with a solar battery and coupled to the under plate; a lens plate array having multiple lens plates, equipped with at least one pattern unit for concentrating an exposed light to the solar battery, arranged and coupled at the upper part of the frame; and a support fixture which supports the lens plate. The side plate includes a horizontal plate and a vertical plate longer than the horizontal plate, having a support rib which supports the support fixture.

Description

HIGH CONCENTRATING PHOTOVOLTAIC MODULE FOR EASILY ARRAYING LENS PLATE,

The present invention relates to a highly-concentrated solar cell module, and more particularly, to a highly-concentrated solar cell module capable of easily arraying a lens plate at an accurate position and improving a heat dissipation function and assemblability by a simple structure.

Recently, photovoltaic (PV) devices using solar light have been widely used. In particular, photovoltaic devices using silicon solar cells are mainly used.

However, due to the breakthrough of high efficiency III-V compound semiconductor solar cell (multi-junction solar cell), it has been concluded that a multi-junction solar cell uses a low-cost condensing device to concentrate solar light (Concetrating Photovoltaic, CPV) devices have been actively studied.

Multi-junction solar cells have a higher energy conversion efficiency than silicon solar cells. In general, multi-junction solar cells have more than 35% energy efficiency, while silicon solar cells have about 20% efficiency Respectively. Particularly under concentration, some multi-junction solar cells currently have an energy efficiency of more than 40%.

The light-gathering type solar cell module using the multi-junction solar cell includes a solar cell, a primary lens that primarily condenses sunlight, a secondary lens that primarily condenses the light condensed from the primary lens, And the solar cell is mounted on a cell mount such as a circuit board or mounted on a receiver as disclosed in Korean Patent Laid-Open No. 10-2010-0135200.

In addition, the light-convergence type solar power generation system is constituted by arranging a plurality of light-collecting type solar cell modules in an array form in a support frame, and in order to improve efficiency of the multi-junction solar cell, the solar cell module maintains a state orthogonal to the sun A tracking device for rotating the solar cell module array is provided.

Also, since the efficiency of the III-V compound semiconductor solar cell, which is mainly used in the light-collecting solar cell module, is drastically lowered by heat, the light-collecting solar cell module is provided with a heat dissipating device for dissipating heat generated in the solar cell .

On the other hand, the light-collecting type solar cell module mainly uses a lens plate having a pattern for collecting sunlight such as a fresnel lens as a primary lens. Such a lens plate has a large area It is difficult to manufacture the lens plate, so that the lens plate having the pattern formed thereon has a structure for bonding them together. However, there is a problem in that it is very difficult to arrange a plurality of lens plates in an accurate position and thus to combine them.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems and it is an object of the present invention to provide an image forming apparatus capable of easily arraying and assembling a plurality of lens plates at precise positions, A highly concentrated solar cell module capable of minimizing the output difference of a plurality of series-connected solar cell arrays by minimizing the output difference of the solar cell arrays.

The present invention also provides a highly concentrated solar cell module capable of improving the heat dissipation function and the assemblability by a simple structure.

The highly concentrated solar cell module according to the present invention comprises a frame including a side plate and a lower plate; A solar cell assembly having a solar cell and coupled to the lower plate; A lens plate array in which a plurality of lens plates having at least one pattern portion for collecting incident light into the solar cell are arranged and coupled to the frame; And the support plate supporting the lens plate, wherein the side plate includes a transverse plate and a longitudinal plate longer than the transverse plate, and the longitudinal plate is formed with a support rib for supporting the support.

A stepped portion may be formed on one side of the lower surface of the lens plate, and a hook may be formed on the support plate to align the position of the lens plate with the stepped portion.

In addition, an insertion portion into which a protrusion formed on one side of another adjacent lens plate is inserted may be formed on one side surface of the lens plate.

In addition, the highly concentrated solar cell module according to the present invention may further include an elastic member for fixing the lens plate supported on the support to the support.

The solar cell assembly includes: a heat pipe extending in a transverse direction; A circuit board on which the solar cell is mounted and attached to the heat pipe; And a pair of seating part forming ribs protruding in the lateral direction so as to be long in the horizontal direction so that the seat part on which the heat pipe is seated is elongated in the transverse direction is formed on the upper part of the lower plate And a radiating rib may protrude from the lower portion of the lower plate.

The solar cell assembly further includes a secondary lens disposed on the heat pipe so as to cover the circuit board and configured to condense sunlight condensed on the lens plate with the solar cell, And a fixing elastic member coupled to the pair of seating part forming ribs in a state of pressing the secondary lens.

Further, the wire is made of uncoated ribbon wire, and the ribbon wire has a length portion having a predetermined width and length; A pair of stepped portions extending downward from both sides of the length portion; And a pair of flanges connected to the circuit board and extending from the step portion to support the ribbon wire.

The highly concentrated solar cell module according to the present invention having the above-described structure can easily array and combine a plurality of lens plates at precise positions, so that the difference in the amount of sunlight incident on each solar cell or the uniformity The output difference of the solar cell arrays generated by the plurality of series-connected solar cell arrays can be minimized and the output drop of the plurality of series-connected solar cell arrays can be minimized.

Further, in the highly concentrated solar cell module according to the present invention, the circuit board on which the solar cell is mounted is directly attached to the heat pipe immediately long in the longitudinal direction, which has a heat dissipating function, and the heat pipe is disposed on the lower plate The heat generated from the solar cell is efficiently dissipated to a large area by the heat pipe, and then the heat can be more effectively radiated to the outside by the lower plate sequentially, thereby maximizing the heat dissipation effect.

Further, since the highly integrated solar cell module according to the present invention is formed of ribbon wires that are not covered with wires connecting a plurality of solar cells, a separate wire cover structure for protecting the wires from sunlight is not required, And the assembly can be simplified.

Further, since the highly concentrated solar cell module according to the present invention further includes a fixing elastic member which is coupled to a pair of seating portion forming ribs formed on the lower plate and presses the secondary lens, it is easy to fix the secondary lens The heat pipe can be more firmly fixed together with the secondary lens and the contact between the circuit board and the heat pipe and the contact between the heat pipe and the lower plate can be made more tight by the pressing of the fixing elastic member, Can be further improved.

The effects according to the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims and the detailed description It will be possible.

1 is a perspective view showing a highly concentrated solar cell module according to an embodiment of the present invention,
FIG. 2 is a partial cross-sectional view taken along line AA of FIG. 1,
FIG. 3 is a partial cross-sectional view taken along the line BB of FIG. 1,
4 is a partially enlarged view of the 'C' region of FIG. 2,
5 is a view showing an embodiment in which the lens plate is engaged,
6 is a perspective view illustrating a solar cell assembly according to an embodiment of the present invention,
FIG. 7 is a partial enlarged view of the 'C' region of FIG. 2,
8 is a partially enlarged view of the 'D' region of FIG. 3,
9 is a view showing a state in which the solar cell assembly is coupled to the lower plate,
10 is an exploded perspective view of the solar cell assembly and the lower plate,
11 is a schematic plan view of a circuit board.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. Rather, the intention is not to limit the invention to the particular forms disclosed, but rather, the invention includes all modifications, equivalents and substitutions that are consistent with the spirit of the invention as defined by the claims.

Also, in the accompanying drawings, thickness and size are exaggerated for clarity of description, and thus the present invention is not limited by the relative size or thickness shown in the attached drawings.

Meanwhile, in this specification, relative terms such as 'vertical direction' and 'horizontal direction' can be used to describe the relationship between the structures on the basis of the directions shown in the drawings, and the present invention is not limited to such terms.

FIG. 1 is a perspective view showing a highly concentrated solar cell module according to an embodiment of the present invention, FIG. 2 is a partial cross-sectional view taken along line AA in FIG. 1, Sectional view.

1 to 3, a highly concentrated solar cell module 10 according to an embodiment of the present invention includes a frame including a side plate and a lower plate 30, a solar cell 102, and a lower plate 30 A lens plate array 20 in which a plurality of lens plates 21 for collecting sunlight incident on the solar cell 102 are arrayed on top of the frame, And a support table 80 for supporting the lens plate 21.

The frame is formed to be long in the longitudinal direction (y) and has a stiffness by itself. The frame may be formed as a side plate and a bottom plate (30) and open upward.

The side plate may be composed of a transverse plate 25 which is shorter in the transverse direction x and a longitudinal plate 50 which is longer than the transverse plate 25 in the longitudinal direction y.

A plurality of heat dissipating ribs 51 may be formed on the outer surface of the vertical plate 50 to improve rigidity and improve the heat radiation effect by increasing the contact area with the outside. A supporting rib 52 may be formed. Therefore, the vertical plate 50 has the heat radiating ribs 51 formed on the outer side surface thereof and the support ribs 52 formed on the inner side surface thereof, whereby the rigidity can be further improved.

The vertical plate 50, the horizontal plate 25, and the lower plate 30 constituting the frame are preferably formed of an aluminum material having a lightweight but high rigidity and excellent thermal conductivity, and can be easily manufactured and assembled as a whole, That is, the vertical plate 50, the transverse plate 25, and the lower plate 30 are integrally formed by extrusion molding so as to have a stiffness structure.

The lens plate 21 is provided in the upper part of the frame so as to condense the sunlight incident on the solar cell 102. The lens plate 21 is provided with a pattern plate 21 for condensing incident sunlight into the solar cells 102, At least one pattern 22 may be formed, and the pattern 22 may be provided in the form of a Fresnel lens. These lens plates 21 are arrayed on top of the frame to form a lens plate array 20.

The lens plate 21 is formed in a substantially rectangular shape and the lens plate array 20 is formed in a substantially grid shape in which a plurality of such rectangular lens plates 21 are arrayed in the horizontal direction x and the vertical direction y, Lt; / RTI >

The support 80 may be formed to have a length of the substantially transverse plate 25 to support the lens plate 21 arranged in the transverse direction x and the module 10 according to an embodiment of the present invention The support plate 80 is supported by the support ribs 52 formed on the inner surface of the vertical plate 50 so as to be elongated in the horizontal direction x to support the lens plate 21 arranged in the horizontal direction x. .

Also, a plurality of support rods 80 may be provided at predetermined intervals in the longitudinal direction x to support the lens plates 21 arranged in the longitudinal direction y. That is, the module 10 according to an embodiment of the present invention may include a plurality of supports 80 spaced apart from each other by a width of the lens plate 21 in the vertical direction y.

FIG. 4 is a partially enlarged view of the 'C' region of FIG. 2, and FIG. 5 is a view showing an embodiment in which lens plates are coupled to each other. 4 and 5, an embodiment of a structure in which a plurality of lens plates 21 are arrayed and fixed at an upper portion of a frame will be described in detail.

As described above, the support rods 80 may be supported by a pair of support ribs 52 formed on the inner surface of the vertical plate 50 so as to be elongated in the longitudinal direction (x) And a fastening portion 82 for screw connection with the vertical plate 50 may be formed on the support base 80. Therefore, the support table 80 can be engaged and fixed to the vertical plate 50 by screwing in a state of being placed on the support ribs 52.

A step 23 is formed on one side of the lower surface of the lens plate 21 and the step 23 is engaged with the support 80 to align the position of the lens plate 21 in the longitudinal direction y The jaw 83 can be formed. The lens plate 21 can be aligned at the correct position in the longitudinal direction y of the frame by being supported by the step 23 on the holding jaw 83 of the support table 80. [

The lens plate 21 is provided on the upper part of the frame to primarily condense incident sunlight. In order to allow the incident light to be accurately focused by the solar cell 102, It is very important to improve the light efficiency. When the lens plates 21 are aligned at the correct positions as described above, the amount of sunlight incident on each solar cell or the uniformity The output difference of the solar cell arrays generated due to the difference can be minimized and the output drop of the plurality of serially connected solar cell arrays can be minimized. The module 10 according to the embodiment of the present invention can be easily moved to the correct position of the upper part of the frame by the step 23 of the lens plate 21 and the engagement step 83 of the support 80 .

The lens plate 21 includes a plate portion 211 having a pattern portion 22 for condensing incident light, a side portion 212 extending downward from one side of the plate portion 211, And a flange portion 213 bent perpendicularly from the lower end to form the step portion 23.

Although one pattern portion 22 is formed on the plate portion 211, the present invention is not limited thereto. The plate portion 211 may have two or more pattern portions 22. That is, the lens plate 21 according to the present invention may be provided with at least one pattern unit 22.

The flange portion 213 is a portion which is in direct contact with the upper portion of the support table 80. The flange portion 213 is formed with a step 23 at the lower side of one side of the lens plate 21, .

4, an insertion portion 214 may be formed on one side of the lens plate 21, in which a protrusion 215 formed on one side of the adjacent lens plate 21 is inserted. Accordingly, the plurality of lens plates 21 are arrayed and coupled with each other in a state where the insertion portion 214 and the protrusion 215 formed in the respective lens plates 21 are inserted and coupled to each other, . When one of the lens plates 21 is inserted into one of the support rods 80 and the other of the insertion portions 214 and the protruding portions 215 is inserted into the lens barrel 21, The other one of the lens plates 21 can be supported by the adjacent one of the lens plates 21 so that the overall configuration can be simplified.

The lens plate 21 having the above-described structure may be integrally formed with the pattern portion 22 by a method such as injection molding or may be integrally formed with the plate portion 21 of the lens plate 21 integrally manufactured by a method such as injection molding. The pattern portion 22 may be attached to the portion 211, and the present invention is not limited thereto.

The module 10 according to the present invention may further include an elastic member 90 for fixing the lens plate 21 supported on the support 80 to the support 80.

The support base 80 may further include an engagement groove 84 to which the elastic member 90 for fixing the lens plate 21 is coupled and the elastic member 90 is engaged with the engagement groove 84 A lens plate 21 which is bent from the end of the length portion 92 and is supported on the support table 80; A fixed end 92 may be formed.

The lens plate 21 can be easily fixed by using the elastic member 90 in a state in which the step portion 23 is hooked on the stopper 83 of the support base 80 and supported. When one of the lens plates 21 is coupled and fixed to the upper part of the frame as described above, the other adjacent lens plate 21 is supported on one side of the support 80 on which the one lens plate 21 is supported The elastic member 90 is similarly used in a state in which the step portion 23 formed on the other side is hooked on the retaining protrusion 83 of the other support block 80 spaced apart from the support block 80 by a predetermined distance So that it can be easily fixed.

Further, the space between the lens plates 21 is sealed with a sealing material 24 such as silicon, so that the space inside the frame can be sealed.

Meanwhile, the solar cell assembly 100 according to the present invention is configured to maximize the heat dissipation effect and simplify the assembling property with a simple structure. Hereinafter, the configuration of the solar cell assembly 100 will be described in detail.

FIG. 6 is a perspective view showing a solar cell assembly according to an embodiment of the present invention, FIG. 7 is a partially enlarged view of the 'D' region of FIG. 2, and FIG. 8 is a partially enlarged view of the 'E' .

6 to 8, a solar cell assembly 100 according to an embodiment of the present invention includes a heat pipe 110 elongated in a longitudinal direction (or a lateral direction x), a solar cell 102 And a wire 130 for allowing the mounted circuit board 104 and the solar cell 102 to conduct with each other.

The solar cell 102 may be a high efficiency III-V compound semiconductor multi-junction solar cell that converts solar energy into electrical energy, and the circuit board 104 may be used with other components And may be a receiver or a carrier commonly used in the technical field of the present invention in which the solar cell 11 is mounted. That is, in the present invention, the circuit board 104 is configured to mount the solar cell 102, and the embodiments can be configured in various forms.

The circuit board 104 is directly attached to the heat pipe 110 by soldering or soldering or the like. That is, in the solar cell assembly 100 according to the present invention, the circuit board 104 on which the solar cell 102 is mounted is directly attached to the heat pipe 110, which is long in the longitudinal direction, The heat generated from the solar cell 102 can be efficiently transmitted along the longitudinal direction of the heat pipe 110 and can be radiated to a wide area do.

The refrigerant pipe 112 circulating the refrigerant is formed in the heat pipe 110 to be long in the longitudinal direction (or the lateral direction x). The refrigerant pipe 112, which is generated in the solar cell 102 mounted on the circuit board 104 The heat is transferred to the refrigerant tube 112 positioned immediately below and the refrigerant present in the refrigerant tube 112 in the area is transferred to the adjacent region by condensation and is returned to the position where the evaporation occurred The heat generated in the solar cell 102 by the circulation process can be dissipated to a larger area along the longitudinal direction of the heat pipe 110. [

6, a solar cell assembly 100 according to the present invention includes a circuit board 104 on which one solar cell 102 is mounted on one heat pipe 110, So as to be arranged at predetermined intervals. The heat generated by the plurality of solar cells 102 is more effectively transmitted along the longitudinal direction of the heat pipe 110 so that the heat can be dissipated to a wider area, and the overall structure and assemblability can be simplified.

A thermally conductive contact member sheet 140 made of a TIM (Thermal Interface Material) material may be interposed between the circuit board 104 and the heat pipe 110. Heat generated in the solar cell 102 mounted on the circuit board 104 can be more smoothly transferred to the heat pipe 110, thereby maximizing the heat radiation effect. Here, a low melting point solder containing tin (Sn), indium (In), silver (Ag), copper (Cu), or the like may be used as the thermally conductive adhesive sheet 140. However, the present invention is not limited thereto.

The wire 130 is configured to connect a plurality of solar cells 102 spaced apart from each other at a predetermined interval in series or in parallel and to be energized with each other, and is preferably formed of a ribbon wire 30 that is not covered. This eliminates the need for a separate wire cover arrangement to protect conventional covered wires from off-axix sunlight, thereby simplifying overall configuration and assembly.

The ribbon wire 30 includes a length portion 32, a pair of step portions 34 extending downward from both sides of the length portion 32 and a pair of flange portions 36 extending from the step path 34 ).

The pair of flange portions 36 are connected to the circuit board 104 and can be attached to the circuit board 104 by soldering or the like and then the ribbon wire 30 is supported after being attached. That is, the ribbon wire 30 is attached to the circuit board 104 which is adjacent to and spaced from the pair of flange portions 36 by soldering, welding, or the like, I have. The ribbon wire 30 can be fixed in a more stable state by itself, and is preferably formed in the form of a plate having a predetermined width as a whole so as to have sufficient current carrying capability.

The ribbon wire 30 can maintain the state that the length portion 32 is spaced upward from the floor by a predetermined distance by the pair of flanges 36 and the pair of step portions 34, So that the overall construction and assembly can be simplified.

The solar cell assembly 100 includes a secondary lens 120 provided on the heat pipe 110 to cover the circuit board 104 and configured to condense solar light collected by the lens plate 20 into the solar cell 102 .

The secondary lens 120 includes a cover portion 122 covering the circuit board 104 and a cover portion 122 extending downward from the center portion of the cover portion 122 to guide light incident on the center portion of the cover portion 122 into the solar cell And a lens unit 124 that focuses the light onto the second lens 120. A predetermined space 126 may be formed in the secondary lens 120. [

The solar cell assembly 100 according to the present invention can protect the solar cell 102 and the circuit board 104 from the outside by the cover portion 122 of the secondary lens 120, And the circuit board 104. Therefore, it is possible to simplify the overall construction and assembly.

The secondary lens 120 may be made of a transparent material by one-body molding. Examples of the transparent material include glass, acrylic, methylmethacrylate, polymethylmethacrylate (PMMA), and PC Polycarbonate, PET (Poly Ethylene Terephthalate) and the like can be used.

Preferably, the heat pipe 110 has a groove 114 formed in the longitudinal direction thereof and the circuit board 104 is provided in the groove 114. Thus, it is easy to provide the secondary lens 120 on the circuit board 104.

The bottom part 123 of the cover part 122 is positioned on the upper surface of the heat pipe 110 so as to cover the solar cell 102 and the circuit board 104. [ And the bottom surface 125 of the lens portion 124 is in contact with the solar cell 102 at a minimum distance from the solar cell 102 as an outgoing surface through which sunlight incident on the lens portion 124 is emitted to the solar cell 102 The bottom surface 123 of the cover portion 122 and the bottom surface 125 of the lens portion 124 may be in contact with the circuit board 104 and the sun It is difficult to provide the secondary lens 120 on the heat pipe 110 and it is difficult to manufacture the secondary lens 120 as well . The bottom surface 125 of the lens portion 124 is formed to be closer to the bottom surface 123 of the cover portion 122 than the bottom surface 123 of the cover portion 122 and the circuit board 104 and the solar cell The bottom surface 125 of the lens unit 124 must be processed by a separate process so that the thickness of the bottom surface 125 of the lens unit 124 is shortened by the sum of the thicknesses of the lens units 124 and 102. However, if the groove 114 formed in the longitudinal direction of the heat pipe 110 is provided on the heat pipe 110 and the circuit board 104 is attached to the bottom surface of the groove 114, the manufacture of the secondary lens 120 And the secondary lens 120 can be easily provided on the circuit board 104.

The depth of the groove 114 is preferably deeper than the sum of the thickness of the circuit board 104 and the thickness of the solar cell 102. If the secondary lens 120 is placed on the circuit board 104 so that the bottom surface 123 of the cover portion 122 and the bottom surface 125 of the lens portion 124 are substantially horizontal, The bottom surface 123 of the lens portion 124 can be substantially in contact with the heat pipe 110 while the bottom surface 125 of the lens portion 124 can be brought into contact with the solar cell 102 with a minimum gap. If the bottom surface 123 of the lens portion 124 and the solar cell 102 are brought into contact with each other with a minimum distance in the case where the secondary lens 120 is provided on the circuit board 104, The secondary lens 120 can be coupled to the upper portion of the solar cell 102 without any additional configuration by attaching the bottom surface 125 of the lens portion 124 and the bottom surface 125 of the lens portion 124 using a transparent sealing material 103 such as silicone In addition, the solar cell 102 can be easily sealed.

On the other hand, the secondary lens 120 is provided with a second lens 120, which prevents the light, which is condensed by the lens plate 20 and is incident on the cover part 122, from entering the lens part 124, The side surface 127 may be further provided. The inner surface 127 may be optically designed to be coated or totally reflected so as to reflect light that is not incident on the lens portion 124, The majority of the components are obtained from off-axis light which is not incident on the lens module 124 and caused by the failure of the solar cell module 10 and the solar tracking device that keeps the sunlight in vertical condition So that damage can be prevented.

FIG. 9 is a view illustrating a state in which the solar cell assembly is coupled to the lower plate, and FIG. 10 is an exploded perspective view of the solar cell assembly and the lower plate.

9 and 10, a seating part 33 on which a heat pipe 110, which is elongated in the longitudinal direction, is installed is provided in the lower plate 30 in a longitudinal direction x. The seating part 33, A pair of seating part forming ribs 32 protruding from the upper part of the lower plate 30 may be formed to be long in the horizontal direction x.

Further, a radiating rib 31 may protrude from the lower portion of the lower plate 30.

Therefore, the highly-concentrated solar cell module 10 according to the present invention attaches the circuit board 104 on which the solar cell 102 is mounted to itself directly over the long heat pipe 110 having a heat dissipating function, The heat generated by the solar cell 102 is effectively dissipated to the large area by the heat pipe 110 because the heat pipe 110 is coupled directly to the lower plate 30 on which the heat dissipating ribs 31 are formed. It is possible to radiate heat to the outside more effectively by the lower plate 30 sequentially, and thus the heat radiating effect can be maximized.

The heat generated by the plurality of solar cells 102 arranged in the longitudinal direction of the heat pipe 110 is rapidly transferred to the heat pipe 110 through the heat pipe 110 before being transferred into the module 10. [ The heat transmitted to the lower plate 30 is transmitted to the heat dissipating rib 32 formed at the lower portion of the lower plate 30, It is possible to radiate heat to the outside more effectively.

The inner side surface of the seating part forming rib 32 may be formed with an inner side engagement step 34 for fixing the heat pipe 110 seated on the seating part 33. When the heat pipe 110 is forced into the seat 33 or the heat pipe 110 is coupled to the seat 33 in a state in which the lower plate 30 is slightly bent, It can be fixed in a state of being hooked on the inner engaging jaw 34. Therefore, the module 10 according to the present invention can easily attach and fix the solar cell assembly 100 to the lower plate 30 without a separate screw connection, thereby simplifying the overall construction and assembly.

A thermally conductive contact member sheet 70 made of a TIM (Thermal Interface Material) material may be interposed between the seat portion 33 and the heat pipe 110. [ The heat transferred to the heat pipe 110 can be more smoothly transmitted to the lower plate 30, thereby maximizing the heat radiation effect. Here, a low melting point solder containing tin (Sn), indium (In), silver (Ag), copper (Cu), or the like may be used as the thermally conductive adhesive sheet 70. However, the present invention is not limited thereto.

9, a plurality of solar cell assemblies 100 may be arrayed in the horizontal direction x on the seating portion 33 of the lower plate 30, a plurality of solar cell assemblies 100 arrayed at a predetermined interval in a longitudinal direction y are coupled to the plurality of solar cells 102 arranged in the arrayed solar cell assembly 100, Can be energized with each other by the renewal wire 130.

The lower plate 30 includes a plurality of piece lower plates 40 each having a predetermined width in the longitudinal direction y and arranged in the longitudinal direction y and coupled to the vertical plate 50, ≪ / RTI > A heat dissipating rib 31 is formed under each of the engraved lower plates 40. An engaging rib 35 for engaging with the adjacent engraved lower plate 40 is formed at both ends, At least one screw-engaging rib 36 and a pair of seat-seating ribs 32 may be formed. Although an embodiment in which one pair of seating portion forming ribs 32 are formed on one piece lower plate 40 is shown in the drawing, the present invention is not limited thereto, and a pair of seating portion forming ribs 32 At least two solar cell assemblies 100 arranged in the transverse direction (x) may be arranged in the longitudinal direction (y).

The rigidity can be improved by the heat dissipating ribs 31, the pair of seating portion forming ribs 32, the fitting ribs 35, the screw coupling ribs 36, The area of contact with the outside is widened by the rib 31, so that the heat generated in the closed frame can smoothly discharge the heat transferred to the engraved lower plate 40, and the engaging rib 35 can be screwed The engaging and assembling of the engraved lower plate 40 made of a thin plate material can be easily performed by the ribs 36. [

The highly concentrated solar cell module 10 according to the present invention may further include a fixing elastic member 60 coupled to the pair of seating part forming ribs 32 in a state of pressing the secondary lens 120 have.

The fixing elastic member 60 includes a body portion 62 and a pair of seating portion forming ribs 32 extending downward from both sides of the body portion 62 and being constrained to the outer projections 37 protruding from the outer surface of the pair of seating portion forming ribs 32 And a fitting hole 64 into which the upper portion of the secondary lens 120 is fitted when the pair of leg portions 66 and the pair of leg portions 66 are constrained to the outer projections 37. [ Therefore, when the pair of leg portions 66 are constrained to the outer projections 37, the fixing elastic member 60 has the secondary lens 120 (see FIG. 2) in a state where the body portion 62 is fitted in the fitting hole 64 Can be squeezed. Here, the fitting hole 64 is for allowing sunlight condensed in the lens plate 20 to be incident on the lens portion 124, and the upper portion of the secondary lens 120 inserted into the fitting hole 64 is approximately And becomes the center portion of the cover portion 122.

When the fixing elastic member 60 presses the secondary lens 120 in this way and simultaneously presses the heat pipe 110, the secondary lens 120 is fixed to the lower plate 30 And the heat pipe 110 can be more firmly fixed together with the secondary lens 120. The contact between the circuit board 104 and the heat pipe 110 and the contact between the heat pipe 110 and the lower plate 30 can be more tightened by the pressing of the fixing elastic member 60, It is possible to maximize it. The sunlight incident on the upper portion of the secondary lens 120 protruding from the fitting hole 64 of the fixing elastic member 60 is mostly incident on the lens portion 124 and condensed by the solar cell 102 On the other hand, off-axis light that is not incident on the lens 124 is blocked or reflected by the body portion 62 of the fixed elastic member 60, so that it is naturally off-axis It is possible to prevent the circuit board 104 from being damaged due to the light.

11 is a schematic plan view of a circuit board.

11, a solar cell 102 is mounted on a substantially central portion of a circuit board 104, and on the surface of the circuit board 104, two solar cells 102 that are not electrically connected to each other One of the two electrically conductive connections 105 and 106 is directly connected to the solar cell 102 and the other one is connected to the solar cell 102 by a lead wire 108, A by-pass diode 107 may be provided between the two electrically conductive connecting parts 105 and 106 and two electrically conductive connecting parts 105 and 106 may be provided with a ribbon wire 130 May be connected by being attached and bonded by a method such as soldering, welding, or the like. Therefore, a plurality of solar cells 102 spaced apart from each other by a predetermined distance can be energized with each other by the ribbon wire 130.

As described above, the present invention relates to a highly-concentrated solar cell module capable of easily arraying the lens plate in a precise position and improving the heat dissipation function and assemblability by a simple structure, It will be changeable. Accordingly, the present invention is not limited to the embodiments disclosed herein, and all changes which can be made by those skilled in the art are also within the scope of the present invention.

10: Highly-concentrated solar cell module 20: Lens plate array
21: Lens plate 22: Pattern part
30: lower plate 50: vertical plate
60: fixing elastic member 70, 140: thermally conductive contact member sheet
80: Support 90: Elastic member
100: solar cell assembly 102: solar cell
104: circuit board 110: heat pipe
120: secondary lens 130: ribbon wire

Claims (7)

A frame comprising a side plate and a lower plate;
A solar cell assembly having a solar cell and coupled to the lower plate;
A lens plate array in which a plurality of lens plates having at least one pattern portion for collecting incident light into the solar cell are arranged and coupled to the frame; And
And a support table for supporting the lens plate,
Wherein the side plate includes a transverse plate and a vertical plate longer than the transverse plate, and the vertical plate is formed with a support rib for supporting the support. The method according to claim 1,
Wherein the lens plate has a step formed at a lower portion of one side of the lens plate, and the supporting base is provided with a latching jaw for latching the stepped portion to align the position of the lens plate. 3. The method of claim 2,
And an inserting portion is formed on one side surface of the lens plate to insert a protrusion formed on one side surface of another adjacent lens plate. The method according to claim 1,
Wherein the highly concentrated solar cell module further comprises an elastic member for fixing the lens plate supported on the support to the support. The method according to claim 1,
The solar cell assembly includes:
A heat pipe extending in the transverse direction;
A circuit board on which the solar cell is mounted and attached to the heat pipe; And
And a wire for allowing the plurality of solar cells to be energized with each other,
Wherein a pair of seating part forming ribs are protruded in a longitudinal direction so that a seating part on which the heat pipe is seated is elongated in a transverse direction, and a heat dissipating rib is protruded from a lower part of the lower plate, Solar module. 6. The method of claim 5,
The solar cell assembly further includes a secondary lens provided on the heat pipe so as to cover the circuit board and configured to condense sunlight condensed on the lens plate with the solar cell,
Wherein the highly concentrated solar cell module further comprises a fixing elastic member coupled to the pair of seating portion forming ribs in a state of pressing the secondary lens. 6. The method of claim 5,
Wherein the wire is made of an uncoated ribbon wire,
The ribbon wire
A length having a predetermined width and length;
A pair of stepped portions extending downward from both sides of the length portion; And
And a pair of flange portions connected to the circuit board and extending from the step portion to support the ribbon wire.

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