CN204947980U - Photovoltaic array in a kind of modular water - Google Patents

Abstract

The utility model relates to a kind of modular optical photovoltaic array, belongs to solar-photovoltaic technology field.Photovoltaic array in a kind of modular water, buoyancy aid is preset the bindiny mechanism can extended in X, Y and Z tri-directions, solar module by Z-direction connector support and be fixed on every block buoyancy aid, form Independent Power Generation photovoltaic module, multiple Independent Power Generation photovoltaic module is interconnected to form photovoltaic array waterborne.The utility model structure is simple, the angle of solar module sensitive surface can be regulated as required by the adaptor in adjusting pole, use flexibly, applicability is strong, water can be put into again after modularization installation in land is in aggregates, avoid installation difficulty in water, save time, laborsaving, buoyancy aid can not collide each other.

Description

Photovoltaic array in a kind of modular water

Technical field

The utility model relates to a kind of modular optical photovoltaic array used on the water surface, belongs to solar-photovoltaic technology field.

Background technology

Solar photovoltaic generation system is installed on the water need to provide the buoyancy aid that photovoltaic module can be floated, the photovoltaic module installed on the water at present has two kinds of forms, one is photovoltaic module is separate with buoyancy aid, this kind of structure just installs buoyancy aid in the support bottom of the photovoltaic module of land installation simply, modularization can not be realized install, and due to supporting structure Heavy Weight, need larger buoyancy aid photovoltaic module could be floated, cause float structure huge, cause difficulty to application; And another kind of form be photovoltaic module and buoyancy aid integrally, photovoltaic module is attached on buoyancy aid, alleviate the weight of original photovoltaic module support, buoyancy aid is made not need just photovoltaic module to be floated very greatly, if China Patent No. 201310048905.1 " a kind of photovoltaic generating system floating platform waterborne " is exactly be directly installed on by photovoltaic module on floating platform (i.e. buoyancy aid), but there is following problem: first, because inclination angle is directly made on floating platform, different regions are needed on floating platform, process different inclination angles, causes poor for applicability; The second, fixed light photovoltaic assembly adopts and on floating platform, processes slot realize, and one is that slot difficulty of processing is large, and two are slots is plastic materials, and its intensity is less, easily ruptures, and causes photovoltaic module to depart from floating platform; 3rd, owing to being that photovoltaic module is directly placed on floating platform, being easy to cause the water soaking photovoltaic module entered on floating platform, making the photovoltaic module lost of life; 4th, because the connection between floating platform is by groove each other and the projection Hard link coordinating formation alternating between negative and positive, cause when photovoltaic array run into lack of water fall into shoal time, due to the injustice in water-bed portion, when photovoltaic module sinks to water-bed portion, the connection fracture causing photovoltaic module middle each other.

Summary of the invention

The purpose of this utility model is exactly modularization and its firm reliability technical problem that will solve installation solar energy solar module waterborne, and photovoltaic module angle can adjust arbitrarily, and photovoltaic array connects each other and can not rupture.

In order to realize above object, the technical solution adopted in the utility model is:

Photovoltaic array in a kind of modular water, photovoltaic array in a kind of modular water, the photovoltaic array be made up of polylith solar module is arranged on buoyancy aid, it is characterized in that described buoyancy aid being preset with the bindiny mechanism can extended in X, Y and Z tri-directions, solar module by Z-direction connector support and be fixed on every block buoyancy aid, form Independent Power Generation photovoltaic module, multiple Independent Power Generation photovoltaic module is interconnected to form photovoltaic array waterborne.

The edge of buoyancy aid is provided with the journal stirrup of band installing hole, and this journal stirrup is split type or integral type.

On buoyancy aid, the connector of Z-direction comprises support bar, adaptor and locking member, and solar module is arranged on support bar by tight latch fitting and adaptor.Support bar is hollow structure, lays the conductor cable connecting solar module in it.

The X that buoyancy aid is preset and the connector of Y-direction are screw thread, chain and/or pin connector.

The upper surface of buoyancy aid has anti-skidding ripple, and lower surface is provided with balance groove, and buoyancy aid edge is also provided with the connecting groove of solar module.

The X that buoyancy aid is preset is connected with built-in beam with the connector of Y-direction, and adjacent photovoltaic module connects into photovoltaic array waterborne by built-in beam, is provided with the connecting groove putting solar module conductor cable in built-in beam.

Locking member in the connector of buoyancy aid Z-direction is made up of briquetting and stay, and solar module is fixed between briquetting and stay, and stay connects support bar by adaptor, is regulated the light angle of solar module by adaptor.

Adaptor is side is leg-of-mutton flanging matrix channel-section steel, and stay is fixed in the concave groove of adaptor, adjusts the angle between solar module and support bar by adaptor.

Adaptor and tight locking plate are L shape, being connected with adaptor of the tight locking plate of L shape, and another side connects compressing tablet, and this compressing tablet is zigzag, and it is provided with solar module.

The cable of solar module is put in guard tube, increases the reliability used.

Photovoltaic module is fixed on the spud pile in water-bed face by rope.

The built-in beam be arranged on buoyancy aid be C shape steel or other can bolted section bar, include horizontal built-in beam and longitudinal built-in beam, horizontal built-in beam and longitudinal built-in beam are bolted.

Buoyancy aid can be hollow closed floating drum also can be solid floating block, and material is the material that plastic cement or other buoyancy are good.

The beneficial effect that the utility model produces: preset X on buoyancy aid, the connector in Y and Z tri-directions, solar module Fast Modular blocking installation on land can be made, and the connector in Z-direction both can as the support of solar module, its support bar is the conductor cable that hollow structure may be used for placing solar module, the angle of solar module sensitive surface can be regulated as required by the adaptor in adjusting pole, structure is simple, use flexibly, applicability is strong, water can be put into again after modularization installation in land is in aggregates, avoid installation difficulty in water, save time, laborsaving, buoyancy aid can not collide each other.And connected mode is convenient flexibly between Independent Power Generation photovoltaic module, make photovoltaic array in the water surface flexible adaptation of fluctuation, if when running into anhydrous shoal simultaneously, the uneven bottom can be adapted to, can not cause and connect fracture.Consist of the power station of whole large-scale photovoltaic array array module, realize modularized design and installation, flexibility and standardization are all strengthened, and decrease manufacturing cost, reduce cost of electricity-generating, shortening payoff period, having very big good effect to applying.

Accompanying drawing explanation

Fig. 1: the overall structure schematic diagram of photovoltaic array and embodiment 1 schematic diagram in modular water of the present utility model.

The structural representation of photovoltaic module waterborne in Fig. 2: Fig. 1.

The cross-sectional view of photovoltaic module waterborne shown in Fig. 3: Fig. 2.

In Fig. 1 to Fig. 3, photovoltaic module waterborne is made up of solar module 1, buoyancy aid 3, support bar 4, adaptor 5 ', stay 5 and briquetting 6, buoyancy aid 3 has pre-buried attaching nut 2-1 and slide fastener ring 2-2, the lower end of support bar 4 screws in attaching nut 2-1, adaptor 5 ' is installed in the upper end of support bar 4, on stay 5 ' ' be arranged on adaptor 5 ' upper and can the anglec of rotation, briquetting 6 is arranged on stay 5 ' ', and with stay 5 ' ' together with solar module 1 is clamped.

Fig. 4: the schematic diagram being the utility model embodiment 2.

In Fig. 4, solar module 1 is rack-mount, support bar 4 is arranged on longitudinal built-in beam 2 ', longitudinal built-in beam 2 ' is fixed on horizontal built-in beam 2, buoyancy aid 3 is arranged on horizontal built-in beam 2, and whole photovoltaic array module is fixed on spud pile 11 by rope 12, and the cable 10 that photovoltaic array is drawn accesses in header box 8, header box 8 is received on inverter 9 by cable, then is accessed on electrical network 13 by inverter 9.

B portion enlarged diagram in Fig. 5: Fig. 4.

A-A generalized section in Fig. 6: Fig. 4.

In Fig. 5,6, the journal stirrup 3-1 of buoyancy aid 3 is fixed on horizontal built-in beam 2, longitudinal built-in beam 2 ' is connected on horizontal built-in beam 2 by bolt, support bar 4 is bolted on longitudinal built-in beam 2 ' by adaptor 5, upper rack posts 4 ' is bolted on support bar 4 by adaptor 5, and solar module 1 is fixed on upper rack posts 4 ' by briquetting 6.

Fig. 7: the structural representation of the first structure of buoyancy aid 3 of the present utility model.

Fig. 8: be in Fig. 6 C to structure schematic diagram.

In Fig. 7,8, four end corner edge of the upper surface of buoyancy aid 3 are extruded with journal stirrup 3-1, and journal stirrup 3-1 has connecting hole, and the upper surface of floating block 3 is anti-skidding ripple 3-2, and the lower surface of buoyancy aid 3 is processed with balance groove 3-3, and being communicated with balance groove 3-3 has shallow slot 3-4 to edge.

Fig. 9: the structural representation of the second structure of buoyancy aid 3 of the present utility model.

In Fig. 9, the journal stirrup 3-1 of buoyancy aid 3 is strip, and runs through whole edge, and strip journal stirrup 3-1 can be processed with several connecting holes.

Figure 10: the structural representation of adaptor 5 of the present utility model.

In Figure 10, adaptor 5 for side be the standard component of leg-of-mutton flanging matrix channel-section steel, when support bar 4 is connected with longitudinal built-in beam 2 ', bottom surface connecting hole 5-2 is connected with longitudinal built-in beam 2 ', side connecting hole 5-1 is connected with support bar 4, when upper rack posts 4 ' is connected with support bar 4, bottom surface connecting hole 5-2 is connected with upper rack posts 4 ', and side connecting hole 5-1 is connected with support bar 4.

Figure 11: the structural representation of briquetting 6 of the present utility model.

In Figure 11, briquetting 6 is in zigzag, and the upper tongue limit 6-1 of briquetting 6 pushes down the edge of solar module 1, and following groove 6-3 blocks two lateral surfaces of upper rack posts 4 ', and middle connecting hole 6-2 connects upper rack posts 4 ', is fixed on upper rack posts 4 ' by solar module 1.

Figure 12: the structural representation of connecting plate 7 of the present utility model.

In Figure 12, connecting plate 7 is strip-shaped steel plate, and the connecting hole 7-1 on strip-shaped steel plate 7 is used for being connected with horizontal built-in beam 2 with longitudinal built-in beam 2 '.

Figure 13: the cabling connection diagram of embodiment 2 of the present utility model.

Figure 14: the electrical connection schematic diagram of embodiment 2 of the present utility model.

Figure 15: the structural representation of embodiment 3 of the present utility model.

D portion enlarged diagram in Figure 16: Figure 13.

In Figure 16, the horizontal built-in beam 2 of two adjacent photovoltaic array modules is connected with longitudinal built-in beam 2 ' by connecting plate 7.

Figure 17: the electrical connection schematic diagram of embodiment 3 of the present utility model.

Embodiment

Embodiment 1

See Fig. 1 to Fig. 3, photovoltaic array in modular water in the present embodiment, the photovoltaic array be made up of polylith solar module is arranged on buoyancy aid, buoyancy aid is preset with the bindiny mechanism can extended in X, Y and Z tri-directions, solar module by Z-direction connector support and be fixed on every block buoyancy aid, form Independent Power Generation photovoltaic module, multiple Independent Power Generation photovoltaic module is interconnected to form photovoltaic array waterborne.The peak power of solar module 1 is 255Wp, operating voltage 30.8V, open circuit voltage 37.6V, operating current 8.28A, short circuit current 8.96A, buoyancy aid 3 is the solid floating block of strip plastic cement PET, there is thickness to be less than the journal stirrup 3-1 of middle part in the two edges of the length direction of buoyancy aid 3, on the journal stirrup 3-1 of both sides, each interval is furnished with the built-in fitting of three slide fastener ring 2-2 and two attaching nut 2-1, one of them slide fastener ring 2-2 is positioned at middle part, the two ends of support bar 4 has the external screw thread coordinated with attaching nut 2-2, support bar 4 has four, adaptor 5 ' is L shape stainless steel flanging part, one side is connected with support bar 4, one side and latch segment 5 ' ' be connected, latch segment 5 ' ' be also L shape stainless steel flanging part, one side is longer, one side is shorter, short and adaptor 5 ', long face is connected with briquetting 6, briquetting 6 is Z-shaped aluminium section bar, one end face and latch segment 5 ' ' be connected.

Four support bar 4 lower ends screw on four attaching nut 2-1 on buoyancy aid 3 respectively, after adjusting the length of support bar 4, from below again with other nut check, in case support bar 4 play, with two nuts, the horizontal plane of adaptor 5 ' is fixedly clamped on support bar 4 in the upper end of support bar 4, the vertical plane of adaptor 5 ' upward, latch segment 5 ' ' vertical plane down, with the vertical plane of adaptor 5 back-to-back, be joined with bolts after adjusting the inclination angle of stay 5, the lower horizontal plane of briquetting 6 is connected with bolt with the horizontal plane of adaptor 5, according to angle of inclination, the setting height(from bottom) calculating the briquetting 6 of two support bars 4 is poor, solar module 1 is placed in the middle of the upper horizontal plane of briquetting 6 and the horizontal plane of stay 5, the thickness of solar module 1 should slightly larger than the height in the center vertical face of briquetting 6, make stay 5 can clamp solar module 1.The X that buoyancy aid is preset and the connector of Y-direction are screw thread, chain and/or pin connector, and also can be that other can play the connector of connection function, the support bar of Z-direction be hollow-core construction, can place the conductor cable connecting solar module in it.The connecting groove of solar module also can be arranged on the edge of buoyancy aid 3.

On module-type water, photovoltaic array is arranged on Shenzhen area, solar module 1 south dip 22.5 °, adopt 10 pieces of solar modules 1 altogether, laterally five row, longitudinally two rows, adjacent one body swimming is connected on the slide fastener ring 2-2 of buoyancy aid 3 by chain 7 between solar module, on the slide fastener ring 2-2 of longitudinal chain 7 centerlock, horizontal chain 7 is fixed on the slide fastener ring 2-2 at edge, rope 8 is pulled in middle slide fastener ring 2-2 and is fixed on water-bed blind rivet ring, 10 pieces of solar module series connection, after series connection, power is 2.55kWp, operating voltage 308V, open circuit voltage 376V, then a 3kW photovoltaic combining inverter is connected to, its parameter is: MPPT scope 250-560, maximum direct voltage input range is 600V, maximum DC input power 3kW, then electrical network is connected by inverter, form photovoltaic plant waterborne.

Embodiment 2

See Fig. 4 to Figure 13, the photovoltaic array module waterborne of the present embodiment to be a gross power be 5kWp, solar module 1 adopts peak power to be 255Wp, every block operating voltage 30.8V, open circuit voltage 37.6V, operating current 8.28A, short circuit current 8.96A, photovoltaic array module adopts solar module 20 pieces altogether, wherein 10 pieces of series connection are one group, after series connection, power is 2.55kWp, operating voltage 308V, open circuit voltage 376V, two groups of gross powers are 5.1kWp, 10 pieces one group is connected to a 5kW photovoltaic combining inverter carries out in parallel with another 10 pieces one group, its parameter is: MPPT scope 250-560, maximum direct voltage input range is 600V, maximum DC input power 5.5kW, then electrical network 13 is connected by inverter 9, form grid-connected photovoltaic system.

The buoyancy aid 3 of the present embodiment makes solid floating block for plastic material, four journal stirrup 3-1 are extruded with at four vertex angle parts of buoyancy aid 3, journal stirrup 3-1 is projected into the outward flange of buoyancy aid, the upper surface of buoyancy aid 3 is anti-skidding ripple 3-2, lower surface is middle part is balance groove 3-3, the shallow slot 3-4 lower than balance groove 3-3 is had to lead to the outward flange of lower surface in four middle parts, limit of balance groove 3-3, built-in beam is C-type steel, in two sides, length direction has inner groovy, built-in beam comprises horizontal built-in beam 2 and longitudinal built-in beam 2 ', support selects same C-type steel with built-in beam, support comprises upper rack posts 4 ' and support bar 4, adaptor 5 for side be leg-of-mutton flanging matrix channel-section steel, when support bar 4 is connected with longitudinal built-in beam 2 ', bottom surface connecting hole 5-2 is connected with longitudinal built-in beam 2 ', side connecting hole 5-1 is connected with support bar 4, when upper rack posts 4 ' is connected with support bar 4, bottom surface connecting hole 5-2 is connected with upper rack posts 4 ', side connecting hole 5-1 is connected with support bar 4, briquetting 6 is zigzag, the upper tongue limit 6-1 of briquetting 6 pushes down the edge of solar module 1, following groove 6-3 blocks the two sides of the C-type steel of upper rack posts 4 ', middle connecting hole 6-2 connects upper rack posts 4 ', solar module 1 is fixed on upper rack posts 4 '.The connecting groove putting solar module conductor cable is provided with in horizontal and/or longitudinal built-in beam, the positive and negative electrode lead-in wire 1-1 of solar photovoltaic assembly 1 is incorporated into and is fixed in longitudinal wire casing 14 ' of longitudinal built-in beam 2 ', after being connected by the cable 10 in guard tube 10-1, from the port outgoing cable 10 of longitudinal wire casing 14 ', cable 10 is connected with the cable 10 in the horizontal wire casing 14 being fixed on horizontal built-in beam 2 again, after gathering, by wire casing cabling under water, be connected on header box.Connecting groove in built-in beam is can the C shape wire casing of buckle closure.

When installing on land, the lower surface of the journal stirrup 3-1 on buoyancy aid 3 both sides is placed on respectively on two horizontal built-in beams 2, and be fixed by bolts on horizontal built-in beam 2, eight buoyancy aids 3 placed by two horizontal built-in beams 2, have five groups, eight longitudinal built-in beams 2 ' ride on five groups of horizontal built-in beams 2, and be fixed by bolts on horizontal built-in beam 2, every two longitudinal built-in beams 2 ' a group, place five pieces of solar modules 1 above, five pieces of solar modules 1 are fixed on upper rack posts 4 ' by briquetting 6, upper rack posts 4 ' is connected with support bar 4 by adaptor 5, support bar 4 is connected with longitudinal built-in beam 2 ' by another adaptor 5, after land installs, photovoltaic array module is put into water, horizontal built-in beam 2 is tied with four ropes 12, rope 12 is fixed on the cement spud pile 11 in water-bed portion, header box 8 and inverter 9 are placed on bank, solar module cable 10 is guided to bank and is linked in header box 8 from bottom, header box 8 is linked into inverter 9 by cable 10, be linked on neighbouring public electric wire net 13 by inverter 9.

The present embodiment is arranged on as a photovoltaic array module whole and completes on the bank, is putting into water, therefore greatly reduce underwater work amount after installation.

Embodiment 3

The present embodiment is 1MW photovoltaic plant project waterborne, is installed on certain reservoir water surface, adopts piecemeal generating, concentrates connect-in strategy, then access 0.38kV public electric wire net 13 side through inverter 9.

The present embodiment adopts the photovoltaic array module of embodiment 1, totally 200 photovoltaic array modules, longitudinally arrangement 20 photovoltaic array modules, laterally arrangement 10 photovoltaic array modules, connecting plate 7 is adopted to be connected between each photovoltaic array module, connecting plate 7 is strip-shaped steel plate, and the horizontal built-in beam 2 of adjacent each module and the termination of longitudinal built-in beam 2 ' couple together by connecting plate 7, and inverter 9 inverter 9 that employing 200 embodiments 1 are same equally forms 1MW photovoltaic generating system.

The technical scheme that native system adopts distributed generation, centralized control, single-point grid-connected, system is divided into 200 unit that generate electricity by way of merging two or more grid systems, 1# to 200# generator unit is made up of solar module, combining inverter, step-up transformer etc.

Multiple photovoltaic system is independent separately, and be convenient to realize step and control, to improve the operational efficiency of system owing to being multiple subsystems, system redundancy is high, is unlikely to because certain inverter breaks down and causes whole system to paralyse; Do not affect most system cloud gray model during local fault maintenance, be conducive to engineering branch and implement.

Claims (10)

1. photovoltaic array in a modular water, the photovoltaic array be made up of polylith solar module is arranged on buoyancy aid, it is characterized in that described buoyancy aid being preset with the bindiny mechanism can extended in X, Y and Z tri-directions, solar module by Z-direction connector support and be fixed on every block buoyancy aid, form Independent Power Generation photovoltaic module, multiple Independent Power Generation photovoltaic module is interconnected to form photovoltaic array waterborne.

2. photovoltaic array in modular water as claimed in claim 1, it is characterized in that the edge of described buoyancy aid is provided with the journal stirrup of band installing hole, this journal stirrup is split type or integral type.

3. photovoltaic array in modular water as claimed in claim 1, it is characterized in that the connector of described Z-direction comprises support bar, adaptor and locking member, solar module is arranged on support bar by tight latch fitting and adaptor.

4. photovoltaic array in modular water as claimed in claim 3, is characterized in that described support bar is hollow structure, lays the conductor cable connecting solar module in it.

5. photovoltaic array in modular water as claimed in claim 1, is characterized in that the connector of X and the Y-direction that described buoyancy aid is preset is screw thread, chain and/or pin connector.

6. photovoltaic array in the modular water as described in claim 1-5 any one, it is characterized in that the upper surface of described buoyancy aid has anti-skidding ripple, lower surface is provided with balance groove, and buoyancy aid edge is also provided with the connecting groove of solar module.

7. photovoltaic array in the modular water as described in claim 1 or 5, it is characterized in that the X that described buoyancy aid is preset is connected with built-in beam with the connector of Y-direction, adjacent photovoltaic module connects into photovoltaic array waterborne by built-in beam, is provided with the connecting groove putting solar module conductor cable in built-in beam.

8. photovoltaic array in modular water as claimed in claim 3, it is characterized in that the locking member in the connector of described buoyancy aid Z-direction is made up of briquetting and stay, solar module is fixed between briquetting and stay, stay connects support bar by adaptor, is regulated the light angle of solar module by adaptor.

9. photovoltaic array in modular water as claimed in claim 8, it is characterized in that described adaptor be side is leg-of-mutton flanging matrix channel-section steel, stay is fixed in the concave groove of adaptor, adjusts the angle between solar module and support bar by adaptor.

10. photovoltaic array in modular water as claimed in claim 8, it is characterized in that described adaptor and tight locking plate are L shape, being connected with adaptor of the tight locking plate of L shape, another side connects compressing tablet, and this compressing tablet is zigzag, and it is provided with solar module.