CN205378614U - Ecological big -arch shelter of photovoltaic and supporting rack thereof - Google Patents

Abstract

The utility model provides an ecological big -arch shelter of photovoltaic and supporting rack thereof, it can be according to the altitude mixture control photovoltaic module's of the plant of different kinds or different growth phases height. A supporting rack of the ecological big -arch shelter of photovoltaic, including be used for installing the stand of subaerial formation supporting with connect in the upper end of stand is used for installing the frame of photovoltaic module unit, the stand include the flexible cover of stand, slidable ground connect in the stand telescopic link of the flexible cover of stand, the flexible cover of stand the draws of stand telescopic link in the two frame attach and another person are used for installing subaerial. Preferably, the stand still including set up in the flexible cover of stand with hydraulic drive mechanism between the stand telescopic link.

Description

A kind of photovoltaic Ecological Greenhouse and bearing support thereof

Technical field

This utility model relates to a kind of photovoltaic ecosphere, particularly to a kind of photovoltaic Ecological Greenhouse and bearing support thereof.

Background technology

At present, solar photovoltaic assembly is applied to absorbing solar energy and being converted into electric energy.And in order to improve land utilization ratio, below solar photovoltaic assembly, understand the plants such as Planting Crops, flowers, Chinese herbal medicine, or cultivate domestic birds and animals Aquatic product etc..And the growing height of difference plant is different, the height of each different growth steps of plant is also different, if according to the height of the altitude mixture control photovoltaic module of vegeto-animal variety classes or different growth phases, then plant growing can also can be more conducive to.

Utility model content

For the problems referred to above, the purpose of this utility model is to provide a kind of photovoltaic Ecological Greenhouse and bearing support thereof, and it can according to the height of the altitude mixture control photovoltaic module of variety classes or the plant of different growth phases.

For solving above-mentioned technical problem, the technical solution adopted in the utility model is:

A kind of bearing support of photovoltaic Ecological Greenhouse, including for installing the column forming supporting on the ground and being connected to the upper end framework for installation photovoltaic component unit of described column, described column includes vertical column expanding set, be slidably connected to the vertical column expanding bar of described vertical column expanding set, one in described vertical column expanding set, described both vertical column expanding bars and described framework connects and another one is for installing on the ground.

Preferably, described column also includes being arranged at the hydraulic drive mechanism between described vertical column expanding set and described vertical column expanding bar.

It is highly preferred that described hydraulic drive mechanism is hydraulic jack.

Preferably, the upper end of described vertical column expanding bar and described framework are fixed and are connected, and the height of described vertical column expanding bar upper end is 3～10m.

Preferably, described column is multiple and is intervally arranged in array.

The another technical scheme that this utility model adopts is:

A kind of photovoltaic Ecological Greenhouse, including bearing support as above and the photovoltaic module unit being arranged on described bearing support upper end.

This utility model adopts technique scheme, have the advantage that column is Telescopic shaft type compared to existing technology, can according to the height adjusting column upper end of the high degree of adaptability of plant, thus adjusting the height of photovoltaic module, keep photovoltaic module distance plant tip to have a segment distance all the time, do not affect plant growing.

Accompanying drawing explanation

Fig. 1 is the perspective view of photovoltaic Ecological Greenhouse of the present utility model；

Fig. 2 is the top view of photovoltaic Ecological Greenhouse of the present utility model；

Fig. 3 is the fragmentary front view of photovoltaic Ecological Greenhouse of the present utility model；

Fig. 4 is the connection diagram at A place in Fig. 3；

Fig. 5 is the partial side elevation view of photovoltaic Ecological Greenhouse of the present utility model；

Fig. 6 is the connection diagram at A place in Fig. 5；

Fig. 7 is photovoltaic module unit of the present utility model schematic diagram after folding；

Fig. 8 is photovoltaic module unit of the present utility model schematic diagram after deployment；

Fig. 9 is the structural representation of transmission mechanism of the present utility model；

Figure 10 is chute schematic diagram of the present utility model；

Figure 11 is the metal contact of the present utility model operating diagram in chute；

Figure 12 is the module diagram of control device of the present utility model；

Figure 13 is the flow chart of control method of the present utility model.

In above-mentioned accompanying drawing:

1, bearing support；11, column；111, vertical column expanding set；112, vertical column expanding bar；113, the hydraulic drive mechanism of column；12, cross slide way；120, horizontal guide groove；13, longitudinal rail；130, longitudinal guide groove；14, assembly placement；15, supply unit；

16, chute；160, the second contact；161, guiding surface；162, guiding surface；17, the second wire；170, the second union joint；

2, photovoltaic module unit；20, photovoltaic module；21, support；

210, insulation crust；211, metal contact；2110, the first contact；212, the first wire；213, the first union joint；214, stage clip；

22, lower supporter；220, slide block；23, telescope support；231, support telescopic；232, support expansion link；233, the hydraulic drive mechanism of telescope support；

3, assembly stacks warehouse；

4, maintenance storehouse；

5, actuating device；51, the first transportation section；52, the second transportation section；53, the 3rd transportation section；54, assembly lift mechanism；

60, controller；61, environment detector；62, third party's data platform；63, soil moisture detector.

Detailed description of the invention

Advantage of the present utility model and feature below in conjunction with accompanying drawing, preferred embodiment of the present utility model be described in detail, so that can be easier to be understood by those skilled in the art.

Referring to shown in Fig. 1 to Figure 12, a kind of photovoltaic Ecological Greenhouse, stacks warehouse 3 including bearing support 1, the photovoltaic module unit 2 being located at bearing support 1 upper end, the assembly that is located at bearing support 1 side, is located at assembly and stacks the maintenance storehouse 4 of warehouse 3 side, for transporting the actuating device 5 of photovoltaic module unit 2.

Bearing support 1,11, one, the column including the arrangement of multiple arrays is fixedly connected on the framework of all column 11 upper ends.Column 11 is Telescopic shaft type, that is, each column 11 includes vertical column expanding set 111 respectively, can slide up and down to be connected to the vertical column expanding bar 112 of vertical column expanding set 111 and be located at the hydraulic drive mechanism 113 (such as hydraulic jack etc.) for driving the relative column telescopic 111 of vertical column expanding bar 112 to slide up and down between vertical column expanding set 111 and vertical column expanding bar 112.The lower end of vertical column expanding set 111 fixedly mounts and forms the fixing connection of stable support, the upper end of vertical column expanding bar 112 and framework on the ground.Framework includes multiple cross slide way 12 longitudinally arranging at equal intervals and extending transversely respectively and multiple longitudinal rail 13 transversely arranging at equal intervals and extending longitudinally respectively, multiple cross slide waies 12 and multiple longitudinal rail 13 intersect and form the rectangular frame unit of multiple arrays arrangement, the frame unit of part is as the assembly placement 14 for installation photovoltaic component, other frame unit then as the supply unit 15 of transfer passage constituting photovoltaic module unit, between two assembly placement 14 of arbitrary neighborhood all between be separated with a supply unit 15.Assembly placement 14 is provided with and carries out being mechanically connected with photovoltaic module unit and/or the bindiny mechanism of electric power transmission, transmission mechanism as mentioned below.Supply unit 15 is provided with the bindiny mechanism being slidingly fitted with the first transportation section hereinafter described, horizontal guide groove as mentioned below and longitudinal guide groove etc..

Photovoltaic module unit 2 includes support 21 and is located at the photovoltaic module 20 of support 21 upper end.Photovoltaic module 20 adopts double; two glass photovoltaic module, and the Main Function of photovoltaic module 20 is to convert solar energy into electrical energy after the solar battery sheet of photovoltaic module 20 is exposed to sunlight, and electric energy is carried by the rosette of photovoltaic module.Support 21 includes lower supporter 22 and the telescope support 23 being arranged on lower supporter 22, telescope support 23 is arranged at a sidepiece of lower supporter 22, one sidepiece of photovoltaic module 20 is connected with a sidepiece of telescope support 23, and the other side of photovoltaic module 20 is connected with the other side of lower supporter 22.

Lower supporter 22 and framework connect with being slidably matched.Specifically, cross slide way 12 is offered the horizontal guide groove 120 extended transversely, longitudinal rail 13 offers the longitudinal guide groove 130 extended longitudinally, at the infall of cross slide way 12 and longitudinal rail 13, the i.e. drift angle place of each frame unit, horizontal guide groove 120 and longitudinal guide groove 130 are interconnected.The bottom of lower supporter 22 has the slide block 220 matched with horizontal guide groove 120 and longitudinal guide groove 130, described slide block 220 is plugged in horizontal guide groove 120 or longitudinal guide groove 130 slidably, and can enter in the horizontal guide groove 120 of longitudinal guide groove 130/ from the longitudinal guide groove 130 of horizontal guide groove 120/ at the infall of cross slide way 12 and longitudinal rail 13.

Telescope support 23 includes support telescopic 231, can slide up and down to be connected to support telescopic 231 support expansion link 232 and the hydraulic drive mechanism 233 (such as hydraulic jack etc.) being arranged between support telescopic 231 and support expansion link 232, hydraulic drive mechanism 233 driving arm expansion link 232 opposite brackets telescopic 231 slides up and down.The lower end of support telescopic 231 and the fixing connection of lower supporter 22, the upper end of support expansion link 232 and the frame of photovoltaic module 20 are flexibly connected, and specifically, the upper end of support expansion link 232 and the frame of photovoltaic module 20 slidably and rotatably connect.When support expansion link 232 stretches out, an above-mentioned sidepiece lifting of photovoltaic module 20, photovoltaic module 20 is obliquely installed, as shown in Figure 8；When support expansion link 232 is return, the above-mentioned side subordinate of photovoltaic module 20 drops, and photovoltaic module 20 is close to lower supporter 22, and photovoltaic module unit 2 is in folded state, as it is shown in fig. 7, consequently facilitating stack in warehouse 3 at assembly and stack, save space.The present embodiment preferably employs two grades of telescope supports, namely support expansion link 232 also can slide up and down to be connected to secondary stent expansion link, it is provided with the 2-level hydraulic driving mechanism driving secondary stent expansion link opposite brackets expansion link 232 to slide up and down between secondary stent expansion link and support expansion link 232, so can increase the stroke sliding up and down adjustment.

Photovoltaic module unit 2 also includes the transmission mechanism for being transferred out by the electric energy that photovoltaic module 20 produces being located at support 21 bottom.Shown in Fig. 9-11, transmission mechanism includes the insulation crust 210 being fixedly installed on the hollow of support 21 bottom, the metal contact 211 being movably disposed in insulation crust 210.One end of metal contact 211 has the first contact 2110, the other end and the first wire 212 be electrically connected.One end of insulation crust 210 offers and is available for the through hole that the first contact 2110 is stretched out, the other end offers the through hole passed for the first wire 212.The elastic component driving metal contact 211 opposing insulation shell 210 to slide it is provided with between metal contact 211 and insulation crust 210, specifically, fixing connection one fastening ring plate on the above-mentioned other end of insulation crust 210, the stage clip 214 of driving metal contact 211 action it is provided with between the above-mentioned other end and the metal ring plate of metal contact 211, stage clip 214 is compressive state, stretches out offer elastic force for the first contact 2110.The one end of the first wire 212 is fixedly connected with the first union joint 213, and the first union joint 213 offers screw thread, and the above-mentioned other end of metal contact 211 offers the screwed hole matched, and the first union joint 213 is connected with metal contact 211 by screw thread.The other end of first wire 212 and the rosette of photovoltaic module 20 are electrically connected.On cross slide way 12 and/or longitudinal rail 13, compartment of terrain is provided with multiple chute 16 matched with metal contact 211.The bottom land of chute 16 is provided with the second contact 160 matched with the first contact 2110.Specifically, one end and second union joint 170 of one second wire 17 are fixedly connected, second union joint 170 offers screw thread, second union joint 170 is connected by screw thread and cross slide way 12 and/or longitudinal rail 13, and second the end of union joint 170 extend the bottom land place of chute 16, second contact 160 and the second union joint 170 are electrically connected, and the other end and the external electrical network of the second wire 17 connect.The above-mentioned one end of metal contact 211 is inserted in chute 16 slidably, and when the first contact 2110 and the second contact 160 contact conducting, photovoltaic module unit 2 is installed and put in place, namely arrives the assembly placement specified.

Being provided with guiding surface 161,162 in chute 16, guiding surface 161,162 is sentenced the mode being gradually distance from support 21 and is tilted to extend from the end of chute 16 to the second contact 160.Guiding surface 161,162 is two and lays respectively at the opposite sides of the second contact 160.Along with photovoltaic module unit 2 slides on cross slide way 12 or longitudinal rail 13, metal contact 211 is inserted in chute 16, and under the effect of the guiding surface 161 of side, stage clip 214 discharges gradually, promoting metal contact 211 to slide in and out, to when moving to the second 160 place, contact, the first contact 2110 mutually pushes against with the second contact 160 and contacts to turn on realization electrical connection, photovoltaic module unit 2 is installed and is put in place, by the electric energy output that photovoltaic module 20 is produced by first wire the 212, second wire 17；When needs remove photovoltaic module unit 2, photovoltaic module unit 2 continues to move to along cross slide way 12 or longitudinal rail 13, and under the effect of the guiding surface 162 of opposite side, metal contact 211 bounces back in insulation crust 210 gradually, and stage clip 214 is compressed.

Assembly stacks warehouse 3, is arranged on the ground of photovoltaic Ecological Greenhouse side, is used for depositing photovoltaic module unit 2, it is simple to supplements photovoltaic module unit 2 to photovoltaic Ecological Greenhouse or is reclaimed by unnecessary photovoltaic module unit 2.After photovoltaic module unit 2 is folding, ranked and stacked pile stacks in warehouse 3 at assembly, reduces storage volume, saves warehouse space.

Maintenance storehouse 4, is arranged in assembly and stacks on the ground of warehouse 3 side, and the photovoltaic module unit 2 for regaining fault keeps in repair.

Actuating device 5 is made up of assembly conveying mechanism and assembly lift mechanism 54.Specifically, to be positioned at the frame unit at a framework wherein drift angle place as up/down material point, conveying mechanism includes the 51, second transportation section, the first transportation section 52 and the 3rd transportation section 53, first transportation section 51 stacks warehouse 3 from assembly and extends to the underface of up/down material point, second transportation section 52 is arranged on each supply unit 15 of framework and each supply unit 15 and up/down material point is interconnected, and the 3rd transportation section 53 extends to the underface of up/down material point from maintenance storehouse 4.Assembly lowering or hoisting gear is arranged on the lower section of up/down material point for the photovoltaic module on the first transportation section 51 being delivered to up/down material point or the photovoltaic module of up/down material point being delivered to the first transportation section 51 or the second transportation section 52.51, second transportation section 52, first transportation section of conveyer device and the 3rd transportation section 53 adopt belt conveyor of the prior art or chain conveying mechanism etc., assembly lowering or hoisting gear adopts pneumatically or electrically hoistable platform of the prior art etc., is not described in detail at this.

Control device is stacked warehouse 3, maintenance storehouse 4, actuating device 5, the hydraulic drive mechanism 113 of column 11, the hydraulic drive mechanism 233 of telescope support 23, environment detector 61, soil humidity tester 63 and controller 60 and constitutes by assembly, is the control axis of the operation of whole photovoltaic Ecological Greenhouse.Wherein, controller 60 is the core controlling device.Environment detector 61 is used for detecting solar irradiation and the air moisture content of this area on the same day, and soil humidity tester 63 is used for detecting the water content of the soil below photovoltaic module on the same day.Controller 60 adopts PLC 60 etc. common in prior art.The mode that controller 60 and environment detector 61 and soil humidity tester 63 are electrically connected by wire or be wirelessly transferred connects, thus obtaining the water content of soil below the solar irradiation of this area on the same day and air moisture content and same day photovoltaic module, controller 60 also and third party's data platform 63 connect to obtain the large-scale meteorological data in this area on the same day with to acquisition the same day this area solar irradiation compare checking, it is ensured that the accuracy of solar irradiation Data Detection.Always according to the water content of soil obtained and air moisture content, controller 60 judges whether the water content of current soil meets current plant needed for, when being unsatisfactory for, in time to soil moisturizing.Controller 60 is also used for driving actuating device 5 action; the mode that can be electrically connected by wire or be wirelessly transferred sends control signal to actuating device 5; send the control signal of shutdown, forward conveying and reversely conveying respectively to the first transportation section 53, the 51, second transportation section the 52, the 3rd, transportation section of actuating device 5, send the control signal risen or fallen to assembly lift mechanism 54.Controller 60 also controls the flexible of column 11, when plant height is more than 3m, sends, to the hydraulic drive mechanism 113 of column 11, the control signal stretched out, and vertical column expanding bar 112 stretches out makes self-adaptative adjustment to greenhouse framework height, and maximum height is less than 10m.Controller 60 also controls the flexible of telescope support 23, and when photovoltaic module unit 2 is to conveying on framework, controller 60 sends, to the hydraulic drive mechanism 233 of telescope support 23, the control signal stretched out, and support expansion link 232 stretches out, and photovoltaic module unit 2 launches；When photovoltaic module unit 2 stacks warehouse 3 to assembly or maintenance storehouse 4 is carried, controller 60 sends, to the hydraulic drive mechanism 233 of telescope support 23, the control signal return, and support expansion link 232 is return, and photovoltaic module unit 2 folds.The running status of each photovoltaic module unit 2 is analyzed in timing detection, when operation troubles, controller 60 sends the control signal of reversely conveying, sends the control signal of decline to assembly lift mechanism 54, sends the control signal of reversely conveying to the 3rd transportation section 53 to the second transportation section 52, from its assembly placement, the photovoltaic module unit 2 broken down is delivered to maintenance storehouse 4 and keeps in repair.

Shown in reference accompanying drawing 13, the control method of above-mentioned photovoltaic Ecological Greenhouse, comprise the steps:

S1, controller calculate the required irradiation on the plant same day according to plant variety and growth cycle；

S2, environment detector obtain the solar irradiation of this area on the same day, the controller meteorological data according to the solar irradiation obtained and the third party's data platform received, the required irradiation of gained is converted into the shielded area of photovoltaic module unit, draws the sum of required photovoltaic module unit；

S3, controller converse line number and the columns of photovoltaic module unit according to the sum of the photovoltaic module unit of gained；

S4, controller judge whether the photovoltaic module unit laid the previous day meets the step S3 line number drawn and columns, if being unsatisfactory for, the photovoltaic module unit exceeded is called in assembly and stacks warehouse, or not enough photovoltaic module unit is stacked warehouse from assembly recall and allocate and transport to specifying placement；

The water content of soil below S5, soil humidity tester monitor in real time photovoltaic module, environment detector obtains the air moisture content of this area on the same day, according to the water content of soil and air moisture content, controller judges whether the moisture in soil meets current plant needed for, if moisture deficit, then keep the skin wet to soil；

S6, detection crops height, when crops height with the difference in height of photovoltaic module unit less than setting value time, controller sends, to the hydraulic drive mechanism 113 of column 11, the control signal stretched out, and vertical column expanding bar 112 stretches out photovoltaic module unit 2 upwards lifting.

Specifically, in step S4, if the photovoltaic module unit laid the previous day meets the step S3 line number drawn and columns, then actuating device 5 is shut down；If the photovoltaic module unit laid the previous day is unsatisfactory for the step S3 line number drawn and columns, then controller sends control signal and drives actuating device 5 action.Specifically, if the photovoltaic module unit laid the previous day is beyond the step S3 line number drawn and/or columns, controller 60 drives the second transportation section 52 and the first transportation section 51 reversely to carry, drive assembly lift mechanism 54 to decline, and from its placement, the photovoltaic module unit exceeded is delivered to assembly and stacks warehouse 3；If the line number that draws beyond step S3 of the photovoltaic module unit laid the previous day and/or columns, controller 60 controls the forward conveying of the 51, second transportation section 52, the first transportation section and from assembly, not enough photovoltaic module unit is stacked warehouse 3 forward is delivered to it and specifies placement.Additionally, controller 60 also controls the flexible of telescope support 23, when photovoltaic module unit 2 is to conveying on framework, controller 60 sends, to the hydraulic drive mechanism 113 of telescope support 23, the control signal stretched out, and support expansion link 232 stretches out, and photovoltaic module unit 2 launches；When photovoltaic module unit 2 is carried to assembly stacking warehouse or maintenance storehouse 4, controller 60 sends, to the hydraulic drive mechanism 113 of telescope support 23, the control signal return, and support expansion link 232 is return, and photovoltaic module unit 2 folds.

Above-described embodiment is only for illustrating technology of the present utility model design and feature; it it is a kind of preferred embodiment; its object is to allow person skilled in the art will appreciate that content of the present utility model and to implement according to this, protection domain of the present utility model can not be limited with this.All equivalences made according to spirit of the present utility model change or modify, and all should be encompassed within protection domain of the present utility model.

Claims (6)

1. the bearing support of a photovoltaic Ecological Greenhouse, including for installing the column forming supporting on the ground and being connected to the upper end framework for installation photovoltaic component unit of described column, it is characterized in that: described column includes vertical column expanding set, be slidably connected to the vertical column expanding bar of described vertical column expanding set, one in described vertical column expanding set, described both vertical column expanding bars and described framework connects and another one is for installing on the ground.

2. bearing support according to claim 1, it is characterised in that: described column also includes the hydraulic drive mechanism being arranged between described vertical column expanding set and described vertical column expanding bar.

3. bearing support according to claim 2, it is characterised in that: described hydraulic drive mechanism is hydraulic jack.

4. bearing support according to claim 1, it is characterised in that: the upper end of described vertical column expanding bar and the fixing connection of described framework, the height of described vertical column expanding bar upper end is 3～10m.

5. bearing support according to claim 1, it is characterised in that: described column is multiple and is intervally arranged in array.

6. a photovoltaic Ecological Greenhouse, it is characterised in that: include as arbitrary in claim 1-5 as described in bearing support and the photovoltaic module unit of bearing support upper end as described in being arranged on.