TWM616181U - Energy production symbiotic system - Google Patents

Abstract

An energy production symbiosis system includes a support unit, a power generation unit, at least one reflection unit and a production unit. The support unit has six side rods that are connected in a hexagonal shape around and six pillars extending downward from the connection points of the side rods. The side rods cooperate with the pillars to define a hexagonal column-shaped cultivation. space. The reflecting unit has a reflecting surface for reflecting sunlight to the solar panel module. The production unit is arranged in the cultivation space and located under the solar panel module. In this way, a modular structure of hexagonal columns can be formed, which not only can obtain a stable architectural structure in terms of mechanics, but also facilitates expansion as required, and obtains excellent space utilization.

Description

Energy production symbiosis system

This new model relates to a production system, especially an energy production symbiosis system.

The traditional method of production and catch is the use of natural water or artificial ponds for aquaculture. However, this type of aquaculture is greatly affected by the weather and will suffer huge losses if it encounters natural disasters.

In recent years, indoor breeding technology has continued to develop. However, most of the current breeding farms are digging tanks inside the buildings to breed fish. After the construction is completed, it is not easy to change and expand according to demand.

Therefore, the purpose of the present invention is to provide an energy production symbiosis system that is convenient for expansion.

Therefore, the new energy production symbiosis system includes at least one energy production symbiosis device.

The at least one energy production symbiosis device includes a support unit, a power generation unit, at least one reflection unit and a production unit.

The support unit has six side rods that are connected in a hexagonal shape around and six pillars extending downward from the connection points of the side rods. The side rods cooperate with the pillars to define a hexagonal column-shaped cultivation. space.

The power generation unit has a power generation support set on the support unit, and a solar panel module set on the power generation support.

The at least one light reflecting unit is arranged on the supporting unit and has a light reflecting surface for reflecting sunlight to the solar panel module.

The production unit is arranged in the cultivation space and located under the solar panel module.

The effect of the present invention is that by arranging the supporting unit in the shape of a hexagonal column, the power generating unit, the at least one reflecting unit and the production unit are arranged to form a modular structure, which not only can obtain a stable building mechanically The architecture can also facilitate expansion based on demand and obtain excellent space utilization.

Before the present invention is described in detail, it should be noted that in the following description, similar elements are represented by the same numbers.

Referring to Figure 1, Figure 2 and Figure 3, a first embodiment of the new energy production symbiosis system includes an energy production symbiosis device 1.

The energy production symbiosis device 1 includes a support unit 2, a power generation unit 3, six reflection units 4, and a production unit 5. The energy production symbiosis device 1 preferably further includes a planting unit 6, a lighting unit 7 and a row of air inlet units 8.

The support unit 2 has six side rods 21 that are circumferentially connected to form a hexagon, and six pillars 22 respectively extending downward from the joints of the side rods 21. The side rods 21 and the pillars 22 cooperate to define a A cultivation space 23 in the shape of a hexagonal column. Among them, the side rods 21 are preferably equal in length so as to be connected in a regular hexagon shape, so that they can have better stability and higher space utilization. Among them, FIG. 1 is a diagram for clarity, and a pillar 22 located at the uppermost layer of the diagram is omitted to avoid blocking other components.

The power generation unit 3 has a power generation support 31 disposed on the support unit 2 and a solar panel module 32 disposed on the power generation support 31 and above the cultivation space 23. 2, 3, 4 and 5, the power generation support 31 has six adjustment rods 311 pivotally mounted on the support unit 2, and an adjustment rod 311 arranged on the adjustment rods 311 and provided for the solar panel module 32 to be installed Support frame 312. The two ends of each adjusting rod 311 are respectively pivoted at the connection between two of the side rods 21 and the support frame 312, whereby the solar panel module 32 can adjust the inclination angle according to the location latitude and the season to achieve the best Effective illumination angle.

Each reflecting unit 4 has two reflecting brackets 41 arranged on one of the rods 21, and a reflecting plate 42 rotatably arranged on the reflecting brackets 41 and having a reflecting surface 421. Among them, the number of the reflective brackets 41 can be set according to actual needs, and can also be three or four or more.

Each reflective bracket 41 has a U-shaped base frame 411 disposed on one of the rods 21, and at least one connecting rod 412 pivotally connected to the base frame 411, and each reflective plate 42 is rotatably disposed on the base frame 411. The rod 412 is connected to adjust the light reflection angle of the light reflection surface 421. As shown in FIG. 5, due to the inclination angle of the solar panel module 32, the reflector plate 42 on the right side needs to be set to a low height. Therefore, the reflector bracket 41 has a single base frame 411 and a single connecting rod. 412. The reflector 42 is pivoted at an end of the base frame 411 near the inner side and an end of the connecting rod 412 opposite to the base frame 411. On the other hand, since the reflector plate 42 on the left side needs to be set to a high height, the reflector bracket 41 has a single base frame 411 and two connecting rods 412, and the two ends of each connecting rod 412 are respectively pivotable. Set on the base frame 411 and the reflector 42. In this way, the reflective plate 42 can be rotated to adjust the light reflection angle of the reflective surface 421 to obtain a better light collection effect.

Referring to FIGS. 1, 2 and 3, in this embodiment, the energy production symbiosis device 1 has six reflective units 4, and each is arranged in a height corresponding to the inclination angle of the solar panel module 32. However, the energy production symbiosis device 1 may also have only two of the reflecting units 4 arranged opposite to each other. At this time, the reflecting units 4 are preferably arranged along the east-west direction, that is, the reflecting surfaces 421 are arranged perpendicular to the east-west direction. Therefore, no matter which latitude, the main orbit of the sun is running from east to west. , Can cover the main trajectory of the sun in a day, and still achieve a certain degree of light collection efficiency. Or, as shown in FIG. 6, the energy production symbiosis device 1 only has a single reflecting unit 4, and the reflecting surface 421 is designed in a semi-circular arc style. In this way, the installation work can be simplified and the reflection can also be achieved. The sun's rays have a light-gathering effect.

1, 2 and 3, the production unit 5 is disposed in the cultivation space 23 and is located under the solar panel module 32, and has a fishery cultivation tank 51 suitable for accommodating water and fishery products. In this embodiment, the production unit 5 is described as fish farming, but the production unit 5 can also be used for animal husbandry, or agricultural planting, etc., and is not limited to this.

Among them, the fish farming tank 51 is preferably made of lightweight materials, for example, a composite material of fiber-reinforced plastic (FRP) and styrofoam, or high-density polyethylene plastic (High Density Polyethylene (abbreviated as HDPE) and Styrofoam are made of a composite material, or it can also be made using a sandwich structure of metal materials, PU, and metal materials. In this way, the fishery aquaculture tank 51 can float on the water. Moreover, the production unit 5 preferably cooperates with the light-weight fishery aquaculture tank 51 and further has a plurality of connecting pieces 52. Each connecting piece 52 is connected to the fishery aquaculture tank 51 and is movably arranged on the corresponding pillar 22 up and down. For example, each connecting member 52 may be ring-shaped or chain-shaped to enclose the corresponding pillar 22. In this way, in the event of a typhoon rain or flood, the fishery aquaculture tank 51 can rise with the water surface unimpeded, so as to prevent the water from flooding into the fishery aquaculture tank 51 and cause loss of fishery products outflow. In addition, the production unit 5 may also have a work platform 53 extending outward from the outside of the fishery aquaculture tank 51, and the work platform 53 can be convenient for the operation activities of aquaculture personnel.

The planting unit 6 is arranged in the cultivation space 23 and located between the fishery aquaculture tank 51 and the solar panel module 32, and is suitable for planting agricultural products. The agricultural products are illustrated in FIG. 1 with vegetables, but they can also It is not limited to small fruits such as strawberries and tomatoes, or plants and trees, gardening flowers and trees.

The planting unit 6 has a cultivation frame 61, a pumping motor 62, a water inlet pipe 63, and an irrigation water channel 64. The cultivating rack 61 is connected to the pillars 22 and is suitable for the installation of a plurality of agricultural production boxes 9. The cultivating rack 61 has a plurality of through holes 611, and the through holes 611 are used for irrigating water to absorb impurities through the agricultural products and filter the rhizomes. Then it flows down to the fish farming tank 51. The pumping motor 62 is suitable for pumping the water in the fish farming tank 51 to the irrigation channel 64 through the water inlet pipe 63 to irrigate the agricultural products. The water inlet pipe 63 can be implemented using a hose, which is convenient for adjustment in coordination with the up and down movement of the fishery aquaculture tank 51.

The lighting unit 7 is installed at the supporting unit 2 corresponding to the planting unit 6, and includes a lamp holder 71 installed on the pillars 22 and a plurality of lamps 72 installed on the lamp holder 71. The lighting unit 7 may include two, three, or more than four lamps 72 according to actual needs, and the lamps 72 are used to provide agricultural lighting for the planting unit 6 when the sunlight is insufficient.

The air intake unit 8 is arranged at the support unit 2 corresponding to the planting unit 6, and includes a plurality of fans 81 arranged on the pillars 22. The fans 81 are used to maintain ventilation at the planting unit 6 and enable the planting The temperature in unit 6 is uniform.

In actual use, water and fishery products can be placed in the fishery cultivation tank 51 for cultivation, and the water from the fishery cultivation tank 51 is pumped by the pumping motor 62 to irrigate the agricultural products of the planting unit 6, due to the excretion of fish After the action of bacteria, it can produce nutrients needed for plant growth. Therefore, by taking the water in the fish farming tank 51 for irrigation, not only can the water be absorbed and filtered by the agricultural products, the water can be restored to clean water. And it flows back down to the fish farming tank 51 for fishery production and storage. The nutrients produced by excrement can also make agricultural production grow better and faster. Therefore, it has the advantage of recycling and almost no pollution. , In line with today's environmentally friendly organic trend.

In addition, the power generation bracket 31 and the reflective brackets 41 can be adjusted according to the latitude and season of the location, so that the inclination angle of the solar panel module 32 can match the latitude and season of the location and the operating angle of the sun. The angle of 42 can match the trajectory of the sun to better reflect solar energy to the solar panel module 32.

Refer to Figure 7, which is a second embodiment of the new energy production symbiosis system. The second embodiment is similar to the first embodiment. The difference between the second embodiment and the first embodiment is:

The second embodiment includes two energy production symbiosis devices 1, each of the supporting unit 2 and the adjacent supporting unit 2 share one of the side poles 21 and two of the pillars 22 connecting the one of the side poles 21. In addition, on the side rods 21 that share the same side, four reflective brackets 41 are arranged at intervals in total, which are grouped two by two for the adjacent reflective plates 42 to be installed. Compared with erecting a single energy production symbiosis device 1, the common side of adjacent energy production symbiosis devices 1, the reflectors 42 on the same side pole 21, need to be retracted to provide sufficient rotation. Adjust the angle of space.

It is worth mentioning that, in the second embodiment, two energy production symbiosis devices 1 are used as an illustration, but in fact, the energy production symbiosis system can include any number of energy production symbiosis devices 1 according to demand. An energy production symbiosis device 1 will be co-located and co-pillared with six adjacent energy production symbiosis devices 1 to form a honeycomb-shaped building group and achieve a stable building structure and good space utilization.

Referring to Figure 1, Figure 2 and Figure 7, through the above description, the effects of the present invention are as follows:

1. By arranging the supporting unit 2 in the shape of a hexagonal column, the power generating unit 3, the reflecting units 4, and the production unit 5 are arranged to form a modular structure, which not only can obtain a stable architectural structure mechanically , And it can also be easily expanded according to demand. When constructing the plural energy production symbiosis device 1, each supporting unit 2 and the adjacent supporting unit 2 share the side rod 21 and the pillar 22 (that is, each supporting unit 2 is connected to the adjacent supporting unit 2). Unit 2 has a common side and a common column). In this way, a honeycomb-shaped building group can be constructed, which is not only convenient for addition, but also has a stable structure and excellent space utilization.

2. By rotatably setting the reflector 42 on the reflector brackets 41, the reflector 42 can adjust the angle according to the latitude and season of the location to correspond to the sun's trajectory, and a better light collection effect can be obtained.

3. A plurality of connecting pieces 52 connected to the fishery aquaculture tank 51 and movably arranged on the pillars 22 are provided, and the fishery aquaculture tank 51 is implemented by using light materials, even in the event of a typhoon rain or flood Therefore, the fishery aquaculture tank 51 can still rise with the water surface unimpeded, so as to avoid the problem of the loss of fishery products caused by the outflow of the fishery products caused by the flooding of the water flow into the fishery aquaculture tank 51.

4. By setting the adjusting rod 311 pivoted on the supporting unit 2 and the supporting frame 312, the solar panel module 32 can adjust the angle according to the latitude and season of the location, and better power generation efficiency can be obtained.

5. By setting up the planting unit 6, the energy production symbiosis system can increase the function of planting agricultural products.

In summary, the new type of energy production symbiosis system can indeed achieve the goal of a new type of cost.

However, the above are only examples of the present model, and should not be used to limit the scope of implementation of the present model, all simple equivalent changes and modifications made in accordance with the patent scope of the present model application and the contents of the patent specification still belong to This new patent covers the scope.

1: Energy production symbiosis device 2: Support unit 21: Side pole 22: Pillar 23: Cultivation space 3: Power generation unit 31: Power generation bracket 311: Adjusting lever 312: Support frame 32: Solar panel module 4: reflective unit 41: Reflective bracket 411: base frame 412: connecting rod 42: reflector 421: reflective surface 5: Production unit 51: fish farming tank 52: connecting piece 53: Operating platform 6: Planting unit 61: Cultivation Frame 611: Through Hole 62: Pumping motor 63: inlet pipe 64: Irrigation Channel 7: Lighting unit 71: Lamp bracket 72: lamps 8: Exhaust air unit 81: Fan 9: Agricultural production box

The other features and effects of the present invention will be clearly presented in the embodiments with reference to the drawings, among which: Figure 1 is an incomplete schematic diagram of a first embodiment of the new energy production symbiosis system; Figure 2 is an incomplete perspective view of the first embodiment; Figure 3 is an incomplete top view of the first embodiment; Figure 4 is an incomplete bottom view of the first embodiment; Figure 5 is an incomplete side view of the first embodiment; Figure 6 is an incomplete perspective view illustrating the first embodiment with a reflective unit; and Fig. 7 is an incomplete schematic diagram of a second embodiment of the new energy production symbiosis system.

2: Support unit

21: Side pole

22: Pillar

3: Power generation unit

31: Power generation bracket

311: Adjusting lever

32: Solar panel module

4: reflective unit

41: Reflective bracket

42: reflector

421: reflective surface

Claims (10)

An energy production symbiosis system, including: At least one energy production symbiosis device, including: A support unit has six side rods connected in a hexagonal shape around the circumference, and six pillars respectively extending downwards from the joints of the side rods. The side rods cooperate with the pillars to define a hexagonal columnar shape Nurturing space, A power generation unit having a power generation support provided on the support unit, and a solar panel module provided on the power generation support, At least one reflective unit is disposed on the supporting unit and has a reflective surface for reflecting sunlight to the solar panel module, and A production unit is arranged in the cultivation space and located under the solar panel module. The energy production symbiosis system according to claim 1, wherein the production unit has a fishery aquaculture tank suitable for holding water and fishery products. The energy production symbiosis system according to claim 1, wherein the at least one reflecting unit has a plurality of reflecting brackets arranged on one of the rods, and a reflecting plate rotatably arranged on the reflecting brackets and having the reflecting surface, The reflector is rotated to adjust the light reflecting angle of the reflecting surface. The energy production symbiosis system according to claim 3, wherein each reflective bracket has a U-shaped base frame provided on one of the poles, and at least one connecting rod pivotally connected to the base frame, each The reflecting plate is rotatably arranged on the connecting rod to adjust the light reflecting angle of the reflecting surface. The energy production symbiosis system described in claim 1 includes two reflective units, and the reflective surfaces of the reflective units are arranged opposite to each other, and the reflective surfaces are arranged substantially perpendicular to the east-west direction. The energy production symbiosis system according to claim 1, wherein the power generation support has a plurality of adjusting rods pivoted on the supporting unit, and a supporting frame provided on the adjusting rods for the solar panel module to be installed. The energy production symbiosis system according to claim 2, wherein the production unit further has a plurality of connectors connected to the fishery aquaculture tank and movably arranged on the pillars. The energy production symbiosis system according to claim 7, wherein the material of the fish farming tank is a composite material of glass fiber reinforced plastic and styrofoam or a composite material of high-density polyethylene plastic and styrofoam. The energy production symbiosis system according to claim 1, comprising a plurality of energy production symbiosis devices, each of the supporting unit and the adjacent supporting unit share one of the side poles and two of the pillars connecting the one of the side poles. The energy production symbiosis system according to claim 2, further comprising a planting unit arranged in the cultivation space and located between the fishery aquaculture tank and the solar panel module, and the planting unit is suitable for planting agricultural products.

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