CN209750176U - solar power generation geological package - Google Patents

Abstract

The utility model relates to a solar energy power generation geology package. A solar power generation geological package comprising: a backpack body; the flexible photovoltaic assembly is attached to the backpack body; the buffer layer is clamped between the flexible photovoltaic assembly and the backpack body; and the power output interface is arranged on the backpack body and is electrically connected with the flexible photovoltaic assembly. Above-mentioned solar energy power generation geology package has the solar energy power generation function, can have the advantage of environmental protection for the electronic product power supply that geology staff such as electron magnifying glass and novel GPS commonly used, just the knapsack inclusion with set up the buffer layer between the flexible photovoltaic module for the knapsack can not harm flexible photovoltaic module when hard things such as rock-loading stone, has the advantage that solar energy power generation component is not fragile.

Description

Solar power generation geological package

Technical Field

The utility model relates to a knapsack especially relates to a solar energy power generation geology package.

Background

The field geological bag, compass, magnifier, GPS (global positioning system) and the like are all indispensable tools for geologists. As a main carrier of field work, geological bags play a very important role. The traditional single-shoulder or double-shoulder geological bags are single in style and simple in function, are limited by market demands, and lack substantial improvement and progress for a long time. For geologists, electronic products such as electronic magnifying glasses and novel GPS are used more and more widely during work, batteries are used as main energy sources of the electronic products, the batteries are limited in electricity bearing capacity and easily cause environmental pollution, and subsequent geological work puts forward higher requirements on mobile energy supply. The geological bag can be used as a good carrier of a solar power generation component as a geological tool used in the field for a long time, but the geological tool is still lack of effective development and utilization at the present stage. In addition, in the field geological work, the main body of the geological package is from a rock sample, the geological package at the present stage excessively emphasizes the layout distribution, the actual storage space is excessively compressed, and meanwhile, the use of the material with hard texture can bring the same problem, so that the practicability of the geological package in the field geological work is seriously restricted. Finally, geological work is different from general outdoor trips, and the work is mainly finished in the daytime, so that devices such as lighting equipment at night are not suitable for backpacks required by geological workers; similarly, the angle-adjustable power generation film can improve the power generation efficiency, but is not suitable for a plurality of geological working scenes, and the applicability is not strong in geological working.

the geological package that has solar energy power generation function at present adopts the solar energy receiver panel to receive solar energy to need cooperate energy storage battery to use, consequently, geological package itself is heavier, has increased geology worker's burden, and in addition, the solar energy receiver panel of the geological package that has the power generation function at present is hard material, and geological package bearing main part is hard rock sample, leads to the solar energy receiver panel breakable.

SUMMERY OF THE UTILITY MODEL

Therefore, it is necessary to provide a solar power generation geological package which is light and portable and has a solar power generation device which is not easy to damage, aiming at the problems that the existing solar power generation geological package is heavy and a solar receiving plate is fragile.

A solar power generation geological package comprising:

A backpack body;

The flexible photovoltaic assembly is attached to the backpack body;

The buffer layer is clamped between the flexible photovoltaic assembly and the backpack body;

And the power output interface is arranged on the backpack body and is electrically connected with the flexible photovoltaic assembly.

the solar power generation geological package is provided with a flexible photovoltaic module and a power output interface, so that the geological package has a solar power generation function, the flexible photovoltaic module converts solar energy into electric energy, the electric energy output by the power output interface can supply power for electronic products commonly used by geological workers such as an electronic magnifier, a novel GPS and the like, and the electronic products generally use a battery as a main energy source, have limited battery power and easily cause environmental pollution, so the solar power generation geological package provided by the application has the advantage of environmental protection, in addition, the solar power generation geological package provided by the application does not contain a battery, so that the solar power generation geological package has the advantage of portability, and finally, set up the buffer layer between geology package and flexible photovoltaic module for the flexible photovoltaic module can not be damaged to the knapsack when hard things such as dress rock, has the not fragile advantage of solar energy power generation component.

In one embodiment, the flexible photovoltaic module comprises a bottom plate, an insulating adhesive layer, a power generation chip and a transparent protective layer. The bottom plate is attached to the outer wall of the backpack body. The insulating adhesive layer covers the bottom plate. The power generation chip covers the insulating adhesive layer. The transparent protective layer covers the power generation chip.

in one embodiment, the solar power generation geological bag further comprises a power supply control unit, wherein the power supply control unit is arranged on the backpack body and is electrically connected with the flexible photovoltaic module and the power supply output interface, and the power supply control unit comprises a controller which is electrically connected with the flexible photovoltaic module and the power supply output interface.

In one embodiment, the power control unit further comprises an inverter electrically connected to the controller and the power output interface.

In one embodiment, the solar power generation geological bag further comprises an automatic winding box, wherein the automatic winding box is arranged on the backpack body and is adjacent to the power output interface.

In one embodiment, the solar electricity generating geological package further comprises a backpack strap. The backpack strap comprises a shoulder strap, a hand strap and a waist belt. The shoulder strap is arranged on one side, far away from the flexible photovoltaic assembly, of the backpack body and is attached to the shoulders of a person during use. The hand strap is arranged on the backpack body. The waistband set up in the knapsack inclusion is kept away from one side of flexible photovoltaic module, with the cooperation of baldric is used, during the use, attaches to people's waist.

In one embodiment, the solar power generation geological package further comprises an accessory bag detachably arranged on the shoulder strap.

in one embodiment, the solar power generation geological package further comprises a buckle, wherein the buckle is a hollow buckle used for fixing an electric wire and is arranged on the shoulder strap.

in one embodiment, the backpack body includes a first storage bag, a second storage bag, side bags, and a top bag. The second storage bag is attached to the first storage bag, and when the portable storage bag is used, the second storage bag is located on one side, far away from a human body, of the first storage bag. The side bag laminating set up in first storing bag, during the use, the side bag is located the left and right sides of first storing bag, top bag laminating set up in first storing bag, during the use, top bag is located the top of first storing bag.

in one embodiment, the power output interface is a universal serial bus interface.

In the embodiment that this application provided, the chip that generates electricity is protected with bottom plate and transparent protective layer to the flexible photovoltaic module of solar energy electricity generation geology package, adopts insulating viscose layer to play waterproof effect simultaneously for flexible electricity generation subassembly has long service life, corrosion-resistant advantage. In addition, the power supply control unit is arranged to adjust the output power of the power supply to be maximum, and the inverter is arranged to change the output current of the power supply into alternating current, so that the solar power generation geological package is suitable for alternating current appliances. The automatic setting of spiral box and buckle for geology worker is at specific operational environment, when environment during operation such as bush forest, the condition that the wire was stumbled and drops can not appear, has avoided the scattered problem that probably leads to of wire under the geology operational environment.

Drawings

FIG. 1 is a schematic front view structure diagram of a solar power generation geological package provided by an embodiment of the application;

FIG. 2 is a schematic rear view structure diagram of a solar power generation geological package provided by the embodiment of the application;

FIG. 3 is a schematic cross-sectional view of a flexible power generation assembly provided in accordance with an embodiment of the present application;

FIG. 4 is a schematic diagram of an electrical connection structure of a solar power generation geological package according to an embodiment of the present application;

Fig. 5 is a schematic view of an electrical connection structure of another solar power generation geological package provided by the embodiment of the present application.

Description of the symbols:

100 solar power generation geological package

110 back bag body

111 first storage bag

112 second storage bag

113 side bag

114 top bag

120 flexible photovoltaic module

121 bottom plate

122 insulating adhesive layer

123 power generation chip

124 transparent protective layer

130 buffer layer

140 power output interface

150 power supply control unit

151 controller

152 inverter

160 automatic winding box

170 backpack strap

171 shoulder strap

172 hand strap

173 waist belt

180 attached bag

190 fastener

Detailed Description

In order to make the objects, features and advantages of the present application more comprehensible, embodiments accompanying the present application are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. This application is capable of embodiments in many different forms than those described herein and that modifications may be made by one skilled in the art without departing from the spirit and scope of the application and it is therefore not intended to be limited to the specific embodiments disclosed below.

It will be understood that when an element is referred to as being "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs. The terminology used herein in the description of the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application.

Referring to fig. 1-2, the present application provides a solar power generation geological bag, which includes a backpack body 110, a flexible photovoltaic module 120, a buffer layer 130, and a power output interface 140.

The flexible photovoltaic module 120 is attached to the backpack body 110. The buffer layer 130 is sandwiched between the flexible photovoltaic module 120 and the back pack body 110. The power output interface 140 is disposed on the backpack body 110 and electrically connected to the flexible photovoltaic module 120.

The backpack body 110 may be made of a knitted fabric having good waterproof and air-permeable properties and relatively flexible texture. The material of the backpack body 110 may be canvas, martin, jean or oxford. In one embodiment, the material of the backpack body 110 is canvas, which can avoid damage to the flexible photovoltaic module 120.

The flexible photovoltaic module 120 may be made of a thin, flexible solar power generation material. For example, classic 7.7W solar charging paper. In one embodiment, the flexible photovoltaic module 120 may be removably disposed to the second storage bag 112. Specifically, the flexible photovoltaic module 120 may be adhered to the second storage bag 112 by a hook and loop fastener. The flexible photovoltaic module 120 may be removably disposed to the second storage bag 112, making the solar power generation geological package 100 easier to clean.

The buffer layer 130 is made of a material having a buffer function. The material of the buffer layer 130 may be rubber, sponge, or foam. In one embodiment, the material of the cushioning layer 130 is sponge. The buffer layer 130 protects the flexible photovoltaic component 120 such that the flexible photovoltaic component 120 is not susceptible to damage when the back pack 110 is loaded with a rock sample. In one embodiment, the cushioning layer 130 may be removable. Specifically, the accommodating space of the buffer layer 130 may be provided with a zipper, and the buffer layer 130 may be taken out when the zipper is unzipped. When no rock sample is placed in the back pack body 110, the buffer layer 130 may be taken out, so that the storage space of the first storage bag 111 may be increased.

the power output interface 140 is used for outputting electric energy. The power output interface 140 may be a headphone jack, a power socket, a universal serial bus interface, or the like. In one embodiment, the power output interface 140 is a universal serial bus interface. In one embodiment, the power output interface 140 is disposed proximate to the flexible photovoltaic module 120 such that the power output interface 140 can be conveniently electrically connected to the flexible photovoltaic module 120.

the solar power generation geological package 100 comprises the flexible photovoltaic module 120 and the power output interface 140, so that the solar power generation geological package 100 has a solar power generation function. The solar power generation geological package 100 can supply power for electronic products commonly used by geological workers such as an electronic magnifier and a novel GPS, and the use of batteries is reduced. Therefore, the solar power generation geological package 100 provided by the application has the advantage of environmental protection. In addition, the solar power generation geological package 100 provided by the application does not comprise an energy storage battery, so that the solar power generation geological package has the advantage of being light. The solar power generation geological package 100 proposed by the present embodiment comprises said buffer layer 130. The buffer layer 130 protects the flexible photovoltaic module 120, so that the solar power generation backpack 100 in this embodiment has an advantage that the solar power generation module is not easily damaged.

In one embodiment, the solar-powered geological package 100 further comprises an automatic coil winding box 160. The automatic wire winding box 160 is disposed in the back pack body 110. In one embodiment, the automatic cord winding reel 160 is disposed near the power output interface 140, so that the automatic cord winding reel 160 can conveniently wind up the connection cord connected to the power output interface 140. The automatic wire winding box 160 can be used to adjust the length of the connection wire connected to the power output interface 140, so that the connection wire is not easily messed. The automatic winding box 160 may be any type and size of automatic winding box, and is not particularly limited in this application. In one embodiment, the automatic take-up reel 160 may be an automatic take-up reel having a reel diameter of 112mm and a reel width of 18mm and weighing about 200 g.

In one embodiment, the solar electricity generating geological package 100 further comprises a backpack strap 170. The backpack strap 170 includes a shoulder strap 171, a hand strap 172, and a waist strap 173. The shoulder straps 171 are disposed on a side of the backpack body 110 away from the flexible photovoltaic module 120. In use, the shoulder straps 171 are attached to the shoulders of a person. The joint of the shoulder straps 171 and the backpack body 110 can be sewn and reinforced, so that damage caused by overweight of the backpack is avoided, and the service life of the shoulder straps 171 is prolonged. The carrying strap 172 is disposed on the backpack body 110. The hand strap 172 may be made of nylon wrapped with rubber. Similarly, the connection of the carry strap 172 to the backpack body 110 may be sewn reinforced. The straps 172 are provided so that the geologist can carry the solar power generation geological bag 100 in a hand-held manner. The waist belt 173 is disposed on a side of the backpack body 110 away from the flexible photovoltaic module 120, and cooperates with the shoulder straps 171. In use, the waist belt 173 is attached to the waist of a human body. When the solar geologic kit 100 bears too much weight, the use of the waist belt 173 may relieve pressure on the shoulders, increasing stability when worn.

In one embodiment, the solar power generation geological package 100 further comprises an appendage 180. The accessory bag 180 is detachably provided to the shoulder strap 171. The accessory bag 180 is used for storing frequently used geological tools, such as a GPS, a field record table, a pencil and the like. The frequently used geological tool is placed in the auxiliary bag 180, so that the trouble that the geological tool needs to be taken out of the bag and then put in the bag after use is avoided. In one embodiment, the additional package 180 may provide a plurality of differently sized packages. When in use, geologists can select bags with proper sizes according to needs. Providing multiple packets of different sizes avoids the problem of having a single size of the additional packet 180 being unusable and therefore unused or discarded.

In one embodiment, the solar power generation geological package 100 further comprises a clasp 190. The buckle 190 is a hollow buckle for fixing an electric wire, and is provided to the shoulder strap 171. In one embodiment, the buckle 190 is disposed in the middle of the shoulder strap 171. The snap 190 may be provided from the automatic wire winding box 160 up to the accessory bag 180 for fixedly connecting the electric appliance located in the accessory bag 180 with the wire of the power output interface 140. The buckle 190 is arranged to prevent the wires from falling off due to being caught in a specific work environment such as a bush forest.

In one embodiment, the back pack body 110 includes a first storage bag 111, a second storage bag 112, side bags 113 and a top bag 114. The first storage bag 111 may be used for storing rock samples, sample bags and the like. The first storage bag 111 is larger in size than the second storage bag 112. When in use, one side of the first storage bag 111 far away from the second storage bag 112 is attached to a human body. The second storage bag 112 may be used to store general geological data or other relatively important and bulky paper data. The side pocket 113 is attached to the first storage pocket 111. In use, the side pockets 113 are positioned on the left and right sides of the first storage pocket 111. The side pocket 113 may be used to store a cup, an umbrella, etc. The top bag 114 is attached to the first storage bag 111. In use, the top bag 114 is positioned on top of the first storage bag 111. The top pocket 114 is used for storing small objects which are difficult to press, such as spare pencils, notebook books, portable raincoats and the like.

Referring to fig. 3, in one embodiment, the flexible photovoltaic module 120 includes a base plate 121, an insulating adhesive layer 122, a power generating chip 123 and a transparent protective layer 124. The bottom plate 121 is attached to the outer wall of the backpack body 110, so as to protect the power generating chip 123. The insulating adhesive layer 122 covers the bottom plate 121, and plays a role in insulation and water resistance. The power generating chip 123 covers the insulating adhesive layer 122. In one embodiment, the power generating chip 123 may be fabricated by a copper indium gallium selenide sputtering method or a co-evaporation method. The transparent protective layer 124 covers the power generating chip 123 and protects the power generating chip. The transparent protection layer 124 may be made of a transparent material with high light transmittance. In one embodiment, the flexible photovoltaic module 120 may be sealed to prevent water from entering the flexible photovoltaic module 120. In particular, the flexible photovoltaic module 120 may be encapsulated with an ethylene-tetrachloroethylene copolymer.

Referring to fig. 4, in one embodiment, the solar power generation geological package 100 further comprises a power control unit 150. The power control unit 150 is disposed in the backpack body 110 and electrically connected to the flexible photovoltaic module 120 and the power output interface 140. The power control unit 150 is integrated and simplified as much as possible, and can avoid occupying redundant space. In addition, the power control unit 150 may be as compact as possible to reduce the likelihood that the devices will be unnecessarily damaged. The power control unit 150 includes a controller 151. The controller 151 is electrically connected to the flexible photovoltaic module 120 and the power output interface 140. The controller 151 is a maximum power point controller for maximizing output power. The controller 151 causes the flexible photovoltaic module 120 to generate power at maximum power. The solar power backpack 100 in this embodiment is used to provide electrical energy to electrical appliances requiring direct current input.

referring to fig. 5, in another embodiment, the power control unit 150 further includes an inverter 152. The inverter 152 is electrically connected to the controller 151 and the power output interface 140. The inverter 152 is a dc-ac inverter for converting dc power into ac power. The solar power generation backpack 100 in this embodiment is used to provide electric power for an electrical appliance requiring ac input.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. A solar power generation geological package (100), characterized by comprising:

A backpack body (110);

The flexible photovoltaic module (120) is attached to the backpack body (110);

A buffer layer (130) sandwiched between the flexible photovoltaic assembly (120) and the back pack body (110);

The power output interface (140) is arranged on the backpack body (110) and is electrically connected with the flexible photovoltaic assembly (120).

2. Solar electricity generating geological package (100) according to claim 1, characterized in that said flexible photovoltaic module (120) comprises:

A bottom plate (121) which is attached to the outer wall of the backpack body (110);

An insulating adhesive layer (122) covering the base plate (121);

A power generating chip (123) covering the insulating adhesive layer (122);

A transparent protective layer (124) covering the power generating chip (123).

3. The solar power generation geological package (100) according to claim 1, characterized in that it further comprises a power control unit (150) disposed in said backpack body (110) and electrically connected to said flexible photovoltaic module (120) and said power output interface (140), said power control unit (150) comprising a controller (151), said controller (151) being electrically connected to said flexible photovoltaic module (120) and said power output interface (140).

4. Solar electricity generating geological package (100) according to claim 3, characterized in that said power control unit (150) further comprises an inverter (152) electrically connected with said controller (151) and with said power output interface (140).

5. The solar power generation geological package (100) according to claim 1, characterized by further comprising an automatic wire winding box (160) disposed in said backpack body (110) and adjacent to said power output interface (140).

6. The solar electricity generating geological package (100) according to claim 1, characterized in that it further comprises a backpack strap (170), said backpack strap (170) comprising:

The shoulder straps (171) are arranged on one side, away from the flexible photovoltaic module (120), of the backpack body (110) and are attached to the shoulders of a person in use;

A carry strap (172) provided to the backpack body (110);

The waist belt (173) is arranged on one side, away from the flexible photovoltaic component (120), of the backpack body (110) and is matched with the shoulder belt (171) for use, and when the backpack is used, the backpack is attached to the waist of a person.

7. solar electricity generating geological kit (100) according to claim 6, characterized by further comprising an additional kit (180) removably attached to said shoulder straps (171).

8. Solar electricity generating geological kit (100) according to claim 6, characterized by further comprising a snap (190), said snap (190) being a hollow snap for fixing electric wires, provided to said shoulder straps (171).

9. Solar electricity generating geological package (100) according to claim 1, characterized in that said backpack body (110) comprises:

A first storage bag (111);

the second storage bag (112) is attached to the first storage bag (111), and when the folding type folding;

the side bags (113) are attached to the first storage bag (111), and when the side bags (113) are used, the side bags (111) are positioned at the left side and the right side of the first storage bag (111);

the top bag (114) is attached to the first storage bag (111), and when the top bag is used, the top bag (114) is located at the top of the first storage bag (111).

10. The solar power generation geological package (100) according to claim 1, characterized in that said power output interface (140) is a universal serial bus interface.