CN204851569U - Small -bore wind -force atmospheric pressure power picotan of deep well - Google Patents

Abstract

The utility model provides a small -bore wind -force atmospheric pressure power picotan of deep well, include the wind wheel, with atmospheric pressure device that the wind wheel is connected and pressurized -water structure the pressurized -water structure includes the support frame, is located bracing piece on the support frame and the structure of being connected with the bracing piece of drawing water, the structure of drawing water include with the well casing be connected and be located the well casing lower extreme the cylinder liner, be located having the piston of first check valve and being located of cylinder liner the second check valve of cylinder liner bottom, connecting piece and hinge joint are passed through to the one end of bracing piece, the atmospheric pressure device is established between support frame and the well casing, the atmospheric pressure device control the bracing piece motion, thus make the piston is in be reciprocating motion in the cylinder liner. Therefore, the utility model has the advantages of simple structure, that the cost is lower, can exttaction water easy more.

Description

Deep-well small-bore wind power pneumatic power picotan

Technical field

The utility model relates to a kind of picotan, especially a kind of deep-well small-bore wind power pneumatic power picotan.

Background technique

In the western China that water resources lacks, the water level of underground water is mostly lower, the underground water of deep under ground to be extracted, all generally then by motor, water is extracted, but just need like this electric power resource of at substantial, and often after at substantial electric power resource, the water yield of extraction is also very limited, not only can not meet the living needs of people, cause again the billow waste of electric power resource simultaneously, in order to address this problem, people have found out the method extracting water with wind-force as power source, but, due to technological deficiency, although do not need wastes power resource, but after utilizing wind wheel to obtain power, still need to use motivational drive electric machine rotation, thus utilize motor to be extracted by the water of deep under ground, in whole process, motor is driven, need larger power, so just need larger wind or more powerful wind wheel, technical difficulty and cost can be increased undoubtedly, simultaneously, each picotan needs outfit motor, cost can be made higher.

Model utility content

In order to overcome the problems referred to above, to society, the utility model provides that a kind of structure is simple, cost is lower, the deep-well small-bore wind power pneumatic power picotan that can be more prone to extract water.

The technical solution of the utility model is: provide a kind of deep-well small-bore wind power pneumatic power picotan, comprise wind wheel, the pneumatic shuttle be connected with described wind wheel, and setting-out structure, described setting-out structure comprises supporting frame, be positioned at the strut on support frame as described above, and the pumping structure to be connected with strut, described pumping structure comprises and to be connected with well casing and to be positioned at the cylinder sleeve of well casing lower end, be positioned at the piston with the first one-way valve of cylinder sleeve, and the second one-way valve be positioned at bottom described cylinder sleeve, one end of described strut is connected with piston by link, described pneumatic shuttle is located between support frame as described above and well casing, described pneumatic shuttle controls the motion of described strut, thus described piston is moved reciprocatingly in described cylinder sleeve.

As to improvement of the present utility model, described pneumatic shuttle comprises the air compressor, cylinder and the pressure-stored tank that connect successively, forms loop between described air compressor, cylinder and pressure-stored tank, and described cylinder is located between support frame as described above and well casing.

As to improvement of the present utility model, described wind wheel is connected by driving mechanism with pneumatic shuttle.

As to improvement of the present utility model, described driving mechanism is connecting rod.

As to improvement of the present utility model, the blade of described wind wheel is sheet material or the single metal plate material of composite structure.

As to improvement of the present utility model, described link is wire rope.

The utility model is owing to also comprising setting-out structure, described setting-out structure comprises supporting frame, be positioned at the strut on support frame as described above, and the pumping structure to be connected with strut, described pumping structure comprises and to be connected with well casing and to be positioned at the cylinder sleeve of well casing lower end, be positioned at the piston with the first one-way valve of cylinder sleeve, and the second one-way valve be positioned at bottom described cylinder sleeve, one end of described strut is connected with piston by link, described pneumatic shuttle is located between support frame as described above and well casing, described pneumatic shuttle controls the motion of described strut, thus described piston is moved reciprocatingly in described cylinder sleeve, in the utility model, structure is simple, used part is all lower-cost, but the effect of the extraction water realized is again good, do not need again the electric power resource of at substantial simultaneously, therefore, it is simple that the utility model has structure, cost is lower, the advantage extracting water can be more prone to.

Accompanying drawing explanation

The overall structure schematic diagram of this practical new original state (not extracting water) of Fig. 1.

The overall structure schematic diagram of another state of Fig. 2 the utility model (after extracting water).

Embodiment

In description of the present utility model, it will be appreciated that, orientation or the position relationship of the instruction such as " " center ", " on ", D score, "front", "rear", "left", "right" in term be based on orientation shown in the drawings or position relationship; be only the utility model and simplified characterization for convenience of description; instead of instruction or imply the device of indication or element must have specific orientation, with specific azimuth configuration and operation, therefore can not be interpreted as restriction of the present utility model.In addition, term " first ", " second " only for describing object, and can not be interpreted as instruction or hint relative importance.

In description of the present utility model, it should be noted that, unless otherwise clearly defined and limited, term " installation ", " connection ", " being connected " should be interpreted broadly, and such as, can be fixedly connected with, and also can be that dismounting connects, or connect integratedly; Can be mechanical connection, also can be electrical connection; Can be directly be connected, also can be indirectly be connected by intermediary, can be the connection of two element internals.For the ordinary skill in the art, concrete condition above-mentioned term can be understood at concrete meaning of the present utility model.In addition, in description of the present utility model, except as otherwise noted, the implication of " multiple ", " some " is two or more.

Refer to Fig. 1 to Fig. 2, that Fig. 1 and Fig. 2 discloses is a kind of embodiment of deep-well small-bore wind power pneumatic power picotan, a kind of deep-well small-bore wind power pneumatic power picotan, comprise wind wheel 1, the pneumatic shuttle 2 be connected with described wind wheel 1, and setting-out structure 3, described wind wheel 1 is located at the top of pylon 10, described pneumatic shuttle 2 comprises the air compressor 21 connected successively, cylinder 22, and pressure-stored tank 23, described air compressor 21, cylinder 22, and be connected to form loop by tracheae between pressure-stored tank 23, described setting-out structure 3 comprises supporting frame 31, be positioned at the strut 32 on support frame as described above 31, and the pumping structure 33 to be connected with strut 32, described strut 32 can move around the intersection point 311 of strut 32 with supporting frame 31, described pumping structure 33 comprises and to be connected with well casing 30 and to be positioned at the cylinder sleeve 331 of well casing 30 lower end, be positioned at the piston 332 with the first one-way valve 71 of cylinder sleeve 331, and the second one-way valve 72 be positioned at bottom described cylinder sleeve 331, one end of described strut 32 is connected with piston 332 by link 34, described pneumatic shuttle 2 controls described strut 32 and moves, thus described piston 332 is moved reciprocatingly in described cylinder sleeve 331, in the present embodiment, described cylinder 22 is located between support frame as described above 31 and well casing 30, certainly, also can be that described pneumatic shuttle 2 is located between support frame as described above 31 and well casing 30.

In the utility model, preferably, described wind wheel 1 is connected by driving mechanism 4 with pneumatic shuttle 2, and in the present embodiment, what described driving mechanism 4 adopted is connecting rod.

In the utility model, in order to make the blade of described wind wheel 1 more durable, the blade of described wind wheel 1 adopts sheet material or the single metal plate material of composite structure.

In the utility model, preferably, wind rudder 12 is also provided with at the other end of described wind wheel 1.

In the utility model, preferably, described link 34 can be that hard material is made, and also can be that soft material is made, such as, be wire rope, described hard material and soft material all belong to prior art, repeat no longer one by one herein.

For Fig. 1 to Fig. 2, the process of water lift of the present utility model is described further below: Fig. 1 is in the utility model, the structural representation of (when namely not having wind) during original state, now owing to there is no wind, just do not have enough energy that the piston rod 221 in described cylinder 22 is moved yet, described strut 32 tilts to the one end at described link 34 place, piston 332 in described cylinder sleeve 331 moves downward under the effect of self gravitation in cylinder sleeve 331, now the first one-way valve 71 is closed, second one-way valve 72 is opened, water bottom deep-well 37 is extracted in cylinder sleeve 331 by the second one-way valve 72, when wind comes, described wind wheel 1 rotates with the wind, described wind wheel 1 makes air compressor 21 be released by pressurized air by running shaft 13 and driving mechanism 4, pressurized air is sent in described cylinder 22 by tracheae, thus the piston rod 221 promoting described cylinder 22 moves upward, strut 32 directly over the piston rod 221 being positioned at described cylinder 22 is propped up, now described strut 32 tends to balance gradually, described link 34 is up mentioned, piston 332 in described cylinder sleeve 331 up moves in cylinder sleeve 331, until move to the top in described cylinder sleeve 331, in the process that described piston 332 moves upward in cylinder sleeve 331, described first one-way valve 71 is opened, second one-way valve 72 is closed (state as shown in Figure 2), water in cylinder sleeve 331 arrives well casing 30 by the first one-way valve 71, when being full of water in described well casing 30, water flows out from water outlet 6 again, when the piston rod 221 of described cylinder 22 stops moving upward, close the air intake valve of described cylinder 22, open the valve of giving vent to anger of described cylinder 22, the pressure release of described cylinder 22,221, the piston rod of described cylinder 22 moves downward, pressurized air in described cylinder 22 moves in described pressure-stored tank 23, described strut 32 is owing to losing support, also tilt to the one end at described link 34 place gradually, described piston 332 moves downward under gravity in cylinder sleeve 331, now, the state shown in Fig. 1 is recovered, when next one circulation starts, described air compressor 21 is air-breathing from described pressure-stored tank 23 again, again forms pressurized air and delivers in described cylinder 22, completes next circulation with this.In the utility model, structure is simple, and used part is all lower-cost, but the effect of the extraction water realized is again good, does not need again the electric power resource of at substantial simultaneously.

Claims (6)

1. a deep-well small-bore wind power pneumatic power picotan, comprise wind wheel (1), and the pneumatic shuttle (2) to be connected with described wind wheel (1), it is characterized in that, also comprise setting-out structure (3), described setting-out structure (3) comprises supporting frame (31), be positioned at the strut (32) on support frame as described above (31), and the pumping structure (33) to be connected with strut (32), described pumping structure (33) comprises and to be connected with well casing (30) and to be positioned at the cylinder sleeve (331) of well casing (30) lower end, be positioned at the piston with the first one-way valve (71) (332) of cylinder sleeve (331), and be positioned at second one-way valve (72) of described cylinder sleeve (331) bottom, one end of described strut (32) is connected with piston (332) by link (34), described pneumatic shuttle (2) is located between support frame as described above (31) and well casing (30), described pneumatic shuttle (2) controls described strut (32) motion, thus described piston (332) is moved reciprocatingly in described cylinder sleeve (331).

2. deep-well according to claim 1 small-bore wind power pneumatic power picotan, it is characterized in that: described pneumatic shuttle (2) comprises the air compressor (21), cylinder (22) and the pressure-stored tank (23) that connect successively, form loop between described air compressor (21), cylinder (22) and pressure-stored tank (23), described cylinder (22) is located between support frame as described above (31) and well casing (30).

3. deep-well according to claim 1 and 2 small-bore wind power pneumatic power picotan, is characterized in that: described wind wheel (1) is connected by driving mechanism (4) with pneumatic shuttle (2).

4. deep-well according to claim 3 small-bore wind power pneumatic power picotan, is characterized in that: described driving mechanism (4) is connecting rod.

5. deep-well according to claim 1 and 2 small-bore wind power pneumatic power picotan, is characterized in that: the blade of described wind wheel (1) is sheet material or the single metal plate material of composite structure.

6. deep-well according to claim 1 and 2 small-bore wind power pneumatic power picotan, is characterized in that: described link (34) is wire rope.