CN210738738U - Wind energy horizontal-pushing low-speed piston type vacuum water lifting device - Google Patents

Abstract

The utility model relates to a wind energy flat push low-speed piston vacuum water lifting device, including water tank and support, rotate on the support and install vertical main shaft and horizontal main shaft, through bevel gear one and the transmission of bevel gear two meshing between vertical main shaft and the horizontal main shaft, two sets of flabellum subassemblies are no less than to the upper portion of vertical pivot, horizontal pivot end fixing has the carousel, the carousel outer end rotates and is connected with the connecting rod, the lower extreme of connecting rod articulates there is the lifting rod, the bottom of water tank is fixed with the inside cylinder of intercommunication, be equipped with the piston in the cylinder, the piston top is fixed with the lifting rod, the bottom of cylinder is equipped with the inlet opening, inlet opening department is equipped with the check valve, fixedly connected with drinking-water pipe. The utility model discloses a this device can turn into kinetic energy with wind energy, then utilizes extraction groundwater to kinetic energy, can use the field irrigation field, and the energy saving is used again promptly.

Description

Wind energy horizontal-pushing low-speed piston type vacuum water lifting device

Technical Field

The utility model belongs to the technical field of pumping device, concretely relates to wind energy flat push low-speed piston vacuum water lift device.

Background

At present, common equipment for pumping underground water is a water pump and a manual water well, the water pump consumes electric power, manpower is consumed, annual average wind power in the southwest Lu is 3-4 levels, more than 4 levels of wind account for 260 plus 280 days, and the wind power is not used for pumping the underground water at present, so that a device is lacked for converting wind energy into kinetic energy to be applied to pumping the underground water.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a wind energy flat push low-speed piston vacuum water lifting device reaches and utilizes wind energy to produce kinetic energy to the purpose of automatic extraction groundwater.

The utility model relates to a wind energy horizontal-pushing low-speed piston type vacuum water lifting device, which comprises a water tank and a support, wherein a vertical main shaft and a horizontal main shaft are rotatably arranged on the support, the vertical main shaft and the horizontal main shaft are driven by a bevel gear I and a bevel gear II in a meshing way, at least two sets of fan blade assemblies are arranged on the upper part of the vertical rotating shaft, each fan blade assembly comprises three supporting shafts which are uniformly fixed on the periphery of the vertical main shaft, the outer end of each supporting shaft is rotatably connected with a blade, the distance from the outer end of each supporting shaft to the two ends of the blade is unequal, each supporting shaft in two adjacent sets of fan blade assemblies is positioned in the middle of the adjacent supporting shaft at the lower layer, a turntable is fixed at the end part of the horizontal rotating shaft, the outer end of the turntable is rotatably connected with, a check valve is arranged at the water inlet, a water pumping pipe is fixedly connected below the water inlet, and a water drainage pipe is arranged on one side of the water tank.

The outer end of the supporting shaft is fixed with a connecting shaft, two ends of the connecting shaft are rotatably provided with rotating sleeves, and the rotating sleeves are fixed with the side parts of the blades.

The distance from the connecting shaft to one end of the blade accounts for three fifths to two thirds of the total length of the blade.

The vertical rotating shaft is rotatably provided with a first supporting sleeve through a bearing, the first supporting sleeve is fixed on the support, the second supporting sleeve is rotatably arranged on the horizontal rotating shaft through a bearing, and the second supporting sleeve is fixed on the support.

The cylinder and the turntables are respectively provided with two turntables which are respectively fixed at two ends of the horizontal rotating shaft, the outer sides of the turntables at two sides are respectively fixed with a pin shaft, the two pin shafts are respectively positioned at the upper side and the lower side of the horizontal rotating shaft, the pin shafts are rotatably provided with connecting sleeves, and the lower ends of the connecting sleeves are fixed with the connecting rods.

An inserted rod is fixed at the bottom of the water tank.

Vertical pivot includes pivot and lower pivot, it rotates to install in supporting cover one to rotate to go up the pivot, lower pivot lower extreme passes through the bearing and rotates to install in supporting cover three, it is fixed with the support to support cover three, bevel gear is fixed in pivot down, lower pivot top is fixed with square connecting block, go up the pivot bottom be equipped with square connecting block complex square groove, it is fixed with backup pad one to go up the pivot lower extreme outside, lower pivot pot head has the spring, lower pivot upper portion is fixed with backup pad two, backup pad two below is equipped with the drive block, drive block fixedly connected with actuating lever, the well lower part of actuating lever articulates there is backup pad three, three bottoms of backup pad are fixed with the supporting shoe, the supporting shoe is fixed with the support.

Compared with the prior art, the utility model has the advantages of:

can turn into kinetic energy with wind energy through this device, then utilize kinetic energy to extract underground or earth's surface aquatic, can use the field of irrigation of farmland, the energy saving promptly, use manpower sparingly again.

Drawings

Fig. 1 is a schematic view of the structure of the present invention;

FIG. 2 is a schematic top view of a fan blade assembly;

FIG. 3 is a schematic structural view of a braking portion;

fig. 4 is a schematic structural view of a lower portion of the present invention;

in the figure: 1. the device comprises blades, 2, rotating sleeves, 3, a connecting shaft, 4, a supporting shaft, 5, a vertical rotating shaft, 6, a first supporting sleeve, 7, a support, 8, a connecting sleeve, 9, a rotating disc, 10, a connecting rod, 11, a lifting rod, 12, a water discharging pipe, 13, a piston, 14, a check valve, 15, a water pumping pipe, 16, an inserting rod, 17, a water tank, 18, a cylinder barrel, 19, a second bevel gear, 20, a second supporting sleeve, 21, a first bevel gear, 22, an upper supporting shaft, 23, a square groove, 24, a square connecting block, 25, a first supporting plate, 26, a driving rod, 27, a supporting block, 28, a horizontal rotating shaft, 29, a third supporting sleeve, 30, a lower rotating shaft, 31, a second supporting plate, 32, a spring, 33 and.

Detailed Description

The following describes the embodiments of the present invention in further detail with reference to the accompanying drawings.

The wind energy horizontal pushing low-speed piston type vacuum water lifting device shown in fig. 1 to 3 comprises a water tank 17 and a support 7, wherein the top of the water tank 17 is fixed with the support 7, a water filling port can be arranged at the top of the water tank 17, a vertical rotating shaft 5 and a horizontal rotating shaft 28 are rotatably mounted on the support 7, the vertical rotating shaft 5 and the horizontal rotating shaft 28 are in meshing transmission through a bevel gear I21 and a bevel gear II 19, no less than two sets of fan blade assemblies are arranged at the upper part of the vertical rotating shaft 5 and are all positioned above the support 7, as shown in fig. 1 and 2 which are examples of two sets of fan blade assemblies, each fan blade assembly comprises three supporting shafts 4 which are uniformly fixed on the periphery of the vertical main shaft, the included angle between each adjacent supporting shafts 4 is 120 degrees, the outer end of each supporting shaft 4 is rotatably connected with a blade 1, the distances from the outer ends of the supporting shafts 4 to the two ends, make the contained angle between upper back shaft 4 and the adjacent back shaft 4 of lower floor be 60 degrees, every blade 1 is round 5 rotatory 360 degrees work circulations of vertical rotating shaft, 180 degrees power loss, 180 degrees atress, three power loss handing-over work, 28 end fixing of horizontal rotating shaft has carousel 9, 9 outer ends of carousel rotate and are connected with connecting rod 10, the lower extreme of connecting rod 10 articulates there is lifting rod 11, the bottom of water tank 17 is fixed with its inside cylinder 18 of intercommunication, be equipped with piston 13 in the cylinder 18, piston 13 top is fixed with lifting rod 11, the bottom of cylinder 18 is equipped with the inlet opening, inlet opening department is equipped with check valve 14, fixedly connected with drinking-water pipe 15 under the inlet opening, drinking-water pipe intercommunication groundwater layer or surface water layer, water tank 17 one side is equipped with drain pipe 12.

The size of the blade and the rotating diameter of the supporting shaft determine the selection of the diameter of the cylinder barrel, and the wind power for driving the piston with the diameter of 100 mm to work is about five grades. It is expected that 1-1.5 mu of farmland can be irrigated every day.

The height of the theoretical vertical pressure of the atmospheric pressure on the water is 7.8 meters, and the device can work at the water level of 6.8 meters under the influence of piston sealing, pipeline resistance and water supply of a water pipe.

The outer end of the supporting shaft 4 is fixed with a connecting shaft 3, the two ends of the connecting shaft 3 are rotatably provided with rotating sleeves 2, and the rotating sleeves 2 are fixed with the side parts of the blades 1.

The distance from the connecting shaft 3 to one end of the blade 1 accounts for three fifths to two thirds of the total length of the blade 1. The wind energy can be better utilized. The distribution of the upper support shafts 22 and the lower support shafts in fig. 2.

The vertical rotating shaft 5 is rotatably provided with a first supporting sleeve 6 through a bearing, the first supporting sleeve 6 is fixed on the support 7, the horizontal rotating shaft 28 is rotatably provided with a second supporting sleeve 20 through a bearing, and the second supporting sleeve 20 is fixed on the support 7.

The cylinder barrel 18 and the turntables 9 are respectively provided with two turntables 9, the two turntables 9 are respectively fixed at two ends of the horizontal rotating shaft 28, the outer sides of the turntables 9 at two sides are respectively fixed with a pin shaft, the two pin shafts are respectively positioned at the upper side and the lower side of the horizontal rotating shaft 28, the pin shafts are rotatably provided with connecting sleeves 8, and the lower ends of the connecting sleeves 8 are fixed with the connecting rods 10. The two pistons 13 can be operated alternately to achieve a continuous flow of water.

An insert rod 16 is fixed to the bottom of the water tank 17.

Vertical shaft 5 includes upper rotating shaft 33 and lower pivot 30, upper rotating shaft 33 rotates and installs in supporting cover one 6, lower pivot 30 lower extreme passes through the bearing rotation and installs in supporting cover three 29, it is fixed with support 7 to support cover three 29, bevel gear 21 is fixed on lower pivot 30, lower pivot 30 top is fixed with square connecting block 24, upper rotating shaft 33 bottom is equipped with square groove 23 with square connecting block 24 complex, upper rotating shaft 33 lower extreme outside is fixed with backup pad one 25, lower pivot 30 upper end cover has spring 32, lower pivot 30 upper portion is fixed with backup pad two 31, backup pad two 31 below are equipped with the drive block, drive block fixedly connected with actuating lever 26, the well lower part of actuating lever 26 articulates there is backup pad three, backup pad three bottoms are fixed with supporting shoe 27, supporting shoe 27 is fixed with support 7. When maintenance is needed, the driving rod 26 can be pressed, the first driving bevel gear 21 is disengaged from the second bevel gear 19, the piston 13 is removed from moving, and the piston 13 is convenient to maintain.

During operation, pour into certain water into at the water filling port of water tank, the upper portion of sealed cylinder, then the wind blows the movable blade, drives vertical pivot rotation to drive horizontal rotating shaft through intermeshing's bevel gear one and bevel gear two and rotate, then drive the piston up-and-down motion through connecting rod and lifting rod, the simulation pressurized-water well carries out the pressurized-water, simple and convenient completion wind energy conversion kinetic energy and be applied to the irrigation farmland of drawing water.

To sum up, the utility model discloses can turn into kinetic energy with wind energy, then utilize kinetic energy to extraction underground or earth's surface aquatic, can use the field irrigation field, the energy saving promptly uses manpower sparingly again.

In the description of the present invention, the terms "inside", "outside", "longitudinal", "lateral", "up", "down", "top", "bottom", etc. indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings, and are only for convenience of description of the present invention rather than requiring the present invention to be constructed and operated in a specific orientation, and thus should not be construed as limiting the present invention.

Claims (7)

1. The utility model provides a wind energy flat push low-speed piston vacuum water lifting device which characterized in that: comprises a water tank (17) and a support (7), a vertical rotating shaft (5) and a horizontal rotating shaft (28) are rotatably installed on the support (7), the vertical rotating shaft (5) and the horizontal rotating shaft (28) are meshed with each other through a bevel gear I (21) and a bevel gear II (19) for transmission, at least two sets of fan blade assemblies are arranged on the upper portion of the vertical rotating shaft (5), each fan blade assembly comprises three supporting shafts (4) which are uniformly fixed on the periphery of a vertical main shaft, the outer end of each supporting shaft (4) is rotatably connected with a blade (1), the distances from the outer end of each supporting shaft (4) to the two ends of each blade (1) are unequal, each supporting shaft (4) in every two adjacent sets of fan blade assemblies is positioned in the middle of the adjacent supporting shafts (4) on the lower layer, a turntable (9) is fixed at the end portion of the horizontal rotating shaft (28, the bottom of water tank (17) is fixed with inside cylinder (18) of intercommunication, is equipped with piston (13) in cylinder (18), and piston (13) top is fixed with lifting rod (11), and the bottom of cylinder (18) is equipped with the inlet opening, and inlet opening department is equipped with check valve (14), fixedly connected with drinking-water pipe (15) under the inlet opening, and water tank (17) one side is equipped with drain pipe (12).

2. The wind energy horizontal-pushing low-speed piston type vacuum water lifting device according to claim 1, characterized in that: the outer end of the supporting shaft (4) is fixed with a connecting shaft (3), two ends of the connecting shaft (3) are rotatably provided with rotating sleeves (2), and the rotating sleeves (2) are fixed with the side parts of the blades (1).

3. The wind energy horizontal-pushing low-speed piston type vacuum water lifting device according to claim 2, characterized in that: the distance from the connecting shaft (3) to one end of the blade (1) accounts for three fifths to two thirds of the total length of the blade (1).

4. The wind energy horizontal-pushing low-speed piston type vacuum water lifting device according to claim 1, characterized in that: the vertical rotating shaft (5) is rotatably provided with a first supporting sleeve (6) through a bearing, the first supporting sleeve (6) is fixed on the support (7), the horizontal rotating shaft (28) is rotatably provided with a second supporting sleeve (20) through a bearing, and the second supporting sleeve (20) is fixed on the support (7).

5. The wind energy horizontal-pushing low-speed piston type vacuum water lifting device according to claim 2, characterized in that: the cylinder barrel (18) and the turntables (9) are both provided with two, the two turntables (9) are respectively fixed at two ends of a horizontal rotating shaft (28), the outer sides of the turntables (9) on two sides are respectively fixed with a pin shaft, the two pin shafts are respectively positioned at the upper side and the lower side of the horizontal rotating shaft (28), the pin shafts are rotatably provided with connecting sleeves (8), and the lower ends of the connecting sleeves (8) are fixed with connecting rods (10).

6. The wind energy horizontal-pushing low-speed piston type vacuum water lifting device according to claim 2, characterized in that: an inserted rod (16) is fixed at the bottom of the water tank (17).

7. The wind energy horizontal-pushing low-speed piston type vacuum water lifting device according to claim 2, characterized in that: the vertical rotating shaft (5) comprises an upper rotating shaft (33) and a lower rotating shaft (30), the upper rotating shaft (33) is rotatably arranged in a first supporting sleeve (6), the lower end of the lower rotating shaft (30) is rotatably arranged in a third supporting sleeve (29) through a bearing, the third supporting sleeve (29) is fixed with a support (7), a first bevel gear (21) is fixed on the lower rotating shaft (30), a square connecting block (24) is fixed at the top of the lower rotating shaft (30), a square groove (23) matched with the square connecting block (24) is arranged at the bottom of the upper rotating shaft (33), a first supporting plate (25) is fixed at the outer side of the lower end of the upper rotating shaft (33), a spring (32) is sleeved at the upper end of the lower rotating shaft (30), a second supporting plate (31) is fixed at the upper part of the lower rotating shaft (30), a driving block is arranged below the second supporting plate (31), a driving rod, supporting blocks (27) are fixed at the three bottoms of the supporting plates, and the supporting blocks (27) are fixed with the bracket (7).

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