阅读说明：本技术 一种安装在楼顶的风力抽水装置 (Wind power pumping device installed on roof ) 是由 徐阳生 于 2020-06-11 设计创作，主要内容包括：本发明公开了一种安装在楼顶的风力抽水装置,包括水泵箱,所述水泵箱内设有压力腔,所述压力腔的下侧连通有连通管,所述连通管的左右两侧连接有球腔,右侧的所述球腔的下侧设有进水管,左侧的所述球腔连通有出水管,所述球腔内安装有能够堵住所述进水管或所述出水管的垫球,所述压力腔内滑动连接有推板,所述推板的上表面上固设有贯穿所述压力腔的顶壁并伸出所述水泵箱外侧的推杆,在风力充足时能够利用风力将水抽至楼顶,能够节省因电力抽水所损耗的电力,当风力不足时能够在电机的带动下保持水位在稳定的高度并提供充足的用水,对于多风的地区来说能够有较好的节能效果。(The invention discloses a wind power pumping device installed on a roof, which comprises a water pump box, wherein a pressure cavity is arranged in the water pump box, the lower side of the pressure cavity is communicated with a communicating pipe, the left side and the right side of the communicating pipe are connected with a ball cavity, the lower side of the ball cavity on the right side is provided with a water inlet pipe, the ball cavity on the left side is communicated with a water outlet pipe, a cushion ball capable of blocking the water inlet pipe or the water outlet pipe is arranged in the ball cavity, a push plate is connected in the pressure cavity in a sliding way, a push rod which penetrates through the top wall of the pressure cavity and extends out of the outer side of the water pump box is fixedly arranged on the upper surface of the push plate, when the wind power is sufficient, the wind power can be utilized to pump water to the roof, the power consumed by electric power pumping can be saved, when the wind power is insufficient, the water level can be kept at a stable height under the driving of the motor, sufficient water is provided, and a good energy-saving effect can be achieved for windy areas.)

1. The utility model provides an install wind-force pumping device at roof, includes the water pump box, its characterized in that: the water pump box is internally provided with a pressure cavity, the lower side of the pressure cavity is communicated with a communicating pipe, the left side and the right side of the communicating pipe are connected with a ball cavity, the lower side of the ball cavity on the right side is provided with a water inlet pipe, the ball cavity on the left side is communicated with a water outlet pipe, a cushion ball capable of blocking the water inlet pipe or the water outlet pipe is installed in the ball cavity, the pressure cavity is internally and slidably connected with a push plate, the upper surface of the push plate is fixedly provided with a push rod penetrating through the top wall of the pressure cavity and extending out of the outer side of the water pump box, the right side of the push rod is provided with an electric water pumping mechanism for enabling the push rod to move up and down, the left side of the push rod is provided with a transmission box fixedly arranged on the upper surface of the water pump box, the right wall of the transmission box is internally and, a first rotating shaft is rotatably connected to the left wall of the wind power cavity, a fan located on the outer side of the wind power box is fixedly arranged at the left end of the first rotating shaft, a tail rod is fixedly arranged on the right wall of the wind power box, a tail fin for changing direction is fixedly arranged at the right end of the tail rod, a first bevel gear is connected to the right end of the first rotating shaft in a key mode, a second bevel gear is connected to the lower side of the first bevel gear in a meshed mode, a second rotating shaft is connected to the lower side of the second bevel gear in a key mode, the lower end of the second rotating shaft penetrates through the bottom wall of the wind power cavity and extends into the transmission cavity, the second rotating shaft is fixedly and rotatably connected to the wind power box through a second bearing, a wind power pumping mechanism located in the transmission cavity and used for enabling the push rod to move up and down is arranged at the lower end of the second rotating shaft, a water tank is, and a control mechanism for controlling the on-off or on-off of the electric water pumping mechanism and the wind water pumping mechanism is arranged in the right wall of the water storage cavity.

2. The wind power water pumping device installed on the roof as claimed in claim 1, wherein: the electric water pumping mechanism comprises a power box fixedly arranged on the upper surface of the water pump box, a power cavity is arranged in the power box, a motor is fixedly arranged in the top wall of the power cavity, the lower side of the motor is in power connection with a motor shaft of which the lower end is rotatably connected into the bottom wall of the power cavity, a rotary column is fixedly arranged on the motor shaft, a track is fixedly arranged in the annular outer surface of the rotary column, and a sliding cavity communicated with the outer side penetrates through the left wall of the power cavity; the right side of push rod has set firmly branch, be equipped with first cavity in the right surface of branch, set firmly first electro-magnet on the left wall of first cavity, the right side fixedly connected with first spring of first electro-magnet, the right-hand member fixedly connected with sliding connection of first spring in the connecting rod of first cavity, the right-hand member of connecting rod set firmly sliding connection in slide cavity and with the support pole of track butt, first electro-magnet with parallelly connected through first electric wire between the motor.

3. The wind power water pumping device installed on the roof as claimed in claim 1, wherein: the wind power pumping mechanism comprises a second cavity which is positioned in the lower surface of the second rotating shaft, a second electromagnet is fixedly arranged on the top wall of the second cavity, the lower end of the second electromagnet is fixedly connected with a second spring, the lower side of the second spring is fixedly connected with a third rotating shaft which is connected with the second cavity in a sliding manner, the lower end of the third rotating shaft is in key connection with a third bevel gear, the right side of the third bevel gear is in meshing connection with a fourth bevel gear, the fourth bevel gear is in key connection with a fourth rotating shaft of which the left end is rotatably connected with the left wall of the transmission cavity, the right end of the fourth rotating shaft is fixedly provided with a rotating disc, the edge of the right surface of the rotating disc is rotatably connected with a short rod, the right end of the short rod is fixedly connected with a rocker of which the lower end is hinged with the push rod, the left wall of the transmission cavity is fixedly connected with a fixed rod, and the right, and a first iron sheet abutted against the inner ring wall of the iron ring is fixedly arranged in the annular outer surface of the second rotating shaft, and the first iron sheet is connected with the second electromagnet through a second electric wire circuit.

4. The wind power water pumping device installed on the roof as claimed in claim 1, wherein: control mechanism is including being located the third cavity in the water storage chamber right wall, run through in the roof of third cavity have with the fourth cavity of outside intercommunication, sliding connection has the pole that moves in the fourth cavity, move the pole about both ends set firmly two conducting rods, downside in the right wall of fourth cavity has set firmly the second iron sheet, the second iron sheet with connect through third electric wire circuit between the motor, upside in the right wall of fourth cavity has set firmly the third iron sheet, the third iron sheet with connect through fourth electric wire circuit between the iron ring, the downside the left side of conducting rod sets firmly and is located the kickboard in the water storage chamber.

Technical Field

The invention relates to the technical field of power driving equipment, in particular to a wind power water pumping device installed on a roof.

Background

Wind power is a very common power in nature, and mechanical force can be obtained from wind and converted into power or energy required by people;

in windy areas, the energy contained in wind power is very abundant, particularly in high positions such as roofs, water tanks are generally placed on the roofs, the water tanks may need water pumps to pump water, more electric energy can be consumed, and if the wind power rich in the roofs can be used for pumping water in the water tanks, the electric energy can be saved particularly in windy areas.

Disclosure of Invention

The invention aims to provide a wind power water pumping device installed on a roof, which is used for overcoming the defects in the prior art.

The wind power pumping device arranged on the roof comprises a water pump box, wherein a pressure cavity is arranged in the water pump box, the lower side of the pressure cavity is communicated with a communicating pipe, the left side and the right side of the communicating pipe are connected with ball cavities, the lower side of the right side of the ball cavity is provided with a water inlet pipe, the left side of the ball cavity is communicated with a water outlet pipe, a cushion ball capable of blocking the water inlet pipe or the water outlet pipe is arranged in the ball cavity, the pressure cavity is connected with a push plate in a sliding manner, the upper surface of the push plate is fixedly provided with a push rod penetrating through the top wall of the pressure cavity and extending out of the outer side of the water pump box, the right side of the push rod is provided with an electric pumping mechanism for enabling the push rod to move up and down, the left side of the push rod is provided with a transmission box fixedly arranged on the upper surface of the, the wind power box is fixedly connected in the first bearing, a wind power cavity is arranged in the wind power box, a first rotating shaft is rotationally connected in the left wall of the wind power cavity, a fan positioned on the outer side of the wind power box is fixedly arranged at the left end of the first rotating shaft, a tail rod is fixedly arranged on the right wall of the wind power box, a tail wing for changing direction is fixedly arranged at the right end of the tail rod, a first bevel gear is connected to the right end of the first rotating shaft in a key mode, a second bevel gear is meshed and connected to the lower side of the first bevel gear, a second rotating shaft is connected to the lower side of the second bevel gear in a key mode, the lower end of the second rotating shaft penetrates through the bottom wall of the wind power cavity and extends into the transmission cavity, the second rotating shaft is fixedly and rotatably connected to the wind power box through a second bearing, and a wind power pumping mechanism which is positioned in the transmission cavity and used, the left side fixedly connected with water tank of transmission case with the water pump case, be equipped with the water storage chamber in the water tank, be equipped with in the right wall in water storage chamber and be used for controlling electronic mechanism of drawing water with the control mechanism of wind-force mechanism switch or break-make.

On the basis of the technical scheme, the electric water pumping mechanism comprises a power box fixedly arranged on the upper surface of the water pump box, a power cavity is arranged in the power box, a motor is fixedly arranged in the top wall of the power cavity, the lower side of the motor is in power connection with a motor shaft of which the lower end is rotatably connected into the bottom wall of the power cavity, a rotary column is fixedly arranged on the motor shaft, a track is fixedly arranged in the annular outer surface of the rotary column, and a sliding cavity communicated with the outer side penetrates through the left wall of the power cavity; the right side of push rod has set firmly branch, be equipped with first cavity in the right surface of branch, set firmly first electro-magnet on the left wall of first cavity, the right side fixedly connected with first spring of first electro-magnet, the right-hand member fixedly connected with sliding connection of first spring in the connecting rod of first cavity, the right-hand member of connecting rod set firmly sliding connection in slide cavity and with the support pole of track butt, first electro-magnet with parallelly connected through first electric wire between the motor.

On the basis of the technical scheme, the wind power pumping mechanism comprises a second cavity which is positioned in the lower surface of the second rotating shaft, a second electromagnet is fixedly arranged on the top wall of the second cavity, the lower end of the second electromagnet is fixedly connected with a second spring, the lower side of the second spring is fixedly connected with a third rotating shaft which is connected with the second cavity in a sliding manner, the lower end of the third rotating shaft is in key connection with a third bevel gear, the right side of the third bevel gear is in meshed connection with a fourth bevel gear, the fourth bevel gear is in key connection with a fourth rotating shaft, the left end of the fourth rotating shaft is rotatably connected with the left wall of the transmission cavity, the right end of the fourth rotating shaft is fixedly provided with a rotating disc, the edge of the right surface of the rotating disc is rotatably connected with a short rod, the right end of the short rod is fixedly connected with a rocker, the lower end of the short rod, the right end of the fixed rod is fixedly provided with an iron ring sleeved with the second rotating shaft in a sliding mode, a first iron sheet abutted to the inner ring wall of the iron ring is fixedly arranged in the annular outer surface of the second rotating shaft, and the first iron sheet is connected with the second electromagnet through a second electric wire circuit.

On the basis of the technical scheme, the control mechanism comprises a third cavity located in the right wall of the water storage cavity, a fourth cavity communicated with the outer side is arranged in the top wall of the third cavity in a penetrating mode, a moving rod is connected in the fourth cavity in a sliding mode, two conducting rods are fixedly arranged at the upper end and the lower end of the moving rod, a second iron sheet is fixedly arranged on the lower side in the right wall of the fourth cavity, the second iron sheet is connected with the motor through a third electric wire circuit, a third iron sheet is fixedly arranged on the upper side in the right wall of the fourth cavity, the third iron sheet is connected with the iron rings through a fourth electric wire circuit, and a floating plate located in the water storage cavity is fixedly arranged on the left side of the conducting rod.

The invention has the beneficial effects that: can utilize wind-force to take out water to the roof when wind-force is sufficient, can save because of the electric power that electric power took out the water loss, can keep the water level at stable height and provide sufficient water under the drive of motor when wind-force is not enough, can have better energy-conserving effect to windy area.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic view showing the overall structure of a wind power pumping device installed on a roof according to the present invention;

FIG. 2 is an enlarged view of the invention at A in FIG. 1;

FIG. 3 is an enlarged view of the invention at B in FIG. 1;

fig. 4 is a schematic view of the structure of fig. 2 in the direction of C-C according to the present invention.

Detailed Description

The invention will now be described in detail with reference to fig. 1-4, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1-4, a wind pumping device installed on a roof according to an embodiment of the present invention includes a water pump tank 10, a pressure chamber 16 is disposed in the water pump tank 10, a communicating pipe 12 is communicated with a lower side of the pressure chamber 16, ball chambers 15 are connected to left and right sides of the communicating pipe 12, a water inlet pipe 13 is disposed on a lower side of the ball chamber 15 on the right side, a water outlet pipe 11 is communicated with the ball chamber 15 on the left side, a cushion ball 14 capable of blocking the water inlet pipe 13 or the water outlet pipe 11 is installed in the ball chamber 15, a push plate 17 is slidably connected in the pressure chamber 16, a push rod 18 penetrating through a top wall of the pressure chamber 16 and extending out of the water pump tank 10 is fixedly disposed on an upper surface of the push plate 17, an electric pumping mechanism 801 for moving the push rod 18 up and down is disposed on a right side of the push rod 18, a transmission box 23 fixedly disposed on an, a transmission cavity 28 is arranged in the right wall of the transmission case 23, a first bearing 50 is fixedly arranged in the top wall of the transmission cavity 28, a wind power case 38 is fixedly connected in the first bearing 50, a wind power cavity 36 is arranged in the wind power case 38, a first rotating shaft 40 is rotatably connected in the left wall of the wind power cavity 36, a fan 39 positioned outside the wind power case 38 is fixedly arranged at the left end of the first rotating shaft 40, a tail rod 33 is fixedly arranged on the right wall of the wind power case 38, a tail wing 32 for changing the direction is fixedly arranged at the right end of the tail rod 33, a first bevel gear 37 is connected to the right end of the first rotating shaft 40 in a key connection manner, a second bevel gear 34 is connected to the lower side of the first bevel gear 37 in a meshing manner, a second rotating shaft 35 is connected to the lower side of the second bevel gear 34 in a key manner, the lower end of the second rotating shaft 35 penetrates through the bottom wall of the wind power cavity 36 and extends into the transmission cavity 28, and the second rotating shaft 35 is fixedly and, the lower end of the second rotating shaft 35 is provided with a wind power pumping mechanism 802 which is positioned in the transmission cavity 28 and used for enabling the push rod 18 to move up and down, the transmission box 23 and the left side of the water pump box 10 are fixedly connected with a water tank 48, a water storage cavity 47 is arranged in the water tank 48, and a control mechanism 803 which is used for controlling the on-off or on-off of the electric pumping mechanism 801 and the wind power pumping mechanism 802 is arranged in the right wall of the water storage cavity 47.

In addition, in one embodiment, the electric water pumping mechanism 801 comprises a power box 19 fixedly arranged on the upper surface of the water pump box 10, a power cavity 69 is arranged inside the power box 19, a motor 67 is fixedly arranged in the top wall of the power cavity 69, a motor shaft 22 with the lower end rotatably connected into the bottom wall of the power cavity 69 is in power connection with the lower side of the motor 67, a rotary column 20 is fixedly arranged on the motor shaft 22, a rail 21 is fixedly arranged in the annular outer surface of the rotary column 20, and a sliding cavity 24 communicated with the outside penetrates through the left wall of the power cavity 69; a supporting rod 70 is fixedly arranged on the right side of the push rod 18, a first cavity 63 is arranged in the right surface of the supporting rod 70, a first electromagnet 64 is fixedly arranged on the left wall of the first cavity 63, a first spring 62 is fixedly connected to the right side of the first electromagnet 64, a connecting rod 65 which is slidably connected to the first cavity 63 is fixedly connected to the right end of the first spring 62, a supporting rod 61 which is slidably connected to the sliding cavity 24 and abutted to the rail 21 is fixedly arranged at the right end of the connecting rod 65, and the first electromagnet 64 and the motor 67 are connected in parallel through a first electric wire 66.

In addition, in one embodiment, the wind pumping mechanism 802 includes a second cavity 55 located in the lower surface of the second rotating shaft 35, a second electromagnet 52 is fixedly arranged on the top wall of the second cavity 55, a second spring 53 is fixedly connected to the lower end of the second electromagnet 52, a third rotating shaft 54 slidably connected to the second cavity 55 is fixedly connected to the lower side of the second spring 53, a third bevel gear 30 is connected to the lower end of the third rotating shaft 54 in a key manner, a fourth bevel gear 29 is connected to the right side of the third bevel gear 30 in a meshing manner, a fourth rotating shaft 31 with the left end rotatably connected to the left wall of the transmission chamber 28 is connected to the fourth bevel gear 29 in a key manner, a rotating disc 27 is fixedly arranged at the right end of the fourth rotating shaft 31, a short rod 26 is rotatably connected to the edge of the right surface of the rotating disc 27, and a rocker 25 with the lower end hinged to the push rod 18 is fixedly connected to the right end of the short, a fixing rod 58 is fixedly connected to the left wall of the transmission cavity 28, an iron ring 57 slidably sleeved on the second rotating shaft 35 is fixedly arranged at the right end of the fixing rod 58, a first iron sheet 51 abutted against the inner ring wall of the iron ring 57 is fixedly arranged on the annular outer surface of the second rotating shaft 35, and the first iron sheet 51 is in circuit connection with the second electromagnet 52 through a second electric wire 56.

In addition, in an embodiment, the control mechanism 803 includes a third cavity 42 located in the right wall of the water storage cavity 47, a fourth cavity 68 communicated with the outside penetrates through the top wall of the third cavity 42, a moving rod 41 is slidably connected in the fourth cavity 68, two conductive rods 43 are fixedly arranged at the upper and lower ends of the moving rod 41, a second iron sheet 45 is fixedly arranged at the lower side in the right wall of the fourth cavity 68, the second iron sheet 45 is electrically connected with the motor 67 through a third wire 46, a third iron sheet 60 is fixedly arranged at the upper side in the right wall of the fourth cavity 68, the third iron sheet 60 is electrically connected with the iron ring 57 through a fourth wire 59, and a floating plate 44 located in the water storage cavity 47 is fixedly arranged at the left side of the conductive rod 43 at the lower side.

In the initial state, water is not present in the water storage cavity 47, the floating plate 44 is located at the lowermost side, the conductive rod 43 at the lower side is in contact with the second iron sheet 45, the motor 67 is in the on state, the first electromagnet 64 is electrified and repels the connecting rod 65, the resisting rod 61 is in butt joint with the track 21, the third iron sheet 60 is in contact with the conductive rod 43 at the upper side, the second electromagnet 52 is electrified and adsorbs the third rotating shaft 54, and the third bevel gear 30 is located at the uppermost side and is not meshed with the fourth bevel gear 29.

When water pumping is needed, the motor 67 is in an open state, so the motor shaft 22 rotates and drives the rotary column 20 to rotate, and the push rod 18, the support rod 70, the connecting rod 65 and the abutting rod 61 can only slide up and down, so the push rod 18 does up-and-down reciprocating motion under the limitation of the track 21; when the push rod 18 moves downwards, the push plate 17 moves downwards, so that the pressure in the pressure cavity 16 and the communication pipe 12 is increased, the cushion ball 14 on the left side moves upwards and opens the water outlet pipe 11, the cushion ball 14 on the right side is pressed downwards and blocks the water inlet pipe 13, at the moment, water in the pressure cavity 16 is discharged from the water outlet pipe 11, when the push plate 17 moves upwards, the pressure in the pressure cavity 16 and the communication pipe 12 is reduced, the cushion ball 14 on the left side is pressed downwards and blocks the water outlet pipe 11, the cushion ball 14 on the right side moves upwards and opens the water inlet pipe 13, at the moment, water in the water inlet pipe 13 is sucked into the pressure cavity 16, and therefore, the function of pumping water is realized by the; therefore, the water level in the water storage cavity 47 gradually rises, the floating plate 44 floats upwards, the moving rod 41 moves upwards, the conducting rod 43 on the lower side is separated from contact with the second iron sheet 45, the motor 67 is turned off, the first electromagnet 64 is powered off, the push rod 18 stops moving upwards and downwards, the connecting rod 65 and the abutting rod 61 move leftwards under the elastic force of the first spring 62, the abutting rod 61 is separated from abutting contact with the track 21, the conducting rod 43 on the upper side is separated from contact with the third iron sheet 60, the second electromagnet 52 is powered off, the third rotating shaft 54 moves downwards under the elastic force of the second spring 53, and the third bevel gear 30 is meshed with the fourth bevel gear 29; if there is wind, the fan 39 rotates, the first rotating shaft 40 rotates, the first bevel gear 37 rotates, and the second bevel gear 34 rotates. Then the second rotating shaft 35 rotates, then the third rotating shaft 54 rotates, then the third bevel gear 30 rotates, then the fourth bevel gear 29 rotates, then the fourth rotating shaft 31 rotates, then the rotating disc 27 rotates, and the push rod 18 continues to move up and down through the rocker 25 and the short rod 26, at this time, the water level in the water storage cavity 47 will rise again; when the water in the water storage cavity 47 is about to be stored fully, the conducting rod 43 on the lower side contacts the third electromagnet 60, the second electromagnet 52 is electrified and adsorbs the third rotating shaft 54, the third rotating shaft 54 moves upwards to separate the third bevel gear 30 from the fourth bevel gear 29, and the push rod 18 does not move any more; when the water is consumed and the water level drops, the push rod 18 will again be moved up and down by the wind and pump water, and once there is not enough wind, the water level drops until the floating plate 44 is at the lowest side, the motor 67 will start and ensure that the water level is maintained at a certain height.

The invention has the beneficial effects that: can utilize wind-force to take out water to the roof when wind-force is sufficient, can save because of the electric power that electric power took out the water loss, can keep the water level at stable height and provide sufficient water under the drive of motor when wind-force is not enough, can have better energy-conserving effect to windy area.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.