CN111058997A

CN111058997A - Double-blade irrigateable wind motor

Info

Publication number: CN111058997A
Application number: CN202010049264.1A
Authority: CN
Inventors: 不公告发明人
Original assignee: Zhuji Dugao Fengneng Technology Co Ltd
Current assignee: Liaocheng Luliao Network Technology Co.,Ltd.
Priority date: 2020-01-16
Filing date: 2020-01-16
Publication date: 2020-04-24

Abstract

The invention discloses a double-blade irrigating wind motor which comprises a machine head, wherein fixed blocks are fixedly arranged on the upper end surface and the lower end surface of the machine head, a base is fixedly arranged on the lower end surface of the machine head, a power generation mechanism is arranged in the fixed blocks, a transmission mechanism for device transmission is arranged in the machine head, an irrigating mechanism for irrigating by using wind power is arranged in the irrigating mechanism, and during working, high-position wind energy and low-position wind energy can be converted into electric energy for storage, so that the utilization rate of the wind energy is improved, and part of the wind energy can be converted into mechanical energy while the wind energy is converted into the electric energy, so that the peripheral grasslands are irrigated in a rotating manner, and the automatic water.

Description

Double-blade irrigateable wind motor

Technical Field

The invention relates to the field of wind motors, in particular to a double-blade irrigated wind motor.

Background

The utilization of new energy is very popular, wherein the wind motor is equipment for generating electricity by using the new energy, and the wind motor can convert wind energy into electric energy through mechanical transmission.

At present, most wind motors only have a wind energy receiving device with a high level, so that the wind energy of the lower level cannot be utilized, and the general wind motors do not have the function of irrigating the surrounding environment by utilizing the wind energy.

Disclosure of Invention

The invention aims to solve the technical problem of providing a double-blade irrigated wind motor, which overcomes the problems that low-level wind energy cannot be utilized and the irrigation function is unavailable and increases the functions of utilizing the low-level wind energy and irrigating.

The invention is realized by the following technical scheme.

The invention discloses a double-blade irrigated wind motor which comprises a machine head, wherein fixed blocks are fixedly arranged on the upper end surface and the lower end surface of the machine head, a base is also fixedly arranged on the lower end surface of the machine head, a power generation mechanism is arranged in the fixed blocks, a transmission mechanism for device transmission is arranged in the machine head, and an irrigation mechanism for irrigating by using wind power is arranged in the irrigation mechanism;

the watering mechanism comprises a driving cavity at the upper end in the base, a rotating rod is rotatably arranged on the left cavity wall and the right cavity wall of the driving cavity, a first bevel gear, a driving belt wheel and a driven chain wheel are arranged on the rotating rod, a first driven cavity is arranged on the lower side of the driving cavity, a water storage cavity is arranged on the lower side of the first driven cavity, a rotating shaft is rotatably arranged on the left cavity wall and the right cavity wall of the first driven cavity, a driven belt wheel is arranged at the left end of the rotating shaft, a belt is connected between the driven belt wheel and the driving belt wheel, a sector gear is arranged at the right end of the rotating shaft, a rack with the upper end extending into the first driven cavity and the rear end surface engaged with the sector gear is arranged on the upper cavity wall of the water storage cavity, a push plate is fixedly arranged on the lower end surface of the rack, a tension, the water storage device is characterized in that a rotating ring capable of rotating in the cavity is arranged in the rotating cavity, four water pipes extending out of the side wall of the base are uniformly and fixedly arranged on the rotating ring, a spray head and four fixed rings are fixedly arranged at one end of each water pipe, a gear ring is fixedly arranged on the inner end face of the upper end of each fixed ring, a second driven cavity is arranged on the right side of the left end of each fixed ring, a rotating rod with the upper end extending into the driving cavity is rotatably arranged on the lower cavity wall of the second driven cavity, a rotating gear connected with the gear ring in a meshed mode is arranged at the lower end of the rotating rod, a second bevel gear connected with the first bevel gear in a meshed mode is arranged at the upper end of the rotating rod, a water inlet is externally connected to the rear cavity wall of the water storage cavity.

Furthermore, the power generation mechanism comprises two third driven cavities in the fixed blocks, a fan shaft with the right end extending out of the right cavity wall of the third driven cavity is rotatably arranged on the left cavity wall and the right cavity wall of the third driven cavity, three fan blades are fixedly arranged on the right end of the fan shaft, a cam and a third bevel gear which are arranged in the third driven cavity are arranged at the left end of the fan shaft, an accelerator and a generator which are arranged on the left side of the third driven cavity are arranged at the left end of the fan shaft, an electric wire is electrically connected with the left end face of the generator, the upper cavity wall of the third driven cavity and the upper cavity wall of the third driven cavity on the upper side and the lower side of the third driven cavity are respectively provided with a pushing block cavity with an upward opening and a downward opening, a pushing block capable of moving up and down in the cavity is arranged in the pushing block cavity, and an elastic.

Further, the transmission mechanism comprises a fifth driven cavity positioned on the right side in the machine head, a fourth driven cavity is arranged on the left side of the fifth driven cavity, a transmission shaft with the right end extending into the fifth driven cavity is rotatably arranged on the left cavity wall of the fourth driven cavity, a driving sprocket positioned in the fourth driven cavity is arranged at the left end of the transmission shaft, a chain is connected between the driving sprocket and the driven sprocket, a fifth bevel gear positioned in the fifth driven cavity is arranged at the right end of the transmission shaft, a sliding bevel gear positioned in the fifth driven cavity is in spline connection with one end of each of the two driven shafts, a sliding cavity with an upward opening is arranged in the sliding bevel gear on the upper side, a sliding block capable of sliding in the cavity is arranged in the sliding cavity, a pull rope is fixedly arranged on the upper end face of the sliding block, and a rotating disc positioned on the upper side of the sliding bevel gear, two reset springs are connected between the lower end face of the rotating disc and the upper end face of the sliding bevel gear, and the lower end face of the push block is fixedly connected with one end of the pull rope.

Further, the sum of the elastic force of the two return springs on the upper side and the gravity of the sliding bevel gear is larger than the friction force received by the sliding bevel gear when sliding on the driven shaft.

Furthermore, the pulling force of the pulling spring is greater than the sum of the friction force borne by the push plate when the push plate slides in the water storage cavity and the gravity of the push plate.

The invention has the beneficial effects that: the rotary irrigation device is simple in structure and convenient and fast to operate, and can convert high-position wind energy and low-position wind energy into electric energy for storage during working so as to improve the utilization rate of the wind energy.

Drawings

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

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural diagram at A-A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram at B-B in FIG. 1 according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram at C-C in FIG. 1 according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of the structure at D in FIG. 1 according to an embodiment of the present invention;

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: 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.

The double-blade irrigated wind motor disclosed by the accompanying drawings 1-5 comprises a machine head 10, wherein fixed blocks 19 are fixedly arranged on the upper end surface and the lower end surface of the machine head 10, a base 54 is also fixedly arranged on the lower end surface of the machine head 10, a power generation mechanism 27 is arranged in the fixed block 19, a transmission mechanism 14 for driving the machine head 10 is arranged in the machine head, an irrigation mechanism 33 for irrigating by wind power is arranged in the irrigation mechanism 33, the irrigation mechanism 33 comprises a driving cavity 29 positioned at the upper end in the base 54, rotating rods 51 are rotatably arranged on the left cavity wall and the right cavity wall of the driving cavity 29, a first bevel gear 52, a driving belt wheel 53 and a driven chain wheel 28 are arranged on the rotating rods 51, a first driven cavity 30 is arranged on the lower side of the driving cavity 29, a water storage cavity 36 is arranged on the lower side of the first driven cavity 30, a rotating shaft 39 is rotatably arranged on, a belt 49 is connected between the driven belt wheel 38 and the driving belt wheel 53, a sector gear 31 is arranged at the right end of the rotating shaft 39, a rack 32 with an upper end extending into the first driven cavity 30 and a rear end surface engaged with the sector gear 31 is arranged on the upper wall of the water storage cavity 36, a push plate 34 is fixedly arranged on the lower end surface of the rack 32, a tension spring 35 is connected between the upper end surface of the push plate 34 and the upper wall of the water storage cavity 36, a rotating cavity 41 with an inward opening is arranged on the lower wall of the water storage cavity 36, a rotating ring 40 capable of rotating in the cavity is arranged in the rotating cavity 41, four water pipes 42 extending out of the side wall of the base 54 are uniformly and fixedly arranged on the rotating ring 40, a spray head 43 is fixedly arranged at one end of each water pipe 42, the same fixing ring 44 is fixedly arranged on the upper end surfaces of the four water pipes 42, and a toothed, the right side of the left end of the fixing ring 44 is provided with a second driven cavity 47, the lower cavity wall of the second driven cavity 47 is rotatably provided with a rotating rod 48, the upper end of the rotating rod 48 extends into the driving cavity 29, the lower end of the rotating rod 48 is provided with a rotating gear 45 in meshed connection with the gear ring 46, the upper end of the rotating rod 48 is provided with a second bevel gear 50 in meshed connection with a first bevel gear 52, the rear cavity wall of the water storage cavity 36 is externally connected with a water inlet hole 55, and a floating plate 37 capable of sliding up and down in the cavity is arranged in the water storage cavity 36.

Advantageously, said power generating means 27 comprise a third driven chamber 21 located inside both said fixed blocks 19, a fan shaft 25 with the right end extending out of the right cavity wall of the third driven cavity 21 is rotatably arranged on the left and right cavity walls of the third driven cavity 21, three fan blades 26 are fixedly arranged at the right end of the fan shaft 25, a cam 20 and a third bevel gear 22 which are positioned in the third driven cavity 21 are arranged at the left end of the fan shaft 25, the left end of the fan shaft 25 is provided with an accelerator 18 and a generator 17 which are positioned on the left side of the third driven chamber 21, the left end face of the generator 17 is electrically connected with an electric wire 16, the lower cavity wall of the third driven cavity 21 at the upper side and the upper cavity wall of the third driven cavity 21 at the lower side are respectively provided with a push block cavity 58 with an upward opening and a downward opening, a push block 56 which can move up and down in the push block cavity 58 is arranged in the push block cavity 58, and an elastic spring 57 is connected between one end face of the push block 56 and one cavity wall of the push block cavity 58.

Advantageously, the transmission mechanism 14 includes a fifth driven cavity 66 located at the right side in the handpiece 10, a fourth driven cavity 12 is provided at the left side of the fifth driven cavity 66, a transmission shaft 15 with the right end extending into the fifth driven cavity 66 is rotatably provided at the left cavity wall of the fourth driven cavity 12, a driving sprocket 13 located in the fourth driven cavity 12 is provided at the left end of the transmission shaft 15, a chain 11 is connected between the driving sprocket 13 and the driven sprocket 28, a fifth bevel gear 59 located in the fifth driven cavity 66 is provided at the right end of the transmission shaft 15, a sliding bevel gear 65 located in the fifth driven cavity 66 is splined at one end of each of the two driven shafts 24, a sliding cavity 64 with an upward opening is provided in the sliding bevel gear 65 at the upper side, a sliding block 60 capable of sliding in the cavity is provided in the sliding cavity 64, a pull rope 62 is fixedly provided at the upper end face of the sliding block 60, one end of the driven shaft 24 is further provided with a rotating disc 61 positioned on the upper side of the sliding bevel gear 65, two return springs 63 are connected between the lower end face of the rotating disc 61 and the upper end face of the sliding bevel gear 65, and the lower end face of the push block 56 is fixedly connected with one end of the pull rope 62.

Advantageously, the sum of the elastic force of the two return springs 63 on the upper side and the weight force of the sliding bevel gear 65 is greater than the frictional force to which the sliding bevel gear 65 is subjected when sliding on the driven shaft 24.

Advantageously, the tension of the tension spring 35 is greater than the sum of the friction force experienced by the push plate 34 when sliding within the reservoir 36 and the weight of the push plate 34.

In the initial state, the fifth bevel gear 59 and the two sliding bevel gears 65 are in a disengaged state, respectively.

In operation, when wind blows to the fan blades 26 from a higher position, the fan blades 26 on the upper side rotate, the fan blades 26 rotate to drive the fan shaft 25, the cam 20 and the third bevel gear 22 to rotate, the fan shaft 25 rotates to convert mechanical energy into electric energy for storage in the generator 17 through the acceleration effect of the accelerator 18, the cam 20 rotates to push the push block 56 to move inwards, after the push block 56 is pushed into the push block cavity 58, the cam 20 slips on the fan shaft 25, the rotating disc 61 is released at the moment, the sliding bevel gear 65 loses the tensile force of the rotating disc 61 and moves downwards under the action of the return spring 63 to be meshed with the fifth bevel gear 59, the third bevel gear 22 rotates to drive the fourth bevel gear 23 meshed with the third bevel gear to rotate, so as to drive the sliding bevel gear 65 on the driven shaft 24 and the driven shaft 24 to rotate, so as to drive the fifth bevel gear 59 meshed with the driven shaft to rotate, so as to drive the transmission shaft 15, when wind blows to the fan blades 26 from a lower position, the wind energy can be used for generating electricity and driving the fifth bevel gear 59 to rotate;

when the wind energy is used for irrigation, the transmission shaft 15 rotates to drive the driving sprocket 13 to rotate, so as to drive the driven sprocket 28 connected with the transmission shaft through the chain 11 to rotate, the driven sprocket 28 rotates to drive the first bevel gear 52 and the driving pulley 53 to rotate, the driving pulley 53 rotates to drive the driven pulley 38 connected with the driving pulley through the belt 49 to rotate, so as to drive the rotating shaft 39 and the sector gear 31 on the rotating shaft 39 to rotate, when the sector gear 31 rotates to be meshed with the rack 32, the rack 32 is driven to move downwards to enable the water pressure water inlet pipe 42 in the water storage cavity 36, when the sector gear 31 rotates to be separated from the rack 32, the push plate 34 and the rack 32 move upwards to reset under the pulling force of the tension spring 35, when water exists in the water storage cavity 36, the floating plate 37 just blocks the water inlet hole 55 under the buoyancy of the water, and when the water in the water storage cavity 36 is discharged, the floating plate 37 descends to stop blocking the water, the water in the water inlet 55 enters the water storage chamber 36, the first bevel gear 52 rotates to drive the second bevel gear 50 in meshed connection therewith to rotate, so as to drive the rotating rod 48 and the rotating gear 45 at the lower end of the rotating rod 48 to rotate, and the rotating gear 45 rotates to drive the toothed ring 46 and the fixed ring 44 in meshed connection therewith to rotate, so as to drive the four water pipes 42 to rotate for rotary irrigation.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. A double-blade irrigated wind motor comprises a machine head, and is characterized in that: the machine head is internally provided with a transmission mechanism driven by a device, and the irrigation mechanism is internally provided with an irrigation mechanism for irrigating by wind power;

2. A dual-bladed, irrigateable wind turbine according to claim 1, wherein: the power generation mechanism comprises two third driven cavities in the fixed blocks, the left cavity wall and the right cavity wall of each third driven cavity are rotatably provided with fan shafts, the right ends of the fan shafts extend out of the right cavity wall of each third driven cavity, three fan blades are fixedly arranged at the right ends of the fan shafts, cams and third bevel gears are arranged at the left ends of the fan shafts and located in the third driven cavities, the left ends of the fan shafts are provided with accelerators and generators which are located on the left sides of the third driven cavities, the left end face of each generator is electrically connected with an electric wire, the upper side of the lower cavity wall and the lower side of each third driven cavity is provided with a push block cavity with an upward opening and a downward opening, a push block capable of moving up and down in the cavity is arranged in the push block cavity, and one end face of the push block is connected with an elastic spring between the first cavity walls.

3. A dual-bladed, irrigateable wind turbine according to claim 1, wherein: the transmission mechanism comprises a fifth driven cavity positioned on the right side in the machine head, a fourth driven cavity is arranged on the left side of the fifth driven cavity, a transmission shaft with the right end extending into the fifth driven cavity is arranged on the left cavity wall of the fourth driven cavity in a rotating manner, a driving sprocket positioned in the fourth driven cavity is arranged at the left end of the transmission shaft, a chain is connected between the driving sprocket and the driven sprocket, a fifth bevel gear positioned in the fifth driven cavity is arranged at the right end of the transmission shaft, a sliding bevel gear positioned in the fifth driven cavity is connected to one end of each of the two driven shafts through a spline, a sliding cavity with an upward opening is arranged in the sliding bevel gear on the upper side, a sliding block capable of sliding in the cavity is arranged in the sliding cavity, a pull rope is fixedly arranged on the upper end face of the sliding block, and a rotating disc positioned on the upper, two reset springs are connected between the lower end face of the rotating disc and the upper end face of the sliding bevel gear, and the lower end face of the push block is fixedly connected with one end of the pull rope.

4. A dual-bladed, irrigateable wind turbine according to claim 3, wherein: the sum of the elastic force of the two return springs on the upper side and the gravity of the sliding bevel gear is larger than the friction force applied to the sliding bevel gear when the sliding bevel gear slides on the driven shaft.

5. A dual-bladed, irrigateable wind turbine according to claim 1, wherein: the pulling force of the pulling spring is larger than the sum of the friction force borne by the push plate when the push plate slides in the water storage cavity and the gravity of the push plate.