CN111567421A - Cattle and sheep feeding device utilizing wind energy - Google Patents

Abstract

The invention discloses a cattle and sheep feeding device utilizing wind energy, which comprises a machine body, wherein a mincing space is arranged in the machine body, a shaft rod space is arranged at the rear side of the mincing space, a belt wheel space is arranged at the lower side of the shaft rod space, a bevel gear space is arranged at the lower side of the belt wheel space, a hydraulic chamber is arranged at the upper side of the mincing space, a nutrition chamber is arranged at the right side of the hydraulic chamber, an auxiliary force space is arranged at the right side of the nutrition chamber, a stirring space is arranged at the lower side of the auxiliary force space, a stirring wheel space is arranged at the lower side of the stirring space, and a rotating space is arranged at the rear side of a lifting space.

Description

Cattle and sheep feeding device utilizing wind energy

Technical Field

The invention relates to the field of wind energy, in particular to a cattle and sheep feeding device utilizing wind energy.

Background

The livestock industry plays an important role from old to present, is a standard for measuring the development level of agriculture, provides milk products, meat products and other necessary products for current life for people, and is rapidly developed along with the rapid development of the economic level in recent years, gradually becomes an important part of the development of modern agriculture and is also an important prop industry for the growth of agricultural economy; however, the development of animal husbandry is accompanied by the problem, the traditional feeding needs workers to operate in person, the workers cannot add the feed in the first time after the feed is used up, the workers need to monitor constantly, the manpower expenditure is increased, meanwhile, the feed cannot be supplied in time, the growth of cattle and sheep is affected, and the breeding economic benefit is reduced.

The invention aims to provide a cattle and sheep feeding device utilizing wind energy to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme: a cattle and sheep feeding device utilizing wind energy comprises a machine body, wherein four movable wheels used for moving are arranged at the bottom of the machine body, a mincing space is arranged in the machine body, a shaft rod space is arranged at the rear side of the mincing space, a belt wheel space is arranged at the lower side of the shaft rod space, a bevel gear space is arranged at the lower side of the belt wheel space, a hydraulic chamber is arranged at the upper side of the mincing space, a nutrition chamber is arranged at the right side of the hydraulic chamber, an auxiliary force space is arranged at the right side of the nutrition chamber, a reaction space is arranged at the right side of the auxiliary force space, a stirring space is arranged at the lower side of the auxiliary force space, a stirring wheel space is arranged at the lower side of the stirring space, a lifting space is arranged at the right side of the stirring wheel space, a rotating space is arranged at the rear side of the lifting space, a contact space is, the upper side of the touch cavity is provided with a power hydraulic cavity, the right side wall of the touch cavity is communicated with a friction space, the right side of the lifting space is provided with a moving space, the lower side of the lifting space is provided with a roller space, the top wall of the machine body is provided with a power supply device which generates power by utilizing wind energy, the power supply device comprises a power supply machine which is fixedly arranged on the top wall of the machine body, a power generation block is fixedly arranged on the power supply machine, the power generation block is rotatably connected with a power rod, the power rod is fixedly connected with a fan frame, the front end of the fan frame is fixedly provided with a guide fan blade, the rear end of the fan frame is provided with a collecting device which is used for collecting grass materials, the rubbing space and the stirring wheel space are internally provided with a collecting device which is used for collecting grass materials, and the rubbing space, the nutrition cavity, the stirring space, the auxiliary, conveying devices are arranged in the reaction space and the lifting space, feeding devices for feeding are arranged in the moving space and the roller space, conveying devices for operation are arranged in the rotating space, the contact space, the touch cavity, the power hydraulic cavity and the friction space, and driving devices are arranged in the shaft lever space, the belt wheel space and the bevel gear space.

Preferably, the collecting device comprises a stirring wheel shaft rotatably mounted on the rear side wall of the stirring wheel space, the stirring wheel shaft extends backwards to penetrate through the rear side wall of the stirring wheel space and enters the bevel gear space and is rotatably connected with the front side wall and the rear side wall of the bevel gear space, the front end of the stirring wheel shaft is fixedly connected with a stirring wheel, the rear end of the stirring wheel shaft is fixedly connected with a driven bevel gear, the left side of the stirring wheel is fixedly provided with a suction pipeline, the upper side of the suction pipeline is fixedly connected with an air pump, the other side of the air pump is communicated with the mincing space, the mincing space is symmetrically and rotatably connected with mincing shafts in the left-right direction, the mincing shafts are fixedly provided with mincing knife wheels, each mincing shaft extends backwards to penetrate through the rear side wall of the mincing space and enters the shaft lever space and is rotatably connected with the front side wall and the rear side wall of the shaft lever space, and the, a driving gear is fixedly arranged at the rear end of the right rubbing shaft and is meshed with the driven gear, and a kinetic energy secondary bevel gear is arranged on the rear side of the driving gear.

Preferably, the stirring device comprises a rotating plate shaft rotatably mounted on the left side wall of the mincing space, a rotating plate is fixedly arranged on the rotating plate shaft, a rotating plate spring is fixedly connected between the rotating plate and the bottom wall of the mincing space, a rotating shaft is rotatably connected to the nutrition cavity, a covering plate is fixedly arranged on the rotating shaft, a hydraulic main rod is slidably connected between the right end of the hydraulic cavity and the nutrition cavity, a hydraulic slave rod is slidably connected between the left end of the hydraulic cavity and the mincing space, the other side of the hydraulic slave rod is hinged to the right end of the rotating plate, stirring shafts are rotatably connected to the upper side wall and the lower side wall of the nutrition cavity, stirring belt wheel reaction spaces are fixedly arranged on the stirring shafts, the stirring shafts extend downwards to penetrate through the lower side wall of the auxiliary force space to enter the stirring space and are rotatably connected with the upper side wall and the lower side wall of the stirring space, and a stirring frame is fixedly arranged on the lower end of the stirring shaft.

Preferably, the conveying device comprises conveying shafts which are rotationally mounted on the lifting space in an up-down symmetry manner, the conveying shafts on the upper side extend backwards to penetrate through the rear side wall of the lifting space and enter the rotating space and are rotationally connected with the front side wall and the rear side wall of the rotating space, conveying bevel gears are fixedly arranged at the rear ends of the conveying shafts on the upper side, belt pulleys are fixedly arranged on each conveying shaft, a belt is connected between the two belt pulleys, four fixing blocks are arranged on the left side of the belt, a fixing shaft is rotationally connected with each fixing block, a button spring is fixedly arranged on each fixing shaft, a lifting plate is fixedly arranged on each button spring, a telescopic spring is arranged between the left side and the right side of each lifting plate, a touch block is fixedly arranged on the upper side wall of the reaction space, and a sliding block is slidably connected with the left side wall of the reaction space, the right side of the sliding block is provided with a touch block, a pressure spring is connected between the touch block and the sliding block, the lower end of the touch block is fixedly provided with a movable plate, the movable plate extends downwards to penetrate through the lower side wall of the reaction space to enter the groove, and the movable plate can move between the groove and the reaction space.

As preferred, feeding device installs including rotating the drum shaft of lateral wall about the drum space, the drum band pulley has set firmly on the right side of drum shaft, the drum has set firmly on the left side of drum shaft, sliding connection has the receipts workbin on the lower lateral wall in removal space, receive the workbin with fixedly connected with removes the plate between the drum, sliding connection has the compression plate on the lateral wall about receiving the workbin, the compression plate with be connected with two atress springs between the diapire of receiving the workbin, fixedly connected with pneumatic pump on the right side wall of receiving the workbin, the left side of pneumatic pump has set firmly the material suction pipe, the shunt tubes has set firmly on the right-hand member of pneumatic pump, six shower nozzles of fixedly connected with on the shunt tubes are used for spraying the fodder, the downside of shower nozzle is in the groove of feeding has set firmly on the receipts workbin.

Preferably, the transportation device comprises a long rotating shaft rotatably mounted on the lower side wall of the rotating space, the long rotating shaft extends downwards to penetrate through the lower side wall of the rotating space to enter the contact space and is rotatably connected with the upper side wall and the lower side wall of the contact space, a secondary conveying bevel gear is fixedly arranged at the upper end of the long rotating shaft and is meshed with the conveying bevel gear, a friction driving wheel is fixedly arranged at the lower end of the long rotating shaft, a hydraulic slide block is slidably connected to the right side of the power hydraulic cavity and is fixedly connected with the hydraulic shaft, a bidirectional motor is slidably connected to the left side of the power hydraulic cavity and is in reverse direction, a bidirectional motor shaft is in power connection with the bidirectional motor, a main friction wheel is fixedly arranged on the shaft of the bidirectional motor and is meshed with the main friction driving wheel, the friction space is characterized in that a friction driving shaft is rotatably connected to the upper side wall and the lower side wall of the friction space, a friction secondary wheel is fixedly arranged at the upper end of the friction driving shaft, a friction bevel gear is fixedly arranged at the lower end of the friction driving shaft, a friction driven shaft is rotatably connected to the wall of the friction secondary wheel on the right side of the friction space, a friction secondary bevel gear is fixedly arranged at the left end of the friction driven shaft, the friction secondary bevel gear is meshed with the friction bevel gear, a roller main belt wheel is fixedly arranged at the right end between the friction driven shafts, and a roller belt is connected between the roller main belt wheel and the roller belt wheel.

Preferably, the driving device includes a driving shaft rotatably mounted on upper and lower side walls of the shaft rod space, the driving shaft is in power connection with the power supply, a driving bevel gear space is fixedly provided on the driving shaft, a kinetic energy bevel gear is fixedly provided on a left end of the driving shaft, the kinetic energy bevel gear is engaged with the kinetic energy secondary bevel gear, a driving secondary bevel gear is fixedly provided on a right end of the driving shaft, the driving secondary bevel gear is engaged with the driving bevel gear in a reverse direction, the driving shaft extends downward to penetrate through a lower side wall of the shaft rod space to enter the belt wheel space and is rotatably connected with the upper and lower side walls of the belt wheel space, a main driving belt wheel is fixedly provided on the driving shaft, a wheel shaft is rotatably connected with the upper and lower side walls of the belt wheel space, a driving secondary belt wheel is fixedly provided on the wheel shaft, and a driving belt is connected between the driving secondary belt wheel and the main driving belt wheel, the driving shaft continuously extends downwards to penetrate through the lower side wall of the belt wheel space and enter the bevel gear space and is rotatably connected with the upper side wall of the bevel gear space, a driving bevel gear is fixedly arranged on the bottom end of the driving shaft, an auxiliary shaft extending left and right is arranged on the lower side wall of the bevel gear space, a driven bevel gear is fixedly arranged on the left end of the auxiliary shaft and is meshed with the driven bevel gear, an auxiliary bevel gear is fixedly arranged on the right end of the auxiliary shaft, and the auxiliary bevel gear is meshed with the driving bevel gear.

In conclusion, the beneficial effects of the invention are as follows: the invention utilizes wind energy as a drive to supply power for the motor, achieves the effects of saving cost and protecting the environment, can continuously harvest forage in the running process, can trigger the devices of the nutrition bin when the forage is harvested to a specified amount, can fall into the stirring cavity to stir the forage and the nutrition bin, can be unfolded through the conveying device to feed cattle and sheep, does not need to be constantly monitored by workers, worrys about the problem that the forage cannot be supplied in time, reduces the expenditure on manpower, and increases the efficiency and the working time.

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 overall cross-sectional front view of a cattle and sheep feeding device using wind energy according to the present invention;

FIG. 2 is a schematic view of the structure A-A of FIG. 1 according to the present invention;

FIG. 3 is a schematic view of the structure B-B of FIG. 2 according to the present invention;

FIG. 4 is a schematic view of the structure C-C of FIG. 2 according to the present invention;

FIG. 5 is an enlarged view of the detail taken at D in FIG. 1 in accordance with the present invention;

FIG. 6 is a schematic view of the structure E-E of FIG. 1 according to the present invention.

Detailed Description

All of the features disclosed in this specification, or all of the steps in any method or process so disclosed, may be combined in any combination, except combinations and/or steps that are mutually exclusive.

Any feature disclosed in this specification (including any accompanying claims, abstract and drawings), may be replaced by alternative features serving equivalent or similar purposes, unless expressly stated otherwise. That is, unless expressly stated otherwise, each feature is only an example of a generic series of equivalent or similar features.

The invention will now be described in detail with reference to fig. 1-6, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, front and rear directions described below correspond to the front, back, left, right, top and bottom directions of the view direction of fig. 1, fig. 1 is a front view of the apparatus of the present invention, and the directions shown in fig. 1 correspond to the front, back, left, right, top and bottom directions of the apparatus of the present invention.

Referring to fig. 1-6, an embodiment of the present invention is shown: a cattle and sheep feeding device utilizing wind energy comprises a machine body 105, four movable wheels 30 used for moving are arranged at the bottom of the machine body 105, a mincing space 5 is arranged in the machine body 105, a shaft rod space 13 is arranged at the rear side of the mincing space 5, a belt wheel space 14 is arranged at the lower side of the shaft rod space 13, a bevel gear space 15 is arranged at the lower side of the belt wheel space 14, a hydraulic chamber 108 is arranged at the upper side of the mincing space 5, a nutrition chamber 6 is arranged at the right side of the hydraulic chamber 108, an auxiliary force space 106 is arranged at the right side of the nutrition chamber 6, a reaction space 8 is arranged at the right side of the auxiliary force space 106, a stirring space 7 is arranged at the lower side of the auxiliary force space 106, a stirring wheel space 9 is arranged at the lower side of the stirring space 7, a lifting space 10 is arranged at the right side of the stirring wheel space 9, a rotating space 16 is arranged at the rear side of, the right side wall of the contact space 17 is communicated with a touch chamber 18, the upper side of the touch chamber 18 is provided with a power hydraulic chamber 19, the right side wall of the touch chamber 18 is communicated with a friction space 20, the right side of the lifting space 10 is provided with a moving space 11, the lower side of the lifting space 10 is provided with a roller space 12, the top wall of the machine body 105 is provided with a power supply device 140 for generating power by wind energy, the power supply device 140 comprises a power supply machine 83 fixedly mounted on the top wall of the machine body 105, a power generation block 147 is fixedly arranged on the power supply machine 83, a power rod 107 is rotatably connected on the power generation block 147, a fan frame 56 is fixedly connected on the power rod 107, a fan guide blade 57 is fixedly arranged on the front end of the fan frame 56, the rear end of the fan frame 56 is provided with a fan blade 55, and a collecting device 141 for collecting grass is arranged in the grinding space 5 and the stirring wheel space 9, stirring devices 142 for stirring are arranged in the mincing space 5, the nutrition chamber 6, the stirring space 7, the auxiliary force space 106 and the hydraulic chamber 108, conveying devices 143 are arranged in the reaction space 8 and the lifting space 10, feeding devices 144 for feeding are arranged in the moving space 11 and the roller space 12, transporting devices 145 for operation are arranged in the rotating space 16, the contact space 17, the touch chamber 18, the power hydraulic chamber 19 and the friction space 20, and driving devices 146 for driving are arranged in the shaft rod space 13, the belt wheel space 14 and the bevel gear space 15.

In addition, in one embodiment, the collecting device 141 includes an agitating shaft 35 rotatably mounted on the rear sidewall of the agitating wheel space 9, the agitating shaft 35 extends backward to penetrate through the rear sidewall of the agitating wheel space 9 to enter the bevel gear space 15 and is rotatably connected with the front and rear sidewalls of the bevel gear space 15, the front end of the agitating shaft 35 is fixedly connected with an agitating wheel 34, the rear end of the agitating shaft 35 is fixedly connected with a driven bevel gear 75, the left side of the agitating wheel 34 is fixedly provided with a suction pipe 22, the upper side of the suction pipe 22 is fixedly connected with an air pump 21, the other side of the air pump 21 is communicated with the grinding space 5, the grinding space 5 is rotatably connected with grinding shafts 24 in a left-right symmetry manner, the grinding cutter wheels 23 are fixedly provided on the grinding shafts 24, each grinding shaft 24 extends backward to penetrate through the rear sidewall of the grinding space 5 to enter the shaft lever space 13, and is connected with the front and back side wall of the shaft lever space 13 in a rotating way, a driven gear 64 is fixedly arranged at the back end of the mincing shaft 24 at the left side, a driving gear 66 is fixedly arranged at the back end of the mincing shaft 24 at the right side, the driving gear 66 is meshed with the driven gear 64, a kinetic energy auxiliary bevel gear 65 is arranged at the back side of the driving gear 66, when the stirring wheel shaft 35 rotates, the stirring wheel 34 is driven to rotate to harvest forage, and the air pump 21 is opened, so that the forage is sucked into the mincing space 5 through the suction pipeline 22, and the mincing shafts 24 which are symmetrical left and right in the mincing space 5 rotate to stir the forage in the process of sucking the forage.

In addition, in one embodiment, the stirring device 142 includes a rotating plate shaft 26 rotatably installed on the left side wall of the grinding space 5, a rotating plate 25 is fixedly installed on the rotating plate shaft 26, a rotating plate spring 29 is fixedly connected between the rotating plate 25 and the bottom wall of the grinding space 5, a rotating shaft 60 is rotatably connected to the nutrition chamber 6, a cover plate 59 is fixedly installed on the rotating shaft 60, a hydraulic main rod 63 is slidably connected between the right end of the hydraulic chamber 108 and the nutrition chamber 6, a hydraulic slave rod 62 is slidably connected between the left end of the hydraulic chamber 108 and the grinding space 5, the other side of the hydraulic slave rod 62 is hinged to the right end of the rotating plate 25, stirring shafts 32 are rotatably connected to the upper and lower side walls of the nutrition chamber 6, stirring pulleys 5 reaction spaces 8 are fixedly installed on the stirring shafts 32, the stirring shafts 32 extend downward to penetrate through the lower side wall of the auxiliary force space 106 to enter the stirring space 7, and with the upper and lower lateral wall of stirring space 7 rotates to be connected, stirring frame 31 has set firmly on the lower extreme of (mixing) shaft 32, works as forage weight on the commentaries on classics board 25 reaches the specified standard, thereby makes commentaries on classics board 25 slope pours the forage into in stirring space 7, thereby makes hydraulic pressure is followed pole 62 and is moved down and drive hydraulic pressure mobile jib 63 moves left, thereby makes nutrition fodder in the counter force space 106 falls into in 6, thereby through (mixing) shaft 32 rotates the drive stirring frame 31 stirs.

In addition, in one embodiment, the conveying device 143 includes conveying shafts 36 rotatably installed on the lifting space 10 in an up-down symmetrical manner, the upper conveying shaft 36 extends backward through a rear sidewall of the lifting space 10 into the rotating space 16 and is rotatably connected to front and rear sidewalls of the rotating space 16, a conveying bevel gear 84 is fixedly installed at a rear end of the upper conveying shaft 36, a belt pulley 50 is fixedly installed on each conveying shaft 36, a belt 49 is connected between two belt pulleys 50, four fixing blocks 98 are installed on a left side of the belt 49, a fixing shaft 99 is rotatably connected to each fixing block 98, a toggle spring 100 is fixedly installed on each fixing shaft 99, a lifting plate 102 is fixedly installed on each toggle spring 100, a telescopic spring lifter 101 is installed between a left side and a right side of each lifting plate 102, a touch stopper 54 is fixedly installed on an upper sidewall of the reaction space 8, the left side wall of the reaction space 8 is slidably connected with a sliding block 53, the right side of the sliding block 53 is provided with a touch block 51, a pressure spring 52 is connected between the touch block 51 and the sliding block 53, the lower end of the touch block 51 is fixedly provided with a movable plate 33, the movable plate 33 extends downwards to penetrate through the lower side wall of the reaction space 8 to enter the groove 61 and can move between the groove 61 and the reaction space 8, when the upper end of the movable plate rotates, the conveying shaft 36 drives the corresponding belt pulley 50 to rotate, so that the belt 49 is driven to transmit, the lifting plate 102 with one end can be arranged on the top of the touch block 51 to move upwards, the movable plate 33 is driven to move upwards, and the feed is poured onto the corresponding lifting plate 102.

In addition, in one embodiment, the feeding device 144 includes a roller shaft 37 rotatably installed on the left and right side walls of the roller space 12, a roller belt wheel 41 is fixedly installed on the right side of the roller shaft 37, a roller 40 is fixedly installed on the left side of the roller shaft 37, a material receiving box 48 is slidably connected to the lower side wall of the moving space 11, a moving plate 39 is fixedly connected between the material receiving box 48 and the roller 40, a pressure receiving plate 43 is slidably connected to the left and right side walls of the material receiving box 48, two force receiving springs 42 are connected between the pressure receiving plate 43 and the bottom wall of the material receiving box 48, a pneumatic pump 46 is fixedly connected to the right side wall of the material receiving box 48, a material suction pipe 47 is fixedly installed on the left side of the pneumatic pump 46, a shunt pipe 103 is fixedly installed on the right end of the pneumatic pump 46, six spray nozzles 45 are fixedly connected to the shunt pipe 103 for spraying the feed, a feeding groove 104 is fixedly installed on the material, when the roller belt wheel 41 rotates to drive the roller shaft 37 to rotate, so as to drive the roller 40 to rotate, so that the material receiving box 48 is driven to move to a specified position through the moving plate 39, and meanwhile, the pneumatic pump 46 is started to suck the feed through the material sucking pipe 47, so that the feed is sprayed onto the feeding trough 104 through the spray head 45.

In addition, in one embodiment, the transportation device 145 includes a long rotating shaft 86 rotatably mounted on the lower sidewall of the rotating space 16, the long rotating shaft 86 extends downward to penetrate through the lower sidewall of the rotating space 16 into the contact space 17 and is rotatably connected with the upper and lower sidewalls of the contact space 17, a secondary conveying bevel gear 85 is fixedly mounted on the upper end of the long rotating shaft 86, the secondary conveying bevel gear 85 is engaged with the conveying bevel gear 84, a friction driving wheel 87 is fixedly mounted on the lower end of the long rotating shaft 86, a hydraulic slider 97 is slidably connected on the right side of the power hydraulic chamber 19, the hydraulic slider 97 is fixedly connected with the hydraulic shaft 44, a bidirectional motor counter 88 is slidably connected on the left side of the power hydraulic chamber 19, a bidirectional motor inter-shaft 89 is dynamically connected on the bidirectional motor 88, a main friction wheel 90 is fixedly mounted on the shaft 8 and 9 of the bidirectional motor, the friction main wheel 90 is engaged with the friction driving wheel 87, the upper and lower side walls of the friction space 20 are rotatably connected with a friction driving shaft 92, the upper end of the friction driving shaft 92 is fixedly provided with a friction auxiliary wheel 91, the lower end of the friction driving shaft 92 is fixedly provided with a friction bevel gear 93, the wall of the right side friction auxiliary wheel 91 of the friction space 20 is rotatably connected with a friction driven shaft 95, the left end of the friction driven shaft 95 is fixedly provided with a friction auxiliary bevel gear 94, the friction auxiliary bevel gear 94 is engaged with the friction bevel gear 93, the right end of the friction driven shaft 95 is fixedly provided with a roller main belt wheel 96, the roller main belt wheel 96 is connected with the roller belt wheel 41, when the bidirectional motor 88 is started in forward rotation, the friction main wheel 90 is driven to rotate by the bidirectional motor shaft 89, so as to be engaged with the friction driving wheel 87 by the friction main wheel 90, thereby rotating the rotary long shaft 86, and thus the conveying shaft 36 is rotated by the engagement of the conveying auxiliary bevel gear 85 with the conveying bevel gear 84, and when the hydraulic slider 97 moves downward, thereby discharging the hydraulic oil in the power hydraulic chamber 19 from the right side to the left side, thereby moving the two-way motor 88 downward, thereby engaging the friction main wheel 90 with the friction auxiliary wheel 91, and starting the two-way motor 88 to rotate in reverse, thereby causing the friction bevel gear 93 to engage the friction auxiliary bevel gear 94 to rotate, thereby rotating the friction driven shaft 95, thereby rotating the roller main pulley 96, and thereby rotating the roller pulley 41 via the roller belt 27.

In addition, in one embodiment, the driving device 146 includes a driving shaft 80 rotatably mounted on the upper and lower sidewalls of the shaft space 13, the driving shaft 80 is in power connection with the power supply 83, a driving bevel gear space 9 is fixedly mounted on the driving shaft 80, a kinetic bevel gear 67 is fixedly mounted on the left end of the driving shaft 109, the kinetic bevel gear 67 is engaged with the kinetic secondary bevel gear 65, a driving secondary bevel gear 81 is fixedly mounted on the right end of the driving shaft 109, the driving secondary bevel gear 81 is engaged with the driving bevel gear 82, the driving shaft 80 extends downward to penetrate through the lower sidewall of the shaft space 13 to enter the pulley space 14 and is rotatably connected with the upper and lower sidewalls of the pulley space 14, a main driving pulley 73 is fixedly mounted on the driving shaft 80, and a pulley shaft 71 is rotatably connected on the upper and lower sidewalls of the pulley space 14, a driving secondary pulley 70 is fixedly arranged on the pulley shaft 71, a driving belt 72 is connected between the driving secondary pulley 70 and the driving pulley 73, a driving belt 69 is connected between the driving secondary pulley 70 and the stirring pulley 58, the driving shaft 80 continuously extends downwards to penetrate through the lower side wall of the pulley space 14 to enter the bevel gear space 15 and is rotatably connected with the upper side wall of the bevel gear space 15, a driving bevel gear 79 is fixedly arranged on the bottom end of the driving shaft 80, a secondary shaft 77 extending leftwards and rightwards is arranged on the lower side wall of the bevel gear space 15, a secondary bevel gear 76 is fixedly arranged on the left end of the secondary shaft 77, the secondary bevel gear 76 is engaged with the driven bevel gear 75, a secondary bevel gear 7-8 is fixedly arranged on the right end of the secondary shaft 77, and the secondary bevel gear 78 is engaged with the driving bevel gear 79, when the driving shaft 80 rotates, the driving bevel gear 82 is rotated, so that the driving bevel pinion 81 is engaged to rotate the driving shaft 109, so that the kinetic energy bevel gear 67 and the kinetic energy bevel pinion 65 are engaged to rotate, so that the driving gear 66 and the driven gear 64 are engaged to rotate, and the driving pulley 73 is rotated, so that the driving pulley 70 is rotated by the driving belt 72, so that the driving belt 69 rotates the stirring pulley 58, and the driving bevel gear 79 on the bottom end of the driving shaft reaction space 80 is engaged to rotate the driven bevel gear 78, so that the driven shaft 77 is rotated, so that the driven bevel gear 76 is engaged to rotate the driven bevel gear 75, so that the stirring shaft 35 is rotated.

In the initial state, the air guiding fan 57 is kept in a static state, the machine body 105 is in a static state, and the material receiving box 48 is recovered in the cavity of the machine body 105.

When the trolley runs on grass, due to the action of wind force, the fan frame 56 is swung to the direction which is most suitable for facing the wind by the 55, the wind force is converted into power to the auxiliary force space 106 through the rotation of the fan guide blade 57 to generate power, the power is led to the power supply 83 through the auxiliary force space 106, the power supply 83 is started, so that the driving shaft 80 rotates, the driving bevel gear 82 rotates, the driving bevel gear 81 is engaged to drive the driving force to rotate from the shaft 109, the kinetic bevel gear 67 and the kinetic bevel gear 65 are engaged to rotate, the driving gear 66 and the driven gear 64 are engaged to rotate, the main driving pulley 73 rotates, the driving secondary pulley 70 is driven to rotate through the driving belt 72, and the stirring pulley 58 is driven to rotate by the driving belt 69, meanwhile, the driving bevel gear 79 on the bottom end of the driving shaft 80 is engaged with the auxiliary bevel gear 78 to rotate, so that the auxiliary shaft 77 rotates, so that the auxiliary bevel gear 76 is engaged with the driven bevel gear 75 to rotate, so that the stirring wheel shaft 35 is driven to rotate, so that the stirring wheel 34 is driven to rotate to harvest forage, and the air pump 21 is opened, so that the forage is sucked into the grinding space 5 through the suction pipeline 22, in the process of sucking the forage, the grinding shafts 24 which are bilaterally symmetrical on the grinding space 5 rotate to stir the forage, when the weight of the forage on the rotating plate 25 reaches a specified standard, so that the rotating plate 25 is inclined to pour the forage into the stirring space 7, so that the hydraulic pressure moves downwards from the rod 62 to drive the hydraulic main rod 63 to move leftwards, so that the nutritional forage in the nutrition cavity 6 falls into the stirring space 7, thereby rotating the stirring frame 31 through the stirring shaft 32 to stir, when controlling the two-way motor 88 to rotate forward, thereby driving the main friction wheel 90 to rotate through the two-way motor shaft 89, thereby engaging with the main friction wheel 87 through the main friction wheel 90, thereby driving the long rotating shaft 86 to rotate, thereby engaging with the bevel conveying gear 84 through the bevel conveying gear 85, thereby driving the upper end conveying shaft 36 to rotate, thereby driving the corresponding belt pulley 50 to rotate, thereby driving the belt 49 to transmit, thereby enabling the lifting plate 102 with one end to be capable of moving upwards by the top-mounted touch block 51, thereby driving the moving plate 33 to move upwards, thereby enabling the stirred feed in the auxiliary force space 106 to be guided onto the corresponding lifting plate 102, and to be guided into the receiving box 48 through transmission, when the amount of the feed reaches the designated standard, thereby enabling the hydraulic shaft 44 on the pressed plate 43 to move downwards, thereby causing the hydraulic slider 97 to move downward, thereby discharging the hydraulic oil in the power hydraulic chamber 19 from the right side to the left side, thereby moving the bi-directional motor 88 downward, thereby engaging the main friction wheel 90 with the auxiliary friction wheel 91, controlling the bi-directional motor 88 to rotate in reverse, so that the friction bevel gear 93 is engaged with the friction secondary bevel gear 94 to rotate, thereby driving the friction driven shaft 95 to rotate, thereby rotating the drum primary pulley 96 and, thus, the drum pulley 41 via the drum belt 27, and, when the drum pulley 41 is rotated, thereby driving the roller shaft 37 to rotate, driving the roller 40 to rotate, driving the material receiving box 4 to reversely move 8 to a designated position by moving the plate 3 and the stirring 9, controlling the bidirectional motor 88 to stop rotating, at the same time, the pneumatic pump 46 is actuated to suck the fodder through the suction pipe 47, thereby spraying the fodder through the spray nozzle 45 onto the feeding tank 104.

The invention has the beneficial effects that: the invention utilizes wind energy as a drive to supply power for the motor, achieves the effects of saving cost and protecting the environment, can continuously harvest forage in the running process, can trigger the devices of the nutrition bin when the forage is harvested to a specified amount, can fall into the stirring cavity to stir the forage and the nutrition bin, can be unfolded through the conveying device to feed cattle and sheep, does not need to be constantly monitored by workers, worrys about the problem that the forage cannot be supplied in time, reduces the expenditure on manpower, and increases the efficiency and the working time.

The above description is only an embodiment of the invention, but the scope of the invention is not limited thereto, and any changes or substitutions that are not thought of through the inventive work should be included in the scope of the invention. Therefore, the protection scope of the invention should be subject to the protection scope defined by the claims.

Claims (7)

1. The utility model provides an utilize wind energy cattle and sheep feeding device, includes the organism, its characterized in that: the bottom of the machine body is provided with four movable wheels for moving, a mincing space is arranged in the machine body, a shaft lever space is arranged at the rear side of the mincing space, a belt wheel space is arranged at the lower side of the shaft lever space, a bevel gear space is arranged at the lower side of the belt wheel space, a hydraulic chamber is arranged at the upper side of the mincing space, a nutrition chamber is arranged at the right side of the hydraulic chamber, an auxiliary force space is arranged at the right side of the nutrition chamber, a reaction space is arranged at the right side of the auxiliary force space, a stirring space is arranged at the lower side of the auxiliary force space, a stirring wheel space is arranged at the lower side of the stirring space, a lifting space is arranged at the right side of the stirring wheel space, a rotating space is arranged at the rear side of the lifting space, a contact space is arranged at the lower side of the rotating space, a touch chamber is communicated with the right side wall of the contact space, a, the right side of the lifting space is provided with a moving space, the lower side of the lifting space is provided with a roller space, the top wall of the machine body is provided with a power supply device which generates power by utilizing wind energy, the power supply device comprises a power supply machine which is fixedly arranged on the top wall of the machine body, a power generation block is fixedly arranged on the power supply machine, a power rod is rotatably connected onto the power generation block, a fan rack is fixedly connected onto the power rod, a fan guide blade is fixedly arranged at the front end of the fan rack, the rear end of the fan rack is provided with a collecting device which is used for collecting grass materials, arranged in the grinding space and the stirring wheel space, stirring devices which are used for stirring are arranged in the grinding space, the nutrition cavity, the stirring space, the auxiliary force space and the hydraulic cavity, conveying devices are arranged in the reaction space and the lifting space, and conveying devices are arranged in the moving space and the roller, The feeding device is provided with a feeding device for feeding, the rotating space, the contact space, the touch cavity, the power hydraulic cavity and the friction space are internally provided with a conveying device for operation, and the shaft lever space, the belt wheel space and the bevel gear space are provided with driving devices for driving.

2. The cattle and sheep feeding device using wind energy as claimed in claim 1, wherein: the collecting device comprises a stirring wheel shaft which is rotatably arranged on the rear side wall of the stirring wheel space, the stirring wheel shaft extends backwards to penetrate through the rear side wall of the stirring wheel space and enters the bevel gear space and is rotatably connected with the front side wall and the rear side wall of the bevel gear space, the front end of the stirring wheel shaft is fixedly connected with a stirring wheel, the rear end of the stirring wheel shaft is fixedly connected with a driven bevel gear, the left side of the stirring wheel is fixedly provided with a suction pipeline, the upper side of the suction pipeline is fixedly connected with an air pump, the other side of the air pump is communicated with the mincing space, the mincing space is symmetrically and rotatably connected with mincing shafts in a left-and-right mode, the mincing shafts are fixedly provided with mincing knife wheels, each mincing shaft extends backwards to penetrate through the rear side wall of the mincing space and enters the shaft lever space and is rotatably connected with the front side wall and the rear side wall of the shaft, a driving gear is fixedly arranged at the rear end of the right rubbing shaft and is meshed with the driven gear, and a kinetic energy secondary bevel gear is arranged on the rear side of the driving gear.

3. The cattle and sheep feeding device using wind energy as claimed in claim 1, wherein: the stirring device comprises a rotating plate shaft which is rotatably arranged on the left side wall of the mincing space, a rotating plate is fixedly arranged on the rotating plate shaft, a rotating plate spring is fixedly connected between the rotating plate and the bottom wall of the mincing space, a rotating shaft is rotatably connected on the nutrition cavity, a covering plate is fixedly arranged on the rotating shaft, a hydraulic main rod is connected between the right end of the hydraulic cavity and the nutrition cavity in a sliding manner, a hydraulic slave rod is connected between the left end of the hydraulic cavity and the mincing space in a sliding way, the other side of the hydraulic slave rod is hinged with the right end of the rotating plate, the upper and lower side walls of the nutrition cavity are rotationally connected with a stirring shaft, a stirring belt wheel reaction space is fixedly arranged on the stirring shaft, the stirring shaft extends downwards to penetrate through the lower side wall of the auxiliary force space and enter the stirring space, and is rotationally connected with the upper and lower side walls of the stirring space, and a stirring frame is fixedly arranged on the lower end of the stirring shaft.

4. The cattle and sheep feeding device using wind energy as claimed in claim 1, wherein: the conveying device comprises conveying shafts which are arranged on the lifting space in a vertically symmetrical manner in a rotating manner, the upper conveying shafts extend backwards to penetrate through the rear side wall of the lifting space and enter the rotating space and are connected with the front side wall and the rear side wall of the rotating space in a rotating manner, conveying bevel gears are fixedly arranged at the rear ends of the upper conveying shafts, belt pulleys are fixedly arranged on each conveying shaft, a belt is connected between the two belt pulleys, four fixing blocks are arranged on the left side of the belt, a fixing shaft is rotatably connected on each fixing block, a button spring is fixedly arranged on each fixing shaft, a lifting plate is fixedly arranged on each button spring, a telescopic spring is arranged between the left side and the right side of each lifting plate, a touch block is fixedly arranged on the upper side wall of the reaction space, a sliding block is slidably connected on the left side wall of the reaction space, and a touch block is arranged on the right side of the sliding block, the pressure spring is connected between the touch block and the sliding block, the lower end of the touch block is fixedly provided with a movable plate, the movable plate extends downwards to penetrate through the lower side wall of the reaction space to enter the groove, and the movable plate can move between the groove and the reaction space.

5. The cattle and sheep feeding device using wind energy as claimed in claim 1, wherein: feeding device installs including rotating the drum shaft of lateral wall about the cylinder space, the drum band pulley has set firmly on the right side of drum shaft, the cylinder has set firmly on the left side of drum shaft, sliding connection has the receipts workbin on the lower lateral wall in removal space, receive the workbin with fixedly connected with removes the plate between the cylinder, sliding connection has the pressure board about receiving the workbin on the lateral wall, the pressure board with be connected with two atress springs between the diapire of receipts workbin, fixedly connected with pneumatic pump on the right side wall of receipts workbin, the left side of pneumatic pump has set firmly inhales the material pipe, the shunt tubes has set firmly on the right-hand member of pneumatic pump, six shower nozzles of fixedly connected with are used for spraying the fodder on the shunt tubes, the downside of shower nozzle is in the groove of feeding has set firmly on the receipts workbin.

6. The cattle and sheep feeding device using wind energy as claimed in claim 1, wherein: the transportation device comprises a rotary long shaft which is rotatably arranged on the lower side wall of the rotary space, the rotary long shaft extends downwards to penetrate through the lower side wall of the rotary space to enter the contact space and is rotatably connected with the upper side wall and the lower side wall of the contact space, a conveying auxiliary bevel gear is fixedly arranged at the upper end of the rotary long shaft and is meshed with the conveying bevel gear, a friction driving wheel is fixedly arranged at the lower end of the rotary long shaft, a hydraulic slide block is slidably connected on the right side of the power hydraulic cavity and is fixedly connected with the hydraulic shaft, a bidirectional motor is slidably connected on the left side of the power hydraulic cavity and is reversely connected with a bidirectional motor, a bidirectional motor shaft is in power connection with the bidirectional motor, a friction main wheel is fixedly arranged on the bidirectional motor shaft in a stirring manner, the friction main wheel is meshed with the friction driving wheel, and friction driving shafts are rotatably connected on the upper side wall and the lower side, the friction driven shaft is characterized in that a friction auxiliary wheel is fixedly arranged at the upper end of the friction driving shaft, a friction bevel gear is fixedly arranged at the lower end of the friction driving shaft, a friction driven shaft is rotatably connected to the wall of the friction auxiliary wheel on the right side of the friction space, a friction auxiliary bevel gear is fixedly arranged at the left end of the friction driven shaft, the friction auxiliary bevel gear is meshed with the friction bevel gear, a roller main belt wheel is fixedly arranged at the right end between the friction driven shafts, and a roller belt is connected between the roller main belt wheel and the roller belt wheel.

7. The cattle and sheep feeding device using wind energy as claimed in claim 1, wherein: the driving device comprises a driving shaft which is rotatably arranged on the upper side wall and the lower side wall of the shaft lever space, the driving shaft is in power connection with the power supply motor, a driving bevel gear space is fixedly arranged on the driving shaft, a kinetic energy bevel gear is fixedly arranged at the left end of the driving shaft, the kinetic energy bevel gear is meshed with the kinetic energy secondary bevel gear, a driving secondary bevel gear is fixedly arranged at the right end of the driving shaft, the driving secondary bevel gear is reversely meshed with the driving bevel gear, the driving shaft extends downwards to penetrate through the lower side wall of the shaft lever space to enter the belt pulley space and is in rotary connection with the upper side wall and the lower side wall of the belt pulley space, a main driving belt pulley is fixedly arranged on the driving shaft, the upper side wall and the lower side wall of the belt pulley space are in rotary connection with a wheel lever shaft, a driving secondary belt pulley is fixedly arranged on the wheel lever shaft, and a driving belt is connected between the driving secondary belt pulley and the main driving belt pulley, the driving shaft continuously extends downwards to penetrate through the lower side wall of the belt wheel space and enter the bevel gear space and is rotatably connected with the upper side wall of the bevel gear space, a driving bevel gear is fixedly arranged on the bottom end of the driving shaft, an auxiliary shaft extending left and right is arranged on the lower side wall of the bevel gear space, a driven bevel gear is fixedly arranged on the left end of the auxiliary shaft and is meshed with the driven bevel gear, an auxiliary bevel gear is fixedly arranged on the right end of the auxiliary shaft, and the auxiliary bevel gear is meshed with the driving bevel gear.

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