CN110637745A

CN110637745A - Fodder equipment of throwing something and feeding

Info

Publication number: CN110637745A
Application number: CN201910921138.8A
Authority: CN
Inventors: 潘声田; 张冠; 周瑞
Original assignee: Luan Yongzhen Jiangdao Electromechanical Technology Co Ltd
Current assignee: Luan Yongzhen Jiangdao Electromechanical Technology Co Ltd
Priority date: 2019-09-27
Filing date: 2019-09-27
Publication date: 2020-01-03

Abstract

The invention provides feed feeding equipment, which comprises a shell, a control device, a feeding and spraying device and a sensor element, wherein the control device is used for controlling the feeding and spraying device to operate, the feeding and spraying device is used for uniformly spraying dry feed, the sensor element is used for sensing the motion condition in the feeding and spraying device and feeding back the motion condition to the control device, the control device comprises an air cylinder, a wiring mechanism that is used for between cylinder and the feeding to spill the device action interlock and is connected, a gas pipe network that is used for between cylinder and the gas compressor to connect the switch-on, the feeding spills the device and includes feed hopper, the feeding spills the mechanism, trigger stroke mechanism, feed hopper is used for carrying dry feed to the feeding and spills in the mechanism, the feeding spills the mechanism and is used for evenly spilling away dry feed, trigger stroke mechanism is used for making the feeding to spill the mechanism and rotate and make the feeding spill the mechanism and loop through along installation shell circumferencial direction and spill a section of thick bamboo and outwards spill the feed.

Description

Fodder equipment of throwing something and feeding

Technical Field

The invention relates to the field of livestock feeding, in particular to feed feeding equipment.

Background

At present in traditional livestock-raising, in order to make the livestock grow better, people need to throw cereal fodder to the livestock every day, the operation mode that the artifical timing fixed point was thrown something and is fed is mostly adopted, this kind of operation mode wastes time and energy, can't satisfy big batch industrialization livestock-raising, and artifical fodder of puting in has taken a large amount of manpower resources, artifical intensity of labour is big, high cost, throw something and feed fodder inefficiency, the fodder is thrown something and fed inhomogeneously, waste time and energy, for this, the inventor designs a dry fodder equipment of throwing something and feeding, its whole process full automatization of throwing something and feeding, need not staff manual operation, greatly reduced intensity of labour, the fodder after spilling away simultaneously is evenly distributed all around this equipment, can effectively avoid the livestock poultry to cause the unnecessary damage because of robbing the fodder.

Disclosure of Invention

In order to solve the defects of the prior art, the invention aims to provide the feed feeding equipment, the whole feeding process is fully automatic, manual operation of workers is not needed, the labor intensity is greatly reduced, and meanwhile, the sprayed feed is uniformly distributed around the equipment, so that unnecessary damage to livestock and poultry caused by catching the feed can be effectively avoided.

In order to achieve the technical purpose, the technical scheme adopted by the invention is as follows.

The feed feeding device comprises a shell, a control device, a feeding spraying device and a sensor element, wherein the control device is used for controlling the feeding spraying device to operate, dry feed is stored in the feeding spraying device, the feeding spraying device is used for uniformly spraying the dry feed out, and the sensor element is used for sensing the motion condition in the feeding spraying device and feeding back the motion condition to the control device;

the shell comprises a base, a fixed shell, an installation shell and a cover shell, wherein the base is fixedly installed on the ground in a detachable mode, the fixed shell/the installation shell is a cylindrical shell structure with openings at two ends and the axial direction of the fixed shell/the installation shell is perpendicular to the ground, the lower opening end of the fixed shell is fixed on the base, the lower opening end of the installation shell is coaxially fixed at the upper opening end of the fixed shell, a built-in step for supporting and limiting is arranged at the lower opening end of the installation shell, the cover shell is a cylindrical shell structure with an opening at one end and a closing at one end and is coaxially arranged with the installation shell, and the opening end of the cover shell is movably installed at the upper;

the outer circular surface of the mounting shell is provided with spraying tubes communicated with the inner cavity of the mounting shell, the diameters of the spraying tubes and the mounting shell at the point are positioned on the same straight line, and the spraying tubes are arranged in a plurality of groups in an array mode along the circumferential direction of the mounting shell.

As a further improvement of the present solution.

The control device is positioned in the fixed shell and comprises an air cylinder, a rope winding mechanism and an air pipe network, the air pipe network is used for connecting and communicating the air cylinder and the gas compressor, and the rope winding mechanism is used for acting linkage connection between the air cylinder and the feeding spraying device;

the cylinder comprises a cylinder body, a piston rod, an energy storage spring and a ventilation pipeline, wherein the cylinder body is of a cylindrical shell structure with one open end and one closed end, the cylinder body is coaxially arranged in the fixed shell, the open end of the cylinder body is fixed on the base, and the closed end of the cylinder body is coaxially provided with a through hole;

the piston is positioned in the cylinder body and forms sealed sliding guide fit, the piston rod and the cylinder body are coaxially arranged, one end of the piston rod is fixedly connected with the piston, the other end of the piston rod penetrates through the through hole and is positioned above the cylinder body, the end is a jacking end, and a connecting nozzle is further arranged on the outer circular surface of the cylinder body and is positioned above the piston;

the energy storage spring is sleeved in the cylinder body and positioned below the piston, one end of the energy storage spring is abutted against the piston, the other end of the energy storage spring is abutted against the base, and the elasticity of the energy storage spring drives the piston/piston rod to do ascending motion;

the bottom end of the piston is coaxially provided with a sliding groove penetrating into the piston rod, the bottom of the sliding groove is close to the jacking end of the piston rod, the outer circular surface of the piston rod is also coaxially provided with an annular groove in an annular structure, the annular groove is close to the jacking end of the piston rod, the bottom of the annular groove is provided with vent holes communicated with the sliding groove, and the vent holes are arrayed in a plurality of groups along the circumferential direction of the annular groove;

the air duct and the piston rod are coaxially arranged, the bottom end of the air duct is fixed on the base, the top end of the air duct is located in the sliding groove, and the air duct and the sliding groove form sealed sliding guide fit.

As a further improvement of the present solution.

The air pipe network comprises an electromagnetic valve, a first connecting air pipe, an air inlet pipe and a second connecting air pipe, wherein the electromagnetic valve is fixed on the base, and a avoidance hole for communicating the air pipe with the outside is formed in the base;

one end of the connecting air pipe I is connected and communicated with the gas compressor, the other end of the connecting air pipe I is connected and communicated with the electromagnetic valve, one end of the air inlet pipe is connected and communicated with the connecting air pipe I, the other end of the air inlet pipe passes through the avoidance hole and is connected and communicated with the bottom end of the ventilation pipeline, one end of the connecting air pipe II is connected and communicated with the electromagnetic valve, and the other end of the connecting air pipe II is connected and communicated;

the motion state of the electromagnetic valve can be divided into a ventilation state that compressed gas in the connecting air pipe I can flow into the connecting air pipe II through the electromagnetic valve, a deflation state that the compressed gas in the cylinder body can be discharged outwards through the connecting air pipe II and the electromagnetic valve, and the initial state of the electromagnetic valve is a ventilation state;

the rope winding mechanism comprises a fixed support, a rack, a gear shaft, a gear and a rope winding disc, the fixed support is fixed outside the piston rod, the fixed support and the metal sheet are respectively positioned on one side of the piston rod, and the gear shaft is horizontally and movably arranged in the fixed shell and can rotate around the axial direction of the gear shaft;

the rack is vertically fixed on the fixed support, the gear is coaxially fixed outside the gear shaft, the rack is meshed with the gear, the rope winding disc is coaxially fixed outside the gear shaft, and the piston rod ascends/descends and can pull the rope winding disc to rotate for winding/unwinding the rope.

As a further improvement of the present solution.

The sensor element comprises a first sensor, a second sensor, a metal sheet and a controller, wherein the first sensor/the second sensor are fixedly arranged in the fixed shell, the first sensor and the closed end of the cylinder body are positioned at the same height, the second sensor is positioned right above the first sensor, the metal sheet is horizontally fixed outside the piston rod and positioned between the first sensor and the second sensor, and the metal sheet is close to the first sensor/the second sensor, so that the first sensor/the second sensor can transmit signals to the controller, and finally the controller can send instructions to control the operation of the electromagnetic valve.

As a further improvement of the present solution.

The feeding spraying device is positioned right above the control device and comprises a feeding hopper, a feeding spraying mechanism and a triggering stroke mechanism, dry feed is stored in the feeding hopper, the feeding hopper is used for conveying the dry feed to the feeding spraying mechanism, the feeding spraying mechanism is used for uniformly spraying the dry feed out through a spraying barrel, and the triggering stroke mechanism is used for enabling the feeding spraying mechanism to rotate and enabling the feeding spraying mechanism to sequentially spray the feed outwards through the spraying barrel along the circumferential direction of the mounting shell;

the upper closed end of the housing is provided with a sliding hole and a guide hole, the guide hole and the housing are coaxially arranged, and the sliding hole and the housing are eccentrically arranged;

the feeding funnel is a circular truncated cone shell structure with openings at two ends and a small end located below a large end, the small end of the feeding funnel is coaxially and fixedly communicated with a feeding pipeline, the bottom end of the feeding pipeline penetrates through the sliding hole and extends into the housing, and sliding guide matching is further formed between the feeding pipeline and the sliding hole.

As a further improvement of the present solution.

The feeding spraying mechanism is positioned in the mounting shell and comprises a material storage block and a pushing piece, the material storage block is horizontally arranged on a built-in step arranged at the lower opening end of the mounting shell, a coaxial rod is vertically arranged on the upper end surface of the material storage block, the top end of the coaxial rod is positioned in a guide hole arranged at the upper closed end of the housing, the coaxial rod and the guide hole form sliding guide fit, the material storage block can rotate around the axial direction of the coaxial rod, and the material storage block and the wall of the mounting shell form sealed rotation fit;

the storage block is also provided with a storage hole penetrating through the storage block along the radial direction of the mounting shell, the storage hole and the spraying barrels are positioned at the same height, the storage hole is communicated with any one group of the spraying barrels in the plurality of groups of the spraying barrels, the upper end surface of the storage block is provided with a feed hole communicated with the storage hole, and the bottom end of the feed pipeline is fixed on the storage block and communicated with the feed hole;

the side surface of the storage block facing the wall of the mounting shell is provided with an air outlet hole, the side surface of the storage block is also provided with an air inlet hole communicated with the air outlet hole, the distance between the maximum height position of the piston rod which rises and an internal step arranged at the lower opening end of the mounting shell is equal to the height distance between the air outlet hole and the storage hole, and the horizontal distance between the air outlet hole and the storage hole is equal to the distance between two adjacent groups of spraying cylinders;

the pushing piece comprises a push plug, a push spring, a rope and a pulley, the push plug is positioned in the material storage hole and forms sealed sliding guide fit, the initial position of the push plug seals the material inlet hole, and when the push plug is positioned at the initial position, part of the push plug is positioned in the spraying barrel;

the pulley is arranged at an orifice of the material storage hole, which is far away from the wall of the installation shell, one end of the rope is fixedly connected with the push plug, and the other end of the rope is wound around the pulley and is wound outside the rope winding disc;

the drill way department that the storage hole deviates from installation shell cavity wall be provided with conflict step, the storage hole is located to the propelling movement spring housing, the one end of propelling movement spring is contradicted with conflict step, the other end is contradicted with the pushing plug, the elasticity of propelling movement spring orders about the pushing plug and is close to the motion of installation shell cavity wall.

As a further improvement of the present solution.

The trigger stroke mechanism comprises a stroke piece and a trigger piece, the trigger piece comprises a fastening frame, an elastic sheet and a cylindrical pin, the fastening frame is fixedly arranged in the fixed shell, the elastic sheet is arranged on the fastening frame, and the cylindrical pin is horizontally arranged on the elastic sheet in a clamping manner;

the stroke piece comprises a stroke body, the stroke body is of a cylindrical structure which is coaxial with the fixed shell, a sleeve hole penetrating through the axial thickness of the stroke body is coaxially arranged on the stroke body, the stroke body is fixedly connected with the lower end face of the material storage block, the stroke body is movably sleeved outside the piston rod through the sleeve hole and forms sealed sliding guide fit with the piston rod, a connection nozzle communicated with a ring groove arranged outside the piston rod is further arranged on the outer circular face of the stroke body, the connection nozzle is connected with an air outlet pipe in a matching way, and the other end of the air outlet pipe is connected with the air inlet hole;

the outer circular surface of the stroke body is also provided with vertical sliding grooves of which the guiding direction is vertical to the ground, the vertical sliding grooves are arrayed in a plurality of groups along the circumferential direction of the stroke body, the number of the vertical sliding grooves is consistent with that of the spraying cylinders, and the free ends of the cylindrical pins are positioned in the top ends of any group of the vertical sliding grooves;

a rotary groove which is used for communicating the two adjacent groups of vertical sliding grooves and is obliquely arranged is arranged between the two adjacent groups of vertical sliding grooves, and the top end of the rotary groove is close to the top end of the vertical sliding groove;

a second one-way block is arranged at the connection position of the top end of the rotary groove and the vertical sliding groove, the second one-way block is positioned in the vertical sliding groove, the side surface of the second one-way block, which faces the ground, is a second guide inclined surface, and the distance between the second guide inclined surface and the central axis of the stroke body is increased from bottom to top;

a first one-way block is arranged at the connection position of the bottom end of the rotary groove and the vertical sliding groove, the first one-way block is positioned in the rotary groove, the side surface of the first one-way block, facing the top end of the rotary groove, is a first guide inclined surface, and the distance between the first guide inclined surface and the central axis of the stroke body is gradually reduced from the bottom end of the rotary groove to the top end;

the first guide inclined surface of the first one-way block is matched with the second guide inclined surface of the second one-way block and is used for enabling the free end of the cylindrical pin to pass through the rotary groove and unidirectionally slide into the adjacent vertical sliding groove from the top end of the vertical sliding groove when the stroke body ascends or enabling the free end of the cylindrical pin to unidirectionally slide into the top end of the same vertical sliding groove from the bottom end of the vertical sliding groove when the stroke body descends.

Compared with the prior art, the automatic dry feed spraying device has the advantages that a worker only needs to pour dry feed into the feeding hopper, the subsequent feed pushing and feeding and outward spraying processes are controlled by the sensor element in a sensing mode, the whole process is full-automatic, manual operation of the worker is not needed, labor intensity is greatly reduced, and meanwhile, the spraying cylinder arrays for spraying the feed outwards are provided with a plurality of groups, so that the feed is sprayed around the device at a constant speed by the feeding and spraying mechanism, feed distribution is more uniform, and unnecessary damage to livestock and poultry due to the fact that the livestock and the poultry are cared for the feed can be effectively avoided.

Drawings

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

Fig. 2 is a schematic structural diagram of the housing of the present invention.

Fig. 3 is a schematic view of the internal structure of the present invention.

Fig. 4 is a schematic view of the internal structure of the present invention.

Fig. 5 is a schematic structural diagram of a control device and a sensor element according to the present invention.

Fig. 6 is a schematic structural view of a cylinder of the present invention.

Fig. 7 is a cross-sectional view of a cylinder of the present invention.

Fig. 8 is a diagram showing the piston rod and the ventilation tube according to the present invention.

Fig. 9 is a schematic view of the structure of the roping arrangement of the invention.

Fig. 10 is a schematic view of the structure of the gas pipe network of the present invention.

Fig. 11 is a schematic structural view of the feed spraying device of the present invention.

Fig. 12 is a schematic structural view of the feed spraying mechanism of the present invention.

Fig. 13 is a schematic structural view of the feed spraying mechanism of the present invention.

Fig. 14 is a schematic structural view of the pushing member of the present invention.

Fig. 15 is a schematic structural view of the trigger stroke mechanism of the present invention.

Fig. 16 is a schematic structural view of the trigger of the present invention.

FIG. 17 is a partial schematic view of a trigger of the present invention.

Fig. 18 is a schematic view of the structure of the stroke member of the present invention.

Fig. 19 is a diagram showing the engagement of the stroke body and the piston rod according to the present invention.

Detailed Description

The advantage of spraying the dry feed outwards is that the worker only needs to pour the dry feed into the feeding hopper, the subsequent processes of pushing the feed and spraying the feed outwards are controlled by the sensor element, the whole process is full-automatic, manual operation of the worker is not needed, the labor intensity is greatly reduced, and meanwhile, a plurality of groups of spraying cylinder arrays for spraying the feed outwards are arranged, so that the feed is sprayed around the device at a constant speed by the feeding and spraying mechanism, the feed is distributed more uniformly, and unnecessary damage to livestock and poultry caused by robbing the feed can be effectively avoided.

The feed throwing device comprises a shell 100, a control device 200, a feeding spraying device 300 and a sensor element 400, wherein the control device 200 is used for controlling the feeding spraying device 300 to operate, dry feed is stored in the feeding spraying device 300, the feeding spraying device 300 is used for uniformly spraying the dry feed, and the sensor element 400 is used for sensing the motion condition in the feeding spraying device 300 and feeding the motion condition back to the control device 200.

The casing 100 comprises a base 110, a fixed shell 120, an installation shell 130 and a cover 140, wherein the base 110 is fixedly installed on the ground in a detachable mode, the fixed shell 120/the installation shell 130 are both cylindrical shell structures with openings at two ends and the axial direction perpendicular to the ground, the lower opening end of the fixed shell 120 is fixed on the base 110, the lower opening end of the installation shell 130 is coaxially fixed at the upper opening end of the fixed shell 120, a built-in step for supporting and limiting is arranged at the lower opening end of the installation shell 130, the cover 140 is a cylindrical shell structure with an opening at one end and a closed end, and the cylindrical shell structure is coaxially arranged with the installation shell 130, and the opening end of the cover 140 is movably installed at the upper opening end of the installation shell 130 and forms.

The outer circular surface of the mounting housing 130 is provided with spraying tubes 131 communicated with the inner cavity of the mounting housing 130, the diameters of the spraying tubes 131 and the mounting housing 130 at the point are positioned on the same straight line, and the spraying tubes 131 are arranged in a plurality of groups in an array along the circumferential direction of the mounting housing 130.

The control device 200 is located in the fixed housing 120, the control device 200 includes an air cylinder 210, a rope winding mechanism 220, and an air pipe network 230, the air pipe network 230 is used for connecting and connecting the air cylinder 210 and the gas compressor, and the rope winding mechanism 220 is used for connecting the air cylinder 210 and the feeding spraying device 300 in a linkage manner.

The cylinder 210 comprises a cylinder body 211, a piston 212, a piston rod 213, an energy storage spring 214 and a ventilation pipeline 215, wherein the cylinder body 211 is of a cylindrical shell structure with an open end and a closed end, the cylinder body 211 is coaxially arranged in the fixed shell 120, the open end of the cylinder body 211 is fixed on the base 110, and a through hole is coaxially formed in the closed end of the cylinder body 211.

The piston 212 is positioned in the cylinder body 211 and forms a sealed sliding guide fit, the piston rod 213 and the cylinder body 211 are coaxially arranged, one end of the piston rod 213 is fixedly connected with the piston 212, the other end of the piston rod passes through the through hole and is positioned above the cylinder body 211, the end is a jacking end, a connecting nozzle 2111 is further arranged on the outer circular surface of the cylinder body 211, and the connecting nozzle 2111 is positioned above the piston 212.

The energy storage spring 214 is sleeved in the cylinder 211 and located below the piston 212, one end of the energy storage spring 214 abuts against the piston 212, the other end of the energy storage spring 214 abuts against the base 110, and the elastic force of the energy storage spring 214 drives the piston 212/the piston rod 213 to move upward.

The bottom end of the piston 212 is coaxially provided with a sliding chute penetrating into the piston rod 213, the bottom of the sliding chute is close to the jacking end of the piston rod 213, the outer circular surface of the piston rod 213 is also coaxially provided with a ring groove 2131 in an annular structure, the ring groove 2131 is close to the jacking end of the piston rod 213, the bottom of the ring groove 2131 is provided with vent holes 2132 communicated with the sliding chute, and the vent holes 2132 are arranged in a plurality of groups in an array manner along the circumferential direction of the ring groove 2131.

The vent pipe 215 and the piston rod 213 are coaxially arranged, the bottom end of the vent pipe 215 is fixed on the base 110, the top end of the vent pipe 215 is located in the sliding groove, and the vent pipe 215 and the sliding groove form a sealed sliding guide fit.

The air pipe network 230 includes an electromagnetic valve 231, a first connecting air pipe 232, an air inlet pipe 233 and a second connecting air pipe 234, the electromagnetic valve 231 is fixed on the base 110, and the base 110 is provided with a avoiding hole for communicating the ventilation pipeline 215 with the outside.

One end of the first connecting air pipe 232 is connected and communicated with the gas compressor, the other end of the first connecting air pipe 232 is connected and communicated with the electromagnetic valve 231, one end of the air inlet pipe 233 is connected and communicated with the first connecting air pipe 232, the other end of the air inlet pipe penetrates through the avoiding hole and is connected and communicated with the bottom end of the ventilation pipeline 215, one end of the second connecting air pipe 234 is connected and communicated with the electromagnetic valve 231, and the other end of the second connecting air pipe 234 is connected and communicated.

The sensor element 400 comprises a first sensor 410, a second sensor 420, a metal sheet 430 and a controller, wherein the first sensor 410/the second sensor 420 are fixedly arranged in the fixed shell 120, the first sensor 410 and the closed end of the cylinder body 211 are positioned at the same height, the second sensor 420 is positioned right above the first sensor 410, the metal sheet 430 is horizontally fixed outside the piston rod 213, the metal sheet 430 is positioned between the first sensor 410 and the second sensor 420, and the metal sheet 430 is close to the first sensor 410/the second sensor 420, so that the first sensor 410/the second sensor 420 can transmit signals to the controller and finally the controller can send instructions to control the operation of the electromagnetic valve 231.

The movement state of the solenoid valve 231 may be divided into a ventilation state in which the compressed gas in the first connection gas pipe 232 can flow into the second connection gas pipe 234 through the solenoid valve 231, a deflation state in which the compressed gas in the cylinder 211 can be discharged to the outside through the second connection gas pipe 234 and the solenoid valve 231, and an initial state of the solenoid valve 231 is a ventilation state.

Compressed gas provided by the gas compressor flows into the cylinder body 211 through the first connecting gas pipe 232, the electromagnetic valve 231, the second connecting gas pipe 234 and the connecting nozzle 2111 and pushes the piston 212/the piston rod 213 to do descending motion, the piston 212 descends and drives the energy storage spring 214 to compress, namely, the energy storage spring 214 stores energy, the piston rod 213 descends and pulls the metal sheet 430 to descend synchronously, when the metal sheet 430 descends to be close to the first sensor 410, the first sensor 410 transmits a signal to the controller, and the controller sends an instruction and enables the electromagnetic valve 231 to be switched to a gas release state;

then the elastic force of the energy storage spring 214 can make the piston 212/the piston rod 213 do ascending movement, the compressed gas in the cylinder body 211 is discharged through the connecting air pipe II 234 and the electromagnetic valve 211, simultaneously the piston rod 213 ascends and pulls the metal sheet 430 to ascend synchronously, when the metal sheet 430 ascends to be close to the sensor II 420, the sensor II 420 transmits a signal to the controller, the controller sends an instruction and the electromagnetic valve 231 is switched to a ventilation state, so that the energy storage process of the next round is carried out, and the process is repeated; in addition, the compressed gas always flows into the ventilation duct 215 through the first connection gas pipe 232 and the first gas inlet pipe 233.

The rope winding mechanism 220 includes a fixing bracket 221, a rack 222, a gear shaft 223, a gear 224, and a rope winding disc 225, the fixing bracket 221 is fixed outside the piston rod 213, the fixing bracket 221 and the metal sheet 430 are respectively located at one side of the piston rod 213, and the gear shaft 223 is horizontally movably installed in the fixing housing 120 and can rotate around itself axially.

The rack 222 is vertically fixed on the fixing bracket 221, the gear 224 is coaxially fixed outside the gear shaft 223, the rack 222 is meshed with the gear 224, the rope winding disc 225 is coaxially fixed outside the gear shaft 223, and the piston rod 213 ascends/descends and can pull the rope winding disc 225 to wind/unwind the rope.

The feeding sprinkling device 300 is located right above the control device 200, the feeding sprinkling device 300 comprises a feeding hopper 310, a feeding sprinkling mechanism 320 and a trigger stroke mechanism 330, dry feed is stored in the feeding hopper 310, the feeding hopper 310 is used for conveying the dry feed to the feeding sprinkling mechanism 320, the feeding sprinkling mechanism 320 is used for evenly sprinkling the dry feed through a sprinkling barrel 131, and the trigger stroke mechanism 330 is used for enabling the feeding sprinkling mechanism 320 to rotate and enabling the feeding sprinkling mechanism 320 to sequentially sprinkle the feed outwards through the sprinkling barrel 131 along the circumferential direction of the installation shell 130.

The upper closed end of the housing 140 is provided with a slide hole and a guide hole, the guide hole and the housing 140 are coaxially arranged, and the slide hole and the housing 140 are eccentrically arranged.

The feeding funnel 310 is a circular truncated cone shell structure with openings at two ends and a small end located below a large end, the small end of the feeding funnel 310 is coaxially and fixedly communicated with a feeding pipeline 311, the bottom end of the feeding pipeline 311 penetrates through a sliding hole and extends into the housing 140, and sliding guide matching is formed between the feeding pipeline 311 and the sliding hole.

Feeding sprinkling mechanism 320 be located installation shell 130, feeding sprinkling mechanism 320 includes storage piece 321, pushing member, storage piece 321 level is laid to setting up on the built-in step of installation shell 130 under shed end, the vertical top that is provided with axostylus axostyle 322 and coaxial pole 322 of up end of storage piece 321 is located and sets up in the guiding hole of encloser 140 upper closed end, and constitute the sliding guide cooperation between coaxial pole 322 and the guiding hole, storage piece 321 can constitute sealed normal running fit around coaxial pole 322 axial rotation and between storage piece 321 and the installation shell 130 chamber wall.

The storage block 321 is further provided with a storage hole penetrating through the thickness of the mounting shell 130 in the radial direction, the storage hole and the spraying barrels 131 are located at the same height, the storage hole is communicated with any one group of the spraying barrels 131 in the plurality of groups of the spraying barrels 131, the upper end face of the storage block 321 is provided with a feeding hole 323 communicated with the storage hole, and the bottom end of the feeding pipeline 311 is fixed on the storage block 321 and communicated with the feeding hole 323.

The side of storage block 321 towards the wall of installation shell 130 chamber be provided with venthole 324, and the side of storage block 321 still is provided with the inlet port 325 of being connected the switch-on with venthole 324, the maximum height department that the piston rod 213 rises and set up the distance between the built-in step of installing shell 130 under the open end equal the high distance between venthole 324 and the storage hole, horizontal distance between venthole 324 and the storage hole equals the distance between adjacent two sets of a section of thick bamboo 131 that sprinkles.

The pushing member comprises a pushing plug 326, a pushing spring 327, a rope 328 and a pulley, the pushing plug 326 is positioned in the storing hole and forms a sealed sliding guide fit, the initial position of the pushing plug 326 closes the feeding hole 323, and when the pushing plug 326 is positioned at the initial position, part of the pushing plug 326 is positioned in the spraying cylinder 131.

The pulley is mounted at the opening of the storage hole away from the wall of the mounting housing 130, and one end of the rope 328 is fixedly connected with the push plug 326, and the other end of the rope is wound around the pulley and is wound outside the rope winding disc 225.

The orifice of the storage hole deviating from the wall of the installation shell 130 is provided with an abutting step, the pushing spring 327 is sleeved in the storage hole, one end of the pushing spring 327 abuts against the abutting step, the other end of the pushing spring 327 abuts against the push plug 326, and the push plug 326 is driven by the elastic force of the pushing spring 327 to move close to the wall of the installation shell 130.

In the ascending process of the piston rod 213, the piston rod 213 firstly takes up the rope 328 through the rope winding mechanism 220, so that the push plug 326 is completely positioned in the material storage hole, then the jacking end of the piston rod 213 is in contact with the material storage block 321 and pulls the material storage block to ascend synchronously, in the synchronous ascending process, the push plug 326 continues to move and cancels the sealing of the material inlet 323, so that the feed in the feed hopper 310 falls into the material storage hole through the material inlet pipeline 311 and the material inlet 323, meanwhile, the trigger stroke mechanism 330 is triggered to rotate the material storage block 321 and the rotational displacement is equal to the distance between two adjacent groups of spraying cylinders 131, at the same time, the material storage hole and the corresponding next group of spraying cylinders 131 are positioned on the same vertical straight line, and the air outlet 324 is communicated with the corresponding next group of spraying cylinders 131;

in the descending process of the piston rod 213, the feeding spraying mechanism 320 descends synchronously under the action of the gravity of the feed, when the storage block 321 descends and is re-placed on the built-in step arranged at the lower opening end of the mounting shell 130, the storage hole is communicated with the next group of spraying tubes 131, the air outlet hole 324 is positioned on the same vertical straight line with the next group of spraying tubes 131, and meanwhile, in the process, the pushing spring 327 drives the pushing plug 326 to move close to the wall of the mounting shell 130 and push the feed into the spraying tubes 131 communicated with the storage hole, and the process is repeated.

The trigger stroke mechanism 330 includes a stroke piece 3310 and a trigger piece 3320, the trigger piece 3320 includes a fastening frame 3321, an elastic piece 3322 and a cylindrical pin 3323, the fastening frame 3321 is fixedly installed in the fixed housing 120, the elastic piece 3322 is installed on the fastening frame 3321, and the cylindrical pin 3323 is horizontally installed on the elastic piece 3322 in a clamping manner.

The stroke part 3310 include the stroke body 3311, the stroke body 3311 is the cylinder structure of arranging with fixed shell 120 is coaxial, coaxial being provided with the cup joint hole that runs through its axial thickness on the stroke body 3311, the lower terminal surface fixed connection of the stroke body 3311 and storage block 321, the stroke body 3311 still cup joints in the piston rod 213 outside and cup joints between hole and the piston rod 213 through cup joint hole activity and constitutes sealed sliding guide cooperation, the outer disc of the stroke body 3311 still is provided with the switch-on mouth with set up the annular 2131 switch-on in the piston rod 213 outside, the switch-on mouth accordant connection switches on the other end that has outlet duct 3316 and inlet port 325 connect-on.

The outer circular surface of the stroke body 3311 is further provided with vertical chutes 3312 having a guiding direction perpendicular to the ground, the vertical chutes 3312 are arrayed in a plurality of groups along the circumferential direction of the stroke body 3311, the number of the vertical chutes 3312 is equal to the number of the spraying tubes 131, and the free ends of the cylindrical pins 3323 are located in the top ends of any group of the vertical chutes 3312.

A rotating groove 3313 which is used for communicating the two adjacent groups of vertical sliding grooves 3312 and is obliquely arranged is arranged between the two adjacent groups of vertical sliding grooves 3312, and the top end of the rotating groove 3313 is close to the top end of the vertical sliding groove 3312.

The connecting position of the top end of the rotating groove 3313 and the vertical sliding groove 3312 is provided with a second unidirectional block 3315, the second unidirectional block 3315 is positioned in the vertical sliding groove 3312, the side surface of the second unidirectional block 3315 facing the ground is a second guiding inclined surface, and the distance between the second guiding inclined surface and the central axis of the stroke body 3311 increases from bottom to top.

The connection between the bottom of the rotating slot 3313 and the vertical sliding slot 3312 is provided with a first unidirectional block 3314, the first unidirectional block 3314 is located in the rotating slot 3313, the side of the first unidirectional block 3314 facing the top of the rotating slot 3313 is a first guiding inclined plane, and the distance between the first guiding inclined plane and the central axis of the stroke body 3311 decreases from the bottom of the rotating slot 3313 to the top.

The first guiding inclined surface of the first unidirectional block 3314 is matched with the second guiding inclined surface of the second unidirectional block 3315 and is used for enabling the free end of the cylindrical pin 3323 to pass through the rotating groove 3313 and to slide unidirectionally from the top end of the vertical chute 3312 into the adjacent vertical chute 3312 when the stroke body 3311 ascends or enabling the free end of the cylindrical pin 3323 to slide unidirectionally from the bottom end of the vertical chute 3312 into the top end of the same vertical chute 3312 when the stroke body 3311 descends.

In the process of the piston rod 213 rising, since the trigger 3320 is fixed and stationary, and the stroke body 3311 will rise synchronously with the material storage block 321, so that the free end of the cylindrical pin 3323 passes through the rotating slot 3313 and slides unidirectionally from the top end of the vertical sliding slot 3312 to the adjacent vertical sliding slot 3312, and the stroke body 3311 rotates around its own axis under the cooperation of the free end of the cylindrical pin 3323 and the rotating slot 3313, the stroke body 3311 rotates and pulls the material storage block 321 to rotate synchronously, and the rotational displacement is equal to the distance between the two adjacent spraying tubes 131;

during the descending process of the piston rod 213, the stroke body 3311 will descend synchronously with the material storage block 321, so that the free end of the cylindrical pin 3323 slides from the bottom end of the vertical chute 3312 to the top end of the same vertical chute 3312 in a single direction, and during the process, the stroke body 3311 does not rotate;

in addition, in the above process, the compressed gas in the ventilation duct 215 flows into the air outlet hole 324 through the chute, the ring groove 2131, the ventilation hole 2132, the communication nozzle, the air outlet pipe 3316 and the air inlet hole 325 which are arranged on the piston rod 213.

In actual operation, compressed gas provided by the gas compressor flows into the cylinder body 211 through the first connecting gas pipe 232, the electromagnetic valve 231, the second connecting gas pipe 234 and the connecting nozzle 2111 and pushes the piston 212/the piston rod 213 to move downwards, the piston 212 descends and drives the energy storage spring 214 to compress, namely, the energy storage spring 214 stores energy, the piston rod 213 descends and pulls the metal sheet 430 to descend synchronously, when the metal sheet 430 descends to be close to the first sensor 410, the first sensor 410 transmits a signal to the controller, the controller sends an instruction and enables the electromagnetic valve 231 to be switched to an air release state, then the elastic force of the energy storage spring 214 enables the piston 212/the piston rod 213 to move upwards, and the compressed gas in the cylinder body 211 is discharged through the second connecting gas pipe 234 and the electromagnetic valve 211, simultaneously the piston rod 213 ascends and pulls the metal sheet 430 to ascend synchronously, when the metal sheet 430 ascends to be close to the, the second sensor 420 transmits a signal to the controller, and the controller sends a command and switches the electromagnetic valve 231 to a ventilation state, so that the energy storage process of the next round is performed, and the process is repeated;

during the ascending process of the piston rod 213, the piston rod 213 firstly takes up the rope 328 by the rope winding mechanism 220, so that the plunger 326 is completely located in the storage hole, then the ascending end of the piston rod 213 contacts with the storage block 321 and pulls the storage block to ascend synchronously, during the synchronous ascending process, the plunger 326 continues to move and removes the sealing of the feeding hole 323, so that the feed in the feeding funnel 310 falls into the storage hole through the feeding pipe 311 and the feeding hole 323, in addition, the storage block 321 ascends and pulls the stroke body 3311 to ascend synchronously, so that the free end of the cylindrical pin 3323 passes through the rotary slot 3313 and slides to the adjacent vertical slide 3312 from the top end of the vertical slide 3312 in one way, and the stroke body 3311 rotates around its own axial direction under the cooperation of the free end of the cylindrical pin 3323 and the rotary slot 3313, the stroke body 3311 rotates and pulls the storage block 321 to rotate synchronously, and the rotational displacement is equal to the distance between the two adjacent spraying tubes 131, finally, the material storage hole and the next group of spraying tubes 131 are positioned on the same vertical straight line, and the air outlet hole 324 is communicated with the next group of spraying tubes 131;

in the descending process of the piston rod 213, the feeding spraying mechanism 320 descends synchronously under the action of the gravity of the feed, when the feed block 321 descends and is rested on the built-in step arranged at the lower opening end of the mounting shell 130, the feed storage hole is communicated with the corresponding next group of spraying tubes 131, the air outlet hole 324 is positioned on the same vertical straight line with the corresponding next group of spraying tubes 131, meanwhile, in the process, the pushing spring 327 drives the pushing plug 326 to move close to the wall of the mounting shell 130 and pushes the feed into the spraying tubes 131 communicated with the feed storage hole, besides, the stroke body 3311 descends synchronously along with the feed block 321, so that the free end of the cylindrical pin 3323 slides unidirectionally from the bottom end of the vertical chute 3312 to the top end of the same vertical chute 3312, and in the process, the stroke body 3311 does not rotate;

the movement process that the feed is pushed into the spraying tubes 131 is repeated until in the process that the feed is pushed into the last group of spraying tubes 131, the compressed gas flows into the first group of spraying tubes 131 through the first connecting air pipe 232, the air inlet pipe 233, the vent pipeline 215, the sliding groove arranged on the piston rod 213, the annular groove 2131, the vent hole 2132, the connecting nozzle, the air outlet pipe 3316, the air inlet hole 325 and the air outlet hole 324, the feed in the first group of spraying tubes 131 is blown and sprayed out, the subsequent feed is repeatedly pushed, fed and blown and sprayed, and the process is repeated.

Claims

1. The feed feeding device is characterized by comprising a shell, a control device, a feeding spraying device and a sensor element, wherein the control device is used for controlling the feeding spraying device to operate, dry feed is stored in the feeding spraying device, the feeding spraying device is used for uniformly spraying the dry feed out, and the sensor element is used for sensing the motion condition in the feeding spraying device and feeding the motion condition back to the control device;

2. The feed feeding device according to claim 1, wherein the control device is located in the fixed housing, the control device comprises a cylinder, a rope winding mechanism and a gas pipe network, the gas pipe network is used for connecting and communicating the cylinder and the gas compressor, and the rope winding mechanism is used for connecting the cylinder and the feeding spraying device in a linkage manner;

3. The feed feeding device according to claim 2, wherein the air pipe network comprises an electromagnetic valve, a first connecting air pipe, an air inlet pipe and a second connecting air pipe, the electromagnetic valve is fixed on the base, and a avoidance hole for communicating the air pipe with the outside is formed in the base;

4. The feed feeding device according to claim 1 or 2, wherein the sensor element comprises a first sensor, a second sensor, a metal sheet and a controller, the first sensor/the second sensor are fixedly arranged in the fixed shell, the first sensor and the closed end of the cylinder body are positioned at the same height, the second sensor is positioned right above the first sensor, the metal sheet is horizontally fixed outside the piston rod and positioned between the first sensor and the second sensor, and the metal sheet is close to the first sensor/the second sensor, so that the first sensor/the second sensor can transmit signals to the controller and finally the controller can send commands to control the operation of the electromagnetic valve.

5. The feed dispensing apparatus of claim 1 wherein the feed dispensing device is located directly above the control device, the feed dispensing device comprises a feed hopper, a feed dispensing mechanism, and a trigger mechanism, the feed hopper stores dry feed and the feed hopper is used for delivering the dry feed to the feed dispensing mechanism, the feed dispensing mechanism is used for uniformly dispensing the dry feed through a dispensing cartridge, the trigger mechanism is used for rotating the feed dispensing mechanism and enabling the feed dispensing mechanism to sequentially dispense the feed outwards through the dispensing cartridge in the circumferential direction of the mounting housing;

6. The feed feeding device according to claim 3 or 5, wherein the feeding spraying mechanism is positioned in the mounting shell and comprises a material storage block and a pushing member, the material storage block is horizontally arranged on a built-in step arranged at the lower opening end of the mounting shell, the upper end surface of the material storage block is vertically provided with a coaxial rod, the top end of the coaxial rod is positioned in a guide hole arranged at the upper closed end of the housing, a sliding guide fit is formed between the coaxial rod and the guide hole, the material storage block can rotate around the axial direction of the coaxial rod, and a sealing rotation fit is formed between the material storage block and the wall of the mounting shell;

7. The feed feeding device according to claim 6, wherein the trigger stroke mechanism comprises a stroke piece and a trigger piece, the trigger piece comprises a fastening frame, an elastic piece and a cylindrical pin, the fastening frame is fixedly arranged in the fixed shell, the elastic piece is arranged on the fastening frame, and the cylindrical pin is horizontally arranged on the elastic piece in a clamping manner;

the stroke piece include the stroke body, the stroke body is the cylinder structure with fixed shell coaxial arrangement, coaxial being provided with on the stroke body runs through the hole of cup jointing of its axial thickness, the lower terminal surface fixed connection of stroke body and storage piece, the stroke body still cup joints in the piston rod outside and cup joints between hole and the piston rod through cup jointing the hole activity and constitutes sealed sliding guide cooperation, the outer disc of stroke body still is provided with and sets up the switch-on mouth of the annular switch-on in the piston rod outside, switch-on mouth accordant connection switch-on has the other end and the inlet port connection switch-on of outlet duct and outlet duct.

8. The feed feeding device according to claim 7, wherein the outer circumferential surface of the stroke body is further provided with vertical chutes of which the guiding directions are perpendicular to the ground, the vertical chutes are arrayed in a plurality of groups along the circumferential direction of the stroke body, the number of the vertical chutes is consistent with the number of the spraying cylinders, and the free ends of the cylindrical pins are positioned in the top ends of any group of the vertical chutes;

and a rotating groove which is used for communicating the two adjacent groups of vertical sliding grooves and is obliquely arranged is arranged between the two adjacent groups of vertical sliding grooves, and the top end of the rotating groove is close to the top end of the vertical sliding groove.

9. The feed feeding device according to claim 8, wherein a second one-way block is arranged at the connection position of the top end of the rotary groove and the vertical sliding groove, the second one-way block is positioned in the vertical sliding groove, the second one-way block is a second guiding inclined plane facing the ground, and the distance between the second guiding inclined plane and the central axis of the stroke body increases from bottom to top;

the connecting part of the bottom end of the rotary groove and the vertical sliding groove is provided with a one-way block I, the one-way block I is positioned in the rotary groove, the side surface of the one-way block I, facing the top end of the rotary groove, is a guide inclined surface I, and the distance between the guide inclined surface I and the central axis of the stroke body is gradually reduced from the direction of the bottom end of the rotary groove, facing the top end.

10. The feed feeding device according to claim 9, wherein the first guiding slope of the first one-way block cooperates with the second guiding slope of the second one-way block and serves to allow the free end of the cylindrical pin to pass through the rotating chute and slide unidirectionally from within the top end of the vertical chute into an adjacent vertical chute when the stroke body is raised or to allow the free end of the cylindrical pin to slide unidirectionally from within the bottom end of the vertical chute into the top end of the same vertical chute when the stroke body is lowered.