CN111772217A - Processing machine and processing method for feed - Google Patents

Abstract

The invention relates to the field of damp hardened feed treatment equipment, in particular to a feed treatment machine and a treatment method; the servo motor is adopted to drive the first gear to rotate, so that the second gear drives the first rotating shaft to rotate and serves as a power source to perform concrete operations such as crushing, drying and the like on the moistened feed, and the device is convenient and quick to use and good in effect; the first crankshaft rotates along with the first rotating shaft and acts on the second rod through the first sleeve and the first rod, so that the second rod drives the crushing plate to reciprocate, and the feed in the hopper falls and is crushed by matching with the material baffle plate; the cam also rotates along with the first rotating shaft, acts on the pressing plate and is matched with the second spring to enable the piston rod to drive the piston plate to move left and right; the piston cylinder sucks air from the air suction pipe and exhausts the air to the air exhaust pipe, the air is heated by the heater and guided into the drying cavity to dry the feed, the wet air with moisture is exhausted from the through hole, and the filter screen plays a role in ventilation and preventing the feed from overflowing.

Description

Processing machine and processing method for feed

Technical Field

The invention relates to the field of damp hardened feed treatment equipment, in particular to a feed treatment machine and a treatment method.

Background

Livestock generally refers to animals which are domesticated by human beings and can be artificially controlled to breed, such as pigs, cattle, sheep, horses, camels, rabbits and the like, and is generally used for functions of eating, labour service, fur, pets, experiments and the like. Common livestock breeding modes include barn feeding, pen feeding, series feeding, grazing and the like.

The term "feed" is a general term for food of all human-raised animals, and in a narrow sense, a general feed mainly refers to food of agricultural or animal-raised animals.

Different livestock can need different feeds due to different life habits.

The feed raw materials comprise more than ten varieties of soybean, soybean meal, corn, fish meal, amino acid, miscellaneous meal, whey powder, grease, meat and bone meal, grains, feed additives and the like. The feeds are mainly classified according to the formula and mainly divided into three categories:

energy feed: corn, bran (wheat middling);

② protein feed: bean cake (dregs), cottonseed dregs, rapeseed dregs, fish meal, blood bone meal, etc.;

③ supplement material of mineral fiber: including phosphorus, calcium and amino acids or premixes.

For example, energy feed generally accounts for 50% -70% of the formulation of swine and poultry, protein feed generally accounts for 20% -35% (except pregnant swine), and mineral supplement feed 3% -12%.

The proportions of the three types of feed vary with the species of the animal and the different stages of growth. The simplest formula is a formula of corn, bean cake (meal) and mineral vitamin premix (including health care medicine). But the price is higher, and the common producers are difficult to adopt. If the cost of the feed is to be reduced, local common cheap bran, wheat middling and corn or cottonseed meal, rapeseed meal and the like can be used for replacing bean cake (meal) feed, but the energy concentration and the content of crude protein are kept to the minimum. If artificially synthesized amino acid is added to balance the amino acid in the feed, the crude fiber protein is reduced by two percent units in the formula, so that the use amount of expensive protein feeds such as bean cakes (dregs), fish meal and the like is reduced, and the cost is reduced.

In the process of storing the feed, the feed can be affected by damp and hardened due to the influence of external environment or other reasons, but the quality of the feed is not affected, so that the feed is wasted if the feed is directly discarded; however, the hardened feed caused by moisture is reduced in taste for livestock, and affects the food intake and, in severe cases, the growth of livestock.

Therefore, there is a need to process such moist, hardened feed, to regrind it into pellets and to dry it, but the prior art involves fewer processing devices of this type. Has certain market space and also has the problems of poor crushing and drying effects and the like.

Therefore, the application designs a processor and a processing method for feed, and solves the problems.

Disclosure of Invention

Technical problem to be solved

The invention aims to overcome the defects in the prior art and provides a processing machine and a processing method for feed.

(II) technical scheme

A processor for feed comprises a frame component, a power component, a feeding component, a crushing component, a turning component, a blanking component and a drying component;

the frame component comprises a base, a main supporting rod, a drying cavity, a material guide pipe, a material guide cavity, a crushing cavity, a hopper and a material discharge pipe; the left part of the base is provided with a power assembly, and the upper part of the right part of the base is connected with a drying cavity through a main supporting rod; the drying cavity is provided with a turnover assembly, and the turnover assembly is connected with the power assembly; a drying component is also arranged on the left side of the drying cavity and is matched with the power component; the bottom of the material guide cavity is of a throat structure, and the drying cavity is upwards communicated with the bottom end of the material guide cavity through a material guide pipe; the material guide pipe is provided with a blanking assembly, and the blanking assembly is matched with the overturning assembly; the top of the material guide cavity is provided with a feeding assembly, and the feeding assembly is connected with the power assembly; the left part above the material guide cavity is also communicated with a crushing cavity, and the top of the crushing cavity is connected with a hopper; the crushing chamber is provided with the crushing subassembly, and the crushing subassembly is connected with power component.

Preferably, the power assembly comprises a servo motor, a first gear, a second gear, a first rotating shaft, a first support plate and a second support plate;

the servo motor is fixed on the base, and the output end of the servo motor extends upwards and is connected with a first gear; the first rotating shaft is arranged on one side of the servo motor, and the bottom end of the first rotating shaft is rotatably connected with the base; the first support plate and the second support plate are arranged at intervals up and down, the right end of the first support plate is fixedly connected with the drying cavity, and the right end of the second support plate is fixedly connected with the material guide cavity; the first rotating shaft penetrates upwards and rotates the first support plate and the second support plate.

Preferably, the crushing assembly comprises a first crankshaft, a first sleeve, a first rod, a second rod, a crushing plate, a material baffle plate and crushing teeth;

the first crankshaft is arranged on the first rotating shaft, the first crankshaft is provided with a first sleeve, the right side of the first sleeve is connected with a first rod, the right end of the first rod is hinged with the left end of a second rod, and the second rod extends rightwards into the compression cavity and is connected with a crushing plate; the top of the crushing plate is connected with a striker plate leftwards; crushing teeth are correspondingly arranged on the crushing plate and the inner wall of the right side of the compression cavity.

Preferably, the feeding assembly comprises a first transmission wheel, a transmission belt, a second transmission wheel, a second rotating shaft, a rotating disc, a lower material passing hole, an upper material passing hole and a connecting seat;

a first driving wheel is arranged at the top end of the first rotating shaft; the second rotating shaft penetrates through and is rotatably connected with the top plate of the material guide cavity, the top end of the second rotating shaft is provided with a second driving wheel, and the bottom end of the second rotating shaft is provided with a turntable; the second driving wheel is in transmission connection with the first driving wheel through a transmission belt; the rotary disc is contacted with the bottom surface of the top plate of the material guide cavity; a lower material through hole is formed in the rotary table, and an upper material through hole communicated with the compression cavity is formed in the top plate of the material guide cavity; when the rotary table rotates, the upper material through holes and the lower material through holes are overlapped intermittently.

Preferably, the overturning assembly comprises a second crankshaft, a second sleeve, a pull rope, a wire guide wheel, an overturning plate, an installation shaft, a limiting block, a vent hole, a filter screen, a first spring and a fixing plate;

the longitudinal section of the drying cavity is three-quarters circular, and the right upper part of the circular shape is rectangular; the drying cavity is rotatably connected with a turnover plate through a mounting shaft, and the left end and the right end of the turnover plate are in lap joint with the inner wall of the circular section; the right lower part of the drying cavity is connected with a discharge pipe, and the discharge pipe is provided with a valve; a wire guide wheel is arranged at the inner bottom of the drying cavity, one end of the pull rope is connected with the bottom surface of the right section of the turnover plate, and the other end of the pull rope bypasses the wire guide wheel and extends out of the drying cavity; the second crankshaft is arranged on the first rotating shaft, a second sleeve is arranged on the second crankshaft, and the outer end of the pull rope is connected with the second sleeve; the bottom surface of the left section of the turning plate is connected with a first spring, the inner bottom of the drying cavity is also provided with a fixed plate, and the bottom end of the first spring is connected with the fixed plate; the right upper part of the drying cavity is provided with an air vent which is provided with a filter screen.

Preferably, the blanking assembly comprises a push-pull rod, a blocking block, a connecting rod, a sliding block and a sliding rail;

the bottom end of the push-pull rod is hinged with the right section of the turnover plate, and the top end of the push-pull rod extends into the material guide pipe and is hinged with a plugging block; the outer diameter of the plugging block corresponds to the inner diameter of the material guide pipe; the top of the plugging block is provided with a conical surface; a slide rail in the vertical direction is arranged in the material guide pipe, a slide block is connected on the slide rail in a sliding manner, and the slide block is connected with a blocking block through a connecting rod.

Preferably, the drying component comprises a heater, a cam, a pressure plate, a piston rod, a piston plate, a second spring, a piston cylinder, a vent pipe and an air suction pipe;

the left upper part of the drying cavity is connected with a vent pipe, and a heater is arranged on the vent pipe; a piston cylinder is arranged on the left side of the material guide cavity, and a piston plate moving left and right is arranged in the piston cylinder; a second spring is connected between the piston plate and the left end of the piston cylinder; the left side of the piston plate is connected with a piston rod, and the piston rod extends out of the piston cylinder leftwards and is connected with a pressing plate; the left side of the pressure plate is matched with a cam, and the cam is arranged on the first rotating shaft; the right end of the piston cylinder is connected with an air suction pipe, and a first check valve for controlling air to flow into the piston cylinder is arranged on the air suction pipe; the right end of the piston cylinder is also connected with a vent cylinder, and a second check valve for controlling gas to flow out of the piston cylinder is arranged on the vent cylinder.

Preferably, the anti-blocking device further comprises an anti-blocking component; the anti-blocking component comprises a strip-shaped plate, a straight hole, a sliding shaft, a moving rod, a limiting plate, a mounting plate and a steel needle;

a strip-shaped plate is arranged on the push-pull rod, a linear hole is formed in the strip-shaped plate, and a sliding shaft is matched with the linear hole; the right side of the sliding shaft is connected with a moving rod, the moving rod passes through a limiting plate rightwards, and the limiting plate is fixedly connected to the inner wall of the drying cavity; the right end of the movable rod is provided with a mounting plate, and the right side of the mounting plate is provided with a plurality of steel needles.

Preferably, the device also comprises a crushing component; the crushing assembly comprises an expanding shaft and a crushing cutter;

the third rotating shaft is connected below the turntable and is coaxial with the second rotating shaft and the material guide cavity; the bottom end of the third rotating shaft is provided with a connecting seat; the expanding shaft is obliquely arranged, and the top end of the expanding shaft is connected with the connecting seat; crushing knives are uniformly arranged on the expanding shaft.

Preferably, the device also comprises a second bevel gear, a first bevel gear, a mounting rod and a fixed frame;

the connecting seat is of a hollow structure, the third rotating shaft and the second rotating shaft are hollow shafts, and the second driving wheel is provided with a through hole; the mounting rod is arranged in the third rotating shaft, the bottom end of the mounting rod extends into the connecting seat and is fixedly connected with a first bevel gear, and the top end of the mounting rod penetrates through the second rotating shaft and the second driving wheel and is connected with the material guide cavity through the fixing frame; the top end of the expanding shaft extends into the connecting seat and is provided with a second bevel gear which is matched with the first bevel gear.

(III) advantageous effects

The invention provides a processor for feed and a processing method, which have the following advantages:

1, a servo motor is adopted to drive a first gear to rotate, so that a second gear drives a first rotating shaft to rotate and serves as a power source to perform concrete operations such as crushing, drying and the like on the moistened feed, and the device is convenient and quick to use and good in effect;

2, the first crankshaft rotates along with the first rotating shaft and acts on the second rod through the first sleeve and the first rod, so that the second rod drives the crushing plate to reciprocate, and the feed in the hopper falls and is crushed by matching with the material baffle plate; a drive wheel of a pivot produces the rotation to make No. two drive wheels drive No. two pivots rotations through the drive belt, thereby make the carousel then rotate, lead to the material hole and lower material hole intermittent type coincidence on making: when the two are staggered, the crushing component can crush conveniently; when the two materials are coincident, the crushed feed falls into the material guide cavity and is guided to the bottom of the material guide cavity.

3, the second crankshaft rotates along with the first rotating shaft, the pull rope acts on the turnover plate through the second sleeve, and the turnover plate generates reciprocating swing by matching with the first spring; when the turnover plate swings, the blocking block moves up and down under the guidance of the slide rail slide block when the push-pull rod is used, and the feeding pipe inlet is blocked and opened intermittently, so that the feed falling into the feeding cavity falls onto the turnover plate in the drying cavity from the feeding pipe intermittently, and is turned over along with the swinging of the turnover plate, and the condition that the drying is not timely due to too much blanking at one time is avoided.

4, the cam also rotates along with the first rotating shaft, acts on the pressing plate, and is matched with the second spring to enable the piston rod to drive the piston plate to move left and right; because the one-way valve is arranged on the pipeline, the piston cylinder sucks air from the air suction pipe and exhausts the air to the air suction pipe, the air is heated by the heater and guided into the drying cavity to dry the feed, the wet air with moisture is exhausted from the through hole, and the filter screen plays a role in ventilation and preventing the feed from overflowing.

Drawings

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

FIG. 1 is a block diagram of the present invention;

FIG. 2 is a block diagram of one embodiment of the present invention;

FIG. 3 is a block diagram of the power assembly and the flipping assembly;

FIG. 4 is a block diagram of a blanking assembly;

FIG. 5 is a structural diagram of a drying assembly;

FIG. 6 is a block diagram of a crushing assembly and a feeding assembly;

FIG. 7 is a block diagram of the size reduction assembly;

FIG. 8 is a block diagram of another embodiment of a size reduction assembly;

FIG. 9 is a block diagram of the anti-blocking assembly;

in the drawings, the components represented by the respective reference numerals are listed below:

1-frame assembly, 101-base, 102-primary support bar, 103-drying chamber, 104-guide tube, 105-guide chamber, 106-crushing chamber, 107-hopper, 108-discharge tube;

2-power component, 201-servo motor, 202-first gear, 203-second gear, 204-first rotating shaft, 205-first support plate and 206-second support plate;

3-a feeding assembly, 301-a first transmission wheel, 302-a transmission belt, 303-a second transmission wheel, 304-a second rotating shaft, 305-a rotating disc, 306-a lower material passing hole, 307-an upper material passing hole, 308-a connecting seat and 309-a third rotating shaft;

4-crushing component, 401-crankshaft, 402-sleeve, 403-rod, 404-rod, 405-crushing plate, 406-striker plate, 407-crushing tooth;

5-turnover assembly, 501-second crankshaft, 502-second sleeve, 503-pull rope, 504-guide wheel, 505-turnover plate, 506-installation shaft, 507-fixing plate, 508-filter screen and 509-first spring;

6-blanking component, 601-push-pull rod, 602-blocking block, 603-connecting rod, 604-sliding block, 605-sliding rail;

7-drying component, 701-heater, 702-cam, 703-pressing plate, 704-piston rod, 705-piston plate, 706-second spring, 707-piston cylinder, 708-vent pipe and 709-suction pipe;

8-anti-blocking component, 801-strip plate, 802-straight hole, 803-sliding shaft, 804-moving rod, 805-limiting plate, 806-mounting plate and 807-steel needle;

9-crushing component, 901-expanding shaft, 902-crushing knife, 903-second bevel gear, 904-first bevel gear, 905-mounting rod and 906-fixing frame.

Detailed Description

The technical solutions of the present invention will be described clearly and completely with reference to the accompanying drawings, and it should be understood that the described embodiments are some, but not all embodiments of the present invention. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, it should be noted that, as the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. appear, their indicated orientations or positional relationships are based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Moreover, the terms "first," "second," and "third," if any, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" should be interpreted broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Example 1

Referring to the attached drawings, the processor for the feed comprises a frame assembly 1, a power assembly 2, a feeding assembly 3, a crushing assembly 4, a turning assembly 5, a blanking assembly 6 and a drying assembly 7;

the frame component 1 comprises a base 101, a main supporting rod 102, a drying cavity 103, a material guide pipe 104, a material guide cavity 105, a crushing cavity 106, a hopper 107 and a material discharge pipe 108; the power assembly 2 is arranged at the left part of the base 101, and the drying cavity 103 is connected to the upper part of the right part of the base through a main supporting rod 102; the drying cavity 103 is provided with a turnover assembly 5, and the turnover assembly 5 is connected with the power assembly 2; a drying component 7 is further arranged on the left side of the drying cavity 103, and the drying component 7 is matched with the power component 2; the bottom of the material guide cavity 105 is of a throat structure, and the drying cavity 103 is upwards communicated with the bottom end of the material guide cavity 105 through a material guide pipe 104; the material guide pipe 104 is provided with a blanking assembly 6, and the blanking assembly 6 is matched with the overturning assembly 5; the top of the material guide cavity 105 is provided with a feeding component 3, and the feeding component 3 is connected with the power component 2; the left part above the material guide cavity 105 is also communicated with a crushing cavity 106, and the top of the crushing cavity 106 is connected with a hopper 107; the crushing cavity 106 is provided with a crushing assembly 4, the crushing assembly 4 being connected with the power assembly 2.

Example 2

Referring to the attached drawings, the processor for the feed comprises a frame assembly 1, a power assembly 2, a feeding assembly 3, a crushing assembly 4, a turning assembly 5, a blanking assembly 6 and a drying assembly 7;

the frame component 1 comprises a base 101, a main supporting rod 102, a drying cavity 103, a material guide pipe 104, a material guide cavity 105, a crushing cavity 106, a hopper 107 and a material discharge pipe 108; the power assembly 2 is arranged at the left part of the base 101, and the drying cavity 103 is connected to the upper part of the right part of the base through a main supporting rod 102; the drying cavity 103 is provided with a turnover assembly 5, and the turnover assembly 5 is connected with the power assembly 2; a drying component 7 is further arranged on the left side of the drying cavity 103, and the drying component 7 is matched with the power component 2; the bottom of the material guide cavity 105 is of a throat structure, and the drying cavity 103 is upwards communicated with the bottom end of the material guide cavity 105 through a material guide pipe 104; the material guide pipe 104 is provided with a blanking assembly 6, and the blanking assembly 6 is matched with the overturning assembly 5; the top of the material guide cavity 105 is provided with a feeding component 3, and the feeding component 3 is connected with the power component 2; the left part above the material guide cavity 105 is also communicated with a crushing cavity 106, and the top of the crushing cavity 106 is connected with a hopper 107; the crushing cavity 106 is provided with a crushing assembly 4, the crushing assembly 4 being connected with the power assembly 2.

The power assembly 2 comprises a servo motor 201, a first gear 202, a second gear 203, a first rotating shaft 204, a first support plate 205 and a second support plate 206;

the servo motor 201 is fixed on the base 101, and the output end of the servo motor 201 extends upwards and is connected with a first gear 202; the first rotating shaft 204 is arranged on one side of the servo motor 201, and the bottom end of the first rotating shaft is rotatably connected with the base 101; the first support plate 205 and the second support plate 206 are arranged at intervals up and down, the right end of the first support plate 205 is fixedly connected with the drying cavity 103, and the right end of the second support plate 206 is fixedly connected with the material guide cavity 105; the first rotating shaft 204 penetrates upwards and rotates the first support plate 205 and the second support plate 206.

The crushing assembly 4 comprises a first crankshaft 401, a first sleeve 402, a first rod 403, a second rod 404, a crushing plate 405, a striker plate 406 and crushing teeth 407;

the first crankshaft 401 is arranged on the first rotating shaft 204, the first sleeve 402 is arranged on the first crankshaft 401, the first rod 403 is connected to the right side of the first sleeve 402, the right end of the first rod 403 is hinged to the left end of the second rod 404, and the second rod 404 extends rightwards into the compression cavity 106 and is connected with the crushing plate 405; the top of the crushing plate 405 is connected with a striker plate 406 leftwards; crushing teeth 407 are correspondingly formed on the crushing plate 405 and the right inner wall of the compression chamber 106.

The feeding assembly 3 comprises a first driving wheel 301, a driving belt 302, a second driving wheel 303, a second rotating shaft 304, a turntable 305, a lower material passing hole 306, an upper material passing hole 307 and a connecting seat 308;

a first driving wheel 301 is fixedly connected to the top of the first rotating shaft 204; a second rotating shaft 304 penetrates through and is rotatably connected with the top plate of the material guide cavity 105, the top end of the second rotating shaft is fixedly connected with a second driving wheel 303, and the bottom end of the second rotating shaft is fixedly connected with a rotating disc 305; the second driving wheel 303 is in driving connection with the first driving wheel 301 through a driving belt 302; the rotating disc 305 is contacted with the bottom surface of the top plate of the material guide cavity 105; a lower material through hole 306 is formed on the turntable 305, and an upper material through hole 307 communicated with the compression cavity 106 is formed on the top plate of the material guide cavity 105; when the turntable 305 rotates, the upper through-hole 307 and the lower through-hole 306 intermittently coincide.

The overturning assembly 5 comprises a second crankshaft 501, a second sleeve 502, a pull rope 503, a guide wire wheel 504, an overturning plate 505, a mounting shaft 506, a limiting block, a vent, a filter screen 508, a first spring 509 and a fixing plate 507;

the longitudinal section of the drying cavity 103 is three-quarters circular, and the right upper part of the circular shape is rectangular; the drying cavity 103 is rotatably connected with a turnover plate 505 through a mounting shaft 506, and the left end and the right end of the turnover plate 505 are lapped with the inner wall of the circular section; the right lower part of the drying cavity 103 is connected with a discharge pipe 108, and the discharge pipe 108 is provided with a valve; a wire guide wheel 504 is arranged at the inner bottom of the drying cavity 103, one end of a pull rope 503 is connected with the bottom surface of the right section of the turnover plate 505, and the other end of the pull rope bypasses the wire guide wheel 504 and extends out of the drying cavity 103; the second crankshaft 501 is arranged on the first rotating shaft 204, the second sleeve 502 is arranged on the second crankshaft 501, and the outer end of the pull rope 503 is connected with the second sleeve 502; the bottom surface of the left section of the turning plate 505 is connected with a first spring 509, the inner bottom of the drying cavity 103 is also fixedly connected with a fixing plate 507, and the bottom end of the first spring 509 is connected with the fixing plate 507; the right upper part of the drying cavity 103 is provided with a vent hole which is provided with a filter screen 508.

The blanking assembly 6 comprises a push-pull rod 601, a blocking block 602, a connecting rod 603, a sliding block 604 and a sliding rail 605;

the bottom end of the push-pull rod 601 is hinged with the right section of the turnover plate 505, and the top end of the push-pull rod extends into the material guide pipe 104 and is hinged with a plugging block 602; the outer diameter of the plugging block 602 corresponds to the inner diameter of the material guide pipe 104; the top of the plugging block 602 is machined with a conical surface; a slide rail 605 in the vertical direction is fixed in the material guiding pipe 104, a slide block 604 is connected on the slide rail 605 in a sliding manner, and the slide block 604 is connected with the blocking block 602 through a connecting rod 603.

Wherein, the drying component 7 comprises a heater 701, a cam 702, a pressure plate 703, a piston rod 704, a piston plate 705, a second spring 706, a piston cylinder 707, a vent pipe 708 and an air suction pipe 709;

the left upper part of the drying cavity 103 is connected with a vent pipe 708, and a heater 701 is arranged on the vent pipe 708; the left side of the material guide cavity 105 is connected with a piston cylinder 707, and a piston plate 705 moving left and right is arranged in the piston cylinder 707; a second spring 706 is connected between the piston plate 705 and the left end of the piston cylinder 707; the left side of the piston plate 705 is connected with a piston rod 704, and the piston rod 704 extends out of a piston cylinder 707 to the left and is connected with a pressure plate 703; a cam 702 is matched on the left side of the pressing plate 703, and the cam 702 is fixedly connected to the first rotating shaft 204; the right end of the piston cylinder 707 is connected with an air suction pipe 709, and the air suction pipe 709 is provided with a first check valve for controlling air to flow into the piston cylinder 707; the right end of the piston cylinder 707 is also connected with a vent cylinder, and a second check valve for controlling gas to flow out of the piston cylinder 707 is arranged on the vent pipe 708.

The processing method of the processor in the embodiment is as follows:

feeding the moisture-hardened feed into the hopper 107, and then starting the servo motor 201 to drive the first gear 202 to rotate, so that the second gear 203 drives the first rotating shaft 204 to rotate;

on the first hand, the first crankshaft 401 rotates along with the first rotating shaft 204, and acts on the second rod 404 through the first sleeve 402 and the first rod 403, so that the second rod 404 drives the crushing plate 405 to reciprocate, and the feed in the hopper 107 falls and is crushed by matching with the striker plate 406;

in the second aspect, the first driving wheel 301 of the first rotating shaft 204 rotates, and the second driving wheel 303 drives the second rotating shaft 304 to rotate through the driving belt 302, so that the turntable 305 rotates, and the upper material passing hole 307 and the lower material passing hole 306 are overlapped intermittently: when the two are staggered, the crushing component 4 can crush conveniently; when the two materials are coincident, the crushed feed falls into the material guide cavity 105 and is guided to the bottom of the material guide cavity 105;

in the third aspect, the second crankshaft 501 rotates along with the first rotating shaft 204, and the pulling rope 503 acts on the turnover plate 506 through the second sleeve 502, and the turnover plate 505 generates reciprocating swing by matching with the first spring 509: when the second sleeve 502 rotates to the rightmost end, the turnover plate 506 rotates to the horizontal position; when the second sleeve 502 rotates to the leftmost end, the turnover plate 506 is high at the left and low at the right, and the right end faces the discharge pipe 107, so that subsequent discharge is facilitated; when the turnover plate 505 swings, the blocking block 602 moves up and down under the guidance of the slide rail slide block when the push-pull rod 601 passes through, and the inlet of the material guide pipe 104 is intermittently blocked and opened, so that the feed falling into the material guide cavity 105 intermittently falls onto the turnover plate 505 in the drying cavity 103 from the material guide pipe 105, and is turned over along with the swing of the turnover plate 505, and the situation that the drying is not timely due to too much blanking at one time is avoided;

in the fourth aspect, the cam 702 also rotates along with the first rotating shaft 204, acts on the pressing plate 703, and cooperates with the second spring 706 to make the piston rod 704 drive the piston plate 705 to move left and right; due to the arrangement of the one-way valve on the pipeline, the piston cylinder 707 sucks air from the air suction pipe 7109 and exhausts the air to the air exhaust pipe 708, the air passes through the heater 701 and is heated and guided into the drying cavity 103 to dry the feed, the wet air with moisture is exhausted from the through hole, and the filter screen 508 plays a role in ventilating and preventing the feed from overflowing;

the valve of the discharge pipe 107 is opened, and the dried feed is automatically discharged along with the shaking of the turnover plate 505.

Example 3

In the process of drying and ventilating, the gas may bring the feed into contact with the filter screen 508 to cause the problems of blockage of the filter screen 508 and unsmooth ventilation, so the anti-blocking component 8 is further arranged on the basis of the above embodiment.

Also comprises an anti-blocking component 8; the anti-blocking component 8 comprises a strip-shaped plate 801, a straight hole 802, a sliding shaft 803, a moving rod 804, a limiting plate 805, a mounting plate 806 and a steel needle 807;

a strip-shaped plate 801 is connected to the push-pull rod 601, a linear hole 802 is processed on the strip-shaped plate 801, and the linear hole 802 is matched with a sliding shaft 803; a moving rod 804 is connected to the right side of the sliding shaft 803, the moving rod 804 passes through a limiting plate 805 rightwards, and the limiting plate 805 is fixedly connected to the inner wall of the drying cavity 103; the right end of the moving rod 804 is fixedly connected with a mounting plate 806, and the right side of the mounting plate 806 is connected with a plurality of steel pins 807.

Specifically, when push-pull rod 601 removed along with returning face plate 505, still made bar 801 follow and remove to make slotted hole 802 and sliding shaft 803 produce the effect, drive movable rod 804 and remove for limiting plate 805, thereby take limiting plate 805 to remove about, make steel needle 807 intermittently insert filter screen 807 and dredge, avoid filter screen 807 to block.

Example 4

On the basis of the above-described embodiments,

also comprises a crushing component 9; the crushing assembly 9 comprises an expanding shaft 901 and a crushing knife 902;

the third rotating shaft 309 is connected below the turntable 305 and is coaxial with the second rotating shaft 304 and the material guide cavity 105; a connecting seat 308 is processed at the bottom end of the third rotating shaft 309; the expanding shaft 901 is obliquely arranged, and the top end of the expanding shaft is connected with the connecting seat 308; crushing knives 902 are uniformly connected to the expanding shaft 901.

Specifically, because the design of shutoff head 602, the fodder that makes to fall on the guide chamber 105 bottom can produce the gathering, and No. three pivot 309 is driven by carousel 305 and produces the rotation, still drives and extends axle 901 and then rotates, makes crushing sword 902 smash the fodder of this department once more, further reduces the size of fodder granule, the follow-up stoving of being convenient for.

Example 5

On the basis of the example 4, the method comprises the following steps of,

the device also comprises a second bevel gear 903, a first bevel gear 904, a mounting rod 905 and a fixed frame 906;

the connecting base 308 is a hollow structure, the third rotating shaft 309 and the second rotating shaft 304 are hollow shafts, and a through hole is processed in the second driving wheel 303; the mounting rod 905 is arranged in the third rotating shaft 309, the bottom end of the mounting rod extends into the connecting seat 308 and is fixedly connected with a first bevel gear 904, and the top end of the mounting rod passes through the second rotating shaft 304 and the second driving wheel 303 and is connected with the material guide cavity 105 through a fixing frame 906; the top end of the expansion shaft 901 extends into the connecting seat 308 and is fixedly connected with a second bevel gear 903, and the second bevel gear 903 is matched with a first bevel gear 904.

Specifically, the mounting rod 905 and the first bevel gear 904 at the bottom of the mounting rod are fixed in position, the expansion shaft 901 rotates along with the third rotating shaft 309, and the second bevel gear 903 and the first bevel gear 904 are meshed to enable the second bevel gear 903 to drive the expansion shaft 901 to rotate, so that the crushing effect of the crushing cutter 902 is enhanced.

It should be noted that the electrical components are provided with power supplies, and the control method is the prior art, and is unified here for avoiding the redundancy of description; and the present invention is primarily intended to protect mechanical equipment, the control means and circuit connections will not be explained in detail herein.

In the description herein, references to the description of "one embodiment," "an example," "a specific example," etc., mean that a particular feature, structure, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The preferred embodiments of the invention disclosed above are intended to be illustrative only. The preferred embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed. Obviously, many modifications and variations are possible in light of the above teaching. The embodiments were chosen and described in order to best explain the principles of the invention and the practical application, to thereby enable others skilled in the art to best utilize the invention. The invention is limited only by the claims and their full scope and equivalents.

Claims (10)

1. A processor for feed is characterized by comprising a frame component (1), a power component (2), a feeding component (3), a crushing component (4), a turning component (5), a blanking component (6) and a drying component (7);

the frame assembly (1) comprises a base (101), a main supporting rod (102), a drying cavity (103), a material guide pipe (104), a material guide cavity (105), a crushing cavity (106), a hopper (107) and a material discharge pipe (108); the power assembly (2) is arranged at the left part of the base (101), and the upper part of the right part of the base is connected with a drying cavity (103) through a main support rod (102); the drying cavity (103) is provided with a turnover component (5), and the turnover component (5) is connected with the power component (2); a drying component (7) is further arranged on the left side of the drying cavity (103), and the drying component (7) is matched with the power component (2); the bottom of the material guide cavity (105) is of a throat structure, and the drying cavity (103) is upwards communicated with the bottom end of the material guide cavity (105) through a material guide pipe (104); the feeding pipe (104) is provided with a blanking assembly (6), and the blanking assembly (6) is matched with the overturning assembly (5); the top of the material guide cavity (105) is provided with a feeding assembly (3), and the feeding assembly (3) is connected with the power assembly (2); the left part above the material guide cavity (105) is also communicated with a crushing cavity (106), and the top of the crushing cavity (106) is connected with a hopper (107); the crushing cavity (106) is provided with a crushing component (4), and the crushing component (4) is connected with the power component (2).

2. The machine according to claim 1, characterized in that the power assembly (2) comprises a servo motor (201), a first gear (202), a second gear (203), a first rotating shaft (204), a first support plate (205) and a second support plate (206);

the servo motor (201) is fixed on the base (101), and the output end of the servo motor (201) extends upwards and is connected with a first gear (202); the first rotating shaft (204) is arranged on one side of the servo motor (201), and the bottom end of the first rotating shaft is rotatably connected with the base (101); the first support plate (205) and the second support plate (206) are arranged at intervals up and down, the right end of the first support plate (205) is fixedly connected with the drying cavity (103), and the right end of the second support plate (206) is fixedly connected with the material guide cavity (105); the first rotating shaft (204) penetrates upwards and rotates the first support plate (205) and the second support plate (206).

3. The feed processor of claim 2, wherein the crushing assembly (4) comprises a first crankshaft (401), a first sleeve (402), a first rod (403), a second rod (404), a crushing plate (405), a striker plate (406) and crushing teeth (407);

the first crankshaft (401) is arranged on the first rotating shaft (204), the first sleeve (402) is arranged on the first crankshaft (401), the first rod (403) is connected to the right side of the first sleeve (402), the right end of the first rod (403) is hinged to the left end of the second rod (404), and the second rod (404) extends rightwards into the compression cavity (106) and is connected with the crushing plate (405); the top of the crushing plate (405) is connected with a material baffle plate (406) leftwards; crushing teeth (407) are correspondingly arranged on the crushing plate (405) and the inner wall of the right side of the compression cavity (106).

4. The feed processor according to claim 3, wherein the feeding assembly (3) comprises a first transmission wheel (301), a transmission belt (302), a second transmission wheel (303), a second rotating shaft (304), a rotating disc (305), a lower feeding hole (306), an upper feeding hole (307) and a connecting seat (308);

a first driving wheel (301) is arranged at the top end of the first rotating shaft (204); the second rotating shaft (304) penetrates through and is rotatably connected with a top plate of the material guide cavity (105), the top end of the second rotating shaft is provided with a second driving wheel (303), and the bottom end of the second rotating shaft is provided with a turntable (305); the second driving wheel (303) is in transmission connection with the first driving wheel (301) through a transmission belt (302); the rotating disc (305) is in contact with the bottom surface of the top plate of the material guide cavity (105); a lower material through hole (306) is formed in the turntable (305), and an upper material through hole (307) communicated with the compression cavity (106) is formed in the top plate of the material guide cavity (105); when the turntable (305) rotates, the upper material passing holes (307) and the lower material passing holes (306) are overlapped intermittently.

5. The machine of claim 4, wherein the turning assembly (5) comprises a second crankshaft (501), a second sleeve (502), a pull rope (503), a wire guide wheel (504), a turning plate (505), a mounting shaft (506), a limiting block, a vent, a filter screen (508), a first spring (509) and a fixing plate (507);

the longitudinal section of the drying cavity (103) is three-quarters circular, and the right upper part of the circular shape is rectangular; the drying cavity (103) is rotatably connected with a turnover plate (505) through a mounting shaft (506), and the left end and the right end of the turnover plate (505) are lapped with the inner wall of the circular section; the right lower part of the drying cavity (103) is connected with a discharge pipe (108), and the discharge pipe (108) is provided with a valve; a wire guide wheel (504) is arranged at the inner bottom of the drying cavity (103), one end of a pull rope (503) is connected with the bottom surface of the right section of the turnover plate (505), and the other end of the pull rope bypasses the wire guide wheel (504) and extends out of the drying cavity (103); the second crankshaft (501) is arranged on the first rotating shaft (204), a second sleeve (502) is arranged on the second crankshaft (501), and the outer end of the pull rope (503) is connected with the second sleeve (502); the bottom surface of the left section of the turnover plate (505) is connected with a first spring (509), the inner bottom of the drying cavity (103) is also provided with a fixed plate (507), and the bottom end of the first spring (509) is connected with the fixed plate (507); and a vent hole is arranged at the upper right part of the drying cavity (103), and a filter screen (508) is arranged on the vent hole.

6. The feed processor according to claim 5, wherein the blanking assembly (6) comprises a push-pull rod (601), a block (602), a connecting rod (603), a sliding block (604) and a sliding rail (605);

the bottom end of the push-pull rod (601) is hinged with the right section of the turnover plate (505), and the top end of the push-pull rod extends into the material guide pipe (104) and is hinged with a blocking block (602); the outer diameter of the blocking block (602) corresponds to the inner diameter of the material guide pipe (104); the top of the plugging block (602) is provided with a conical surface; a sliding rail (605) in the vertical direction is arranged in the material guide pipe (104), a sliding block (604) is connected to the sliding rail (605) in a sliding mode, and the sliding block (604) is connected with the blocking block (602) through a connecting rod (603).

7. The machine of claim 6, wherein the drying assembly (7) comprises a heater (701), a cam (702), a pressing plate (703), a piston rod (704), a piston plate (705), a second spring (706), a piston cylinder (707), a vent pipe (708) and an air suction pipe (709);

a vent pipe (708) is connected to the upper left part of the drying cavity (103), and a heater (701) is arranged on the vent pipe (708); a piston cylinder (707) is arranged on the left side of the material guide cavity (105), and a piston plate (705) moving left and right is arranged in the piston cylinder (707); a second spring (706) is connected between the piston plate (705) and the left end of the piston cylinder (707); the left side of the piston plate (705) is connected with a piston rod (704), and the piston rod (704) extends out of the piston cylinder (707) to the left and is connected with a pressure plate (703); the left side of the pressure plate (703) is matched with a cam (702), and the cam (702) is arranged on the first rotating shaft (204); the right end of the piston cylinder (707) is connected with an air suction pipe (709), and the air suction pipe (709) is provided with a one-way valve for controlling air to flow into the piston cylinder (707); the right end of the piston cylinder (707) is also connected with a vent cylinder, and a second check valve for controlling gas to flow out of the piston cylinder (707) is arranged on the vent cylinder (708).

8. A machine for processing fodder as claimed in claim 7, characterized in that it further comprises an anti-clogging assembly (8); the anti-blocking component (8) comprises a strip-shaped plate (801), a straight hole (802), a sliding shaft (803), a moving rod (804), a limiting plate (805), a mounting plate (806) and a steel needle (807);

a strip-shaped plate (801) is arranged on the push-pull rod (601), the strip-shaped plate (801) is provided with a straight hole (802), and the straight hole (802) is matched with a sliding shaft (803); a moving rod (804) is connected to the right side of the sliding shaft (803), the moving rod (804) penetrates through a limiting plate (805) rightwards, and the limiting plate (805) is fixedly connected to the inner wall of the drying cavity (103); the right end of the moving rod (804) is provided with a mounting plate (806), and the right side of the mounting plate (806) is provided with a plurality of steel needles (807).

9. A machine as claimed in claim 7 or 8, characterized by comprising a shredding assembly (9); the crushing assembly (9) comprises an expanding shaft (901) and a crushing knife (902);

the third rotating shaft (309) is connected below the rotating disc (305) and is coaxial with the second rotating shaft (304) and the material guide cavity (105); the bottom end of the third rotating shaft (309) is provided with a connecting seat (308); the expansion shaft (901) is obliquely arranged, and the top end of the expansion shaft is connected with the connecting seat (308); crushing cutters (902) are uniformly arranged on the expanding shaft (901).

10. The machine of claim 9, further comprising a second bevel gear (903), a first bevel gear (904), a mounting bar (905), and a mounting bracket (906);

the connecting seat (308) is of a hollow structure, the third rotating shaft (309) and the second rotating shaft (304) are hollow shafts, and the second driving wheel (303) is provided with a through hole; the mounting rod (905) is arranged in the third rotating shaft (309), the bottom end of the mounting rod extends into the connecting seat (308) and is fixedly connected with a first bevel gear (904), and the top end of the mounting rod passes through the second rotating shaft (304) and the second driving wheel (303) and is connected with the material guide cavity (105) through a fixing frame (906); the top end of the expansion shaft (901) extends into the connecting seat (308) and is provided with a second bevel gear (903), and the second bevel gear (903) is matched with the first bevel gear (904).

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