CN215541609U - Mechanical power type organic waste regeneration system - Google Patents

Abstract

The utility model relates to the technical field of agricultural machinery, in particular to a mechanical power type organic waste regeneration system, which comprises a humidifying mechanism, wherein a feeding port I of the humidifying mechanism is connected with an automatic feeding mechanism, and the humidifying mechanism is sequentially provided with: the crushing mechanism, the conveying mechanism and the granulating mechanism; the humidifying mechanism is internally provided with a liquid storage cavity, the lifting device is connected with the separating device through the turnover device, the lifting device is used for driving the separating device to reciprocate along the liquid storage cavity to a discharge port I of the humidifying mechanism, and the turnover device is used for driving the separating device to incline along the discharge port I of the humidifying mechanism; the water in the liquid storage cavity soaks the organic waste, dust is prevented from being generated in the crushing process, the organic waste is conveyed to a discharge port I of the humidifying mechanism through the lifting device, and the organic waste is poured into the discharge port I of the humidifying mechanism through the overturning device.

Description

Mechanical power type organic waste regeneration system

Technical Field

The utility model relates to the technical field of agricultural machinery, in particular to a mechanical power type organic waste regeneration system.

Background

In the traditional agricultural field, the residual organic wastes (such as straws, beanstalks and the like) after the crops are harvested are generally converted into utilizable heat energy through burning, the residual organic wastes are directly burned in the field, and a large amount of inhalable particles, sulfur dioxide, nitrogen dioxide and other substances are generated after burning; at present, redundant organic wastes are subjected to powder cutting in the field by loading a powder cutting machine on an agricultural vehicle, and the machine wastes after powder cutting are thrown in the field to be used as fertilizers.

However, this method has the following problems;

the dried organic waste can generate a large amount of dust in the crushing process, and operators can be injured by the operation environment for a long time; in addition, in windy weather, the generated dust is easy to hoist into the air, so that air pollution is caused.

SUMMERY OF THE UTILITY MODEL

Aiming at the defects in the prior art, the utility model aims to provide a mechanical power type organic waste regeneration system.

In order to achieve the above purpose, the utility model provides the following technical scheme:

the utility model provides a mechanical power's organic waste regeneration system, includes humidification mechanism, humidification mechanism's pan feeding mouth I is connected with automatic feeding mechanism, along humidification mechanism's discharge gate I, has set gradually: the crushing mechanism, the conveying mechanism and the granulating mechanism;

the humidifying mechanism is internally provided with a liquid storage cavity, the lifting device is connected with the separating device through the turnover device, the lifting device is used for driving the separating device to reciprocate between the liquid storage cavity and a discharge port I of the humidifying mechanism, and the turnover device is used for driving the separating device to incline along the discharge port I of the humidifying mechanism.

The separating device is a separating frame; the lifting device is a linear sliding table, and a bearing with a seat is mounted on a support plate of one linear sliding table.

The turnover device is a turnover motor which is fixedly arranged on a support plate of another linear sliding table, rotating shafts are arranged on two sides of the separating frame, the output end of the turnover motor is fixedly connected with one rotating shaft in a coaxial mode, and the bearing with the base is fixedly connected with the other rotating shaft in a coaxial mode.

The separation device is a separation hopper, and the lifting device comprises at least two linear slide rails arranged in parallel and a driving assembly;

the back side of the separation hopper is provided with a sliding assembly, the driving assembly props against the separation hopper through the transmission assembly, and the separation hopper is driven to move along the linear sliding rail through the sliding assembly.

The turnover device is a turning slide rail, the linear slide rail where the sliding assembly is located is fixedly connected with the turning slide rail, a blocking piece is fixedly mounted at one end of the turning slide rail, which is not connected with the linear slide rail, and the blocking piece is used for preventing the sliding assembly from being separated from the turning slide rail.

The bottom in the liquid storage cavity is provided with a diffusion device, and a filtering device is arranged above the diffusion device.

The automatic feeding mechanism comprises an automatic cutting device and an automatic feeding device;

the automatic feeding device comprises a crawler conveyor and a pressing roller assembly, and the crawler conveyor is arranged on the inner bottom surface of the storage box; in the vertical direction of the track conveyor, the pinch roller assembly is driven to reciprocate in a direction toward or away from the track conveyor.

The automatic cutting device comprises a cutter and a cutter abutting table, the cutter abutting table is installed on the inner bottom surface of the storage box, and the cutter is driven to move back and forth along the direction close to or far away from the cutter abutting table in the vertical direction of the cutter abutting table.

The inner side of the cutter support table is provided with a storage groove, the inner bottom surface of the storage groove is inclined along the direction of an inclined pipe and is communicated with a feeding port I of the humidifying mechanism through the inclined pipe.

The crushing mechanism is a rotating roller crusher, a discharge port II of the rotating roller crusher is connected with a storage box, and pesticide spraying nozzles are uniformly distributed on the inner wall of the storage box.

The conveying mechanism is a spiral feeding machine, a feeding port of the spiral feeding machine extends to the storage box, and a feeding port of the granulating mechanism is located below a discharging port III of the spiral feeding machine.

Compared with the prior art, the utility model has the beneficial effects that:

the device is provided with a humidifying mechanism, after the organic waste enters the liquid storage cavity, water in the liquid storage cavity soaks the organic waste to avoid dust generation in the crushing process, the organic waste is conveyed to a discharge port I of the humidifying mechanism through the lifting device, and then the organic waste is poured into the discharge port I of the humidifying mechanism through the overturning device.

The equipment is provided with an automatic cutting device and an automatic feeding device, wherein the automatic feeding device can convey longer organic wastes to the automatic cutting device, the organic wastes are cut into shorter organic wastes through the automatic cutting device, and the shorter organic wastes can be crushed through a rotating roller crusher regardless of vertical or horizontal placement of the shorter organic wastes into the rotating roller crusher after being soaked by the humidifying mechanism.

Drawings

Fig. 1 is a schematic view of a mechanically powered organic waste recycling system from a first perspective.

Fig. 2 is a schematic structural view of a mechanically powered organic waste recycling system from a second perspective.

Fig. 3 is a schematic structural diagram of the turnover device and the lifting device.

Fig. 4 is a schematic structural view of the separation frame.

Fig. 5 is a schematic structural view of a mechanically powered organic waste recycling system from a third perspective.

Fig. 6 is a schematic structural view of the automatic cutting device and the automatic feeding device.

Fig. 7 is a schematic view of a mechanically powered organic waste recycling system from a fourth perspective.

Fig. 8 is a schematic structural view of a mechanically powered organic waste recycling system at a fifth viewing angle.

Fig. 9 is a schematic view of a mechanically powered organic waste recycling system from a sixth perspective.

Fig. 10 is a schematic structural view of a lifting device and a turnover device in the second embodiment.

FIG. 11 is a schematic view of the connection of the chain to the bearing of the drive assembly.

In the turning device drawings: the device comprises a vehicle body 1, a humidifying mechanism 2, a liquid storage cavity 21, a separating frame 22, a rotating shaft 221, a linear sliding table 23, a belt seat bearing 232, a turnover motor 24, a closing door 25, a sealing door 27, a discharge port I28, a feeding port I29, a storage box 3, an inclined pipe 31, a rotating roller crusher 4, a mixing box 5, a feeding machine 6, a discharge port III62, a granulator 7, a crawler conveyor 81, a pinch roller assembly 82, a pinch roller 821, a pinch roller mounting rack 822, a pinch roller electric cylinder 83, a cutter 91, a cutter electric cylinder 92, a storage tank 93, a separating hopper 10, a permeable hole 101, a linear slide rail 11, a bending slide rail 12, a baffle 13, a chain 14, an upper chain wheel 15, a lower chain wheel 16, a transmission chain 17, a transmission chain wheel 18, a motor chain wheel 19, an upper rotating shaft 41, a lower rotating shaft 42, a driving motor 43, a sliding rotating shaft 44, a pulley 45 and a bearing 46.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. 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.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used in the description of the utility model herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the utility model. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Implementation mode one

Referring to fig. 1, a mechanical power type organic waste regeneration system includes a humidifying mechanism 2, a feeding port I29 of the humidifying mechanism 2 is connected with an automatic feeding mechanism, and a discharging port I28 along the humidifying mechanism is sequentially provided with: the crushing mechanism, the conveying mechanism and the granulating mechanism;

the humidifying mechanism 2 soaks the organic waste, avoids producing the dust at the kibbling in-process of organic waste, and automatic feeding mechanism transmits and cuts organic waste, makes the organic waste who gets into the humidifying mechanism 2 all be shorter organic waste, and no matter organic waste transversely gets into rubbing crusher structure or vertically gets into rubbing crusher structure, all can smash organic waste, conveys granulation mechanism in through transport mechanism, makes organic waste become granular fertilizer.

Specifically, the automatic feeding mechanism comprises an automatic cutting device and an automatic feeding device;

referring to fig. 5 to 7, the automatic feeding device includes a crawler conveyor 81 and a pinch roller assembly 82, the pinch roller assembly 82 includes a pinch roller 821 and a pinch roller mounting bracket 822, two ends of the pinch roller 821 are rotatably mounted on the pinch roller mounting bracket 822 through bearings, two ends of the pinch roller mounting bracket 822 are fixedly connected to an output end of a pinch roller electric cylinder 83, and the crawler conveyor 81 is mounted on an inner bottom surface of the storage box 3; in the vertical direction of the track conveyor 81, the pinch roller mounting 822 is driven by the pinch roller electric cylinder 83 to move back and forth in the direction close to or away from the track conveyor 81, a gap between the pinch roller 821 and the track conveyor 81 is used for accommodating organic waste, when the pinch roller electric cylinder 83 drives the pinch roller assembly 82 to move in the direction of the track conveyor 81, the pinch roller 821 compresses the organic waste on the track conveyor 81, and the track conveyor 81 is started to drive the organic waste to enter the range of the automatic cutting device;

furthermore, considering that the uncut organic waste is long in length and the storage box 3 is shallow in depth, in order to reduce the pressure between the pressing roller 821 and the crawler conveyor 81, the apparatus further includes a support plate 84, a jack is disposed below the storage box 3, and the support plate 84 is inserted into the storage box 3, in this embodiment, a hinge iron is disposed below the support plate 84, a threaded hole I is formed in the hinge iron, a corresponding threaded hole II is formed in the storage box 3, and a bolt penetrates through the threaded hole I and the threaded hole II to fix the support plate 84 on the storage box 3; the organic waste is placed on the supporting plate 84, the pressure between the pressing roller 821 and the crawler conveyor 81 is dispersed, and the supporting plate 84 can be detached when the use is completed, so that the occupied space is reduced.

Referring to fig. 1 and 6, in particular, the automatic cutting device includes a cutter 91 and a cutter support platform, the cutter electric cylinder 92 is vertically installed in the storage box 3, an output end of the cutter electric cylinder 92 is fixedly connected with the cutter 91, the cutter support platform is installed on the inner bottom surface of the storage box 3, a mounting groove is formed in the inner bottom surface of the storage box 3, the cutter support platform is arranged in the mounting groove, the top surface of the cutter support platform is flush with the inner bottom surface of the storage box 3, resistance when the organic waste moves is reduced, in the vertical direction of the cutter support platform, the cutter 91 is driven by the cutter electric cylinder 92 to move back and forth along the direction close to or far away from the cutter support platform, and accordingly, the longer organic waste is cut into the shorter organic waste.

Specifically, a storage tank 93 is arranged on the inner side of the cutter supporting table, a crawler conveyor 81 is arranged on the outer side of the cutter supporting table, namely, along the inlet direction of the storage box 3, the organic waste sequentially passes through the crawler conveyor 81 and the cutter supporting table, and then falls into the storage tank 93 after being cut by the cutter 91;

specifically, the inner bottom surface of the storage tank 93 is cut and inclined along the direction of an inclined pipe 31 and is communicated with a material inlet I29 of the humidifying mechanism 2 through the inclined pipe 31; that is, the inner bottom surface of the storage tank 93 is of a slope structure and is inclined towards the inclined tube 31, the cut short organic waste slides into the inclined tube 31 through the storage tank 93 under the action of self weight, enters the material inlet I29 of the humidifying mechanism 2 through the inclined tube 31, and further enters the humidifying mechanism 2, so that the transmission of the short organic waste is realized, it should be noted that the organic waste is cut into short blocks by the cutter 91, and therefore the organic waste cannot be clamped in the inclined tube 31 in the sliding process.

Referring to fig. 1 and 2, specifically, a liquid storage cavity 21 is formed in the humidifying mechanism 2, and organic waste falling into the liquid storage cavity 21 is wetted by water in the liquid storage cavity 21; the lifting device is connected with the separating device through the turnover device, the lifting device is used for driving the separating device to reciprocate along the liquid storage cavity 21 to the discharge port I28 of the humidifying mechanism 2, when the separating device is exposed out of the water surface, the organic wastes floating on the water surface are collected into the separating device, the lifting device moves the separating device to the discharge port I28 of the humidifying mechanism 2, and the turnover device is used for driving the separating device to incline along the discharge port I28 of the humidifying mechanism 2, so that the organic wastes in the separating device are poured into the discharge port I28 of the humidifying mechanism 2; it should be noted that the organic waste in the utility model is dry organic waste, and floats on the water surface after entering the water.

Referring to fig. 1 to 4, specifically, the separating device is a separating frame 22, the lifting device is a linear sliding table 23, a support plate of one of the linear sliding tables 23 is provided with a bearing with a seat 232, the turnover device is a turnover motor 24, the turnover motor 24 is fixedly installed on a support plate of the other of the linear sliding tables 23, two sides of the separating frame 22 are provided with rotating shafts 221, an output end of the turnover motor 24 is coaxially and fixedly connected with one of the rotating shafts 221, and the bearing with a seat 232 is coaxially and fixedly connected with the other rotating shaft 221;

the output end of the turning motor 24 is coaxially and fixedly connected with one of the rotating shafts 221, the bearing 232 with the seat is coaxially and fixedly connected with the other rotating shaft 221, namely, the bearing of the bearing 232 with the seat is coaxially and fixedly connected with the other rotating shaft 221, and the bearing seat of the bearing 232 with the seat is rotatably connected with the other rotating shaft 221;

in this embodiment, upset motor 24 adopts the waterproof motor that can be at underwater operation, and the motor and the battery of sharp slip table 23 are installed in the one end that sharp slip table 23 kept away from liquid storage chamber 21, and the battery of upset motor is also installed in the one end that sharp slip table 23 kept away from liquid storage chamber 21, and outside the power supply line of upset motor 24, the cover is equipped with waterproof tensile hose, and the distance that upset motor 24 removed along with the support plate of sharp slip table 23 can be satisfied to upset motor 24's power supply line length.

When organic waste in the liquid storage cavity 21 needs to be conveyed to the crushing mechanism, the two groups of linear sliding tables 23 are started simultaneously to drive the separation frame 22 to move along the direction of the discharge port I28 of the humidifying mechanism 2, when the separation frame 22 rises from the water surface, the organic waste floating on the water surface is driven to move along the direction of the discharge port I28 of the humidifying mechanism 2, when the organic waste reaches the discharge port I28 of the humidifying mechanism 2, the linear sliding tables 23 stop, the separation frame 22 stays at the discharge port I28 of the humidifying mechanism 2, the turnover motor 24 is started, the output end drives the separation frame 22 to rotate towards the discharge port I28 of the humidifying mechanism 2, namely, the separation frame 22 inclines towards the discharge port I28 of the humidifying mechanism 2, the organic waste on the separation frame 22 enters the discharge port I28 of the humidifying mechanism 2, and the lower part of the discharge port I28 of the humidifying mechanism 2 is the feeding port I29 of the crushing mechanism.

Further, a diffusion device is arranged at the bottom in the liquid storage cavity 21, and a filtering device is arranged above the diffusion device;

specifically, in order to accelerate the diffusion of the organic waste in the liquid storage cavity 21 and enable the organic waste to be rapidly immersed into water, the diffusion device is arranged below the filter steel mesh, the diffusion device adopts an anti-winding stirrer, and when the anti-winding stirrer is started, water flow drives the organic waste to rotate so as to accelerate the diffusion of the organic waste in the liquid storage cavity 21;

referring to fig. 1 and 7, specifically, the filtering device can filter the slag that the organic waste dropped, prevent that the slag from sinking into the bottom of storage tank 3, the filtering device is a filter steel mesh, the inner wall of liquid storage chamber 21 has been seted up the slide, rotate on the inner wall of liquid storage chamber 21 towards the slide tip and be connected with sealing door 27, when the slag on the filter steel mesh piles up when great, open sealing door 27, take out the filter steel mesh, fall the slag on the filter screen 26 can, in addition, sealing door 27 can also turn on the water and use, after this equipment use was accomplished, open sealing door 27, emit the water in the liquid storage chamber 21.

Please refer to fig. 3, specifically, a mounting groove II has been seted up at pan feeding port I29 of humidification mechanism 2, a vertical electric telescopic handle has been installed in mounting groove II, electric telescopic handle's output end fixedly connected with closing door 25, when organic waste in liquid storage chamber 21 needs to be transported to discharge port I28 of humidification mechanism 2, electric telescopic handle drives closing door 25 of pan feeding port I29 department of humidification mechanism 2 and stretches out, non-wetted organic waste temporarily exists in storage tank 3, can not fall in liquid storage chamber 21.

Referring to fig. 7, specifically, the crushing mechanism is a roller crusher 4, a discharge port of the roller crusher 4 is connected to a mixing box 5, pesticide spraying nozzles are uniformly distributed on an inner wall of the mixing box 5, a liquid fertilizer can be stored in the mixing box 5 of the pesticide spraying nozzles, and when organic waste is crushed by the roller crusher 4 and discharged from the discharge port of the roller crusher 4, the liquid fertilizer sprayed by the pesticide spraying nozzles is attached to the organic waste, so that the nutrition of the organic waste is increased.

Specifically, the conveying mechanism is a spiral feeding machine 6, a feeding port of the spiral feeding machine 6 extends to the mixing box 5, a feeding port of the granulating mechanism is positioned below a discharging port III62 of the spiral feeding machine 6, and the granulating mechanism is a granulator 7;

the organic waste mixed with the liquid fertilizer agent is conveyed into the granulator 7 through the spiral feeding machine 6, the granulator 7 makes the organic waste mixed with the liquid fertilizer agent into granular fertilizer, and the granular fertilizer is large in volume and mass and cannot be hoisted into the air.

Specifically, the equipment is arranged on the vehicle body 1, and can be moved to the field.

Second embodiment

The present embodiment differs from the first embodiment in the following:

referring to fig. 9 and 10, the separating device is a separating bucket 10, a plurality of water permeable holes 101 are uniformly distributed on the surface of the separating bucket 10, and the lifting device comprises at least two linear slide rails 11 arranged in parallel and a driving assembly;

specifically, in the present embodiment, two parallel linear sliding rails 11 are provided, and the driving assembly includes a chain 14, an upper chain wheel 15, a lower chain wheel 16, a transmission chain 17, a transmission chain wheel 18, and a motor chain wheel 19;

the top of one of them linear slide rail 11 is provided with pivot 41 on, and the bottom is provided with lower pivot 42, go up sprocket 15 and the coaxial fixed connection of last pivot 41, lower sprocket 16 and the coaxial fixed connection of lower pivot 42, chain 14 meshes with lower sprocket 16 and last sprocket 15 respectively, and drive sprocket 18 is coaxial fixed on last pivot 41, and coaxial fixed connection motor sprocket 19 on the output of driving motor 43, drive sprocket 18 meshes motor sprocket 19 and drive sprocket 18 respectively.

The back of the separation hopper 10 is provided with a sliding assembly, the driving assembly props against the separation hopper 10 through the transmission assembly and drives the separation hopper 10 to move along the linear sliding rail 11 through the sliding assembly;

referring to fig. 11, specifically, the sliding assembly includes a sliding rotation shaft 44 and a pulley 45, the sliding rotation shaft 44 is rotatably connected to the pulley 45 through a bearing 46, the transmission assembly and the sliding assembly have the same structure, the sliding rotation shaft 44 of the sliding assembly is fixedly mounted on the back of the separation bucket 10, the pulley 45 of the sliding assembly is mounted in one of the linear slide rails 11, the sliding rotation shaft 44 of the transmission assembly movably abuts against the separation bucket 10, the pulley 45 of the transmission assembly is mounted in the other one of the linear slide rails 11, and two ends of the chain 14 are respectively fixedly connected to bearing sleeves of the bearing 46 of the transmission assembly, so as to drive the sliding rotation shaft 44 of the transmission assembly to abut against the separation bucket 10 and then move along the linear slide rails 11, so as to realize the reciprocating movement of the separation bucket 10 between the liquid storage cavity 21 and the discharge port I28 of the humidifying mechanism 2.

The overturning device is a turning slide rail 12, a linear slide rail 11 where the sliding assembly is located is fixedly connected with the turning slide rail 12, a blocking piece 13 is fixedly installed at one end, which is not connected with the linear slide rail 11, of the turning slide rail 12, and the blocking piece 13 is used for preventing the sliding assembly from being separated from the turning slide rail 12;

specifically, when the sliding shafts 44 of the transmission assembly and the sliding assembly are respectively located in the two parallel linear sliding rails 11, the distance between the axes of the transmission assembly and the sliding rotating shaft 44 of the sliding assembly is basically in a constant state, the sliding rotating shaft 44 of the transmission assembly is abutted against the separating hopper 10 to drive the separating hopper 10 and the sliding assembly to move along the linear slide rail 11, when the sliding rotating shaft 44 of the sliding assembly enters the bending sliding rail 12, the axle center distance between the transmission assembly and the sliding rotating shaft 44 of the sliding assembly is increased, when the sliding rotating shafts 44 of the transmission component and the sliding component are in the same plane, the separating hopper 10 is in a flat state, when the pulley 45 of the sliding assembly abuts against the blocking piece 13, the separating hopper 10 is abutted by the sliding rotating shaft 44 of the transmission assembly, the separating hopper 10 is turned over along the sliding rotating shaft 44 of the sliding assembly, the separating hopper 10 is inclined towards the discharge port I28 of the humidifying mechanism 2, and the organic waste in the separating hopper enters the discharge port I28 of the humidifying mechanism 2.

The working principle of the embodiment one is as follows:

the supporting plate 84 is arranged on the storage box 3, an operator puts the organic waste into a placing area formed by the track conveyor 81 and the supporting plate 84 according to the length direction of the organic waste, then the pinch roller electric cylinder 83 is started, the pinch roller mounting bracket 822 is driven by the pinch roller electric cylinder 83 to move in the direction close to the track conveyor 81, the pinch roller 821 compresses the organic waste on the track conveyor 81, and the track conveyor 81 is started to drive the organic waste to enter the range of the automatic cutting device;

the cutter 91 is driven by the cutter electric cylinder 92 to move along the direction close to the cutter support platform, longer organic waste is cut into shorter organic waste, the organic waste falls into the storage tank 93 after being cut, the inner bottom surface of the storage tank 93 is of a slope structure and is cut obliquely towards the direction of the inclined pipe 31, the cut shorter organic waste slides into the inclined pipe 31 through the storage tank 93 under the action of self weight, enters the material inlet I29 of the humidifying mechanism 2 through the inclined pipe 31 and then enters the humidifying mechanism 2, and the transmission of the shorter organic waste is realized;

a liquid storage cavity 21 is formed in the humidifying mechanism 2, and organic waste falling into the liquid storage cavity 21 is wetted by water in the liquid storage cavity 21; when organic waste in the liquid storage cavity 21 needs to be conveyed to the crushing mechanism, the two groups of linear sliding tables 23 are started simultaneously to drive the separation frame 22 to move along the direction of the discharge port I28 of the humidifying mechanism 2, when the separation frame 22 rises from the water surface, the organic waste floating on the water surface is driven to move along the direction of the discharge port I28 of the humidifying mechanism 2, when the organic waste reaches the discharge port I28 of the humidifying mechanism 2, the linear sliding tables 23 stop, the separation frame 22 stays at the discharge port I28 of the humidifying mechanism 2, the turnover motor 24 is started, the output end drives the separation frame 22 to rotate towards the discharge port I28 of the humidifying mechanism 2, namely the separation frame 22 inclines towards the discharge port I28 of the humidifying mechanism 2, the organic waste on the separation frame 22 enters the discharge port I28 of the humidifying mechanism 2, and the lower part of the discharge port I28 of the humidifying mechanism 2 is the feeding port I29 of the crushing mechanism;

the discharge port of the rotating roller crusher 4 is connected with a mixing box 5, when organic waste is crushed by the rotating roller crusher 4 and is discharged from the discharge port of the rotating roller crusher 4, liquid fertilizer sprayed by the pesticide spraying nozzle is attached to the organic waste, the organic waste mixed with the liquid fertilizer is conveyed into a granulator 7 through a spiral feeding machine 6, the granulator 7 makes the organic waste mixed with the liquid fertilizer into granular fertilizer, and the granular fertilizer has large volume and mass and cannot be hoisted into the air.

The above description is intended to describe in detail the preferred embodiments of the present invention, but the embodiments are not intended to limit the scope of the claims of the present invention, and all equivalent changes and modifications made within the technical spirit of the present invention should fall within the scope of the claims of the present invention.

Claims (9)

1. The utility model provides a mechanical power's organic waste regeneration system, its characterized in that, includes humidification mechanism (2), pan feeding mouth I (29) of humidification mechanism (2) are connected with automatic feeding mechanism, along humidification mechanism's discharge gate I (28), have set gradually: the crushing mechanism, the conveying mechanism and the granulating mechanism;

a liquid storage cavity (21) is formed in the humidifying mechanism (2), a lifting device is connected with the separating device through a turning device, the lifting device is used for driving the separating device to reciprocate along the liquid storage cavity (21) to a discharge port I (28) of the humidifying mechanism (2), and the turning device is used for driving the separating device to incline along the discharge port I (28) of the humidifying mechanism (2);

the separating device is a separating frame (22), the lifting device is a linear sliding table (23), and a bearing with a seat (232) is installed on a carrier plate of one linear sliding table (23).

2. The mechanical power type organic waste recycling system of claim 1, wherein the turning device is a turning motor (24), the turning motor (24) is fixedly installed on a carrier plate of another linear sliding table (23), rotating shafts (221) are installed on two sides of the separating frame (22), an output end of the turning motor (24) is coaxially and fixedly connected with one of the rotating shafts (221), and the pedestal bearing (232) is coaxially and fixedly connected with the other of the rotating shafts (221).

3. A mechanically powered organic waste recycling system according to claim 2, wherein said separating means is a separating hopper (10), said lifting means comprises at least two linear slides (11) arranged in parallel, and a driving assembly;

the back side of the separation hopper (10) is provided with a sliding assembly, the driving assembly props against the separation hopper (10) through the transmission assembly, and the separation hopper (10) is driven to move along the linear sliding rail (11) through the sliding assembly.

4. The mechanical power type organic waste recycling system according to claim 3, wherein the turning device is a turning slide rail (12), the linear slide rail (11) where the sliding component is located is fixedly connected with the turning slide rail (12), a blocking piece (13) is fixedly installed on one end of the turning slide rail (12) which is not connected with the linear slide rail (11), and the blocking piece (13) is used for preventing the sliding component from being separated from the turning slide rail (12).

5. The mechanically powered organic waste recycling system according to claim 4, wherein the automatic feeding mechanism comprises an automatic cutting device and an automatic feeding device;

the automatic feeding device comprises a crawler conveyor (81) and a pressing roller assembly (82), wherein the crawler conveyor (81) is arranged on the inner bottom surface of the storage box (3); in the vertical direction of the track conveyor (81), the pinch roller assembly (82) is driven to reciprocate in a direction toward or away from the track conveyor (81).

6. A mechanically powered organic waste recycling system according to claim 5, wherein said automatic cutting device comprises a cutter (91) and a cutter abutment, the cutter abutment is mounted on the inner bottom surface of the storage bin (3), and the cutter (91) is driven to move back and forth in a direction approaching to or away from the cutter abutment in the vertical direction of the cutter abutment.

7. A mechanical power type organic waste recycling system as claimed in claim 6, wherein said cutter support is provided with a storage tank (93) inside, the inner bottom surface of the storage tank (93) is inclined along the direction of an inclined pipe (31), and is connected to the inlet I (29) of the humidifying mechanism (2) through the inclined pipe (31).

8. The mechanical power type organic waste recycling system according to claim 7, wherein said pulverizing mechanism is a roller pulverizer (4), a mixing box (5) is connected to a discharge port II of said roller pulverizer (4), and said mixing box (5) has uniformly distributed chemical spraying nozzles on the inner wall.

9. A mechanically powered organic waste recycling system according to claim 8, characterized in that said conveyor is a screw feeder (6), the inlet of said screw feeder (6) extends to the mixing tank (5), and the inlet of said pelletizing mechanism is located below the outlet III (62) of said screw feeder (6).

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