CN113148681A - Non-fluid agent distributor - Google Patents

Abstract

The invention relates to the technical field of distributing devices, in particular to a non-fluid agent distributor, which comprises a main box body, wherein the top of the main box body is provided with a feeding door, a buffer plate is arranged in the main box body below the feeding door, the buffer plate is fixed in the main box body in a V shape with a downward opening, through holes are arrayed on the buffer plate, and a distributor is arranged at an outlet at the bottom of the main box body; the top of the main box body is provided with a connecting piece connected with a crane, and four corners of the lower end of the main box body extend downwards to form supporting legs. The non-fluid agent distributor disclosed by the invention is uniform in distribution, environment-friendly, reliable, capable of moving and transferring rapidly, light in weight and high in construction efficiency.

Description

Non-fluid agent distributor

Technical Field

The invention relates to the technical field of distributing devices, in particular to a non-fluid agent distributor.

Background

The rapid promotion of the national urbanization process leads the urban population to rapidly rise; in order to improve urban living environment, the policy of coming out of each big city one after another is adopted, and polluted enterprises and heavy industry enterprises are migrated; however, the pollution of the surrounding environment and soil of the polluted enterprises still needs to be treated harmlessly for many years. The polluted fields are not continuous and centralized, large-scale continuous treatment equipment is high in construction cost, and the transition moving period is long, so that certain difficulty is brought to harmless treatment of soil, and an additive spreading device with flexible disassembly and assembly is urgently needed.

With the rapid development of national economic construction, the contradiction between the requirement of construction land and the occupation of cultivated land is increasingly prominent, 18 hundred million mu cultivated land red lines are defined by the country for protecting the livelihood of people, and the sight of constructors has to be more shifted to rivers, lakes and sea-facies sedimentary lands. The depth of the sea phase deposition silt layer reaches dozens of meters, the depth of silt of soft foundation of artificial hydraulic reclamation is also nearly ten meters, the bearing capacity of the silt foundation is extremely low, the water content is high, and the silt foundation cannot be directly used for construction. Therefore, the sludge must be solidified, the conventional solution is to cut mountain and break stone, and the mixture of the broken stone and soil is called mountain skin soil, and the material is filled to the surface of the sludge layer, and the filled material sinks continuously, and then is filled and extruded continuously until the filled mountain skin soil is stable. But the cost is high, the period is long, and the investment is large; at present, a certain amount of curing agent is usually added into the sludge to cure the shallow surface sludge.

Limited by the prior art, the curing agent is usually intensively treated by a mixing station or manually and directly poured into the sludge to be treated, and then mixed on site. The treatment method has relatively high efficiency, but has large manual workload, uneven curing agent laying, large dust emission and serious environmental pollution. The invention is based on the pain point, is developed in a forward direction, and fundamentally solves the problems.

Disclosure of Invention

The present invention provides a non-fluid material distributor to solve the above technical deficiencies, which has the advantages of light weight, uniform distribution, convenient transition and movement and high efficiency.

The invention discloses a non-fluid agent distributor, which comprises a main box body, wherein a feeding door is arranged at the top of the main box body, a buffer plate is arranged in the main box body below the feeding door, the buffer plate is fixed in the main box body in a V shape with a downward opening, through holes are arrayed on the buffer plate, and a distributor is arranged at an outlet at the bottom of the main box body; the top of the main box body is provided with a connecting piece connected with a crane, and the lower end of the main box body is provided with a supporting leg.

The supporting legs are arranged at four corners of the lower end of the main box body, connecting rods are arranged between adjacent supporting legs, and the connecting rods are used for strengthening the stability of the supporting legs.

Among the above-mentioned scheme, the main tank body can be poured into through the feed door to non-fluid agent, and at the in-process that non-fluid agent got into the main tank body, because the action of gravity, it can strike on the buffer board to make the agent material broken up, can not form the cubic, have the through-hole on the buffer board moreover, it is better to the effect of breaing up of agent material. The scattered agents are uniformly conveyed outwards through the distributor. The whole volume of this equipment is less, light in weight, and it is convenient to shift, and its connecting piece can be connected with loop wheel machine, excavator etc. is convenient for operate.

The bottom of the main box body is composed of inclined side plates, a rectangular outlet is formed in the middle of the main box body, the distributor is arranged at the outlet and comprises a distributing pipe and a shifting shaft, the shifting shaft is sleeved inside the distributing pipe, two ends of the shifting shaft are rotatably connected through a bearing, the distributing pipe is horizontally fixed at the outlet at the bottom of the main box body, the distributing pipe is hermetically connected with the outlet, the upper end of the distributing pipe is positioned inside the main box body, the lower end of the distributing pipe is positioned outside the main box body, a feeding through hole is formed in the distributing pipe inside the main box body, a discharging through hole is formed in the distributing pipe outside the main box body, a power mechanism is arranged on the main box body and is in transmission connection with the shifting shaft, the shifting shaft comprises a shaft body and partition plates which are arranged on the shaft body at intervals, the partition plates are arranged along the axial direction, and the partition plates are arranged on the shaft body at even intervals, when the stirring shaft is positioned in the material distributing pipe, the outer end of the partition plate is contacted with the inner wall of the material distributing pipe. The angle of the central angle of the feeding through hole on the material distributing pipe is smaller than that of the central angle of the discharging through hole on the material distributing pipe. Preferably, the central angle corresponding to the feeding through hole is 60 degrees, and the central angle corresponding to the discharging through hole is 120 degrees. The feeding through holes and the discharging through holes occupy most or all areas of the material distributing pipe in the range, a small amount of connecting ribs can be reserved, and the conveying of the agent is not influenced. The power mechanism can be a hydraulic motor, is suitable for outdoor operation, is more convenient to be matched with an excavator and the like, and can also be a pneumatic motor or an electric motor and the like.

According to the scheme of the distributor, the non-fluid agent is located at the bottom of the main box body, the inclined side plates at the bottom of the main box body are arranged, the non-fluid agent can be gathered towards the distributor, meanwhile, due to the design of the feeding through holes at the upper part of the distributing pipe and the discharging through holes at the lower part of the distributing pipe, the agent can fall into the area between the partition plates on the material stirring shaft in the distributing pipe, the outer side of each partition plate basically contacts with the inner wall of the distributing pipe, the agent only falls into the area between the partition plates corresponding to the feeding through holes, the partition plates can drive the agent to rotate to the discharging through holes after the material stirring shaft rotates, the agent falls under the action of gravity, the power mechanism drives the material stirring shaft to rotate at a constant speed, and the distribution of the agent is uniform and stable. Because the partition plates are uniformly spaced, the spaces among the partition plates are consistent, and the distribution of the agent is uniform. The existence of a small amount of splice bar in order to increase branch material pipe's intensity and stability.

A pressure distributing plate is arranged above a rectangular outlet at the bottom of the main box body, the pressure distributing plate is a V-shaped plate with a downward opening, the length direction of the pressure distributing plate is consistent with the axial direction of the material stirring shaft, and two ends of the pressure distributing plate are fixed on side plates at the bottom of the main box body at two ends of the material stirring shaft. A material distributing plate is arranged above the material distributor, so that a large amount of materials in the main box body can be prevented from being compacted downwards and cannot enter the material distributing pipe. Therefore, the material distributing plate can reduce the stacking density of the material below the material distributing plate, ensure that the material can smoothly enter the material distributing pipe from two sides, and ensure the stability and the continuity of the material distribution.

The lower end of the main box body is fixedly connected with a passive scattering plate, two ends of the passive scattering plate are connected to the main box body, the passive scattering plate is located under the material stirring shaft, a gap exists between the passive scattering plate and the material stirring shaft, and the passive scattering plate is of a V-shaped structure with a downward opening. Because the agent material gets into between the baffle of stirring the material axle after, the agent material in its main tank body can produce certain pressure to it, stir the material axle simultaneously and rotate the in-process, divide the material pipe inner wall also can produce certain extrusion to the agent material between the baffle, so stir the agent material between the baffle of material axle and have certain compactness, rotate to ejection of compact through-hole department as it, it can fall under the action of gravity, can block structure occasionally, so stir the passive board of breaing up of material axle below and can break up the agent material that drops, avoid it to be massive cloth, so the cloth is more even, stability and excellent in use effect.

A plurality of reinforcing plates are arranged at the bottom of the main box body below the pressure dividing plate at intervals, two ends of each reinforcing plate are fixed on the side plates of the main box body, and material passing holes are formed in the middle of each reinforcing plate. The design of reinforcing plate can carry out better support to the pressure divider plate, avoids the agent in the main tank body too big and cause the circumstances such as pressure divider plate bending deformation damage even on the effort of pressure divider plate, and the design in punishment in advance hole simultaneously can make the agent can pass the reinforcing plate, so, the reinforcing plate can not lead to the fact the restriction to the transport of agent.

The connecting piece is davit and/or colludes the hanger plate, the davit is hollow tubular structure, and its both ends are fixed at the both ends of main tank body through the side connection board, collude hanger plate quantity at least two, and it is linear arrangement and fixes at the top of main tank body, colludes and is provided with the grafting opening that inclines downwards on the hanger plate. In the scheme, one of the suspension arm and the hook suspension plate can be selected to be arranged on the main box body, and the suspension arm and the hook suspension plate can be assembled on the main box body, so that the suspension arm and the hook suspension plate cannot interfere with each other, and a reasonable connection form can be selected according to actual requirements. The suspension arm is of a hollow tubular structure and can be connected to a mechanical arm of an excavating machine or a mechanical arm of a crane through bolts or bolts and the like. And collude the hanger plate through the design of the grafting opening of slope decurrent, can insert the front end of the scraper bowl of excavator inside this grafting opening, can realize connecting, connect simple and conveniently, need not the dismouting moreover, can raise the efficiency.

One end of the top of the main box body is provided with a material input pipe, and the other end is provided with an exhaust pipe. Through the design of agent input tube, can utilize engineering machine tool to directly carry the agent in to the main tank body, high efficiency more reduces the manual work and throws the material, and is efficient, and in addition, the design of blast pipe can make the main tank body inside keep atmospheric pressure balanced, and equipment stability is better.

A pedal is arranged on the side wall of the main box body close to one side of the feeding door. The design of running-board can be so that the operation workman can stand on the running-board to the inside in-process of throwing the material of main tank, and its operation is simpler, and efficiency is higher, and the security is high.

The feed inlet is arranged at the top of the main box body of the feed door, the main box bodies on two sides of the feed inlet are provided with mutually parallel slide rails, the opposite side surfaces on the slide rails are provided with slide grooves, two ends of the feed door are positioned inside the slide grooves, the feed door is connected with the slide rails in a sliding manner, two limiting connecting plates are arranged on the lower surface of the feed door, a limiting rod is arranged between the limiting connecting plates, two ends of the limiting rod are positioned outside the two limiting connecting plates, and two ends of at least one limiting rod are positioned inside the main box body below the feed inlet.

According to the technical scheme design of the feeding door, the feeding door is matched with the sliding grooves in the sliding rails on the two sides, so that the feeding door can be connected in the sliding grooves in a sliding mode, and the feeding door is convenient to open and close. In addition, the limiting connecting plate stretches into the main box body, and the limiting rod is arranged in the main box body, so that the movement of the feeding door on the sliding rail is limited, the falling off and the like are avoided, the misoperation of workers is limited, the feeding door is removed, the using performance of the feeding door can be ensured, the closing is reliable, and the damage and the like are avoided.

One end of the sliding rail is located in the range corresponding to the feed inlet, when the feed door is pulled to the limit connecting plate to be in contact with the side wall of the feed inlet at the end, the feed door is separated from the groove of the rail, and the difference between the axial width of the limit rod and the distance between the outer side surfaces of the two limit connecting plates of the feed inlet is greater than the length of the limit rod outside the limit connecting plates. The design of this structure, under the normal use's the condition, the feeding door can not drop, is difficult for being demolishd. If need demolish the maintenance with the feed door or when maintaining, can be located one side pulling to the tip of feed inlet within range to the slide rail with the feed door to make the feed door break away from in the slide rail completely, then remove to the at utmost with the feed door to being close to one of them slide rail one side, thereby make the gag lever post tip of the other end be located the feed inlet within range, with the feed door slope, the gag lever post tip is taken out from the feed inlet, thereby realizes demolising of whole feed door.

The baffle is made of rubber. Adopt the rubber material as the baffle, can direct contact between the branch material pipe of its rubber and metal promotes the leakproofness between baffle and the branch material pipe to ensure the accuracy nature of branch material, the wearing and tearing between rubber and the metal are less simultaneously.

The material stirring shaft is characterized in that a plurality of clamping grooves are uniformly formed in the circumferential direction of the material stirring shaft at intervals, each clamping groove is arranged along the axial direction of the material stirring shaft, the opening size of each clamping groove is smaller than the internal size of each clamping groove, the size and the shape of the connecting end of the partition board made of rubber and the material stirring shaft are consistent with the internal shape and the size of each clamping groove, and the partition board is inserted into the clamping grooves. According to the design of the structure, the section of the partition plate can be T-shaped, and the section of the clamping groove can also be T-shaped, so that the partition plate and the clamping groove can be spliced, the replacement is convenient, the difficulty in manufacturing and connecting matching is reduced, and the cost is low.

The side wall of the main box body is provided with an access window, so that the inside of the main box body can be cleaned conveniently and internal components can be maintained conveniently.

The non-fluid agent distributor disclosed by the invention is uniform in distribution, environment-friendly, reliable, capable of moving and transferring rapidly, light in weight and high in construction efficiency.

The non-fluid agent distributor obtained by the invention can be applied to sludge solidification and soil pollution treatment.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic view of the present invention with the top removed;

FIG. 3 is a side cross-sectional view of the present invention;

FIG. 4 is a schematic view of the structure of the distributor of the present invention;

FIG. 5 is a schematic view of the exploded structure of the dispenser of the present invention;

FIG. 6 is a schematic structural view of the distributing pipe of the present invention;

FIG. 7 is a perspective view of the dispensing tube of the present invention;

FIG. 8 is a schematic structural view of the stirring shaft of the present invention;

FIG. 9 is a side view of the kick-off shaft of the present invention;

FIG. 10 is a schematic view of the construction of the hook plate of the present invention;

FIG. 11 is a schematic view of the external structure of the feed gate of the present invention;

FIG. 12 is a schematic view of the internal structure of the feed gate of the present invention;

FIG. 13 is a schematic cross-sectional view of a feed gate of the present invention;

fig. 14 is a schematic view of the connection between the stirring shaft and the partition plate according to the present invention.

Detailed Description

To further clarify the technical measures and effects of the present invention adopted to achieve the intended purpose, the following detailed description is given of specific embodiments, structures, characteristics and effects according to the present invention with reference to the accompanying drawings and preferred embodiments.

Example 1:

as shown in fig. 1, 2 and 3, the invention discloses a non-fluid agent distributor, which comprises a main box body 1, wherein a feeding door 2 is arranged at the top of the main box body 1, a buffer plate 10 is arranged in the main box body 1 below the feeding door 2, the buffer plate 10 is fixed in the main box body 1 in a V shape with a downward opening, through holes are arrayed on the buffer plate 10, and a distributor 3 is arranged at the bottom outlet of the main box body 1; the top of the main box body 1 is provided with a connecting piece connected with a crane, and four corners of the lower end of the main box body 1 extend downwards to form supporting legs 8.

As shown in fig. 4-9, the bottom of the main box 1 is formed by inclined side plates, a rectangular outlet is formed in the middle of the main box, the distributor 3 is disposed at the outlet, the distributor 3 includes a distributing pipe 16 and a stirring shaft 17, the stirring shaft 17 is sleeved inside the distributing pipe 16, and two ends of the stirring shaft are rotatably connected through a bearing, the distributing pipe 16 is horizontally fixed at the outlet at the bottom of the main box 1, the distributing pipe 16 is hermetically connected with the outlet, the upper end of the distributing pipe 16 is located inside the main box 1, the lower end of the distributing pipe 16 is located outside the main box 1, a feeding through hole 22 is disposed on the distributing pipe 16 inside the main box 1, a discharging through hole 23 is disposed on the distributing pipe 16 outside the main box 1, a power mechanism 21 is disposed on the main box 1, the power mechanism 21 is in transmission connection with the stirring shaft 17, the stirring shaft 17 includes a shaft body and partition plates 18 disposed on the shaft body at intervals, the partition plates 18 are arranged along the axial direction, the partition plates 18 are uniformly arranged on the shaft body at intervals, and when the material stirring shaft 17 is positioned in the material distributing pipe 16, the outer ends of the partition plates 18 are in contact with the inner wall of the material distributing pipe 16. The central angle of the feed-through opening 22 on the distributing pipe 16 should be smaller than the central angle of the discharge-through opening 23 on the distributing pipe 16. Preferably, the central angle corresponding to the feeding through hole 22 is 60 degrees, and the central angle corresponding to the discharging through hole 23 is 120 degrees. An annular dust cover 19 is arranged at the lower end outlet of the distributor 3.

A pressure distributing plate 13 is arranged above the rectangular outlet at the bottom of the main box body 1, the pressure distributing plate 13 is a V-shaped plate with a downward opening, the length direction of the pressure distributing plate is consistent with the axial direction of the material stirring shaft 17, and two ends of the pressure distributing plate 13 are fixed on side plates at the bottom of the main box body 1 at two ends of the material stirring shaft 17.

The lower end of the main box body 1 is fixedly connected with a passive scattering plate 20, two ends of the passive scattering plate 20 are connected to the main box body 1, the passive scattering plate 20 is located right below the material stirring shaft 17, a gap exists between the passive scattering plate 20 and the material stirring shaft 17, and the passive scattering plate 20 is of a V-shaped structure with a downward opening.

A plurality of reinforcing plates 14 are arranged at the bottom of the main box body 1 below the pressure dividing plate 13 at intervals, two ends of each reinforcing plate 14 are fixed on side plates of the main box body 1, and a material passing hole 15 is formed in the middle of each reinforcing plate 14.

The connecting piece is composed of a suspension arm 4 and hook plates 5, the suspension arm 4 is of a hollow tubular structure, two ends of the suspension arm 4 are fixed at two ends of the main box body 1 through side connecting plates 11, as shown in fig. 10, at least two hook plates 5 are arranged linearly and fixed at the top of the main box body 1, and the hook plates 5 are provided with inserting openings 12 which are inclined downwards.

One end of the top of the main box body 1 is provided with a dosage input pipe 6, and the other end is provided with an exhaust pipe 7.

A pedal 9 is arranged on the side wall of the main box body 1 close to one side of the feeding door 2.

As shown in fig. 11, 12, and 13, a feed inlet 28 is disposed at the top of the main box body 1 at the feed door 2, slide rails 24 parallel to each other are disposed on the main box body 1 at both sides of the feed inlet 28, slide grooves 25 are disposed on opposite sides of the slide rails 24, both ends of the feed door 2 are located inside the slide grooves 25, the feed door 2 is slidably connected with the slide rails 24, two limit connection plates 26 are disposed on the lower surface of the feed door 2, a limit rod 27 is disposed between the limit connection plates 26, both ends of the limit rod 27 are located outside the two limit connection plates 26, and at least both ends of the limit rod 27 are located inside the main box body 1 below the feed inlet 28.

One end of the slide rail 24 is located in the range corresponding to the feed inlet 28, when the feed door 2 is pulled until the limit connecting plate 26 contacts with the side wall of the feed inlet 28 at the end, the feed door 2 is separated from the groove of the rail, and the difference between the axial width of the feed inlet 28 in the limiting rod 27 and the distance between the outer side surfaces of the two limit connecting plates 26 is greater than the length of the limiting rod 27 located outside the limit connecting plate 26.

An access window 29 is provided on a side wall of the main body 1, and facilitates cleaning of the inside of the main body 1 and maintenance of internal components.

Example 2:

the technical solution of the present embodiment is different from that of embodiment 1 in that: the partition 18 is made of a rubber material.

As shown in fig. 14, a plurality of clamping grooves 30 are uniformly arranged at intervals in the circumferential direction of the material shifting shaft 17, each clamping groove 30 is arranged along the axial direction of the material shifting shaft 17, the opening size of the clamping groove 17 is smaller than the internal size of the clamping groove 30, the size and shape of the connecting end of the rubber partition plate 18 and the material shifting shaft 17 are consistent with the internal shape and size of the clamping groove 30, and the partition plate 28 is inserted into the clamping groove 30.

Although the present invention has been described with reference to the preferred embodiments, it should be understood that various changes, substitutions and alterations can be made herein without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (14)

1. A non-fluid agent distributor characterized by: the material distributor comprises a main box body, wherein a feeding door is arranged at the top of the main box body, a buffer plate is arranged in the main box body below the feeding door, the buffer plate is fixed in the main box body in a V shape with a downward opening, through holes are arrayed on the buffer plate, and a distributor is arranged at an outlet at the bottom of the main box body; the top of the main box body is provided with a connecting piece connected with a crane, and the lower end of the main box body is provided with a supporting leg.

2. A non-fluid agent distributor as defined in claim 1 wherein: the bottom of the main box body is composed of inclined side plates, a rectangular outlet is formed in the middle of the main box body, the distributor is arranged at the outlet and comprises a distributing pipe and a shifting shaft, the shifting shaft is sleeved inside the distributing pipe, two ends of the shifting shaft are rotatably connected through bearings, the distributing pipe is horizontally fixed at the outlet at the bottom of the main box body, the distributing pipe is hermetically connected with the outlet, the upper end of the distributing pipe is positioned inside the main box body, the lower end of the distributing pipe is positioned outside the main box body, a feeding through hole is formed in the distributing pipe inside the main box body, a discharging through hole is formed in the distributing pipe outside the main box body, a power mechanism is arranged on the main box body and is in transmission connection with the shifting shaft, the shifting shaft comprises a shaft body and partition plates which are arranged on the shaft body at intervals, the partition plates are arranged along the axial direction, and the partition plates are arranged on the shaft body at even intervals, when the stirring shaft is positioned in the material distributing pipe, the outer end of the partition plate is contacted with the inner wall of the material distributing pipe.

3. A non-fluid agent distributor as defined in claim 2 wherein: a pressure distributing plate is arranged above a rectangular outlet at the bottom of the main box body, the pressure distributing plate is a V-shaped plate with a downward opening, the length direction of the pressure distributing plate is consistent with the axial direction of the material stirring shaft, and two ends of the pressure distributing plate are fixed on side plates at the bottom of the main box body at two ends of the material stirring shaft.

4. A non-fluid agent distributor as claimed in claim 2 or claim 3 wherein: the lower end of the main box body is fixedly connected with a passive scattering plate, two ends of the passive scattering plate are connected to the main box body, the passive scattering plate is located under the material stirring shaft, a gap exists between the passive scattering plate and the material stirring shaft, and the passive scattering plate is of a V-shaped structure with a downward opening.

5. A non-fluid agent distributor as defined in claim 4 wherein: a plurality of reinforcing plates are arranged at the bottom of the main box body below the pressure dividing plate at intervals, two ends of each reinforcing plate are fixed on the side plates of the main box body, and material passing holes are formed in the middle of each reinforcing plate.

6. A non-fluid agent distributor as claimed in claim 1 or claim 2 wherein: the connecting piece is davit and/or colludes the hanger plate, the davit is hollow tubular structure, and its both ends are fixed at the both ends of main tank body through the side connection board, collude the hanger plate quantity and be two at least, and it is linear arrangement and fixes at the top of main tank body, colludes and is provided with the grafting opening that inclines downwards on the hanger plate.

7. A non-fluid agent distributor as claimed in claim 1 or claim 2 wherein: one end of the top of the main box body is provided with a material input pipe, and the other end is provided with an exhaust pipe.

8. A non-fluid agent distributor as claimed in claim 1 or claim 2 wherein: a pedal is arranged on the side wall of the main box body close to one side of the feeding door.

9. A non-fluid agent distributor as claimed in claim 1 or claim 2 wherein: the feed inlet is arranged at the top of the main box body of the feed door, the main box bodies on two sides of the feed inlet are provided with mutually parallel slide rails, the opposite side surfaces on the slide rails are provided with slide grooves, two ends of the feed door are positioned inside the slide grooves, the feed door is connected with the slide rails in a sliding manner, the lower surface of the feed door is provided with two limiting connecting plates, a limiting rod is arranged between the limiting connecting plates, two ends of the limiting rod are positioned outside the two limiting connecting plates, and two ends of at least one limiting rod are positioned inside the main box body below the feed inlet.

10. A non-fluid agent distributor as defined in claim 9 wherein: one end of the sliding rail is located in the range corresponding to the feed inlet, when the feed door is pulled to the limit connecting plate to be in contact with the side wall of the feed inlet at the end, the feed door is separated from the groove of the track, and the difference between the axial width of the feed inlet at the limit rod and the distance between the outer side surfaces of the two limit connecting plates is larger than the length of the limit rod outside the limit connecting plates.

11. A non-fluid agent distributor as defined in claim 2 wherein: the baffle is made of rubber.

12. A non-fluid agent distributor as defined in claim 11 wherein: the material stirring shaft is characterized in that a plurality of clamping grooves are uniformly formed in the circumferential direction of the material stirring shaft at intervals, each clamping groove is arranged along the axial direction of the material stirring shaft, the opening size of each clamping groove is smaller than the internal size of each clamping groove, the size and the shape of the connecting end of the partition plate made of rubber and the material stirring shaft are consistent with the internal shape and the size of each clamping groove, and the partition plate is inserted into the clamping grooves.

13. A non-fluid agent distributor as defined in claim 1 wherein: an access window is arranged on the side wall of the main box body.

14. A non-fluid agent distributor as defined in claim 1 wherein: the supporting legs are arranged at four corners of the lower end of the main box body, connecting rods are arranged between adjacent supporting legs, and the connecting rods are used for strengthening the stability of the supporting legs.

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