CN111792067A - Granular slurry material filling machine - Google Patents

Abstract

The utility model provides a granule pulpiness material liquid filling machine, the conveying line who solves prior art existence is big to the flow resistance of granule pulpiness material, easily causes the jam of viscous material in the pipeline, is unfavorable for going on smoothly of material filling, influences the production progress, the poor problem of reliability. Including braced frame, its characterized in that: a stirring tank inlet is formed in the upper end of the material stirring tank on the upper portion of the supporting frame, a material stirring outlet is formed in the lower end of the material stirring tank, and a material stirring and conveying mechanism is arranged in a stirring cavity of the material stirring tank; a bearing platform is arranged on a supporting frame below the material stirring groove, a material conveying cylinder is arranged on the bearing platform, and a filling cylinder piston arranged in the material conveying cylinder is connected with a filling cylinder behind the material conveying cylinder through a filling cylinder telescopic rod. Its reasonable in design, compact structure can carry out continuous stirring and transport to granule pulpiness material, and material fluidity is good, and fluid resistance is little, can effectively prevent to glue thick granule pulpiness material to be detained and block up, and production efficiency is high.

Description

Granular slurry material filling machine

Technical Field

The invention belongs to the technical field of material filling equipment, and particularly relates to a particle slurry material filling machine which can continuously stir and convey particle slurry materials, has good material fluidity and small fluid resistance, can ensure the smoothness of a conveying pipeline, effectively prevents viscous particle slurry materials from being detained and blocked, has high production efficiency and strong use reliability.

Background

Because the phenomenon such as deposit, material concentration are inhomogeneous often appears in granule pulpiness material depositing and transportation process, so, at the filling in-process, can have the problem that granule pulpiness material deposits, is detained in the filling inslot layering, and then has reduced the mobility of granule pulpiness material, influences the normal transportation of granule pulpiness material. In addition, the conveying pipeline of the material filling equipment with the existing structure has large flow resistance to particle slurry materials, the conveying smoothness of the pipeline is poor, and the blockage of the thick particle slurry materials in the pipeline is easily caused in the long-time filling process. Simultaneously, fill remaining viscous material of discharge gate department, piling up too much the time, the condition of blockking up the discharge gate often can appear, is unfavorable for going on smoothly of material filling, seriously influences the production progress, and the use reliability of device is poor. There is a need for improvements in the prior art material filling apparatus.

Disclosure of Invention

The invention aims at the problems and provides the particle slurry material filling machine which can continuously stir and convey particle slurry materials, has good material fluidity and small fluid resistance, can ensure the smoothness of a conveying pipeline, effectively prevents viscous particle slurry materials from being detained and blocked, has high production efficiency and strong use reliability.

The technical scheme adopted by the invention is as follows: this granule pulpiness material liquid filling machine includes braced frame, its characterized in that: a material stirring tank is arranged at the upper part of the supporting frame, a stirring tank inlet is formed in the upper end of a stirring cavity of the material stirring tank, a material stirring outlet is formed in the lower end of the stirring cavity of the material stirring tank, and a material stirring and conveying mechanism is arranged in the stirring cavity of the material stirring tank; a bearing platform is arranged on the supporting frame below the material stirring tank, a material conveying cylinder is arranged on the bearing platform, a filling cylinder piston is arranged in the material conveying cylinder, and the filling cylinder piston is connected with a driving end of a filling cylinder arranged behind the material conveying cylinder through a filling cylinder telescopic rod; the upper part of the front end of the material conveying cylinder is connected with a material stirring outlet at the lower end of the material stirring tank, and the lower part of the front end of the material conveying cylinder is provided with a filling discharge hole.

The material stirring and conveying mechanism comprises a stirring rotating shaft horizontally arranged in the stirring cavity, and spiral conveying sheets continuously arranged along the axial direction of the rotating shaft are arranged on the stirring rotating shaft; and a plurality of groups of stirring blades are respectively arranged between two adjacent groups of spiral sheets of the spiral conveying sheet and on the stirring rotating shaft. The spiral conveying piece and the stirring blades arranged on the stirring rotating shaft are used for continuously stirring and conveying the materials in the stirring cavity of the material stirring tank.

The spiral conveying piece is composed of a spiral piece body which is spirally arranged on the outer side of the stirring rotating shaft, and the spiral piece body is connected with the stirring rotating shaft through a plurality of groups of supporting and connecting columns. In order to arrange at the epaxial spiral lamellar body of stirring through being the heliciform, come the propelling movement material to effectively prevent the delay of material in the material stirred tank stirring chamber material.

The stirring blade consists of a connecting rotating rod, the middle part of the connecting rotating rod is provided with an installation shaft hole, and two ends of the connecting rotating rod are respectively provided with a material stirring rotary vane; the connecting rotating rod is sleeved on the stirring rotating shaft through a mounting shaft hole. In order to utilize the setting between the adjacent two sets of flight of auger delivery piece, stir epaxial stirring vane, carry out continuous stirring to the material of material stirred tank stirring intracavity, and then avoid the layering of material to deposit, increase the mobility of material.

The front end of the material conveying cylinder is provided with a material conveying reversing valve, the material conveying reversing valve is composed of a reversing valve main body, the upper side of the reversing valve main body is provided with a stirring tank connecting port used for being connected with a material stirring outlet at the lower end of a material stirring tank, the rear side of the reversing valve main body is provided with a material cylinder connecting port used for being connected with the front end of the material conveying cylinder, and the lower side of the reversing valve main body is provided with a material conveying connecting port used for being connected with a filling discharge port; and a rotary valve core is also arranged in the reversing valve main body. The conveying path of materials in the material conveying reversing valve is changed by rotating the valve core, so that the materials in the material stirring groove enter the material conveying cylinder, pressurization filling is carried out by pushing of the filling cylinder, and retention and blockage of viscous materials are effectively prevented.

The rotary valve core is of a cylindrical structure, and an arc-shaped reversing groove for communicating two adjacent connecting ports on the material conveying reversing valve is formed in the cylindrical surface of the rotary valve core; and the rotating valve core is connected with the driving end of the swing cylinder through a valve core rotating shaft arranged at the side end. The arc-shaped reversing groove on the cylindrical surface of the rotary valve core is utilized to reduce the fluid resistance and further avoid the blockage of materials.

And a conical connecting pipe with a large rear port diameter and a small front port diameter is arranged between the material cylinder connecting port of the material conveying reversing valve and the front end of the material conveying cylinder. The conical connecting pipe arranged between the material conveying cylinder and the material conveying reversing valve effectively reduces the flow resistance of materials and ensures the smoothness of a conveying pipeline.

And a material conveying bent pipe is arranged between the material conveying connector of the material conveying reversing valve and the filling discharge port. The material conveying elbow pipe is arranged between the material conveying reversing valve and the filling discharge port, so that the flow resistance of materials is effectively reduced, and the smoothness of a conveying pipeline is ensured.

The upper portion of filling discharge gate is provided with vertical arrangement's ejection of compact cylinder, and the lower extreme of ejection of compact cylinder telescopic link of ejection of compact cylinder is provided with ejection of compact jar piston, ejection of compact jar piston activity inserts in the ejection of compact piston sleeve that is linked together with the supplementary filling mouth of filling discharge gate upper end, and the upper end of ejection of compact piston sleeve links to each other with the lower extreme of ejection of compact cylinder through the cylinder adapter sleeve. With the ejection of compact jar piston of the ejection of compact jar telescopic link lower extreme that utilizes ejection of compact cylinder, carry out supplementary propelling movement clearance to filling remaining material in the discharge gate, and then avoid remaining the material to pile up the jam after too much.

The invention has the beneficial effects that: according to the invention, the supporting frame with the material stirring tank arranged at the upper part is adopted, the stirring tank inlet is arranged at the upper end of the material stirring tank, the material stirring outlet is arranged at the lower end of the material stirring tank, and the material stirring and conveying mechanism is arranged in the stirring cavity of the material stirring tank; a bearing platform is arranged on the supporting frame below the material stirring groove, a material conveying cylinder is arranged on the bearing platform, a filling cylinder piston is arranged in the material conveying cylinder, and the filling cylinder piston is connected with a driving end of a filling cylinder behind the material conveying cylinder through a filling cylinder telescopic rod; the upper portion of conveying cylinder front end links to each other with the material stirring export of material stirred tank lower extreme, the lower part of conveying cylinder front end sets up the structural style of filling discharge gate, so its reasonable in design, compact structure, and occupation space is reasonable, can stir in succession and carry the material, the mobility of material is good, fluid resistance is little, guarantee pipeline's noncongestion, effectively prevent viscous material's delay and jam, and can ensure the homogeneity of material, high production efficiency, filling product quality is good, the use reliability of device is strong.

Drawings

FIG. 1 is a schematic diagram of an embodiment of the present invention.

Fig. 2 is a view in the direction a of fig. 1.

Fig. 3 is a view from direction B of fig. 2.

Fig. 4 is a schematic structural diagram of the material stirring and conveying mechanism in fig. 2.

Fig. 5 is a schematic view of a structure of the spiral conveying sheet of fig. 4.

Fig. 6 is a schematic view of a structure of the agitating blade of fig. 4.

Fig. 7 is a schematic view showing a structure of the feeding direction changing valve of fig. 1.

Fig. 8 is a schematic diagram of the exploded structure of fig. 7.

Fig. 9 is a sectional view showing a state in which the material in the material agitating tank of the present invention is introduced into the feed cylinder.

Fig. 10 is a sectional view showing a state of use in which the material in the feed delivery cylinder is discharged through the feed delivery elbow and the discharge fill port after the feed delivery changeover valve of fig. 9 is rotated counterclockwise.

The sequence numbers in the figures illustrate: 1 supporting frame, 2 material stirring grooves, 3 stirring groove inlets, 4 material stirring and conveying mechanisms, 5 material stirring outlets, 6 bearing tables, 7 material conveying cylinders, 8 filling cylinders, 9 material conveying reversing valves, 10 material conveying bent pipes, 11 filling discharge holes, 12 material discharging cylinders, 13 stirring driving motors, 14 speed reducers, 15 electric cabinets, 16 air source interfaces, 17 foot switches, 18 stirring cavities, 19 stirring rotating shafts, 20 spiral conveying sheets, 21 stirring blades, 22 spiral sheet bodies, 23 supporting connecting columns, 24 connecting rotating rods, 25 mounting shaft holes, 26 material stirring rotating sheets, 27 reversing valve bodies, 28 stirring groove connectors, 29 material barrel connectors, 30 conical connecting pipes, 31 material conveying connectors, 32 swinging cylinders, 33 air cylinder connecting sleeves, 34 material discharging piston sleeves, 35 auxiliary filling ports, 36 connecting clamp hoops, 37 valve cavities, 38 rotating valve cores, 39 arc-shaped reversing grooves, 40 valve core rotating shafts, 40 valve core connecting shafts, 30 conical connecting pipes, 31 material conveying connectors, 32 swinging air cylinders, 33 air cylinder connecting sleeves, 34, 41 discharge cylinder telescopic rods, 42 discharge cylinder pistons, 43 filling cylinder telescopic rods and 44 filling cylinder pistons.

Detailed Description

The specific structure of the present invention will be described in detail with reference to FIGS. 1 to 10. The particle slurry material filling machine comprises a supporting frame 1, wherein a material stirring tank 2 is arranged on the upper portion of the supporting frame 1, a stirring tank inlet 3 is arranged at the upper end of a stirring cavity 18 of the material stirring tank 2, and a stirring tank upper cover is arranged at the stirring tank inlet 3. The lower end of the stirring cavity 18 of the material stirring tank 2 is provided with a material stirring outlet 5; and, the lower extreme lateral part of the stirring chamber 18 of material stirred tank 2 is provided with the washing discharge valve that is convenient for when wasing material stirred tank 2, evacuation stirring chamber 18 material. Inside the stirring chamber 18 of the material stirring tank 2, a material stirring and conveying mechanism 4 is further arranged.

The material stirring and conveying mechanism 4 comprises a stirring rotating shaft 19 which is horizontally arranged inside the stirring cavity 18, the stirring rotating shaft 19 extends out of a driving end outside the stirring cavity 18, the output end of the stirring driving motor 13 is connected with the speed reducer 14 arranged on the supporting frame 1, and the electric cabinet 15 is also arranged on the supporting frame 1. The stirring rotating shaft 19 of the material stirring and conveying mechanism 4 is provided with a spiral conveying sheet 20 which is continuously arranged along the axial direction of the rotating shaft. The spiral conveying sheet 20 is composed of a spiral sheet body 22 spirally arranged on the outer side of the stirring rotating shaft 19, and the spiral sheet body 22 is connected with the stirring rotating shaft 19 through a plurality of groups of supporting and connecting columns 23; and then through being the spiral lamellar body 22 of heliciform arrangement on stirring pivot 19, come propelling movement granule pulpiness material to effectively prevent the delay of granule pulpiness material in material agitator tank 2 stirring chamber 18.

A plurality of groups of stirring blades 21 are respectively arranged between two adjacent groups of spiral blades on the spiral blade body 22 of the spiral conveying blade 20 of the material stirring and conveying mechanism 4 and on the stirring rotating shaft 19. Each group of stirring blades 21 consists of a connecting rotating rod 24, the middle part of the connecting rotating rod 24 is provided with an installation shaft hole 25, and two ends of the connecting rotating rod 24 are respectively provided with a material stirring rotary vane 26; the connecting rotating rod 24 is sleeved on the stirring rotating shaft 19 through the mounting shaft hole 25; in order to utilize setting up between two sets of adjacent flights of auger delivery piece 20, stirring rotating shaft 19 on stirring vane 21, carry out continuous stirring to the granule pulpiness material in material stirring groove 2 stirring chamber 18, and then avoid the layering of granule pulpiness material to deposit, increase the mobility of granule pulpiness material. Thus, the granular slurry material in the stirring chamber 18 of the material stirring tank 2 is continuously stirred and conveyed by the screw conveyor 20 and the stirring blade 21 provided on the stirring shaft 19.

A bearing platform 6 is arranged below the material stirring outlet 5 of the material stirring tank 2, and the bearing platform 6 is connected with the supporting frame 1. A horizontally arranged material conveying cylinder 7 is arranged on the bearing platform 6, and the material conveying cylinder 7 is fixed on the bearing platform 6 through a material cylinder mounting seat plate; a filling cylinder piston 44 is arranged in the cylinder cavity of the material conveying cylinder 7. The filling cylinder piston 44 is connected with the driving end of the filling cylinder 8 arranged behind the material conveying cylinder 7 through a filling cylinder telescopic rod 43. The rear end of the bearing table 6 is provided with an air source interface 16 for connecting with a compressed air conveying pipeline. Meanwhile, a cylinder stroke control magnetic switch for limiting the reciprocating position of the filling cylinder piston 44 is also arranged on the cylinder body of the filling cylinder 8. A foot switch 17 is provided under the platform 6 and outside the support frame 1 for the operator to pedal.

The discharging end of the front part of the material conveying cylinder 7 is provided with a material conveying reversing valve 9 for changing the material conveying path. The material conveying reversing valve 9 is composed of a reversing valve main body 27, and a stirring tank connecting port 28 used for being connected with a material stirring outlet 5 at the lower end of the material stirring tank 2 is arranged on the upper side of the reversing valve main body 27; a material barrel connecting port 29 used for being connected with the front end of the material conveying barrel 7 is arranged at the rear side of the reversing valve main body 27; a material delivery connecting port 31 for connecting with the filling and discharging port 11 is provided on the lower side of the direction valve main body 27. Meanwhile, a rotary valve core 38 is further arranged inside a valve cavity 37 of the reversing valve main body 27 of the material conveying reversing valve 9, so that a conveying path of the granular slurry materials in the material conveying reversing valve 9 is changed through the rotary valve core 38, the granular slurry materials in the material stirring tank 2 enter the material conveying cylinder 7, pressurization filling is carried out by pushing of the filling cylinder 8, and retention and blockage of thick granular slurry materials are effectively prevented.

The rotary valve core 38 in the reversing valve main body 27 of the material conveying reversing valve 9 is of a cylindrical structure, and an arc-shaped reversing groove 39 for communicating two adjacent connecting ports on the material conveying reversing valve 9 is formed in the cylindrical surface of the rotary valve core 38. The rotary valve core 38 is connected with the driving end of the swing cylinder 32 which swings reciprocally by 90 degrees through a valve core rotating shaft 40 arranged at the side end; so that the arc-shaped reversing groove 39 on the cylindrical surface of the rotary valve core 38 is utilized to reduce the fluid resistance and further avoid the blockage of the particle slurry material. And, both sides end of the change-over valve body 27 is provided with the rolling bearing and bearing gland respectively, the bearing gland passes through the removable type setting in the side of the change-over valve body 27 of bayonet clamp plate and area slot installation pole, and then makes things convenient for maintenance and washing of defeated material change-over valve 9.

In order to effectively reduce the flow resistance of particle slurry materials and ensure the smoothness of a conveying pipeline, a conical connecting pipe 30 with a large rear port diameter and a small front port diameter is arranged between a material cylinder connecting port 29 of a material conveying reversing valve 9 and the front end of a material conveying cylinder 7; a material conveying bent pipe 10 is arranged between the material conveying connecting port 31 of the material conveying reversing valve 9 and the filling discharge port 11. Meanwhile, the filling and discharging port 11 adopts a three-channel structural form, a vertically arranged discharging cylinder 12 is arranged above the filling and discharging port 11, a discharging cylinder piston 42 is arranged at the lower end of a discharging cylinder telescopic rod 41 of the discharging cylinder 12, and the discharging cylinder piston 42 is movably inserted into a discharging piston sleeve 34 communicated with an auxiliary filling port 35 at the upper end of the filling and discharging port 11; the upper end of the discharging piston sleeve 34 is connected with the lower end of the discharging air cylinder 12 through an air cylinder connecting sleeve 33; and then utilize ejection of compact jar piston 42 of ejection of compact jar telescopic link 41 lower extreme of ejection of compact cylinder 12, carry out supplementary propelling movement clearance to remaining granule pulpiness material after filling in filling discharge gate 11 to avoid remaining granule pulpiness material to pile up the jam after too much. It can be understood that, according to specific use requirements, the stirring tank connecting port 28, the material barrel connecting port 29 and the material conveying connecting port 31 of the material conveying reversing valve 9 are detachably connected with the material stirring outlet 5, the front end of the material conveying barrel 7 and the filling discharge port 11, and the material discharge piston sleeve 34 and the air cylinder connecting sleeve 33 through connecting clamps 36 with flange butt clamps respectively, so as to facilitate maintenance of each material conveying pipeline.

When the granular slurry material filling machine is used, firstly, granular slurry materials to be filled are injected through a stirring tank inlet 3 at the upper end of a material stirring tank 2; then, the stirring drive motor 13 is turned on, and the stirring shaft 19 of the material stirring and conveying mechanism 4 in the stirring chamber 18 of the material stirring tank 2 is driven to rotate by the speed reducer 14. Therefore, the rotation of the spiral sheet body 22 spirally arranged on the stirring rotating shaft 19 is utilized to continuously push the granular slurry-like material, so that the granular slurry-like material in the material stirring tank 2 is effectively prevented from being detained; meanwhile, the particle slurry material in the material stirring tank 2 is continuously stirred by the stirring blade 21 arranged between two adjacent groups of spiral sheets of the spiral conveying sheet 20, so that the layered precipitation of the particle slurry material is avoided, and the fluidity of the particle slurry material is increased.

The material stirring and conveying mechanism 4 in the material stirring tank 2 conveys the uniformly stirred particle slurry material to the material stirring outlet 5 at the lower end of the stirring cavity 18 of the material stirring tank 2, and the arc-shaped reversing groove 39 on the rotary valve core 38 of the material conveying reversing valve 9 is in a position (as shown in fig. 9) which is communicated with the material stirring outlet 5 and the discharge end at the front part of the material conveying cylinder 7 by default. Then, the filling cylinder telescopic rod 43 of the filling cylinder 8 drives the filling cylinder piston 44 to retract backwards, and further, the granular slurry materials at the material stirring outlet 5 are sucked into the cylinder cavity of the material conveying cylinder 7 in a centralized manner. Then, the swing cylinder 32 is used to drive the rotary valve core 38 of the material conveying reversing valve 9 to rotate 90 degrees, namely: rotating the arc-shaped reversing groove 39 on the valve core 38 to communicate the discharge end at the front part of the feed delivery cylinder 7 with the filling discharge hole 11 (as shown in fig. 10); then, the telescopic rod 43 of the filling cylinder and the piston 44 of the filling cylinder at the front end thereof extend out, so that the pumped granular slurry-like material is intensively pressurized and filled and pushed to the filling discharge hole 11 through the delivery elbow 10 by using the filling cylinder 8, and the stagnation and the blockage of the viscous granular slurry-like material are effectively prevented.

After the pushing of the particle slurry material inside the material conveying cylinder 7 is finished, the telescopic rod 41 of the discharging cylinder 12 is extended out, and the discharging cylinder piston 42 at the lower end is utilized to carry out auxiliary pushing and cleaning on the residual particle slurry material after being filled in the filling and discharging port 11, so that the blockage caused by the excessive accumulation of the residual particle slurry material is avoided. Then, the swing cylinder 32 drives the rotary valve core 38 of the material conveying reversing valve 9 to rotate reversely by 90 degrees, so as to prepare for the next operation cycle of intensively sucking the granular slurry-like material at the material stirring outlet 5 by the material conveying cylinder 7 and performing pressurization filling. This granule pulpiness material liquid filling machine can carry out continuous stirring and transport to granule pulpiness material, and the mobility of granule pulpiness material is good, and fluid resistance is little, guarantees pipeline's noncongestion, can effectively prevent to glue the delay and the jam of thick granule pulpiness material.

Claims (9)

1. A granule pulpiness material liquid filling machine, includes braced frame (1), its characterized in that: a material stirring tank (2) is arranged at the upper part of the supporting frame (1), a stirring tank inlet (3) is arranged at the upper end of a stirring cavity (18) of the material stirring tank (2), a material stirring outlet (5) is arranged at the lower end of the stirring cavity (18) of the material stirring tank (2), and a material stirring and conveying mechanism (4) is arranged in the stirring cavity (18) of the material stirring tank (2); on braced frame (1) of material agitator tank (2) below, be provided with plummer (6), be provided with on plummer (6) defeated feed cylinder (7), be provided with filling cylinder piston (44) in defeated feed cylinder (7), filling cylinder piston (44) pass through filling cylinder telescopic link (43), link to each other with the drive end of filling cylinder (8) that defeated feed cylinder (7) rear set up.

2. The particulate slurry material filling machine of claim 1, wherein: the material stirring and conveying mechanism (4) comprises a stirring rotating shaft (19) horizontally arranged in the stirring cavity (18), and spiral conveying sheets (20) continuously arranged along the axial direction of the rotating shaft are arranged on the stirring rotating shaft (19); and a plurality of groups of stirring blades (21) are respectively arranged between two adjacent groups of spiral sheets of the spiral conveying sheet (20) and on the stirring rotating shaft (19).

3. The particulate slurry material filling machine of claim 2, wherein: the spiral conveying sheet (20) is composed of spiral sheet bodies (22) which are spirally arranged on the outer side of the stirring rotating shaft (19), and the spiral sheet bodies (22) are connected with the stirring rotating shaft (19) through a plurality of groups of supporting connecting columns (23).

4. The particulate slurry material filling machine of claim 2, wherein: the stirring blade (21) is composed of a connecting rotating rod (24), the middle part of the connecting rotating rod (24) is provided with an installation shaft hole (25), and two ends of the connecting rotating rod (24) are respectively provided with a material stirring rotary vane (26); the connecting rotating rod (24) is sleeved on the stirring rotating shaft (19) through an installation shaft hole (25).

5. The particulate slurry material filling machine of claim 1, wherein: the front end of the material conveying cylinder (7) is provided with a material conveying reversing valve (9), the material conveying reversing valve (9) is composed of a reversing valve main body (27), the upper side of the reversing valve main body (27) is provided with a stirring tank connecting port (28) used for being connected with a material stirring outlet (5) at the lower end of a material stirring tank (2), the rear side of the reversing valve main body (27) is provided with a material cylinder connecting port (29) used for being connected with the front end of the material conveying cylinder (7), and the lower side of the reversing valve main body (27) is provided with a material conveying connecting port (31) used for being connected with a filling discharge port (11); the reversing valve main body (27) is also internally provided with a rotary valve core (38).

6. The particulate slurry material filling machine of claim 5, wherein: the rotary valve core (38) is of a cylindrical structure, and an arc-shaped reversing groove (39) for communicating two adjacent connecting ports on the material conveying reversing valve (9) is formed in the cylindrical surface of the rotary valve core (38); and the rotating valve core (38) is connected with the driving end of the swing cylinder (32) through a valve core rotating shaft (40) arranged at the side end.

7. The particulate slurry material filling machine of claim 5, wherein: and a conical connecting pipe (30) with a large rear port diameter and a small front port diameter is arranged between a material cylinder connecting port (29) of the material conveying reversing valve (9) and the front end of the material conveying cylinder (7).

8. The particulate slurry material filling machine of claim 5, wherein: and a material conveying bent pipe (10) is arranged between the material conveying connecting port (31) of the material conveying reversing valve (9) and the filling discharge port (11).

9. The particulate slurry material filling machine of claim 1, wherein: the upper portion of filling discharge gate (11) is provided with vertical arrangement's ejection of compact cylinder (12), and the lower extreme of ejection of compact cylinder telescopic link (41) of ejection of compact cylinder (12) is provided with ejection of compact cylinder piston (42), ejection of compact cylinder piston (42) activity is inserted in ejection of compact piston bush (34) that are linked together with supplementary filling mouth (35) of filling discharge gate (11) upper end, and the upper end of ejection of compact piston bush (34) is passed through cylinder adapter sleeve (33) and is linked to each other with the lower extreme of ejection of compact cylinder (12).

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