CN110576510A - Production line for sintering shale microporous bricks by using plant fibers - Google Patents

Abstract

the invention discloses a production line of plant fiber sintered shale microporous bricks, which comprises a storage tank, wherein a connecting and fixing frame is fixedly arranged on the storage tank, a crushing and stirring machine is fixedly arranged at the upper end of the connecting and fixing frame, a charging opening is fixedly arranged at the upper end of the crushing and stirring machine, a discharging opening is fixedly arranged at the lower end of the crushing and stirring machine, a fixed mounting bracket is fixedly arranged at one end of the storage tank, a feeding conveyer belt is movably arranged on the fixed mounting bracket, a driving motor is movably arranged at the outer side of the feeding conveyer belt, a receiving bin is movably arranged at one end of the feeding conveyer belt, a material conveying conveyer belt is fixedly arranged at the lower end of the receiving bin, and a fixing rack is fixedly arranged at. This plant fiber sintered shale micropore brick production line has increased and has carried out comminuted reducing mechanism, can directly carry out kibbling work to the material, lets whole work can be more quick go on, saves the preparation work before processing simultaneously.

Description

Production line for sintering shale microporous bricks by using plant fibers

Technical Field

The invention relates to the technical field of production of sintered shale bricks, in particular to a production line of plant fiber sintered shale microporous bricks.

background

The shale brick is used as a novel building energy-saving material, can be used for building a bearing wall, has good thermal property, accords with the construction building modulus, reduces the loss in the construction process, improves the working efficiency, has the hole rate of more than thirty-five percent, can reduce the dead weight of the wall body, saves the basic engineering cost, has the characteristics of heat preservation, heat insulation, light weight, high strength, high construction efficiency and the like compared with the common sintered porous brick, has the greatest advantage that the shale brick is completely the same as the traditional clay brick construction method, does not need to be added with any special construction facilities and special tools, is the best substitute of the traditional clay solid brick, fully utilizes waste resources to be paid more and more attention by people, adds straw powder with a certain proportion and certain fineness as a pore-forming agent in the shale sintered brick, is not only favorable for reducing the consumption of various traditional energy sources, but also has good thermal property, can also solve the problems of incineration pollution and recycling of straw and other biological resource wastes.

however, the plant fiber sintered shale microporous brick production line in the existing market generally adopts manual work for feeding, and carries out the work of machine-shaping through the corresponding device, and the work of feeding is carried out by the manual work, a large amount of workers need to be added for cooperation to work, meanwhile, when the preparation of materials in advance is carried out, a large amount of manual work is also needed for work, the time of the whole work is prolonged, the speed of the work is slowed down, the efficiency of the whole work is reduced, meanwhile, after the processing is completed, the work of cutting off the formed brick strips needs to be carried out, but the work of transferring is carried out by the manual work after the cutting off, the workload of the workers is increased, the labor intensity of the operators is increased, and the operation cost in the production process is increased to a certain extent.

disclosure of Invention

The invention aims to provide a production line of plant fiber sintered shale microporous bricks, which aims to solve the problems that the production line of the plant fiber sintered shale microporous bricks on the existing market generally adopts manual feeding work and carries out processing and forming work through corresponding devices, the manual feeding work is used, a large amount of workers are required to be added for work, meanwhile, when the preparation of materials in advance is carried out, a large amount of manual work is also required, the whole work time is prolonged, the work speed is slowed, the efficiency of the whole work is reduced, meanwhile, after the processing is finished, the formed brick strips are required to be cut off, but the manual transferring work is required after the cutting, the workload of the workers is increased, and the labor intensity of the operators is increased, the problem of operation cost in production is increased to a certain extent.

in order to achieve the purpose, the invention provides the following technical scheme: plant fiber sintered shale micropore brick production line, including the storage tank, fixed mounting has the connection mount on the storage tank, the upper end fixed mounting who connects the mount has crushing-stirring machine, crushing-stirring machine's upper end fixed mounting has the charge door, crushing-stirring machine's lower extreme fixed mounting has the discharge gate, the one end fixed mounting of storage tank has the fixed mounting support, movable mounting has the material loading conveyer belt on the fixed mounting support, the outside movable mounting of material loading conveyer belt has driving motor, the one end movable mounting of material loading conveyer belt connects the feed bin, the lower extreme fixed mounting who connects the feed bin passes the material conveyer belt, the lower extreme fixed mounting who passes the material conveyer belt has fixed frame, the lower extreme movable mounting of fixed frame has adjustable stabilizer blade. A driving rotating shaft is movably mounted on the material conveying belt, a connecting conveying belt is movably mounted at one end of the material conveying belt, a mounting rack is movably mounted at the lower end of the connecting conveying belt, a material guide plate is fixedly mounted at one end of the connecting conveying belt, a material storage bin is movably mounted at the lower end of the material guide plate, a feeding rack is fixedly mounted at the lower end of the material storage bin, a fixed base is fixedly mounted at the lower end of the feeding rack, a feeding motor is fixedly mounted on the feeding rack, a connecting material pipe is fixedly mounted at one end of the feeding rack, a feeding bin is fixedly mounted at the lower end of the connecting material pipe, a fixed support is fixedly mounted at the lower end of the feeding bin, an extrusion head is fixedly mounted at one end of the fixed support, a forming head is movably mounted at one end of the extrusion head, and a discharging support, the utility model discloses a material pushing and pushing device, including ejection of compact support, cutting cylinder, connecting plate, cutting knife, scraping plate, material pushing cylinder, material pushing connecting rod, material pushing cylinder.

Preferably, the storage tank is designed to be of a rectangular structure, and the size of the storage tank is larger than that of the crushing and stirring machine.

Preferably, the feeding conveyer belt is the structural design of slope, and the equidistant eight at least groups of material loading baffles that are provided with of feeding conveyer belt.

preferably, the fixed frame is designed to be an H-shaped structure, and three groups of adjustable support legs are symmetrically arranged at the lower end of the fixed frame.

Preferably, the connecting conveyer belt is designed to be of a trapezoidal structure, and two adjustable support legs are symmetrically arranged at the lower end of the connecting conveyer belt.

Preferably, the stirring shaft can be installed in the feeding rack in a dry mode, the length of the stirring shaft is matched with that of the feeding rack, and the stirring blade with a spiral structure is fixedly installed on the stirring shaft.

Preferably, the fixed support is fixedly provided with a control box, the control box is movably provided with a power switch, an adjusting knob and a function key, and the lower end of the control box is fixedly provided with a supporting seat.

Preferably, the last fixed mounting of fixed bolster has the headstock, and fixed mounting has the motor case on the headstock to movable mounting has output gear in the headstock, the meshing is connected with drive gear on the output gear, drive gear's upper end meshing is connected with drive gear, fixed mounting has the connecting axle on the drive gear.

Preferably, the size of the extrusion head on the fixed bracket is larger than or equal to that of the molding head, and the interior of the molding head is designed to be a rectangular structure.

Compared with the prior art, the invention has the beneficial effects that:

According to the plant fiber sintered shale microporous brick production line, a crushing device capable of crushing materials is additionally arranged, the materials can be directly crushed, the whole work can be carried out more quickly, and meanwhile, the preparation work before processing is saved;

According to the plant fiber sintered shale microporous brick production line, a spiral lifting device capable of carrying out secondary stirring and crushing is additionally arranged, so that the conveying work of materials is carried out, and meanwhile, the caking of the materials during the whole work is prevented when the materials are transported, so that the continuity of the work is better;

this plant fiber sintered shale micropore brick production line has increased the cutter that can carry out the stripping plate that the stripping and slicing and carry out the material and remove, can be with the work of directly cutting through the material strip of vacuum extruder processing on conveyor, the integrality of assurance material that can be better, conveniently carry out the removal work of product simultaneously, let subsequent sintering work can be more convenient go on, improve the speed of work and the efficiency of work, reduce artificial input, help reduce the cost.

Drawings

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

FIG. 2 is a schematic view of the internal structure of the spiral feeding device of the present invention;

FIG. 3 is a schematic view of the structure of the vacuum extruder of the present invention;

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

FIG. 5 is a schematic view of a driving structure according to the present invention;

Fig. 6 is a schematic structural diagram of the material pushing plate of the present invention.

In the figure: 1. a material storage tank; 2. connecting the fixed frame; 3. a crushing and stirring machine; 4. a feed inlet; 5. a discharge port; 6. a feeding conveyer belt; 7. fixing the mounting bracket; 8. a drive motor; 9. a material receiving bin; 10. a material conveying conveyer belt; 11. fixing the frame; 12. an adjustable support leg; 13. driving the rotating shaft; 14. connecting the conveyer belt; 15. installing a frame; 16. a material guide plate; 17. a storage bin; 18. a feeding motor; 19. a feeding rack; 191. a stirring shaft; 192. a stirring blade; 20. a fixed base; 21. connecting the material pipe; 22. fixing a bracket; 221. a control box; 222. a power switch; 223. adjusting a knob; 224. function keys; 225. a power box; 226. a supporting seat; 227. a motor case; 228. an output gear; 229. a transmission gear; 23. a feeding bin; 231. a connecting shaft; 232. a drive gear; 24. an extrusion head; 25. a forming head; 26. a discharging support; 27. a discharge conveyer belt; 28. cutting the stent; 29. cutting the air cylinder; 30. connecting the fixed plate; 31. a cutting knife; 32. a material pushing plate; 33. a material pushing cylinder; 34. a material pushing connecting rod; 35. installing a positioning plate; 36. a material push plate.

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.

Referring to fig. 1-6, the present invention provides a technical solution: plant fiber sintered shale microbore brick production line, including storage tank 1, fixed mounting has connection mount 2 on the storage tank 1, the upper end fixed mounting who connects mount 2 has crushing-stirring machine 3, the upper end fixed mounting of crushing-stirring machine 3 has charge door 4, the lower extreme fixed mounting of crushing-stirring machine 3 has discharge gate 5, the one end fixed mounting of storage tank 1 has fixed mounting support 7, movable mounting has material loading conveyer belt 6 on the fixed mounting support 7, the outside movable mounting of material loading conveyer belt 6 has driving motor 8, the one end movable mounting of material loading conveyer belt 6 connects feed bin 9, the lower extreme fixed mounting who connects feed bin 9 has material conveying conveyer belt 10, the lower extreme fixed mounting who passes material conveyer belt 10 has fixed frame 11, the lower extreme movable mounting of fixed frame 11 has adjustable stabilizer blade 12. A driving rotating shaft 13 is movably mounted on the material conveying belt 10, a connecting conveying belt 14 is movably mounted at one end of the material conveying belt 10, a mounting rack 15 is movably mounted at the lower end of the connecting conveying belt 14, a material guide plate 16 is fixedly mounted at one end of the connecting conveying belt 14, a material storage bin 17 is movably mounted at the lower end of the material guide plate 16, a feeding rack 19 is fixedly mounted at the lower end of the material storage bin 17, a fixed base 20 is fixedly mounted at the lower end of the feeding rack 19, a feeding motor 18 is fixedly mounted on the feeding rack 19, a connecting material pipe 21 is fixedly mounted at one end of the feeding rack 19, a feeding bin 23 is fixedly mounted at the lower end of the connecting material pipe 21, a fixed support 22 is fixedly mounted at the lower end of the feeding bin 23, an extrusion head 24 is fixedly mounted at one end of the fixed support 22, a forming head 25 is movably mounted at one, the upper end of the discharging support 26 is movably provided with a discharging conveyer belt 27, the upper end of the discharging support 26 is fixedly provided with a cutting support 28, the upper end of the cutting support 28 is fixedly provided with a cutting cylinder 29, the lower end of the cutting cylinder 29 is fixedly provided with a connecting fixing plate 30, the lower end of the connecting fixing plate 30 is fixedly provided with a cutting knife 31, one end of the discharging support 26 is fixedly provided with a pushing plate 32, the pushing plate 32 is movably provided with a pushing cylinder 33, the pushing cylinder 33 is fixedly provided with a pushing connecting rod 34, one end of the pushing connecting rod 34 far away from the pushing cylinder 33 is fixedly provided with an installation positioning plate 35, and the installation positioning plate 35 is;

Further, the material storage tank 1 is designed to be of a rectangular structure, and the size of the material storage tank 1 is larger than that of the crushing stirrer 3, so that the material storage tank can be used better;

furthermore, the feeding conveyor belt 6 is designed to be an inclined structure, and at least eight groups of feeding baffles are arranged on the feeding conveyor belt 6 at equal intervals, so that feeding work is facilitated;

Furthermore, the fixed frame 11 is designed to be in an H-shaped structure, and three groups of adjustable support legs 12 are symmetrically arranged at the lower end of the fixed frame 11, so that the stability of the whole device is improved;

Furthermore, the connecting conveyer belt 14 is designed to be a trapezoid structure, and the two adjustable support legs 12 are symmetrically arranged at the lower end of the connecting conveyer belt 14, so that the equipment can be conveniently adjusted;

furthermore, a stirring shaft 191 can be movably arranged in the feeding frame 19, the length of the stirring shaft 191 is matched with that of the feeding frame 19, and a spiral stirring blade 192 is fixedly arranged on the stirring shaft 191, so that secondary stirring work can be performed;

further, a control box 221 is fixedly installed on the fixed bracket 22, a power switch 222, an adjusting knob 223 and a function key 224 are movably installed on the control box 221, and a support seat 226 is fixedly installed at the lower end of the control box 221, so that the control work is facilitated;

further, a power box 225 is fixedly mounted on the fixed support 22, a motor box 227 is fixedly mounted on the power box 225, an output gear 228 is movably mounted in the power box 225, a transmission gear 229 is connected to the output gear 228 in a meshing manner, a driving gear 232 is connected to the upper end of the transmission gear 229 in a meshing manner, and a connecting shaft 231 is fixedly mounted on the driving gear 232, so that the power box can work better;

furthermore, the size of the extrusion head 24 on the fixing bracket 22 is larger than or equal to that of the forming head 25, and the inside of the forming head 25 is designed to be a rectangular structure, so that the effect of one-step forming is improved.

the working principle is as follows: after the whole device is fixedly installed, the corresponding power supply and air source are switched on, the production work is started, the materials which are mixed in proportion are added into the charging opening 4, the crushing and stirring machine 3 carries out the processing work again, the processed products enter the storage tank 1 through the discharging opening 5, the feeding work is carried out through the feeding conveyer belt 6 on the storage tank 1, the materials are conveyed into the material receiving bin 9 through the feeding conveyer belt 6 under the drive of the driving motor 8 and are conveyed onto the material conveying conveyer belt 10 through the material receiving bin 9, then the materials on the material conveying conveyer belt 10 enter the material storage bin 17 through the connecting conveyer belt 14, the stirring shaft 191 and the stirring blades 192 are driven through the feeding motor 18 on the feeding frame 19, the materials are stirred again and enter the charging bin 23 through the connecting pipe 21, under the operation of the output gear 228 in the motor box 227, the transmission gear 229 meshed with the output gear is rotated to drive the driving gear 232 to rotate, the connecting shaft 231 is rotated to enable the materials to enter the extruder, the materials are pushed out through the extrusion head 24, the forming operation is performed through the matching of the forming head 25, then under the driving of the discharging conveying belt 27, the cutting knife 31 driven by the cutting cylinder 29 cuts off the materials, the material pushing plate 36 driven by the material pushing cylinder 33 on the material pushing plate 32 performs the discharging operation, the above operation steps are repeated to perform continuous processing production operation, and after the processing is completed, the power supply of the equipment is turned off, and the operation is completed.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. Plant fiber sintering shale micropore brick production line, including storage tank (1), its characterized in that: a connecting fixing frame (2) is fixedly arranged on the storage tank (1), a crushing and stirring machine (3) is fixedly arranged at the upper end of the connecting fixing frame (2), the upper end of the crushing and stirring machine (3) is fixedly provided with a charging hole (4), the lower end of the crushing and stirring machine (3) is fixedly provided with a discharging hole (5), one end of the material storage tank (1) is fixedly provided with a fixed mounting bracket (7), a feeding conveyer belt (6) is movably arranged on the fixed mounting bracket (7), a driving motor (8) is movably arranged on the outer side of the feeding conveyer belt (6), one end of the feeding conveyer belt (6) is movably provided with a material receiving bin (9), the lower end of the material receiving bin (9) is fixedly provided with a material conveying conveyer belt (10), the lower end of the material conveying conveyer belt (10) is fixedly provided with a fixed frame (11), the lower end of the fixed frame (11) is movably provided with an adjustable supporting leg (12). The material conveying device is characterized in that a driving rotating shaft (13) is movably mounted on the material conveying belt (10), a connecting conveying belt (14) is movably mounted at one end of the material conveying belt (10), an installing rack (15) is movably mounted at the lower end of the connecting conveying belt (14), a guide plate (16) is fixedly mounted at one end of the connecting conveying belt (14), a storage bin (17) is movably mounted at the lower end of the guide plate (16), a feeding rack (19) is fixedly mounted at the lower end of the storage bin (17), a fixed base (20) is fixedly mounted at the lower end of the feeding rack (19), a feeding motor (18) is fixedly mounted on the feeding rack (19), a connecting pipe (21) is fixedly mounted at one end of the feeding rack (19), a feeding bin (23) is fixedly mounted at the lower end of the connecting pipe (21), a fixed support (22) is fixedly mounted at the lower end of the feeding bin (23), the one end fixed mounting of fixed bolster (22) has extrusion head (24), the one end movable mounting who extrudes head (24) has shaping head (25), the one end movable mounting of shaping head (25) has discharging support (26), the upper end movable mounting of discharging support (26) has ejection of compact conveyer belt (27), the upper end fixed mounting of discharging support (26) has cutting support (28), the upper end fixed mounting of cutting support (28) has cutting cylinder (29), the lower extreme fixed mounting of cutting cylinder (29) has connection fixed plate (30), the lower extreme fixed mounting of connection fixed plate (30) has cutting knife (31), the one end fixed mounting of discharging support (26) has scraping wings (32), movable mounting has pushing cylinder (33) on scraping wings (32), the last fixed mounting that pushes away pushing cylinder (33) has pushing connecting rod (34), the one end fixed mounting that pushes away material connecting rod (34) and keep away from material pushing cylinder (33) has installation locating plate (35), fixed mounting has material push pedal (36) on installation locating plate (35).

2. The plant fiber sintered shale microporous brick production line according to claim 1, characterized in that: the storage tank (1) is designed to be of a rectangular structure, and the size of the storage tank (1) is larger than that of the crushing and stirring machine (3).

3. The plant fiber sintered shale microporous brick production line according to claim 1, characterized in that: the feeding conveyer belt (6) is of an inclined structural design, and at least eight groups of feeding baffles are arranged on the feeding conveyer belt (6) at equal intervals.

4. The plant fiber sintered shale microporous brick production line according to claim 1, characterized in that: the fixed rack (11) is designed to be H-shaped, and three groups of adjustable supporting legs (12) are symmetrically arranged at the lower end of the fixed rack (11).

5. The plant fiber sintered shale microporous brick production line according to claim 1, characterized in that: the connecting conveying belt (14) is designed to be of a trapezoidal structure, and two adjustable supporting legs (12) are symmetrically arranged at the lower end of the connecting conveying belt (14).

6. the plant fiber sintered shale microporous brick production line according to claim 1, characterized in that: stirring shaft (191) can be equipped with futilely in material loading frame (19), and the length of stirring shaft (191) and the length of material loading frame (19) mutual adaptation to stirring shaft (191) are gone up fixed mounting has helical structure's stirring vane (192).

7. The plant fiber sintered shale microporous brick production line according to claim 1, characterized in that: the control box (221) is fixedly installed on the fixed support (22), the power switch (222), the adjusting knob (223) and the function key (224) are movably installed on the control box (221), and the supporting seat (226) is fixedly installed at the lower end of the control box (221).

8. The plant fiber sintered shale microporous brick production line according to claim 1, characterized in that: fixed mounting has headstock (225) on fixed bolster (22), and fixed mounting has motor case (227) on headstock (225) to movable mounting has output gear (228) in headstock (225), meshing is connected with drive gear (229) on output gear (228), the upper end meshing of drive gear (229) is connected with drive gear (232), fixed mounting has connecting axle (231) on drive gear (232).

9. The plant fiber sintered shale microporous brick production line according to claim 1, characterized in that: the size of the extrusion head (24) on the fixed support (22) is larger than or equal to that of the forming head (25), and the interior of the forming head (25) is designed to be a rectangular structure.