CN110253737B

CN110253737B - Material distribution equipment for green brick powder

Info

Publication number: CN110253737B
Application number: CN201910521731.3A
Authority: CN
Inventors: 陈锦; 杨学先; 邓伟; 丁有馀
Original assignee: Foshan Saipu Feite Technology Co ltd; Foshan Henglitai Machinery Co Ltd
Current assignee: Foshan Saipu Feite Technology Co ltd; Foshan Henglitai Machinery Co Ltd
Priority date: 2019-06-17
Filing date: 2019-06-17
Publication date: 2024-01-30
Anticipated expiration: 2039-06-17
Also published as: CN110253737A

Abstract

The invention discloses a distributing device for green brick powder, which comprises a blanking device and a conveying device, wherein the blanking device comprises a discharger, a first belt conveying mechanism, a transfer hopper and a second belt conveying mechanism which are arranged from top to bottom; the second belt conveying mechanism comprises a small-diameter roller and a large-diameter roller, the diameter of the small-diameter roller is smaller than that of the large-diameter roller, and the small-diameter roller is positioned at the tail end of the conveying direction; the third belt conveying mechanism comprises an inner layer conveying mechanism and an outer layer conveying mechanism surrounding the inner layer conveying mechanism inside, the outer layer conveying mechanism comprises a first belt, the inner layer conveying mechanism comprises a second belt, the outer layer conveying mechanism and the inner layer conveying mechanism are driven by motors respectively, and the lower surface of an upper layer belt body of the first belt is contacted with the upper surface of an upper layer belt body of the second belt; the distribution equipment effectively ensures the compact and stability of the powder in the distribution and transportation processes, thereby ensuring the quality of the subsequent green bricks during pressing.

Description

Material distribution equipment for green brick powder

Technical Field

The invention relates to the field of building material equipment, in particular to distribution equipment for green brick powder.

Background

Powder is often used in the building material industry to produce green bricks, and the working procedures of material distribution, transportation, green brick pressing and the like are generally carried out in the production process, but the problems of bulk materials, cracks and the like of the primary form after material distribution often occur in the process, and the final product forming quality of the green bricks is seriously affected.

Disclosure of Invention

In order to overcome the defects of the prior art, the invention provides the material distribution equipment capable of improving the production quality of green bricks.

In order to achieve the above purpose, the technical scheme of the invention is as follows:

the distributing equipment for the green brick powder comprises a discharging device and a conveying device, wherein the discharging device comprises a discharging device, a first belt conveying mechanism, a transfer hopper and a second belt conveying mechanism which are arranged from top to bottom, and the transfer hopper comprises a discharging hole capable of being controlled to be opened and closed; the second belt conveying mechanism comprises a small-diameter roller and a large-diameter roller, the diameter of the small-diameter roller is smaller than that of the large-diameter roller, and the small-diameter roller is positioned at the tail end of the conveying direction; the conveying device comprises a frame and a third belt conveying mechanism arranged on the frame, the third belt conveying mechanism comprises an inner layer conveying mechanism and an outer layer conveying mechanism surrounding the inner layer conveying mechanism, the outer layer conveying mechanism comprises a first belt, the inner layer conveying mechanism comprises a second belt, the outer layer conveying mechanism and the inner layer conveying mechanism are driven by a motor I, II respectively, and the lower surface of an upper layer belt body of the first belt and the upper surface of an upper layer belt body of the second belt are in contact with each other.

As an improvement of the technical scheme, a first scraping plate is arranged at the bottom of the transfer hopper, and the lower end of the first scraping plate is close to the surface of the second belt conveying mechanism.

As a further improvement of the technical scheme, an adjusting screw and a second scraping plate fixedly connected to the lower end of the adjusting screw are arranged above the second belt conveying mechanism, and the distance between the second scraping plate and the second belt conveying mechanism is changed through the adjusting screw.

Further, transfer hopper internally mounted has the inductor that is used for monitoring its inside material storage capacity, the inductor is connected with discharger, first belt conveying mechanism.

Further, the outer diameter of the shaft body of the large-diameter roller is divided into three sections, the middle section of the shaft body is cylindrical, the left section and the right section of the shaft body are round tables, the outer diameters of the left section and the right section of the shaft body gradually decrease from the middle section to the two ends, the outer diameter of the middle section of the shaft body is the largest, and the left section and the right section of the large-diameter roller are symmetrically arranged.

Further, the small-diameter roller comprises a main shaft and a plurality of segmented shafts, the tail end of the second belt conveying mechanism is provided with a plurality of installation seats, the main shaft is fixedly connected to the installation seats in an inserting mode, and the segmented shafts are sequentially sleeved on the main shaft.

Further, a plurality of bearing rollers are arranged at the lower part of the frame, and when the belt conveyer runs, the lower layer belt body of the first belt and the lower layer belt body of the second belt are respectively lapped on different bearing rollers, so that gaps are reserved between the lower layer belt body of the first belt and the lower layer belt body of the second belt.

Further, the conveying device further comprises a movable frame capable of moving on the frame and a motor III for driving the movable frame to move, the third belt conveying mechanism is mounted on the movable frame, and the movable frame drives the third belt conveying mechanism to move on the frame.

Further, a pressing mechanism is arranged behind the frame and comprises an upper mold core, a lower mold core, a moving frame and a press, wherein the moving frame is sleeved Bao Rao on the edge of the upper end face of the lower mold core and moves up and down, and the press drives the upper mold core/lower mold core to move up and down; the movable frame moves on the frame to drive the third belt conveying mechanism to move in and out in the direction between the upper mold core and the lower mold core.

The beneficial effects of the invention are as follows: 1. the first belt conveying mechanism transfers the powder to the transfer hopper for storage, when the powder is stored in the transfer hopper to a certain amount, the powder falls onto the second belt conveying mechanism from the transfer hopper, and the powder forms a compact green brick primary form on the second belt conveying mechanism, so that the compactness of the green brick primary form in material distribution is ensured;

2. the second belt conveying mechanism comprises a small-diameter roller and a large-diameter roller, the area of the arc bending position of the tail end of the belt is greatly reduced by the small-diameter roller, namely, the path of powder at the arc bending position is reduced, so that the continuity of the powder when the formed primary powder is conveyed and transited from the tail end of the second belt conveying mechanism to a subsequent device is ensured, the problem of bulk material of the powder is effectively prevented, and the production quality of subsequent green bricks is ensured;

3. the third belt conveying mechanism comprises an inner layer conveying mechanism and an outer layer conveying mechanism surrounding the inner layer conveying mechanism inside, the outer layer conveying mechanism comprises a first belt, the inner layer conveying mechanism comprises a second belt, the second belt can exert a thrust pushing effect on the first belt, the stable transportation of the first belt in the transportation process is ensured, the load of a motor I can be effectively reduced, the motor I is protected, a motor with smaller relative power can be selected under the same equipment size, the structural cost is reduced, and meanwhile, the stability of powder in transition conveying can be ensured;

the distribution equipment effectively ensures the compact and stability of the powder in the distribution and transportation processes, thereby ensuring the quality of the follow-up green brick pressing.

Drawings

Further description is provided below with reference to the drawings and examples.

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

FIG. 2 is a schematic cross-sectional front view of the overall structure of the present invention;

FIG. 3 is a schematic diagram of the structure of the blanking device of the present invention;

FIG. 4 is an enlarged view of a partial structure A of the present invention;

FIG. 5 is an enlarged view of a partial structure B of the present invention;

FIG. 6 is a schematic view of a second belt conveyor mechanism of the present invention;

FIG. 7 is an enlarged view of a partial structure C of the present invention;

FIG. 8 is a schematic view of a third belt conveyor mechanism of the present invention;

FIG. 9 is a schematic front view of a third belt conveyor mechanism of the present invention;

FIG. 10 is a schematic view of the frame structure of the present invention;

FIG. 11 is a schematic view of the structure of the mobile frame of the present invention;

fig. 12 is a schematic view of the structure of the green compact mechanism of the present invention.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

Referring to fig. 1 to 9, a distributing device for green brick powder comprises a blanking device 1 and a conveying device 3, wherein the blanking device 1 comprises a discharger 11, a first belt conveying mechanism 12, a transfer hopper 13 and a second belt conveying mechanism 2 which are arranged from top to bottom, and the transfer hopper 13 comprises a discharge hole 131 capable of controlling opening and closing; in this embodiment, the plurality of discharging devices 11 are controlled to fall onto the first belt conveying mechanism 12 according to the pattern and shape of the green bricks, the powder pattern layers are longitudinally distributed, the first belt conveying mechanism 12 transfers the powder to the transfer hopper 13 for storage, at this time, the direction of the pattern layers of the powder is changed from the longitudinal direction to the transverse direction in the transfer hopper 13, when the powder is stored in a certain amount in the transfer hopper 13, the discharging hole 131 of the transfer hopper 13 is opened, the powder falls onto the second belt conveying mechanism 2, the direction of the pattern layers of the powder is changed from the transverse direction to the longitudinal direction again, and as the powder falls onto the second belt conveying mechanism 2 from the transfer hopper 13 in a certain pattern structure, the powder forms a compact green brick primary shape on the second belt conveying mechanism 2, so that the compactness of the green brick primary shape during distribution is ensured;

the second belt conveying mechanism 2 comprises a small-diameter roller 21 and a large-diameter roller 22, the diameter of the small-diameter roller 21 is smaller than that of the large-diameter roller 22, the small-diameter roller 21 is positioned at the tail end of the conveying direction, the small-diameter roller 21 and the large-diameter roller 22 are matched to enable the second belt conveying mechanism 2 to form a knife-like shape, when powder is conveyed from the second belt 421 conveyor to a subsequent device, the large-diameter roller 22 ensures the conveying speed and stability, when the tail end of the powder is transited to the subsequent device, the powder needs to fall onto the subsequent device after passing through the arc bending position of the tail end of the belt, the small-diameter roller 21 greatly reduces the arc bending position area of the tail end of the belt, namely reduces the path of the powder at the arc bending position, so that the continuity of the powder is ensured when the tail end conveying of the formed primary powder is transited to the subsequent device from the second belt conveying mechanism 2, the problem of powder is effectively prevented, and the production quality of a subsequent green brick is ensured;

the conveying device 3 comprises a frame 31 and a third belt conveying mechanism 4 arranged on the frame 31, the third belt conveying mechanism 4 comprises an inner layer conveying mechanism 42 and an outer layer conveying mechanism 41 surrounding the inner layer conveying mechanism 42 inside, the outer layer conveying mechanism 41 comprises a first belt 411, the inner layer conveying mechanism 42 comprises a second belt 421, the outer layer conveying mechanism 41 and the inner layer conveying mechanism 42 are respectively driven by a motor I, II, the lower surface of an upper layer belt body of the first belt 411 and the upper surface of an upper layer belt body of the second belt 421 are contacted with each other, the second belt conveying mechanism 2 conveys powder to the third belt conveying mechanism 4, compared with the conventional belt conveying equipment, when the belt is designed to be of a larger size due to the requirement of products, the motor with high power is required to drive the belt conveying mechanism, or when the conveyed materials are overweight, the motor can bear high load, the conveying speed can be reduced, the relative speeds of the second belt conveying mechanism 2 and the third belt conveying mechanism 4 are possibly changed, the stability of powder conveying is affected, meanwhile, the service life of the equipment is shortened due to the problem of overload, and the like; the third belt conveying mechanism 4 has the advantages that the conveying speed of the inner layer conveying mechanism 42 is equal to or slightly greater than that of the outer layer conveying mechanism 41, the lower surface of the upper layer belt body of the first belt 411 and the upper surface of the upper layer belt body of the second belt 421 are in contact with each other, the second belt 421 can exert a thrust pushing effect on the first belt 411, so that stable transportation of the first belt 411 in the transportation process is ensured, the load of a motor I can be effectively reduced, the motor I is protected, a motor with smaller relative power can be selected under the same equipment size, the structural cost is reduced, and meanwhile, the stability of powder in transitional conveying can be ensured;

In this embodiment, the discharge port 131 of the transfer hopper 13 is provided with a gate, and the gate may be driven by a motor or an air cylinder to control the opening and closing of the discharge port 131.

Referring to fig. 3 and 4, a first scraper 132 is installed at the bottom of the transfer hopper 13, the lower end of the first scraper 132 is close to the surface of the second belt conveying mechanism 2, powder falls onto the second belt conveying mechanism 2 from the discharge port 131, and the upper surface of the material on the second belt conveying mechanism 2 is scraped flatly by the first scraper 132, so that the smoothness of the surface of the material is ensured, and the product quality is improved.

Referring to fig. 3 and 5, an adjusting screw 133 and a second scraper 134 fixedly connected to the lower end of the adjusting screw 133 are disposed above the second belt conveying mechanism 2, the distance between the second scraper 134 and the second belt conveying mechanism 2 is changed by the adjusting screw 133, powder falls onto the second belt conveying mechanism 2 from the discharge hole 131, and the first scraper 132 is used for scraping the upper surface of the powder on the second belt conveying mechanism 2, so that the smoothness of the surface of the material is ensured, and the product quality is improved.

Preferably, the transfer hopper 13 internally mounted has the inductor that is used for monitoring its inside material storage capacity, the inductor is connected with discharger 11, first belt conveyor 12, and when the powder that stores in the transfer hopper 13 reached the induction position, inductor feedback signal to discharger 11, first belt conveyor 12 connect and stop to transfer hopper 13 blanking, prevent that the material from excessively overflowing.

Referring to fig. 2 and 6, preferably, the shaft body of the large-diameter roller 22 is divided into three sections, the middle section of the shaft body is cylindrical, the left and right sections of the shaft body are in a circular truncated cone shape, the outer diameters of the left and right sections of the shaft body gradually decrease from the middle section to two ends, the outer diameter of the middle section of the shaft body is the largest, the left and right sections of the large-diameter roller 22 are symmetrically arranged, and the structure of the large-diameter roller is described below by an embodiment, in the embodiment, the outer diameter of the middle section of the large-diameter roller 22 is 208mm, the length of the middle section is 1000mm, the lengths of the left and right sections are 500mm, the outer diameters of the two ends of the large-diameter roller 223 are 206mm, and the left and right sections are the outer diameters of the middle section which are linearly reduced from the outer diameter of 208mm to the outer diameters of the two ends of the middle section which are 206mm are in a circular truncated cone shape; the sectional structure of the large-diameter roller 22 can effectively avoid the deflection of the belt after long-time conveying, ensure the stability of the belt during conveying, and further ensure the stability of powder conveying.

Referring to fig. 2, 6 and 7, preferably, the small-diameter roller 21 includes a main shaft 211 and a plurality of segmented shafts 212, the tail end of the second belt conveying mechanism 2 is provided with a plurality of mounting seats 23, the main shaft 211 is fixed on the mounting seats 23 in a plugging manner, the segmented shafts 212 are sequentially sleeved on the main shaft 211, when the small-diameter roller 21 is longer, the small-diameter roller 21 is small in outer diameter and small in structural strength, deformation is easy to occur when supporting a belt, the small-diameter roller 21 is set into a segmented mounting structure, the structural strength of each segmented shaft 212 is greatly improved, and the stability of belt conveying is ensured.

Referring to fig. 2 and 9, the lower portion of the frame 31 is provided with a plurality of bearing rollers 43, and when in operation, the lower layer belt body of the first belt 411 and the lower layer belt body of the second belt 421 are respectively supported on different bearing rollers 43, so that a gap exists between the lower layer belt body of the first belt 411 and the lower layer belt body of the second belt 421, friction and abrasion caused by contact between the first belt 411 and the second belt 421 are reduced, and the bearing rollers 43 also have an expanding effect on the first belt 411 and the second belt 421.

Referring to fig. 2, 10 and 11, the conveying device 3 further includes a moving frame 5 that can move on the frame 31, and a motor III that drives the moving frame 63 to move, the third belt conveying mechanism 4 is mounted on the moving frame 5, the moving frame 5 drives the third belt conveying mechanism 4 to move on the frame 31, and the moving frame 63 integrally moves the third belt conveying mechanism 4 in the subsequent device direction.

Referring to fig. 1, 2 and 12, further, a compacting mechanism 6 is disposed at the rear of the frame 31, the compacting mechanism 6 includes an upper mold core 61, a lower mold core 62, a moving frame 63, and a press 64, the moving frame 63 is sleeved Bao Rao on the upper end surface edge of the lower mold core 62 and moves up and down, and the press 64 drives the upper mold core 61/lower mold core 62 to move up and down; the moving frame 5 moves on the frame 31 to drive the third belt conveying mechanism 4 to move in and out in the direction between the upper mold core 61 and the lower mold core 62, the moving frame 5 moves the third belt conveying mechanism 4 between the upper mold core 61 and the lower mold core 62, the third belt conveying mechanism 4 transfers powder to the lower mold core 62, and the moving frame 5 drives the third belt conveying mechanism 4 to move while transferring the powder to realize that the powder on the third belt conveying mechanism 4 is distributed on the lower mold core 62 according to the shape of a green brick.

While embodiments of the present invention have been shown and described above, it will be understood that the above embodiments are illustrative and not to be construed as limiting the invention, and that variations, modifications, alternatives and variations may be made to the above embodiments by one of ordinary skill in the art within the scope of the invention.

Claims

1. A cloth equipment for adobe powder, its characterized in that: the automatic feeding device comprises a feeding device (1) and a conveying device (3), wherein the feeding device (1) comprises a discharging device (11), a first belt conveying mechanism (12), a transfer hopper (13) and a second belt conveying mechanism (2) which are arranged from top to bottom, and the transfer hopper (13) comprises a discharging hole (131) which can be controlled to be opened and closed;

the second belt conveying mechanism (2) comprises a small-diameter roller (21) and a large-diameter roller (22), the diameter of the small-diameter roller (21) is smaller than that of the large-diameter roller (22), and the small-diameter roller (21) is positioned at the tail end in the conveying direction;

the conveying device (3) comprises a frame (31), a third belt conveying mechanism (4) arranged on the frame (31), wherein the third belt conveying mechanism (4) comprises an inner layer conveying mechanism (42) and an outer layer conveying mechanism (41) surrounding the inner layer conveying mechanism (42) inside, the outer layer conveying mechanism (41) comprises a first belt (411), the inner layer conveying mechanism (42) comprises a second belt (421), the outer layer conveying mechanism (41) and the inner layer conveying mechanism (42) are respectively driven by a motor (I, II), and the lower surface of an upper layer belt body of the first belt (411) and the upper surface of an upper layer belt body of the second belt (421) are in contact with each other; the conveying speed of the inner layer conveying mechanism (42) is equal to or slightly greater than the conveying speed of the outer layer conveying mechanism (41).

2. A distribution device for green brick powders according to claim 1, characterized in that: the bottom of the transfer hopper (13) is provided with a first scraping plate (132), and the lower end of the first scraping plate (132) is close to the surface of the second belt conveying mechanism (2).

3. A distribution device for green brick powders according to claim 1, characterized in that: and an adjusting screw (133) and a second scraping plate (134) fixedly connected to the lower end of the adjusting screw (133) are arranged above the second belt conveying mechanism (2), and the distance between the second scraping plate (134) and the second belt conveying mechanism (2) is changed through the adjusting screw (133).

4. A distribution device for green brick powders according to claim 1, characterized in that: the transfer hopper (13) internally provided with an inductor for monitoring the storage quantity of materials in the transfer hopper, and the inductor is connected with the discharger (11) and the first belt conveying mechanism (12).

5. A distribution device for green brick powders according to claim 1, characterized in that: the shaft body outer diameter of the large-diameter roller (22) is divided into three sections, the middle section of the shaft body is cylindrical, the left section and the right section of the shaft body are round tables, the outer diameters of the left section and the right section of the shaft body gradually decrease from the middle section to the two ends, the outer diameter of the middle section of the shaft body is maximum, and the left section and the right section of the large-diameter roller (22) are symmetrically arranged.

6. A distribution device for green brick powders according to claim 1, characterized in that: the small-diameter roller (21) comprises a main shaft (211) and a plurality of segmented shafts (212), the tail end of the second belt conveying mechanism (2) is provided with a plurality of mounting seats (23), the main shaft (211) is fixedly connected to the mounting seats (23) in a plugging mode, and the segmented shafts (212) are sequentially sleeved on the main shaft (211).

7. A distribution device for green brick powders according to claim 1, characterized in that: the lower part of the frame (31) is provided with a plurality of bearing rollers (43), and when the machine is in operation, the lower layer belt body of the first belt (411) and the lower layer belt body of the second belt (421) are respectively lapped on different bearing rollers (43), so that gaps are reserved between the lower layer belt body of the first belt (411) and the lower layer belt body of the second belt (421).

8. A distribution device for green brick powders according to claim 1, characterized in that: the conveying device (3) further comprises a moving frame (5) capable of moving on the frame (31) and a motor (III) for driving the moving frame (5) to move, the third belt conveying mechanism (4) is installed on the moving frame (5), and the moving frame (5) drives the third belt conveying mechanism (4) to move on the frame (31).

9. A distribution device for green brick powders according to claim 8, characterized in that: a pressing mechanism (6) is arranged behind the frame (31), the pressing mechanism (6) comprises an upper mold core (61), a lower mold core (62), a moving frame (63) and a press (64), the moving frame (63) is sleeved Bao Rao on the edge of the upper end face of the lower mold core (62) and moves up and down, and the press (64) drives the upper mold core (61)/the lower mold core (62) to move up and down; the movable frame (5) moves on the frame (31) to drive the third belt conveying mechanism (4) to move in and out in the direction between the upper mold core (61) and the lower mold core (62).