CN117428915A

CN117428915A - Automatic concrete brick production system

Info

Publication number: CN117428915A
Application number: CN202311533816.6A
Authority: CN
Inventors: 戴亮
Original assignee: Xinghua Fishing Xiangsheng Building Materials Factory
Current assignee: Xinghua Fishing Xiangsheng Building Materials Factory
Priority date: 2023-11-17
Filing date: 2023-11-17
Publication date: 2024-01-23
Anticipated expiration: 2043-11-17
Also published as: CN117428915B

Abstract

The invention discloses an automatic concrete brick production system, which relates to the technical field of concrete brick production and comprises a workbench, wherein a stirring part is fixedly arranged on the workbench, the stirring part comprises a mixing bracket, and at least three mixing barrels are fixedly arranged on the mixing bracket. According to the invention, the concrete raw materials can be uniformly mixed, the quality of concrete is improved, and the provided drag reduction ports can be used for more uniformly mixing the concrete, so that the stirring efficiency of the concrete is improved; the stirred concrete can be conveyed while being molded, and can be solidified in the conveying process, so that the production speed of the concrete brick is greatly improved; the guiding chute and the forming part are matched with each other, so that the device can control the work of the whole production conveying part only by controlling the start and stop of the conveying driving motor, a complex control system is not needed, and the manufacturing cost of the whole equipment is reduced.

Description

Automatic concrete brick production system

Technical Field

The invention relates to the technical field of concrete brick production, in particular to an automatic concrete brick production system.

Background

The concrete brick is made up by mixing cement, sand, stone and water according to a certain proportion, and is a new wall material with extensive application. The concrete brick has the characteristics of high strength, high density, low water absorption, low noise, environmental protection and the like, can be widely applied to the fields of industrial and civil buildings, municipal facilities, garden landscapes and the like, is a green building material with good prospects, and most of the concrete drilling block production systems in the current market adopt a mode of combining production lines one by one for production, so that the manufacturing cost of production equipment of the concrete brick is improved, and the production efficiency is reduced.

In the prior art, the invention patent with the publication number of CN112045823B utilizes a concrete brick block production system to realize the current production of a plurality of concrete bricks, and when the concrete bricks are prepared, the concrete is divided into a plurality of layers for layered preparation, so that the pore volume generated when the air is removed from the concrete can be reduced, the compactness of the concrete bricks is improved, but the concrete bricks cannot be produced in a large scale, and the production efficiency is improved but is relatively low.

Disclosure of Invention

In order to overcome the defects in the prior art, the invention provides the following technical scheme: the automatic concrete brick production system comprises a workbench, wherein a stirring part is fixedly arranged on the workbench, the stirring part comprises a mixing bracket, at least three mixing barrels are fixedly arranged on the mixing bracket, two stirring blades which are vertically arranged are arranged in each mixing barrel, a drag reduction opening is formed in each stirring blade and used for uniformly stirring concrete in the mixing barrel, two discharging motors are symmetrically arranged on the mixing bracket, discharging screw rods are fixedly arranged on output shafts of each discharging motor, mixing motor brackets are arranged on the two discharging screw rods in a threaded manner, mixing motors with the same number as the mixing barrels are fixedly arranged on the mixing motor brackets, the output shafts of the mixing motors are fixedly connected with the stirring blades through mixing rods, and discharging trays which are in rotary fit with the mixing rods are slidably arranged at the bottoms of the inner walls of the mixing barrels; still fixed mounting has shaping portion on the workstation, shaping portion is including rotating the transport subassembly that sets up on the workstation, and the check baffle is installed to transport subassembly's both sides face, and fixed mounting has limited altitude board on the check baffle, transport subassembly's top still is provided with shaping cutting board, still fixed mounting has the cutting board support on the check baffle, and slidable mounting has the rack slide bar on the cutting board support, and cutting board mount pad and shaping cutting board fixed connection are passed through to the bottom of rack slide bar, fixed mounting has the spacing piece of spring on the rack slide bar, is provided with the spring between spacing piece of spring and the cutting board support, still fixed mounting has first gearbox, conveying driving motor, second gearbox and third gearbox on the workstation, and wherein the second gearbox passes through pushing down passive gear support and workstation fixed connection.

Preferably, the mixing bracket is fixedly installed on the workbench through a mixing bracket fixing frame, and the stirring part further comprises a guide chute arranged below the mixing bracket.

Preferably, the guide chute is obliquely arranged relative to the workbench, and the splash guard and the reinforcing plate are fixedly arranged on the guide chute, and the splash guard is fixedly arranged on the workbench through the chute bracket.

Preferably, the distance between the bottom edge of the height limiting plate and the upper surface of the conveying assembly is equal to the thickness of the required formed concrete brick.

Preferably, the two ends of the spring are fixedly connected with the spring limiting piece and the cutting board support, and the spring is arranged on the outer side of the rack sliding rod in a surrounding mode.

Preferably, the pressing-down driven gear support is further rotatably provided with a pressing-down executing gear and a pressing-down driven gear, the pressing-down executing gear and the pressing-down driven gear are fixedly connected through a synchronous rotating shaft, the pressing-down executing gear is in meshed transmission with the rack sliding rod, and the output shaft of the second gearbox is fixedly provided with a pressing-down tooth-missing gear in meshed fit with the pressing-down driven gear.

Preferably, the output shaft of the transmission driving motor is fixedly provided with a linkage tooth-missing gear, the input shaft of the first gearbox is fixedly provided with a first shaking input gear meshed and matched with the linkage tooth-missing gear, the workbench is also rotatably provided with a forming input gear meshed and matched with the linkage tooth-missing gear, and the forming input gear is in transmission connection with the input shaft of the second gearbox through a forming input transmission belt.

Preferably, the output shaft of the first gearbox is fixedly connected with the input shaft of the third gearbox, the first gearbox is used for driving the transmission assembly to rotate, two symmetrically arranged shaking cams are further rotatably installed on the workbench through shaking cam supports, the two shaking cams are fixed into a whole through a rotating shaft, and the output shaft of the third gearbox is in transmission connection with the two shaking cams through shaking transmission belts.

Preferably, two shaking spring plates which are symmetrically arranged are fixedly arranged on the lower surface of the guide chute, and the two shaking spring plates are in contact sliding fit with the two shaking cams.

Preferably, a heating cover is fixedly installed on the workbench and used for solidifying the formed concrete brick blocks, and the heating cover is arranged above the conveying assembly.

Compared with the prior art, the invention has the following beneficial effects: (1) The stirring part provided by the invention can uniformly stir and mix concrete raw materials, so that the quality of concrete is improved, and the provided drag reduction port can more uniformly mix the concrete, so that the stirring efficiency of the concrete is improved; (2) The forming part provided by the invention can form and convey the stirred concrete at the same time, and can be solidified in the conveying process, so that the production speed of the concrete brick is greatly improved; (3) The invention sets the guiding chute and the forming part to match with each other, so that the device can control the work of the whole production conveying part only by controlling the start and stop of the conveying driving motor without a complex control system, thereby reducing the manufacturing cost of the whole equipment.

Drawings

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

Fig. 2 is a schematic diagram of the structure a in fig. 1 according to the present invention.

FIG. 3 is a schematic view of the stirring section structure of the present invention.

Fig. 4 is a view of the discharge tray of the present invention in a closed position.

Fig. 5 is a view showing the position of the discharge tray of the present invention in an opened state.

In the figure: 101-a mixing scaffold; 102-a discharging motor; 103-a discharge screw rod; 104-a hybrid motor bracket; 105-a hybrid motor; 106, a mixing drum; 107-mixing rod; 108-stirring blades; 1081-drag reducing ports; 109-a discharge tray; 110-guiding a chute; 111-splash guard; 112-reinforcing plates; 113-a chute support; 114-a mixed bracket fixing frame; 115-shaking shrapnel; 201-a transfer assembly; 202-grid baffles; 203-heating mantle; 204-a height limiting plate; 205-a first gearbox; 206-a first wobble input gear; 207-linkage gear lack; 208-shaping the input gear; 209-a conveyor drive motor; 210-shaping an input drive belt; 211-a second gearbox; 212-forming a cutting plate; 213-cutting plate holder; 214-cutting board mount; 215-rack slide bar; 216-springs; 217-spring limit piece; 218-depressing the actuator gear; 219-synchronizing the rotation shafts; 220-pressing down the driven gear; 221-pressing down a tooth-missing gear; 222-depressing the passive gear support; 223-third gearbox; 224-shake drive belt; 225-dithering the cam bracket; 226-a dither cam; 3-a workbench.

Detailed Description

The technical scheme of the invention is further described below by means of specific embodiments with reference to the accompanying drawings 1-5.

The invention provides an automatic concrete brick production system, which comprises a workbench 3, wherein a stirring part is fixedly arranged on the workbench 3, the stirring part comprises a mixing bracket 101, at least three mixing barrels 106 are fixedly arranged on the mixing bracket 101, two stirring blades 108 which are vertically arranged are arranged in each mixing barrel 106, a drag reduction opening 1081 is formed in each stirring blade 108 and used for uniformly stirring concrete in the mixing barrels 106, two discharging motors 102 are symmetrically arranged on the mixing bracket 101, discharging screw rods 103 are fixedly arranged on output shafts of each discharging motor 102, mixing motor brackets 104 are arranged on the two discharging screw rods 103 in a threaded manner, mixing motors 105 with the same number as the mixing barrels 106 are fixedly arranged on the mixing motor brackets 104, output shafts of the mixing motors 105 are fixedly connected with the stirring blades 108 through mixing rods 107, and discharging trays 109 which are in running fit with the mixing rods 107 are also slidably arranged at the bottoms of inner walls of the mixing barrels 106. The mixing bracket 101 is fixedly mounted on the workbench 3 through a mixing bracket fixing bracket 114, and the stirring part further comprises a guide chute 110 arranged below the mixing bracket 101. The guide chute 110 is arranged obliquely relative to the workbench 3, and a splash guard 111 and a reinforcing plate 112 are fixedly mounted on the guide chute 110, and the splash guard 111 is fixedly mounted on the workbench 3 through a chute bracket 113.

The workbench 3 is further fixedly provided with a forming part, the forming part comprises a conveying assembly 201 which is rotatably arranged on the workbench 3, two side surfaces of the conveying assembly 201 are provided with grid baffles 202, a limited height plate 204 is fixedly arranged on the grid baffles 202, a forming cutting plate 212 is further arranged above the conveying assembly 201, a cutting plate support 213 is fixedly arranged on the grid baffles 202, a rack sliding rod 215 is slidably arranged on the cutting plate support 213, the bottom end of the rack sliding rod 215 is fixedly connected with the forming cutting plate 212 through a cutting plate mounting seat 214, a spring limiting piece 217 is fixedly arranged on the rack sliding rod 215, a spring 216 is arranged between the spring limiting piece 217 and the cutting plate support 213, and a first gearbox 205, a conveying driving motor 209, a second gearbox 211 and a third gearbox 223 are fixedly arranged on the workbench 3, wherein the second gearbox 211 is fixedly connected with the workbench 3 through a downward-pressing driven gear support 222. The bottom edge of the height limiting plate 204 is spaced from the upper surface of the transfer assembly 201 by a distance equal to the thickness of the desired molded concrete block. The two ends of the spring 216 are fixedly connected with the spring limiting piece 217 and the cutting plate bracket 213, and the spring 216 is arranged on the outer side of the rack sliding rod 215 in a surrounding manner. The pressing driven gear bracket 222 is also rotatably provided with a pressing executing gear 218 and a pressing driven gear 220, the pressing executing gear 218 and the pressing driven gear 220 are fixedly connected through a synchronous rotating shaft 219, the pressing executing gear 218 is in meshed transmission with the rack sliding rod 215, and the output shaft of the second gearbox 211 is fixedly provided with a pressing tooth-missing gear 221 in meshed fit with the pressing driven gear 220. The output shaft of the transmission driving motor 209 is fixedly provided with a linkage gear lack 207, the input shaft of the first gearbox 205 is fixedly provided with a first shaking input gear 206 meshed and matched with the linkage gear lack 207, the workbench 3 is also rotatably provided with a forming input gear 208 meshed and matched with the linkage gear lack 207, and the forming input gear 208 is in transmission connection with the input shaft of the second gearbox 211 through a forming input transmission belt 210. The output shaft of the first gearbox 205 is fixedly connected with the input shaft of the third gearbox 223, the first gearbox 205 is used for driving the transmission assembly 201 to rotate, two shaking cams 226 which are symmetrically arranged are further rotatably arranged on the workbench 3 through shaking cam supports 225, the two shaking cams 226 are fixed into a whole through a rotating shaft, and the output shaft of the third gearbox 223 is in transmission connection with the two shaking cams 226 through shaking transmission belts 224. Two symmetrically arranged shaking spring plates 115 are fixedly arranged on the lower surface of the guide chute 110, and the two shaking spring plates 115 are in contact sliding fit with the two shaking cams 226.

The invention discloses an automatic concrete brick production system, which has the following working principle: pouring the concrete which is not completely and uniformly mixed into all mixing barrels 106, starting the mixing motor 105, driving the mixing blades 108 to rotate by the output shafts of the mixing motor 105 through the mixing rod 107, continuously shoveling the concrete on the discharging tray 109 (namely, the bottom of the mixing barrel 106) through the rotation of the mixing blades 108, then falling down through the drag reduction port 1081, shoveling again, and reciprocally carrying out, wherein the drag reduction port 1081 can be used for reducing the resistance between the concrete and the mixing blades 108, and stirring the concrete in multiple layers to ensure that the concrete is more uniformly mixed (which is equivalent to using a plurality of small-sized mixing blades 108), controlling the output shafts of the two discharging motors 102 to rotate after the stirring is completed, driving the mixing motor bracket 104 to vertically move through the discharging screw 103, so that all the mixing motors 105 move downwards, which can lead the discharging tray 109 to move downwards, so that the concrete falls onto the guiding chute 110 from the position shown in fig. 4 to the position shown in fig. 5, then the conveying driving motor 209 is started, the output shaft of the conveying driving motor 209 drives the linkage gear-missing 207 to rotate, the linkage gear-missing 207 rotates to drive the first shaking input gear 206 or the forming input gear 208 to rotate (the first shaking input gear 206 and the forming input gear 208 are not simultaneously driven by the linkage gear-missing 207), when the first shaking input gear 206 rotates, the first shaking input gear 206 drives the input shaft of the first gearbox 205 to rotate, the output shaft of the first gearbox 205 drives the grid baffle 202 to rotate, and simultaneously drives the input shaft of the third gearbox 223 to rotate, so that the output shaft of the third gearbox 223 drives the shaking cam 226 to rotate through the shaking transmission belt 224, the shaking cam 226 rotates to continuously stir the shaking elastic sheet 115, the shaking elastic sheet 115 drives the guiding chute 110 to shake, the concrete on the guiding chute 110 is beneficial to sliding down to the conveying assembly 201, meanwhile, the sliding concrete moves along with the conveying assembly 201, when the concrete moves to the height limiting plate 204, the concrete is blocked by the height limiting plate 204 to be changed into a required thickness, then the concrete moves to the lower part of the forming cutting plate 212, at the moment, the linkage tooth-missing gear 207 is just separated and meshed with the first shaking input gear 206 and then meshed with the forming input gear 208, the forming input gear 208 rotates, the forming input gear 208 drives the input shaft of the second gearbox 211 to rotate through the forming input transmission belt 210, the output shaft of the second gearbox 211 drives the pressing driven gear 220 to rotate through the pressing tooth-missing gear 221, the pressing driven gear 220 rotates to drive the pressing executing gear 218 to rotate through the synchronous rotating shaft 219 (the pressing executing gear 218 can be in friction fit with the synchronous rotating shaft 219, when the transmission precision of parts is low and parts is used, the pressing executing gear 218 and the synchronous rotating shaft 219 can slide relatively when the rack slide rod 215 moves to the lowest point, so that the manufacturing cost of parts can be reduced, but the connection part of the pressing executing gear 218 and the synchronous rotating shaft 219 is worn), the pressing executing gear 218 rotates to drive the rack slide rod 215 to move vertically, the forming cutting plate 212 is driven to move downwards through the cutting plate mounting seat 214, the forming cutting plate 212 cuts concrete into a plurality of required shapes (generally rectangular parallelepiped), when the pressing tooth-missing gear 221 rotates to a position separated from the pressing driven gear 220, the pressing executing gear 218 is reset under the elasticity of the spring 216, the depressing of the gear 221 is not limited by depressing the actuator gear 218 and depressing the driven gear 220. The interlocking tooth-missing gear 207 is then meshed with the first shaking input gear 206 again to drive, so that the formed concrete state is moved into the heating mantle 203, formed by drying, heating and curing, and then separated from the conveying assembly 201.

Claims

1. An automatic concrete brick production system comprises a workbench (3), and is characterized in that: the stirring part comprises a mixing bracket (101), at least three mixing barrels (106) are fixedly arranged on the mixing bracket (101), two stirring blades (108) which are vertically arranged are arranged in each mixing barrel (106), drag reduction ports (1081) are formed in each stirring blade (108) and are used for uniformly stirring concrete in the mixing barrels (106), two discharging motors (102) are symmetrically arranged on the mixing bracket (101), discharging screw rods (103) are fixedly arranged on output shafts of each discharging motor (102), mixing motor brackets (104) are threadedly arranged on the two discharging screw rods (103), mixing motors (105) which are the same in number with the mixing barrels (106) are fixedly arranged on the mixing motor brackets (104), output shafts of the mixing motors (105) are fixedly connected with the stirring blades (108) through mixing rods (107), and discharging trays (109) which are in running fit with the mixing rods (107) are slidably arranged at bottoms of inner walls of the mixing barrels (106);

still fixed mounting has shaping portion on workstation (3), shaping portion is including rotating conveying subassembly (201) that sets up on workstation (3), and grid baffle (202) are installed to the both sides face of conveying subassembly (201), and fixed mounting limited height board (204) on grid baffle (202), the top of conveying subassembly (201) still is provided with shaping cutting board (212), still fixed mounting has cutting board support (213) on grid baffle (202), slidable mounting has rack slide bar (215) on cutting board support (213), and rack slide bar (215)'s bottom is through cutting board mount pad (214) and shaping cutting board (212) fixed connection, be provided with spring (216) on rack slide bar (215) between spring limit piece (217) and cutting board support (213), still fixed mounting has first gearbox (205), transmission driving motor (209), second gearbox (211) and third gearbox (223) on workstation (3), and wherein second gearbox (211) are passed through and are pushed by driven gear support (222) fixed connection.

2. An automated concrete tile production system according to claim 1, wherein: the mixing bracket (101) is fixedly arranged on the workbench (3) through a mixing bracket fixing frame (114), and the stirring part further comprises a guide chute (110) arranged below the mixing bracket (101).

3. An automated concrete tile production system according to claim 2, wherein: the guide chute (110) is obliquely arranged relative to the workbench (3), the splash guard (111) and the reinforcing plate (112) are fixedly arranged on the guide chute (110), and the splash guard (111) is fixedly arranged on the workbench (3) through the chute bracket (113).

4. An automated concrete tile production system according to claim 3, wherein: the distance between the bottom edge of the height limiting plate (204) and the upper surface of the conveying assembly (201) is equal to the thickness of the required formed concrete brick.

5. An automated concrete tile production system according to claim 4, wherein: the two ends of the spring (216) are fixedly connected with the spring limiting piece (217) and the cutting plate bracket (213), and the spring (216) is arranged on the outer side of the rack sliding rod (215) in a surrounding mode.

6. An automated concrete tile production system according to claim 5, wherein: the pressing-down driven gear bracket (222) is further rotatably provided with a pressing-down executing gear (218) and a pressing-down driven gear (220), the pressing-down executing gear (218) and the pressing-down driven gear (220) are fixedly connected through a synchronous rotating shaft (219), the pressing-down executing gear (218) is in meshed transmission with the rack sliding rod (215), and an output shaft of the second gearbox (211) is fixedly provided with a pressing-down tooth-missing gear (221) in meshed fit with the pressing-down driven gear (220).

7. An automated concrete tile production system according to claim 6, wherein: the output shaft of the transmission driving motor (209) is fixedly provided with a linkage tooth-missing gear (207), the input shaft of the first gearbox (205) is fixedly provided with a first shaking input gear (206) meshed and matched with the linkage tooth-missing gear (207), the workbench (3) is further rotatably provided with a forming input gear (208) meshed and matched with the linkage tooth-missing gear (207), and the forming input gear (208) is in transmission connection with the input shaft of the second gearbox (211) through a forming input transmission belt (210).

8. An automated concrete tile production system according to claim 7, wherein: the output shaft of first gearbox (205) and the input shaft fixed connection of third gearbox (223), and first gearbox (205) are used for driving conveying subassembly (201) and rotate, still install shake cam (226) that two symmetries set up through shake cam support (225) rotation on workstation (3), fix as an organic wholely through the pivot between two shake cams (226), and the output shaft of third gearbox (223) is connected through shake drive belt (224) transmission with two shake cams (226).

9. An automated concrete tile production system according to claim 8, wherein: two shaking elastic pieces (115) which are symmetrically arranged are fixedly arranged on the lower surface of the guide chute (110), and the two shaking elastic pieces (115) are in contact sliding fit with the two shaking cams (226).

10. An automated concrete tile production system according to claim 9, wherein: and the workbench (3) is fixedly provided with a heating cover (203) for solidifying the formed concrete brick blocks, and the heating cover (203) is arranged above the conveying assembly (201).