CN212888214U - Intelligent manufacturing equipment for building wiring groove bricks - Google Patents

Intelligent manufacturing equipment for building wiring groove bricks Download PDF

Info

Publication number
CN212888214U
CN212888214U CN202021820215.5U CN202021820215U CN212888214U CN 212888214 U CN212888214 U CN 212888214U CN 202021820215 U CN202021820215 U CN 202021820215U CN 212888214 U CN212888214 U CN 212888214U
Authority
CN
China
Prior art keywords
brick
mold core
mold
groove
hydraulic cylinder
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Active
Application number
CN202021820215.5U
Other languages
Chinese (zh)
Inventor
莫诗原
林智勇
Original Assignee
林智勇
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 林智勇 filed Critical 林智勇
Priority to CN202021820215.5U priority Critical patent/CN212888214U/en
Application granted granted Critical
Publication of CN212888214U publication Critical patent/CN212888214U/en
Active legal-status Critical Current
Anticipated expiration legal-status Critical

Links

Abstract

An intelligent manufacturing device for building wiring groove bricks comprises a press, a brick mold, a feeding mechanical arm, a metering device, a rotary blanking valve, a storage bin, a brick discharging mechanical arm and a controller; during the use, utilize rotatory unloading valve to carry the metering device measurement with the brick material of feed bin, utilize metering device to carry the pay-off manipulator with the brick material after the measurement, utilize the pay-off manipulator to carry the brick mould with the brick material after the measurement, then utilize press and brick mould to press into building wiring groove brick with the brick material, recycle out the brick manipulator and carry the delivery wagon with building wiring groove brick on, and carry the warehouse with building wiring groove brick through the delivery wagon, solve the problem of making various building wiring groove bricks, reduce the waste of brickmaking resource and be favorable to environmental protection.

Description

Intelligent manufacturing equipment for building wiring groove bricks
Technical Field
The utility model relates to a manufacture equipment of brick, in particular to building wiring groove brick intelligence manufacture equipment.
Background
At present, when hydroelectric facilities are installed in a building, a plurality of grooves are drilled on a built brick wall by using a cutting machine and an impact drill, and then a lead pipe or a water pipe and the like are installed on the grooves; so construction, not only extravagant manpower resources causes air pollution, extravagant short brick making resource simultaneously, including extravagant brickmaking material and extravagant brickmaking energy, be unfavorable for environmental protection, a brand-new building wiring groove brick has become the needs that the building saved resources and environmental protection, needs a building wiring groove brick intelligent manufacturing equipment for making building wiring groove brick.
Disclosure of Invention
The utility model aims at overcoming the not enough of prior art, provide a building wiring groove brick intelligence manufacture equipment for producing building wiring groove brick, save building resources and be favorable to environmental protection.
The technical proposal adopted by the utility model is that: designing a brand new building wiring groove brick, wherein the building wiring groove brick comprises an angle-lacking brick, a straight groove brick, a narrow brick, a complete brick and an inclined groove brick, and the building wiring groove brick is formed by connecting the angle-lacking brick, the straight groove brick, the narrow brick, the complete brick and the inclined groove brick; the unfilled corner brick is provided with unfilled corner concave positions, the straight groove brick is provided with straight grooves, and the inclined groove brick is provided with inclined grooves; the length of the narrow bricks is the same as that of the unfilled corner bricks, the straight groove bricks and the inclined groove bricks, the width of the narrow bricks is smaller than that of the unfilled corner bricks, the straight groove bricks, the complete bricks and the inclined groove bricks, and the heights of the unfilled corner bricks, the straight groove bricks, the narrow bricks, the complete bricks and the inclined groove bricks are the same; the building wiring groove brick is provided with a plurality of wiring grooves, the plurality of wiring grooves comprise corner grooves, T-shaped grooves, linear grooves and inclined wire grooves, and the corner grooves are formed by corner-lacking concave positions of corner-lacking bricks and straight grooves of straight groove bricks; the T-shaped groove is formed by a straight groove of a straight groove brick and a front width position of a narrow brick; the linear groove is formed by a plurality of straight grooves of straight groove bricks, and the inclined line groove is formed by a plurality of inclined grooves of inclined groove bricks; the unfilled corner brick is provided with a concave corner, the concave corner is in a cuboid or square shape, the length and the width of the concave corner are smaller than those of the unfilled corner brick, and the height of the concave corner is the same as that of the unfilled corner brick; the concave angle comprises a front notch face and a side notch face, wherein the front notch face and the side notch face are perpendicular to each other, the front notch face of the concave angle is parallel to the front face of the notch brick in the length direction, and the side notch face of the concave angle is parallel to the side face of the notch brick in the width direction; the straight groove of the straight groove brick is in a cuboid or square shape, the length and the width of the straight groove are smaller than those of the straight groove brick, the height of the straight groove is the same as that of the straight groove brick, the straight groove comprises a left groove face, a right groove face and an inner groove face, the left groove face and the right groove face are perpendicular to the inner groove face, the inner groove face is parallel to the front face of the straight groove brick in the length direction, and the left groove face and the right groove face are parallel to the side face of the straight groove brick in the width direction; the inclined groove of the inclined groove brick comprises a left inclined groove surface, a right inclined groove surface and an inner groove surface, wherein the left inclined groove surface is parallel to the right inclined groove surface, the left inclined groove surface and the right inclined groove surface are inclined to the side surface of the inclined groove brick in the width direction, and the inner groove surface is parallel to the front surface of the inclined groove brick in the length direction; when the building wiring groove brick is used, a wiring diagram for building construction is designed before wall building, then the wall is built according to the wiring diagram, and according to the position of a wiring groove of the building wiring diagram, the wiring groove is built by using the unfilled brick, the straight groove brick, the narrow-width brick, the complete brick and the inclined groove brick, so that the wiring groove is drilled by using impact drilling after the wall building is avoided; reduce the waste of scarce brick material, avoid wasting and beating the wall expense and reduce dust pollution.
In order to manufacture the building wiring groove brick, intelligent manufacturing equipment for the building wiring groove brick is needed, and comprises a press, a brick mold, a feeding mechanical arm, a metering device, a rotary blanking valve, a storage bin, a brick discharging mechanical arm and a controller, wherein the brick mold is arranged on the press, the feeding mechanical arm and the brick discharging mechanical arm are arranged beside the press, the metering device is arranged below the rotary blanking valve, the rotary blanking valve is connected with the storage bin, and the storage bin is connected with a foundation;
the press comprises a frame, a driving cylinder, an upper pressure plate, a bottom plate and a hydraulic device; the driving cylinder is connected with the upper pressure plate, the upper pressure plate is connected with the rack in a movable fit manner, and the bottom plate is fixedly connected with the rack; the brick die comprises an upper die and a lower die, the upper die is fixedly connected with the upper pressing plate, and the lower die is fixedly connected with the bottom plate; the lower die comprises a die frame, a lower die core, a die holder, a first hydraulic cylinder, a second hydraulic cylinder, a third hydraulic cylinder, a fourth hydraulic cylinder and a fifth hydraulic cylinder, the die frame is connected with the lower die core in a movable fit manner, the lower die core is connected with the die holder, the die holder is connected with a bottom plate, the fifth hydraulic cylinder is arranged between the die frame and the bottom plate, a shell of the fifth hydraulic cylinder is connected with the die holder, and a driving rod of the fifth hydraulic cylinder is connected with the die frame; the lower mold core comprises a unfilled corner mold core, a straight groove mold core, a narrow mold core, an inclined groove mold core and a fixed mold core, wherein the unfilled corner mold core, the straight groove mold core, the inclined groove mold core and the narrow mold core are movably matched and connected with the mold frame and the fixed mold core; a driving rod of the first hydraulic cylinder is fixedly connected with the unfilled corner mold core, a shell of the first hydraulic cylinder is connected with the mold base, and the mold base is connected with the bottom plate; a driving rod of a second hydraulic cylinder is fixedly connected with the straight groove mold core, and a shell of the second hydraulic cylinder is connected with the mold base; a driving rod of a third hydraulic cylinder is fixedly connected with the inclined groove die core, and a shell of the third hydraulic cylinder is connected with the die holder; a driving rod of a fourth hydraulic cylinder is fixedly connected with the narrow mold core, and a shell of the fourth hydraulic cylinder is connected with the mold base; when in use, the measured brick material is pressed into the building wiring groove brick by using a brick die and a press;
the feeding manipulator comprises a first rotating motor, a first rotating arm and a discharging device, and the discharging device is arranged beside the metering device; the shell of the first rotating motor is fixedly connected with the rack, a rotating shaft of the first rotating motor is connected with a first rotating arm, and the first rotating arm is connected with the discharging device; the discharging device comprises a discharging groove, a discharging door and a discharging electric push rod, the discharging door is connected with the discharging groove in a movable fit manner, the shell of the discharging electric push rod is fixedly connected with the discharging groove, and the driving rod of the discharging electric push rod is connected with the discharging door; when in use, the measured brick materials are conveyed to the brick mold by the feeding mechanical arm;
the metering device comprises an electronic scale, a weighing hopper and an unloading electric push rod, wherein a base of the electronic scale is fixedly connected with a stock bin or a foundation, the weighing hopper is hinged with a weighing platform of the electronic scale, a shell of the unloading electric push rod is connected with the base of the electronic scale, and a driving rod of the unloading electric push rod is positioned below the weighing hopper; when the device is used, the driving rod of the discharging electric push rod is used for pushing the weighing hopper to incline, so that the metered bricks can flow to the discharging groove of the discharging device;
the brick discharging manipulator comprises a second rotating motor, a second rotating arm and a brick grabbing claw, wherein the shell of the second rotating motor is fixedly connected with the rack, the motor shaft of the second rotating motor is connected with the second rotating arm, and the second rotating arm is connected with the brick grabbing claw; when the brick grabbing device is used, the brick grabbing claw of the brick discharging manipulator is used for grabbing the bricks of the building wiring groove pressed by the brick die onto the conveying vehicle;
the controller comprises a press upper travel proximity switch, a press lower travel proximity switch, a swinging position sensor, a first mold core upper limit sensor, a first mold core lower limit sensor, a first mold core induction piece, a second mold core upper limit sensor, a second mold core lower limit sensor, a second mold core induction piece, a third mold core upper limit sensor, a third mold core lower limit sensor, a third mold core induction piece, a fourth mold core upper limit sensor, a fourth mold core lower limit sensor, a fourth mold core induction piece, a mold frame upper limit sensor, a mold frame lower limit sensor and a mold frame induction piece; the first die core upper limit sensor and the first die core lower limit sensor are arranged on a shell of the first hydraulic cylinder, and the first die core induction piece is arranged on a piston of the first hydraulic cylinder and used for controlling the stroke of the first hydraulic cylinder; the second die core upper limit sensor and the second die core lower limit sensor are arranged on a shell of a second hydraulic cylinder, and the second die core induction piece is arranged on a piston of the second hydraulic cylinder and used for controlling the stroke of the second hydraulic cylinder; a third die core upper limit sensor and a third die core lower limit sensor are arranged on a shell of a third hydraulic cylinder, and a third die core induction piece is arranged on a piston of the third hydraulic cylinder and used for controlling the stroke of the third hydraulic cylinder; a fourth die core upper limit sensor and a fourth die core lower limit sensor are arranged on a shell of a fourth hydraulic cylinder, and a fourth die core induction piece is arranged on a piston of the fourth hydraulic cylinder and used for controlling the stroke of the fourth hydraulic cylinder; the upper die frame limiting sensor and the lower die frame limiting sensor are arranged on the rack, and the die frame sensing piece is arranged on a driving rod of the fifth hydraulic cylinder; the controller is connected with the press, the feeding manipulator, the metering device, the rotary blanking valve, the press upper stroke proximity switch, the press lower stroke proximity switch, the swing-in position sensor, the swing-out position sensor, the first mold core upper limit sensor, the first mold core lower limit sensor, the second mold core upper limit sensor, the second mold core lower limit sensor, the third mold core upper limit sensor, the third mold core lower limit sensor, the fourth mold core upper limit sensor, the fourth mold core lower limit sensor, the mold frame upper limit sensor and the mold frame lower limit sensor through control lines; the intelligent manufacturing equipment is used for controlling the work of intelligent manufacturing equipment for the building wiring groove bricks.
The initial state of the brick mold is: the unfilled corner mold core, the straight groove mold core, the inclined groove mold core, the narrow mold core and the mold frame of the lower mold core are positioned at a lower limiting position, and the upper end surfaces of the unfilled corner mold core, the straight groove mold core, the inclined groove mold core, the narrow mold core and the mold frame of the lower mold core are flush with the upper end surface of the fixed mold core; a first mold core induction piece of the controller is close to a first mold core lower limit sensor, a second mold core induction piece is close to a second mold core lower limit sensor, a third mold core induction piece is close to a third mold core lower limit sensor, a fourth mold core induction piece is close to a fourth mold core lower limit sensor, and a mold frame induction piece is close to a mold frame lower limit sensor.
The use method of the intelligent manufacturing equipment for the building wiring groove bricks comprises the following steps: when in use, the weight of the brick material is set according to the unfilled corner bricks, straight groove bricks, narrow width bricks, complete bricks and inclined groove bricks with different specifications; when preparing the brick material, firstly, manufacturing the brick material by using brick material manufacturing equipment, and conveying the brick material to a storage bin, wherein the brick material is a non-solidified lime-sand mixture containing a small amount of moisture, or a non-solidified cement-lime-sand mixture containing a small amount of moisture; the controller controls the driving cylinder, the first hydraulic cylinder, the second hydraulic cylinder, the third hydraulic cylinder, the fourth hydraulic cylinder and the fifth hydraulic cylinder to work through the hydraulic device; when the building wiring groove brick is manufactured, a controller starts a press to work, after the press is started, the controller controls a driving cylinder to drive an upper pressing plate and an upper die to ascend, so that the upper die and a lower die of the brick die are separated, when the upper pressing plate approaches an upper stroke approach switch of the press, the upper stroke approach switch of the press transmits a signal to the controller, the controller controls the driving cylinder to stop driving the upper pressing plate and the upper die to ascend, and meanwhile, the controller controls a fifth hydraulic cylinder to drive a die frame of the lower die to ascend to an upper limit and stop;
when the building wiring groove bricks are manufactured, the brick materials in the storage bin are conveyed to a metering device by a rotary blanking valve to be metered according to the weight of the brick materials of the unfilled corner bricks, the straight groove bricks, the narrow width bricks, the complete bricks and the inclined groove bricks; after the metering device meters the brick materials, the metered brick materials are unloaded to a discharging device of the material conveying manipulator;
when the unfilled corner brick is manufactured, the controller controls the unfilled corner mold core of the lower mold core to ascend through the first hydraulic cylinder, so that the upper end face of the unfilled corner mold core is flush with the upper end face of the mold frame; after the unfilled corner mold core stops rising, the controller controls the feeding manipulator to feed the measured brick materials into a mold frame of a lower mold of the brick mold through the discharging device;
when the straight groove brick is manufactured, the controller controls the straight groove mold core of the lower mold core to ascend through the second hydraulic cylinder, so that the upper end surface of the straight groove mold core is flush with the upper end surface of the mold frame; after the straight groove mold core stops rising, the controller controls the feeding manipulator to feed the metered brick material into a mold frame of a lower mold of the brick mold through the discharging device;
when the inclined groove brick is manufactured, the controller controls the inclined groove mold core of the lower mold core to ascend through the third hydraulic cylinder, so that the upper end surface of the inclined groove mold core is flush with the upper end surface of the mold frame; after the inclined groove mold core stops rising, the controller controls the feeding manipulator to feed the measured brick materials into a mold frame of the lower mold of the brick mold through the discharging device;
when the narrow-width brick is manufactured, the controller controls the unfilled corner mold core, the straight groove mold core and the narrow-width mold core of the lower mold core to ascend through the first hydraulic cylinder, the second hydraulic cylinder and the fourth hydraulic cylinder, so that the upper end faces of the unfilled corner mold core, the straight groove mold core and the narrow-width mold core are flush with the upper end face of the mold frame; after the unfilled corner mold core, the straight groove mold core and the narrow mold core stop rising, the controller controls the feeding manipulator to feed the measured brick materials into a mold frame of the lower brick mold through the discharging device;
when the whole brick is manufactured, the controller controls the unfilled corner mold core, the straight groove mold core, the inclined groove mold core and the narrow mold core of the lower mold core to be positioned at the lower limiting position through the first hydraulic cylinder, the second hydraulic cylinder, the third hydraulic cylinder and the fourth hydraulic cylinder, so that the upper end faces of the unfilled corner mold core, the straight groove mold core, the inclined groove mold core and the narrow mold core of the lower mold core are flush with the upper end face of the fixed mold core; then, the controller controls the feeding manipulator to feed the measured brick materials into a mold frame of a lower mold of the brick mold through the discharging device;
when the building wiring groove brick is manufactured, after the measured brick material is conveyed into a cavity of a mold frame of a lower mold, a controller controls an upper pressure plate of a press to drive an upper mold to descend, after the upper mold and the lower mold are closed, the brick material in the mold frame is continuously compacted along with the continuous descending of the upper mold and the mold frame, when the brick material is compacted to a designed standard, the upper pressure plate is close to a lower stroke approach switch of the press, the lower stroke approach switch of the press transmits a signal to the controller, and the controller controls the upper pressure plate and the upper mold of the press to stop descending; after the upper pressure plate stops descending, the controller controls the upper pressure plate of the press to drive the upper die to ascend, when the upper pressure plate ascends to be close to the upper travel proximity switch of the press, the upper travel proximity switch of the press transmits a signal to the controller, and the controller controls the upper pressure plate of the press to stop ascending; after the upper pressing plate of the press stops rising, the controller controls a brick grabbing claw of the brick discharging manipulator to grab the building wiring groove bricks pressed by the brick die onto the conveying vehicle; and the process is continuously circulated.
The utility model has the advantages that: an intelligent manufacturing device for building wiring groove bricks comprises a press, a brick mold, a feeding mechanical arm, a metering device, a rotary blanking valve, a storage bin, a brick discharging mechanical arm and a controller; during the use, utilize rotatory unloading valve to carry the metering device measurement with the brick material of feed bin, utilize metering device to carry the pay-off manipulator with the brick material after the measurement, utilize the pay-off manipulator to carry the brick mould with the brick material after the measurement, then utilize press and brick mould to press into building wiring groove brick with the brick material, recycle out the brick manipulator and carry the delivery wagon with building wiring groove brick on, and carry the warehouse with building wiring groove brick through the delivery wagon, solve the problem of making various building wiring groove bricks, reduce the waste of brickmaking resource and be favorable to environmental protection.
Drawings
FIG. 1 is a schematic view of a brick wall of a construction wiring groove;
FIG. 2 is a schematic structural view of a corner-lacking tile;
FIG. 3 is a schematic structural view of a straight groove brick;
FIG. 4 is a schematic structural view of a narrow width brick;
FIG. 5 is a schematic view of the construction of a complete brick;
FIG. 6 is a schematic structural view of a slanted groove brick;
FIG. 7 is a schematic structural diagram of an intelligent manufacturing apparatus for building wiring groove bricks;
fig. 8 is a plan view of the lower mold of the brick mold.
Detailed Description
The invention will be further described with reference to the following detailed description of embodiments and with reference to the accompanying drawings:
the structure of the building wiring groove brick shown in fig. 1, the structure of the corner-lacking brick shown in fig. 2, the structure of the straight groove brick shown in fig. 3, the structure of the narrow width brick shown in fig. 4, the structure of the complete brick shown in fig. 5 and the structure of the inclined groove brick shown in fig. 6; designing a brand new building wiring groove brick, wherein the building wiring groove brick comprises a unfilled corner brick 1, a straight groove brick 2, a narrow brick 3, a complete brick 4 and an inclined groove brick 5, and the building wiring groove brick is formed by connecting the unfilled corner brick 1, the straight groove brick 2, the narrow brick 3, the complete brick 4 and the inclined groove brick 5; the unfilled corner brick 1 is provided with unfilled corner concave positions 6, the straight groove brick 2 is provided with straight grooves 7, and the inclined groove brick 5 is provided with inclined grooves 8; the length of the narrow bricks 3 is the same as that of the unfilled corner bricks 1, the straight groove bricks 2 and the inclined groove bricks 5, the width of the narrow bricks 3 is smaller than that of the unfilled corner bricks 1, the straight groove bricks 2, the complete bricks 4 and the inclined groove bricks 5, and the heights of the unfilled corner bricks 1, the straight groove bricks 2, the narrow bricks 3, the complete bricks 4 and the inclined groove bricks 5 are the same; the building wiring groove brick is provided with a plurality of wiring grooves 9, the plurality of wiring grooves 9 comprise corner grooves 10, T-shaped grooves 11, linear grooves 12 and inclined line grooves 13, and the corner grooves 10 are formed by corner-lacking concave positions 6 of corner-lacking bricks 1 and straight grooves 7 of straight groove bricks 2; the T-shaped groove 11 is formed by a straight groove 7 of the straight groove brick 2 and a front width position 14 of the narrow brick 3; the linear groove 12 is formed by a plurality of straight grooves 7 of the straight groove bricks 2, and the inclined groove 13 is formed by a plurality of inclined grooves 8 of the inclined groove bricks 5; the unfilled corner brick 1 is provided with a recessed corner 15, the recessed corner 15 is cuboid or cuboid, the length and the width of the recessed corner 15 are smaller than those of the unfilled corner brick 1, and the height of the recessed corner 15 is the same as that of the unfilled corner brick 1; the reentrant corner 15 comprises a front gap surface 16 and a side gap surface 17, wherein the front gap surface 16 is vertical to the side gap surface 17, the front gap surface 16 of the reentrant corner 15 is parallel to a front surface 18 of the reentrant corner brick 1 in the length direction, and the side gap surface 17 of the reentrant corner 15 is parallel to a side surface 19 of the reentrant corner brick 1 in the width direction; the straight groove 7 of the straight groove brick 2 is cuboid or cuboid, the length and the width of the straight groove 7 are smaller than those of the straight groove brick 2, the height of the straight groove 7 is the same as that of the straight groove brick 2, the straight groove 7 comprises a left groove face 20, a right groove face 21 and an inner groove face 22, the left groove face 20 and the right groove face 21 are perpendicular to the inner groove face 22, the inner groove face 22 is parallel to the front face 18 of the straight groove brick 2 in the length direction, and the left groove face 20 and the right groove face 21 are parallel to the side face 19 of the straight groove brick 2 in the width direction; the inclined groove 8 of the inclined groove brick 5 comprises a left inclined groove surface 23, a right inclined groove surface 24 and an inner groove surface 25, the left inclined groove surface 23 is parallel to the right inclined groove surface 24, the left inclined groove surface 23 and the right inclined groove surface 24 are inclined to the width direction side 19 of the inclined groove brick 5, and the inner groove surface 25 is parallel to the length direction front 18 of the inclined groove brick 5; when the building wiring groove brick is used, a wiring diagram for building construction is designed before wall building, then the wall is built according to the wiring diagram, and a wiring groove 9 is built by utilizing the unfilled corner brick 1, the straight groove brick 2, the narrow width brick 3, the complete brick 4 and the inclined groove brick 5 according to the position of the wiring groove of the building wiring diagram, so that the wiring groove 9 is drilled by utilizing impact drilling after the wall is prevented from being built; reduce the waste of scarce brick material, avoid wasting and beating the wall expense and reduce dust pollution.
Fig. 7 is a schematic structural view of an intelligent manufacturing apparatus for building wiring groove bricks, and fig. 8 is a top view of a lower mold of a brick mold; in order to manufacture the building wiring groove brick, an intelligent manufacturing device for the building wiring groove brick is needed, the intelligent manufacturing device for the building wiring groove brick comprises a press 31, a brick mold 32, a feeding manipulator 33, a metering device 34, a rotary blanking valve 35, a storage bin 36, a brick discharging manipulator 82 and a controller 37, wherein the brick mold 32 is installed on the press 31, the feeding manipulator 33 and the brick discharging manipulator 82 are installed beside the press 31, the metering device 34 is arranged below the rotary blanking valve 35, the rotary blanking valve 35 is connected with the storage bin 36, and the storage bin 36 is connected with a foundation; when the device is used, the rotary blanking valve 35 is used for conveying the brick material in the storage bin 36 to the metering device 34 for metering, after metering, the metering device 34 is used for conveying the brick material to the feeding mechanical arm 33, the feeding mechanical arm 33 is used for conveying the metered brick material to the brick die 32, then the press 31 and the brick die 32 are used for pressing the brick material into the architectural wiring groove brick 58, the brick discharging mechanical arm 82 is used for conveying the architectural wiring groove brick 58 to the conveying vehicle, and the conveying vehicle is used for conveying the architectural wiring groove brick 58 to the warehouse;
the press 31 comprises a frame 38, a driving cylinder 39, an upper pressure plate 40, a bottom plate 41 and a hydraulic device 42; the driving cylinder 39 is connected with an upper pressure plate 40, the upper pressure plate 40 is movably matched and connected with the rack 38, and the bottom plate 41 is fixedly connected with the rack 38; the brick die 32 comprises an upper die 43 and a lower die 44, wherein the upper die 43 is fixedly connected with the upper pressing plate 40, and the lower die 44 is fixedly connected with the bottom plate 41; the lower die 44 comprises a die frame 45, a lower die core 46, a die holder 47, a first hydraulic cylinder 48, a second hydraulic cylinder 49, a third hydraulic cylinder 50, a fourth hydraulic cylinder 77 and a fifth hydraulic cylinder 51, the die frame 45 is movably matched and connected with the lower die core 46, the lower die core 46 is connected with the die holder 47, the die holder 47 is connected with the bottom plate 41, the fifth hydraulic cylinder 51 is arranged between the die frame 45 and the bottom plate 41, the shell of the fifth hydraulic cylinder 51 is connected with the die holder 47, and a driving rod of the fifth hydraulic cylinder 51 is connected with the die frame 45; the lower mold core 46 comprises a unfilled corner mold core 52, a straight groove mold core 53, a narrow mold core 78, an inclined groove mold core 54 and a fixed mold core 55, wherein the unfilled corner mold core 52, the straight groove mold core 53, the inclined groove mold core 54 and the narrow mold core 78 are movably matched and connected with the mold frame 45 and the fixed mold core 55; a driving rod of the first hydraulic cylinder 48 is fixedly connected with the unfilled corner mold core 52, the shell of the first hydraulic cylinder 48 is connected with the mold base 47, and the mold base 47 is connected with the bottom plate 41; a driving rod of the second hydraulic cylinder 49 is fixedly connected with the straight groove mold core 53, the shell of the second hydraulic cylinder 49 is connected with the mold base 47, and the mold base 47 is connected with the bottom plate 41; a driving rod of the third hydraulic cylinder 50 is fixedly connected with the inclined groove mold core 54, a shell of the third hydraulic cylinder 50 is connected with the mold base 47, and the mold base 47 is connected with the bottom plate 41; a driving rod of a fourth hydraulic cylinder 77 is fixedly connected with the narrow mold core 78, the shell of the fourth hydraulic cylinder 77 is connected with the mold base 47, and the mold base 47 is connected with the bottom plate 41; when in use, the brick die 32 and the press 31 are utilized to press the metered brick material into the building wiring groove brick 58;
the feeding manipulator 33 comprises a first rotating motor 56, a first rotating arm 57 and a discharging device 59, wherein the discharging device 59 is arranged beside the metering device 34; the shell of the first rotating motor 56 is fixedly connected with the frame 38, the rotating shaft of the first rotating motor 56 is connected with a first rotating arm 57, and the first rotating arm 57 is connected with a discharging device 59; the discharging device 59 comprises a discharging groove 60, a discharging door 61 and a discharging electric push rod 62, the discharging door 61 is connected with the discharging groove 60 in a movable fit manner, the shell of the discharging electric push rod 62 is fixedly connected with the discharging groove 60, and the driving rod of the discharging electric push rod 62 is connected with the discharging door 61; when in use, the measured brick materials are conveyed to the brick die 32 by the feeding manipulator 33;
the metering device 34 comprises an electronic scale 83, a scale hopper 84 and an unloading electric push rod 85, wherein the base of the electronic scale 83 is fixedly connected with the stock bin 36 or a foundation, the scale hopper 84 is hinged with a scale platform 86 of the electronic scale 83, the shell of the unloading electric push rod 85 is connected with the base of the electronic scale 83, and a driving rod of the unloading electric push rod 85 is positioned below the scale hopper 84; when in use, the weighing hopper 84 is pushed to incline by the driving rod of the discharging electric push rod 85, so that the metered bricks can flow to the discharging groove 60 of the discharging device 59;
the brick discharging manipulator 82 comprises a second rotating motor 87, a second rotating arm 88 and a brick grabbing claw 89, wherein the shell of the second rotating motor 87 is fixedly connected with the rack 38, the motor shaft of the second rotating motor 87 is connected with the second rotating arm 88, and the second rotating arm 88 is connected with the brick grabbing claw 89; when in use, the brick grabbing claw 89 of the brick discharging manipulator 82 is utilized to grab the building wiring groove brick 58 pressed by the brick die 32 onto the conveying vehicle;
the controller 37 comprises a press upper stroke proximity switch 66, a press lower stroke proximity switch 63, a swing-in position sensor 64, a swing-out position sensor 65, a first mold core upper limit sensor 68, a first mold core lower limit sensor 69, a first mold core induction part 70, a second mold core upper limit sensor 71, a second mold core lower limit sensor 72, a second mold core induction part 73, a third mold core upper limit sensor 74, a third mold core lower limit sensor 75, a third mold core induction part 76, a fourth mold core upper limit sensor 79, a fourth mold core lower limit sensor 80, a fourth mold core induction part 81, a mold frame upper limit sensor 90, a mold frame lower limit sensor 91 and a mold frame induction part 92; a first upper die core limit sensor 68 and a first lower die core limit sensor 69 are mounted on the housing of the first hydraulic cylinder 48, and a first die core induction part 70 is mounted on the piston of the first hydraulic cylinder 48 for controlling the stroke of the first hydraulic cylinder 48; a second upper die core limit sensor 71 and a second lower die core limit sensor 72 are mounted on the housing of the second hydraulic cylinder 49, and a second die core sensing piece 73 is mounted on the piston of the second hydraulic cylinder 49 and used for controlling the stroke of the second hydraulic cylinder 49; a third upper die core limit sensor 74 and a third lower die core limit sensor 75 are mounted on the housing of the third hydraulic cylinder 50, and a third die core induction piece 76 is mounted on the piston of the third hydraulic cylinder 50 and used for controlling the stroke of the third hydraulic cylinder 50; a fourth upper die core limit sensor 79 and a fourth lower die core limit sensor 80 are mounted on the shell of the fourth hydraulic cylinder 77, and a fourth die core induction piece 81 is mounted on the piston of the fourth hydraulic cylinder 77 and used for controlling the stroke of the fourth hydraulic cylinder 77; a die frame upper limit sensor 90 and a die frame lower limit sensor 91 are mounted on the frame 38, and a die frame sensing member 92 is mounted on a driving rod of the fifth hydraulic cylinder 51; the controller 37 is connected with the press 31, the feeding manipulator 33, the metering device 34, the rotary blanking valve 35, the press upper stroke proximity switch 66, the press lower stroke proximity switch 63, the swing-in position sensor 64, the swing-out position sensor 65, the first mold core upper limit sensor 68, the first mold core lower limit sensor 69, the second mold core upper limit sensor 11, the second mold core lower limit sensor 72, the third mold core upper limit sensor 74, the third mold core lower limit sensor 75, the fourth mold core upper limit sensor 79, the fourth mold core lower limit sensor 80, the mold frame upper limit sensor 90 and the mold frame lower limit sensor 91 through control lines; the intelligent manufacturing equipment is used for controlling the work of intelligent manufacturing equipment for the building wiring groove bricks.
The initial state of the brick mold 32 is: the unfilled corner mold core 52, the straight groove mold core 53, the inclined groove mold core 54, the narrow mold core 78 and the mold frame 45 of the lower mold core 46 are positioned at the lower limiting position, and the upper end surfaces of the unfilled corner mold core 52, the straight groove mold core 53, the inclined groove mold core 54, the narrow mold core 78 and the mold frame 45 of the lower mold core 46 are flush with the upper end surface of the fixed mold core 55; the first core part 70 of the controller 37 is close to the first core lower limit sensor 69, the second core part 73 is close to the second core lower limit sensor 72, the third core part 76 is close to the third core lower limit sensor 75, the fourth core part 81 is close to the fourth core lower limit sensor 80, and the frame part 92 is close to the frame lower limit sensor 91.
The use method of the intelligent manufacturing equipment for the building wiring groove bricks comprises the following steps: when in use, the weight of brick materials is set according to unfilled corner bricks 1, straight groove bricks 2, narrow width bricks 3, complete bricks 4 and inclined groove bricks 5 with different specifications; when preparing the brick material, firstly, the brick material is manufactured by using brick material manufacturing equipment, and is conveyed to the storage bin 36, wherein the brick material is a non-solidified lime-sand mixture containing a small amount of moisture, or a non-solidified cement-lime-sand mixture containing a small amount of moisture; the controller 37 controls the operation of the driving cylinder 39, the first hydraulic cylinder 48, the second hydraulic cylinder 49, the third hydraulic cylinder 50, the fourth hydraulic cylinder 77 and the fifth hydraulic cylinder 51 through the hydraulic device 42;
when the building wiring groove brick 58 is manufactured, the controller 37 starts the press 31 to work, after the press 31 is started, the controller 37 controls the driving cylinder 39 to drive the upper pressing plate 40 and the upper die 43 to ascend, so that the upper die 43 of the brick die 32 is separated from the lower die 44, when the upper pressing plate 40 approaches the upper stroke approach switch 66 of the press, the upper stroke approach switch 66 of the press transmits a signal to the controller 37, the controller 37 controls the driving cylinder 39 to stop driving the upper pressing plate 40 and the upper die 43 to ascend, and meanwhile, the controller 37 controls the fifth hydraulic cylinder 51 to drive the die frame 45 of the lower die 44 to ascend to an upper limit and stop;
when the building wiring groove brick 58 is manufactured, according to the weight of brick materials of the unfilled corner brick 1, the straight groove brick 2, the narrow width brick 3, the complete brick 4 and the inclined groove brick 5, the brick materials in the storage bin 36 are conveyed to the metering device 34 by the rotary blanking valve 35 for metering; after the metering device 34 meters the brick material, the metered brick material is discharged to a discharging device 59 of the material conveying manipulator 33;
when the unfilled corner brick 1 is manufactured, the controller 37 controls the unfilled corner mold core 52 of the lower mold core 46 to ascend through the first hydraulic cylinder 48, so that the upper end face of the unfilled corner mold core 52 is flush with the upper end face of the mold frame 45; after the unfilled corner mold core 52 stops rising, the controller 37 controls the feeding manipulator 33 to feed the metered brick materials into the mold frame 45 of the lower mold 44 of the brick mold 32 through the discharging device 59;
when the straight groove brick 2 is manufactured, the controller 37 firstly controls the straight groove mold core 53 of the lower mold core 46 to ascend through the second hydraulic cylinder 49, so that the upper end surface of the straight groove mold core 53 is flush with the upper end surface of the mold frame 45; after the straight groove mold core 53 stops rising, the controller 37 controls the feeding manipulator 33 to feed the metered brick materials into the mold frame 45 of the lower mold 44 of the brick mold 32 through the discharging device 59;
when the inclined groove brick 5 is manufactured, the controller 37 controls the inclined groove mold core 54 of the lower mold core 46 to ascend through the third hydraulic cylinder 50, so that the upper end surface of the inclined groove mold core 54 is flush with the upper end surface of the mold frame 45; after the inclined groove mold core 54 stops rising, the controller 37 controls the feeding manipulator 33 to feed the metered brick materials into the mold frame 45 of the lower mold 44 of the brick mold 32 through the discharging device 59;
when the narrow-width brick 3 is manufactured, the controller 37 controls the unfilled corner mold core 52, the straight groove mold core 53 and the narrow-width mold core 78 of the lower mold core 46 to ascend through the first hydraulic cylinder 48, the second hydraulic cylinder 49 and the fourth hydraulic cylinder 77, so that the upper end faces of the unfilled corner mold core 52, the straight groove mold core 53 and the narrow-width mold core 78 are flush with the upper end face of the mold frame 45; after the unfilled corner mold core 52, the straight groove mold core 53 and the narrow mold core 78 stop rising, the controller 37 controls the feeding manipulator 33 to feed the measured brick materials into the mold frame 45 of the lower mold 44 of the brick mold 32 through the discharging device 59;
when the whole brick 4 is manufactured, the controller 37 controls the unfilled corner mold core 52, the straight groove mold core 53, the inclined groove mold core 54 and the narrow width mold core 78 of the lower mold core 46 to be at the lower limit position through the first hydraulic cylinder 48, the second hydraulic cylinder 49, the third hydraulic cylinder 50 and the fourth hydraulic cylinder 77, so that the upper end surfaces of the unfilled corner mold core 52, the straight groove mold core 53, the inclined groove mold core 54 and the narrow width mold core 78 of the lower mold core 46 are flush with the upper end surface of the fixed mold core 55; then, the controller 37 controls the feeding manipulator 33 to feed the measured brick materials into the mold frame 45 of the lower mold 44 of the brick mold 32 through the discharging device 59;
when the building wiring groove brick 58 is manufactured, after the metered brick material is conveyed into a cavity of a mold frame 45 of a lower mold 44, a controller 37 controls an upper pressure plate 40 of a press 31 to drive an upper mold 43 to descend, after the upper mold 43 and the lower mold 44 are closed, the brick material in the mold frame 45 is continuously compacted along with the continuous descending of the upper mold 43 and the mold frame 45, when the brick material is compacted to a designed standard, the upper pressure plate 40 approaches a lower stroke approach switch 63 of the press, the lower stroke approach switch 63 of the press transmits a signal to the controller 37, and the controller 37 controls the upper pressure plate 40 and the upper mold 43 of the press 31 to stop descending;
after the upper pressing plate 40 stops descending, the controller 37 controls the upper pressing plate 40 of the press 31 to drive the upper die 43 to ascend, when the upper pressing plate 40 ascends to be close to the upper stroke approach switch 66 of the press, the upper stroke approach switch 66 of the press transmits a signal to the controller 37, and the controller 37 controls the upper pressing plate 40 of the press 31 to stop ascending;
after the upper pressing plate 40 of the press 31 stops rising, the controller 37 controls the brick grabbing claw 89 of the brick discharging manipulator 82 to grab the architectural wiring groove brick 58 pressed by the brick mold 32 onto the conveying vehicle 69; and the process is continuously circulated.
The use method of the intelligent manufacturing equipment for the building wiring groove bricks comprises the following steps: before the upper pressing plate 40 of the press 31 drives the upper die 43 to press downwards, the controller 37 controls the fifth hydraulic cylinder 51 to drive the die frame 45 to ascend, when the die frame sensing piece 92 on the driving rod of the fifth hydraulic cylinder 51 approaches the die frame upper limit sensor 90, the die frame upper limit sensor 90 transmits a signal thereof to the controller 37, and the controller 37 controls the fifth hydraulic cylinder 51 to stop; after the fifth hydraulic cylinder 51 stops, the mold frame 45 stops rising, and the controller 37 controls the feeding manipulator 33 to convey the metered brick material into the cavity of the mold frame 45;
after the measured brick materials are conveyed into the cavity of the mold frame 45, the controller 37 controls the upper pressing plate 40 of the press 31 to drive the upper mold 43 to press downwards, and after the upper mold 43 is jointed with the mold frame 45 and pressed into the mold frame 45, the controller 37 controls the fifth hydraulic cylinder 51 to drive the mold frame 45 and the upper mold 43 to synchronously descend; when the brick material is pressed into the building wiring groove brick 58, the upper pressing plate 40 approaches the lower stroke approach switch 63 of the press, the lower stroke approach switch 63 of the press transmits a signal to the controller 37, and the controller 37 controls the upper pressing plate 40 to stop pressing; after the upper pressure plate 40 stops pressing down, the fifth hydraulic cylinder 51 drives the mold frame 45 to continuously descend, when the upper end face of the mold frame 45 descends to be flush with the upper end face of the fixed mold core 55, the mold frame sensing piece 92 on the driving rod of the fifth hydraulic cylinder 51 approaches the mold frame lower limit sensor 91, the mold frame lower limit sensor 91 transmits a signal of the mold frame lower limit sensor to the controller 37, the controller 37 controls the fifth hydraulic cylinder 51 to stop descending, and the mold frame 45 stops descending; after the fifth hydraulic cylinder 51 stops descending, the controller 37 controls the brick discharging manipulator 82 to grab the construction wiring groove bricks 58 pressed by the brick mold 32 onto the conveying vehicle through the brick grabbing claws 89; after the building wiring groove brick 58 is grabbed on the conveying vehicle, the controller 37 controls the fifth hydraulic cylinder 51 to drive the mold frame 45 to ascend, when the mold frame 45 ascends to the upper limit, the mold frame sensing piece 92 on the driving rod of the fifth hydraulic cylinder 51 approaches the mold frame upper limit sensor 90, the mold frame upper limit sensor 90 transmits a signal to the controller 37, the fifth hydraulic cylinder 51 of the controller 37 stops ascending, and the mold frame 45 stops ascending; and the process is continuously circulated.
The use method of the intelligent manufacturing equipment for the building wiring groove bricks comprises the following steps: when the straight groove brick 2 is manufactured, the controller 37 controls the fifth hydraulic cylinder 51 to drive the mold frame 45 to ascend to the upper limit and then stop; meanwhile, the controller 37 controls the second hydraulic cylinder 49 to drive the straight groove mold core 53 to ascend, the second mold core induction part 73 on the piston of the second hydraulic cylinder 49 is close to the second mold core lower limit sensor 72, the second mold core lower limit sensor 72 transmits a signal to the controller 37, the controller 37 controls the second hydraulic cylinder 49 to stop ascending, the straight groove mold core 53 stops ascending, and the upper end face of the straight groove mold core 53 is flush with the upper end face of the mold frame 45; after the straight groove mold core 53 is lifted and stopped, the controller 37 controls the metering device 34 to meter the brick material according to the designed weight of the straight groove brick 2, and controls the feeding manipulator 33 to convey the metered brick material into the cavity of the mold frame 45; after the measured brick materials are conveyed into the mold frame 45, the controller 37 drives the upper mold 43 and the upper mold 43 to press downwards by controlling the upper pressing plate 40 of the press 31, and when the upper mold 43 is jointed with the mold frame 45 and pressed into the mold frame 45 with the depth of 5 mm to 10 mm, the controller 37 controls the second hydraulic cylinder 49 to drive the straight groove mold core 53 to descend synchronously along with the upper mold 43 and the mold frame 45; when the density of the brick material pressed by the upper die 43 in the die frame 45 reaches the design requirement, the upper pressing plate 40 approaches the lower stroke approach switch 63 of the press, the lower stroke approach switch 63 of the press transmits a signal to the controller 37, the controller 37 controls the upper pressing plate 40 of the press 31 to stop pressing down, and the upper die 43 stops pressing down; after the upper pressing plate 40 stops pressing down, the controller 37 controls the upper pressing plate 40 and the upper die 43 of the press 31 to ascend, when the upper pressing plate 40 ascends to the upper limit, the upper pressing plate 40 approaches the upper stroke approach switch 66 of the press, the upper stroke approach switch 66 of the press transmits a signal to the controller 37, and the upper pressing plate 40 of the press 31 of the controller 37 stops ascending; after the upper press plate 40 stops rising, the controller 37 controls the second hydraulic cylinder 49 to drive the straight-groove mold core 53 to descend, when the straight-groove mold core 53 descends to an initial position, the second mold core induction part 73 on the piston of the second hydraulic cylinder 49 approaches the second mold core lower limit sensor 72, the second mold core lower limit sensor 72 transmits a signal to the controller 37, and the controller 37 controls the straight-groove mold core 53 to stop descending through the second hydraulic cylinder 49; meanwhile, the controller 37 controls the fifth hydraulic cylinder 51 to drive the mold frame 45 to descend, and when the mold frame 45 descends until the upper end surface of the mold frame is flush with the upper end surface of the fixed mold core 55, the controller 37 controls the fifth hydraulic cylinder 51 to stop descending, and the mold frame 45 stops descending; after the fifth hydraulic cylinder 51 stops descending, the controller 37 controls the brick discharging manipulator 82 to grab the straight-groove brick 2 pressed by the brick mold 32 onto the conveying vehicle 69 through the brick grabbing claw 89 thereof.
The use method of the intelligent manufacturing equipment for the building wiring groove bricks comprises the following steps: when the unfilled corner brick 1 is manufactured, the controller 37 controls the fifth hydraulic cylinder 51 to drive the mold frame 45 to ascend to the upper limit and then stop; meanwhile, the controller 37 controls the first hydraulic cylinder 48 to drive the unfilled corner mold core 52 to ascend, when the first mold core induction part 70 on the piston of the first hydraulic cylinder 48 approaches the first mold core lower limit sensor 69, the first mold core lower limit sensor 69 transmits a signal to the controller 37, the controller 37 controls the first hydraulic cylinder 48 to stop ascending, and the unfilled corner mold core 52 stops ascending; meanwhile, the controller 37 controls and controls the second hydraulic cylinder 49 to drive the straight groove mold core 53 to ascend to the upper limit and then stop, so that the upper end surfaces of the unfilled corner mold core 52 and the straight groove mold core 53 are flush with the upper end surface of the mold frame 45; after the unfilled corner mold core 52 stops rising, the controller 37 controls the metering device 34 to meter the brick material according to the designed weight of the unfilled corner brick 1, and controls the feeding manipulator 33 to convey the metered brick material into the cavity of the mold frame 45; after the measured brick materials are conveyed into the mold frame 45, the controller 37 controls the upper pressing plate 40 of the press 31 to drive the upper mold 43 to press downwards, and when the upper mold 43 is jointed with the mold frame 45 and pressed into the mold frame 45 with the depth of 5 mm to 10 mm, the controller 37 controls the first hydraulic cylinder 48 to drive the unfilled corner mold core 52 to synchronously descend along with the upper mold 43 and the mold frame 45; when the density of the brick material in the mold frame 45 after being pressed by the upper mold 43 reaches the design requirement, the upper pressing plate 40 approaches the lower stroke approach switch 63 of the press, the lower stroke approach switch 63 of the press transmits a signal to the controller 37, the controller 37 controls the upper pressing plate 40 of the press 31 to stop pressing down, and the upper mold 43 stops pressing down; after the upper platen 40 stops pressing, the controller 37 controls the upper platen 40 and the upper die 43 of the press 31 to ascend, and when the upper platen 40 ascends to the upper limit, the controller 37 stops ascending the upper platen 40 of the press 31; after the upper press plate 40 stops rising, the controller 37 controls the first hydraulic cylinder 48 to drive the unfilled corner mold core 52 to descend, when the unfilled corner mold core 52 descends to an initial position, the first mold core induction part 70 on the piston of the first hydraulic cylinder 48 approaches the first mold core lower limit sensor 69, the first mold core lower limit sensor 69 transmits a signal thereof to the controller 37, and the controller 37 controls the unfilled corner mold core 52 to stop descending through the first hydraulic cylinder 48; meanwhile, the fifth hydraulic cylinder 51 of the controller 37 drives the mold frame 45 to descend, and when the mold frame 45 descends until the upper end surface of the mold frame is flush with the upper end surface of the fixed mold core 55, the controller 37 controls the fifth hydraulic cylinder 51 to stop descending, and the mold frame 45 stops descending; after the fifth hydraulic cylinder 51 stops descending, the controller 37 controls the brick discharging manipulator 82 to grab the unfilled corner brick 1 pressed by the brick mold 32 onto the conveying vehicle 69 through the brick grabbing claw 89.
The use method of the intelligent manufacturing equipment for the building wiring groove bricks comprises the following steps: when the inclined groove brick 5 is manufactured, the controller 37 controls the fifth hydraulic cylinder 51 to drive the mold frame 45 to ascend to the upper limit and then stop; meanwhile, the controller 37 controls the third hydraulic cylinder 50 to drive the inclined groove mold core 54 to ascend, a third mold core induction piece 76 on a piston of the third hydraulic cylinder 50 is close to a third mold core upper limit sensor 74, the third mold core upper limit sensor 74 transmits a signal to the controller 37, the controller 37 controls the third hydraulic cylinder 50 to stop ascending, the inclined groove mold core 54 stops ascending, and the upper end face of the inclined groove mold core 54 is aligned with the upper end face of the mold frame 45; after the inclined groove mold core 54 is lifted and stopped, the controller 37 controls the metering device 34 to meter the brick material according to the designed weight of the inclined groove brick 5, and controls the feeding manipulator 33 to convey the metered brick material into the cavity of the mold frame 45; after the measured brick materials are conveyed into the mold frame 45, the controller 37 drives the upper mold 43 and the upper mold 43 to press downwards by controlling the upper pressing plate 40 of the press 31, and when the upper mold 43 is jointed with the mold frame 45 and pressed into the mold frame 45 with the depth of 5 mm to 10 mm, the controller 37 controls the third hydraulic cylinder 50 to drive the inclined groove mold core 54 to synchronously descend along with the upper mold 43 and the mold frame 45; when the density of the brick material pressed by the upper die 43 in the die frame 45 reaches the design requirement, the upper pressing plate 40 approaches the lower stroke approach switch 63 of the press, the lower stroke approach switch 63 of the press transmits a signal to the controller 37, the controller 37 controls the upper pressing plate 40 of the press 31 to stop pressing down, and the upper die 43 stops pressing down; after the upper platen 40 stops pressing, the controller 37 controls the upper platen 40 and the upper die 43 of the press 31 to ascend, and when the upper platen 40 ascends to the upper limit, the controller 37 stops ascending the upper platen 40 of the press 31; after the upper press plate 40 stops rising, the controller 37 controls the third hydraulic cylinder 50 to drive the inclined groove mold core 54 to descend, when the inclined groove mold core 54 descends to an initial position, the third mold core induction part 76 on the piston of the third hydraulic cylinder 50 approaches the third mold core lower limit sensor 75, the third mold core lower limit sensor 75 transmits a signal thereof to the controller 37, and the controller 37 controls the inclined groove mold core 54 to stop descending through the third hydraulic cylinder 50; meanwhile, the controller 37 controls the fifth hydraulic cylinder 51 to drive the mold frame 45 to descend, and when the mold frame 45 descends until the upper end surface of the mold frame is flush with the upper end surface of the fixed mold core 55, the controller 37 controls the fifth hydraulic cylinder 51 to stop descending, and the mold frame 45 stops descending; after the fifth hydraulic cylinder 51 stops descending, the controller 37 controls the brick discharging manipulator 82 to grab the inclined groove bricks 5 pressed by the brick mold 32 onto the conveying vehicle 69 through the brick grabbing claws 89 thereof.
The use method of the intelligent manufacturing equipment for the building wiring groove bricks comprises the following steps: when the narrow brick 3 is manufactured, the controller 37 controls the fifth hydraulic cylinder 51 to drive the mold frame 45 to ascend to the upper limit and then stop; meanwhile, the controller 37 controls the fourth hydraulic cylinder 77 to drive the narrow mold core 78 to ascend, when the fourth mold core induction piece 81 on the piston of the fourth hydraulic cylinder 77 approaches to the fourth mold core upper limit sensor 79, the fourth mold core upper limit sensor 79 transmits a signal to the controller 37, the controller 37 controls the fourth hydraulic cylinder 77 to stop ascending, and the narrow mold core 78 stops ascending; meanwhile, the controller 37 controls the first hydraulic cylinder 48 to drive the unfilled corner mold core 52 to ascend and controls the second hydraulic cylinder 49 to drive the straight groove mold core 53 to ascend to an upper limit, and then the operation is stopped, so that the upper end surfaces of the unfilled corner mold core 52, the straight groove mold core 53 and the narrow mold core 78 are flush with the upper end surface of the mold frame 45;
after the unfilled corner mold core 52, the straight groove mold core 53 and the narrow mold core 78 stop rising, the controller 37 controls the metering device 34 to meter the brick material according to the designed weight of the narrow brick 3, and controls the feeding manipulator 33 to convey the metered brick material into the cavity of the mold frame 45; after the measured brick materials are conveyed into the mold frame 45, the controller 37 drives the upper mold 43 to press downwards by controlling the upper pressing plate 40 of the press 31, and when the upper mold 43 is jointed with the mold frame 45 and pressed into the mold frame 45 with the depth of 5 mm to 10 mm, the controller 37 controls the first hydraulic cylinder 48 to drive the unfilled corner mold core 52, controls the second hydraulic cylinder 49 to drive the straight groove mold core 53 and controls the fourth hydraulic cylinder 77 to drive the narrow width mold core 78 to synchronously descend along with the upper mold 43 and the mold frame 45;
when the density of the brick material pressed by the upper die 43 in the die frame 45 reaches the design requirement, the upper pressing plate 40 approaches the lower stroke approach switch 63 of the press, the lower stroke approach switch 63 of the press transmits a signal to the controller 37, and the controller 37 controls the upper pressing plate 40 of the press 31 to stop pressing; after the upper platen 40 stops pressing, the controller 37 controls the upper platen 40 and the upper die 43 of the press 31 to ascend, and when the upper platen 40 ascends to the upper limit, the controller 37 stops ascending the upper platen 40 of the press 31;
after the upper press plate 40 stops rising, the controller 37 controls the fourth hydraulic cylinder 77 to drive the narrow mold core 78 to descend, when the fourth mold core induction part 81 on the piston of the fourth hydraulic cylinder 77 approaches the fourth mold core lower limit sensor 80, the fourth mold core lower limit sensor 80 transmits a signal to the controller 37, the controller 37 controls the fourth hydraulic cylinder 77 to stop descending, and the narrow mold core 78 stops descending; meanwhile, the controller 37 controls the first hydraulic cylinder 48 to drive the unfilled corner mold core 52 to descend and controls the second hydraulic cylinder 49 to drive the straight groove mold core 53 to descend to a lower limit position, so that the upper end surfaces of the unfilled corner mold core 52, the straight groove mold core 53 and the narrow width mold core 78 are flush with the upper end surface of the fixed mold core 55, and the unfilled corner mold core 52, the straight groove mold core 53 and the narrow width mold core 78 are reset to an initial state;
meanwhile, the controller 37 controls the fifth hydraulic cylinder 51 to drive the mold frame 45 to descend, and when the mold frame 45 descends until the upper end surface of the mold frame is flush with the upper end surface of the fixed mold core 55, the controller 37 controls the fifth hydraulic cylinder 51 to stop descending, and the mold frame 45 stops descending; after the fifth hydraulic cylinder 51 stops descending, the controller 37 controls the brick discharging robot 82 to grab the narrow bricks 3 pressed by the brick mold 32 onto the conveying vehicle 69 by the brick grabbing claws 89 thereof.
A chute 60 for feeding the brick material after measurement to a discharging device 59 in order to measure and convey the brick material by the measuring device 34; one end of a scale hopper 84 of the metering device 34 is hinged with a scale platform 86 of the electronic scale 83, and the other end of the scale hopper 84 is positioned above a driving rod of a discharging electric push rod 85; the controller 37 is provided with an upper metering limit sensor 93 and a metering reset sensor 94, and the upper metering limit sensor 93 and the metering reset sensor 94 are installed on the rotary blanking valve 35 through a mounting plate; the initial state of the metering device 34 is: the driving rod of the discharging electric push rod 85 is in a non-extending state, the driving rod of the discharging electric push rod 85 is not contacted with the other end of the scale hopper 84, one end of the scale hopper 84 is close to the metering reset sensor 94, and the other end of the scale hopper 84 is not close to the metering upper limit sensor 93.
To convey the brick material to the position of the brick mold 32 by the discharging device 59 of the feeding robot 33; the controller 37 is provided with a swing-in position sensor 64 and a swing-out position sensor 65, the swing-out position sensor 65 is installed outside the rack 38, and the swing-in position sensor 64 is installed inside the rack 38; the initial state of the feeding robot 33 is: the discharging groove 60 of the discharging device 59 is positioned outside the frame 38, and the discharging groove 60 of the discharging device 59 is positioned below the weighing hopper 84; the discharge chute 60 approaches the swing-out position sensor 65; the initial state of the discharge gate 61 of the discharge device 59 is: the discharging door 61 is in a closed state, the driving rod of the discharging electric push rod 62 is in an extending state, and the driving rod of the discharging electric push rod 62 pushes the discharging door 61 to be closed.
When the metering device 34 meters, the controller 37 controls the rotary blanking valve 35 to rotate, the brick material is placed below the weighing hopper 84, when the blanking weight reaches a set value, the electronic scale 83 transmits a signal that the blanking weight reaches the set value to the controller 37 through a data output port of the electronic scale, the controller 37 controls the rotary blanking valve 35 to stop blanking, after the rotary blanking valve 35 stops blanking, the controller 37 controls a driving rod of an unloading electric push rod 85, the driving rod is used for pushing the weighing hopper 84 upwards to swing around a hinge shaft hinged with the weighing platform 86, so that the weighing hopper 84 is inclined, and the brick material of the weighing hopper 84 is unloaded to the discharging groove 60 of the feeding manipulator 33; when the other end of the scale hopper 84 approaches the upper metering limit sensor 93, the upper metering limit sensor 93 transmits a signal to the controller 37, and the controller 37 controls the discharging electric push rod 85 to stop extending; when the brick material of the scale hopper 84 is discharged to the discharging chute 60 of the feeding manipulator 33, the controller 37 controls the discharging electric push rod 85 to retract, when one end of the scale hopper 84 approaches the metering reset sensor 94, the metering reset sensor 94 transmits a signal to the controller 37, and the controller 37 controls the discharging electric push rod 85 to stop.
When the feeding manipulator 33 feeds materials, after the brick materials of the weighing hopper 84 are unloaded to the discharging groove 60 of the feeding manipulator 33, the controller 37 controls the first rotating motor 56 to drive the discharging device 59 to rotate, the discharging groove 60 of the discharging device 59 rotates into the frame 38 of the press 31, and when the discharging groove 60 is aligned with the brick mold 32, the discharging groove 60 approaches the swinging-in position sensor 64, the swinging-in position sensor 64 transmits a signal to the controller 37, and the controller 37 controls the first rotating motor 56 to stop; after the first rotating motor 56 stops, the controller 37 controls the discharging electric push rod 62 to drive the driving rod to retract, and pulls the discharging door 61 on the discharging groove 60 to open, so that the brick material in the discharging groove 60 flows into the cavity of the lower die 44 of the brick die 32; after the brick material in the discharging groove 60 flows into the lower die 44 of the brick die 32, the controller 37 controls the discharging electric push rod 62 to drive the rod to extend, and the push discharging door 61 is closed; meanwhile, the first rotating motor 56 is controlled to drive the discharging device 59 to reset and rotate, so that the discharging groove 60 rotates out of the rack 38, when the discharging groove 60 resets to the initial state, when the discharging groove 60 approaches the swing-out position sensor 65, the swing-out position sensor 65 transmits a signal to the controller 37, and the controller 37 controls the first rotating motor 56 to stop.
In order to utilize the discharging device 59 to vibrate and level the bricks which are put down to the brick mold 32, the discharging device 59 is provided with a discharging vibration device 97, the discharging vibration device 97 comprises a vibration sieve 98 and a first vibration motor 99, the vibration sieve 98 is connected with the discharging groove 60 in a movable fit manner, the vibration sieve 98 is arranged on the discharging groove 60, a base of the first vibration motor 99 is fixedly connected with the discharging groove 60, and a vibration head of the first vibration motor 99 is connected with the vibration sieve 98; before the discharging device 59 discharges materials to the lower die 44 of the brick die 32, the controller 37 controls the first vibrating motor 99 to drive the vibrating screen 98 to vibrate through the vibrating head of the first vibrating motor, so that the brick materials in the discharging groove 60 of the discharging device 59 are vibrated to be flat, and the brick materials can uniformly fall into the lower die 44 of the brick die 32.
In order to further vibrate and level the bricks which are put down to the brick mold 32, the lower mold 44 of the brick mold 32 comprises a mold vibrating device 100, the mold vibrating device 100 comprises a second vibrating motor 103 and a top mold hydraulic cylinder 104, the mold base 47 comprises a vibrating mold base 101 and a fixed mold base 102, the fixed mold base 102 is provided with a conical groove 105, and the vibrating mold base 101 is provided with a conical boss 106; the fixed die holder 102 is fixedly connected with the bottom plate 41, the vibration die holder 101 is movably matched and connected with the fixed die holder 102, a conical boss 106 of the vibration die holder 101 is movably matched and connected with a conical groove 105 of the fixed die holder 102, a top die hydraulic cylinder 104 is installed on the fixed die holder 102, a driving rod of the top die hydraulic cylinder 104 is contacted with the conical boss 106 of the vibration die holder 101 through a spring, a base of a second vibration motor 103 is fixedly connected with the fixed die holder 102, and a vibration head of the second vibration motor 103 is connected with the vibration die holder 101; the initial state of the mold oscillation device 100 is: the drive rod of the top die hydraulic cylinder 104 is in an unextended state; the initial state of the die holder 47 is: the conical boss 106 of the vibration die holder 101 is in contact with the conical groove 105 of the fixed die holder 102, and the conical boss 106 of the vibration die holder 101 is sleeved with the conical groove 105 of the fixed die holder 102.
When the mold vibration device 100 is used, after the brick material of the material discharge groove 60 is placed into the cavity of the lower mold 44, the controller 37 controls the driving rod of the mold ejecting hydraulic cylinder 104 to extend out to eject the vibration mold base 101 to the set height and then stop, so that the conical boss 106 of the vibration mold base 101 is separated from the conical groove 105 of the fixed mold base 102, and a gap is reserved between the conical boss 106 and the conical groove 105; after the die ejecting hydraulic cylinder 104 ejects the vibration die holder 101, the controller 37 controls the second vibration motor 103 to drive the vibration die holder 101 to vibrate through the vibration head, and stops after vibrating and leveling the brick in the cavity of the lower die 44; after the second vibration motor 103 is stopped, the controller 37 controls the driving rod of the top die hydraulic cylinder 104 to retract to the initial state, and the vibration die holder 101 is reset to the initial state, so that the tapered boss 106 is combined with the tapered groove 105.
In order to convey the pressed wiring groove bricks to the conveying vehicle 69 by using the brick discharging manipulator 82, the brick discharging manipulator 82 is provided with a lifting oil cylinder 107 and an arm spreading oil cylinder 108, the shell of the lifting oil cylinder 107 is connected with the rack 38, a driving rod of the lifting oil cylinder 107 is connected with the shell of a second rotating motor 87, the motor shaft of the second rotating motor 87 is connected with the shell of the arm spreading oil cylinder 108, and a driving rod of the arm spreading oil cylinder 108 is connected with a second rotating arm 88; the controller 37 controls the lifting and the rotation of the brick grasping claw 89 through the lifting oil cylinder 107 and the arm spreading oil cylinder 108, controls the power motor of the brick grasping claw 89 to work, and utilizes the power motor to grasp and release the brick grasping claw 89 to the building wiring groove bricks 58.
In order to control the operation of the press 31, the brick mold 32, the feeding manipulator 33, the metering device 34, the rotary blanking valve 35, the bin 36 and the brick discharging manipulator 82 by using the controller 37, the hydraulic device 42 is connected with the driving cylinder 39, the first hydraulic cylinder 48, the second hydraulic cylinder 49, the third hydraulic cylinder 50, the fourth hydraulic cylinder 77, the fifth hydraulic cylinder 51, the top mold hydraulic cylinder 104 lifting cylinder 107 and the arm spreading cylinder 108 through pipelines, and the controller 37 is connected with the hydraulic device 42 through control lines and used for controlling the operation of the hydraulic device 42.

Claims (10)

1. The utility model provides a building wiring groove brick intelligence manufacture equipment which characterized in that: the intelligent manufacturing equipment for the building wiring groove bricks comprises a press (31), a brick mold (32), a feeding manipulator (33), a metering device (34), a rotary blanking valve (35), a storage bin (36), a brick discharging manipulator (82) and a controller (37), wherein the brick mold (32) is installed on the press (31), the feeding manipulator (33) and the brick discharging manipulator (82) are installed beside the press (31), the metering device (34) is arranged below the rotary blanking valve (35), the rotary blanking valve (35) is connected with the storage bin (36), and the storage bin (36) is connected with a foundation; the press (31) comprises a frame (38), a driving cylinder (39), an upper pressure plate (40), a bottom plate (41) and a hydraulic device (42); the driving cylinder (39) is connected with the upper pressure plate (40), the upper pressure plate (40) is movably matched and connected with the rack (38), and the bottom plate (41) is fixedly connected with the rack (38);
the brick die (32) comprises an upper die (43) and a lower die (44), the upper die (43) is fixedly connected with the upper pressing plate (40), and the lower die (44) is fixedly connected with the bottom plate (41); the lower die (44) comprises a die frame (45), a lower die core (46), a die holder (47), a first hydraulic cylinder (48), a second hydraulic cylinder (49), a third hydraulic cylinder (50), a fourth hydraulic cylinder (77) and a fifth hydraulic cylinder (51), the die frame (45) is movably matched and connected with the lower die core (46), the lower die core (46) is connected with the die holder (47), the die holder (47) is connected with the bottom plate (41), the fifth hydraulic cylinder (51) is arranged between the die frame (45) and the bottom plate (41), a shell of the fifth hydraulic cylinder (51) is connected with the die holder (47), and a driving rod of the fifth hydraulic cylinder (51) is connected with the die frame (45); the lower mold core (46) comprises a unfilled corner mold core (52), a straight groove mold core (53), a narrow mold core (78), an inclined groove mold core (54) and a fixed mold core (55), wherein the unfilled corner mold core (52), the straight groove mold core (53), the inclined groove mold core (54) and the narrow mold core (78) are movably matched and connected with the mold frame (45) and the fixed mold core (55); a driving rod of the first hydraulic cylinder (48) is fixedly connected with the unfilled corner mold core (52), a shell of the first hydraulic cylinder (48) is connected with the mold base (47), and the mold base (47) is connected with the bottom plate (41); a driving rod of a second hydraulic cylinder (49) is fixedly connected with a straight groove mold core (53), the shell of the second hydraulic cylinder (49) is connected with a mold base (47), and the mold base (47) is connected with a bottom plate (41); a driving rod of a third hydraulic cylinder (50) is fixedly connected with the inclined groove mold core (54), a shell of the third hydraulic cylinder (50) is connected with the mold base (47), and the mold base (47) is connected with the bottom plate (41); a driving rod of a fourth hydraulic cylinder (77) is fixedly connected with the narrow mold core (78), the shell of the fourth hydraulic cylinder (77) is connected with the mold base (47), and the mold base (47) is connected with the bottom plate (41);
the feeding manipulator (33) comprises a first rotating motor (56), a first rotating arm (57) and a discharging device (59), and the discharging device (59) is arranged beside the metering device (34); the shell of the first rotating motor (56) is fixedly connected with the rack (38), the rotating shaft of the first rotating motor (56) is connected with the first rotating arm (57), and the first rotating arm (57) is connected with the discharging device (59); the discharging device (59) comprises a discharging groove (60), a discharging door (61) and a discharging electric push rod (62), the discharging door (61) is movably matched and connected with the discharging groove (60), the shell of the discharging electric push rod (62) is fixedly connected with the discharging groove (60), and the driving rod of the discharging electric push rod (62) is connected with the discharging door (61);
the metering device (34) comprises an electronic scale (83), a scale hopper (84) and an unloading electric push rod (85), wherein the base of the electronic scale (83) is fixedly connected with the stock bin (36) or a foundation, the scale hopper (84) is hinged with a scale platform (86) of the electronic scale (83), the shell of the unloading electric push rod (85) is connected with the base of the electronic scale (83), and a driving rod of the unloading electric push rod (85) is positioned below the scale hopper (84); the brick discharging manipulator (82) comprises a second rotating motor (87), a second rotating arm (88) and a brick grabbing claw (89), the shell of the second rotating motor (87) is fixedly connected with the rack (38), the motor shaft of the second rotating motor (87) is connected with the second rotating arm (88), and the second rotating arm (88) is connected with the brick grabbing claw (89);
the controller (37) comprises a press upper-stroke proximity switch (66), a press lower-stroke proximity switch (63), a swing-in position sensor (64), a swing-out position sensor (65), a first mold core upper limit sensor (68), a first mold core lower limit sensor (69), a first mold core induction piece (70), a second mold core upper limit sensor (71), a second mold core lower limit sensor (72), a second mold core induction piece (73), a third mold core upper limit sensor (74), a third mold core lower limit sensor (75), a third mold core induction piece (76), a fourth mold core upper limit sensor (79), a fourth mold core lower limit sensor (80), a fourth mold core induction piece (81), a mold frame upper limit sensor (90), a mold frame lower limit sensor (91) and a mold frame induction piece (92).
2. The intelligent building wiring groove brick manufacturing equipment according to claim 1, characterized in that: the initial state of the brick mould (32) is as follows: the unfilled corner mold core (52), the straight groove mold core (53), the inclined groove mold core (54), the narrow mold core (78) and the mold frame (45) of the lower mold core (46) are located at a lower limiting position, and the upper end faces of the unfilled corner mold core (52), the straight groove mold core (53), the inclined groove mold core (54), the narrow mold core (78) and the mold frame (45) of the lower mold core (46) are flush with the upper end face of the fixed mold core (55).
3. The intelligent building wiring groove brick manufacturing equipment as claimed in claim 2, wherein: one end of a weighing hopper (84) of the metering device (34) is hinged with a weighing platform (86) of an electronic scale (83), and the other end of the weighing hopper (84) is positioned above a driving rod of a discharging electric push rod (85); the controller (37) is provided with a metering upper limit sensor (93) and a metering reset sensor (94), and the metering upper limit sensor (93) and the metering reset sensor (94) are arranged on the rotary blanking valve (35) through a mounting plate; the initial state of the metering device (34) is: the driving rod of the discharging electric push rod (85) is in a non-extending state.
4. The intelligent building wiring groove brick manufacturing equipment according to claim 3, characterized in that: the controller (37) is provided with a swinging-in position sensor (64) and a swinging-out position sensor (65), the swinging-out position sensor (65) is installed outside the rack (38), and the swinging-in position sensor (64) is installed inside the rack (38); the initial state of the feeding manipulator (33) is as follows: the discharge chute (60) of the discharge device (59) is positioned outside the frame (38), and the discharge chute (60) of the discharge device (59) is positioned below the side of the weighing hopper (84).
5. The intelligent building wiring groove brick manufacturing equipment according to claim 4, characterized in that: the initial state of a discharging door (61) of the discharging device (59) is as follows: the discharging door (61) is in a closed state, the driving rod of the discharging electric push rod (62) is in an extending state, and the driving rod of the discharging electric push rod (62) pushes the discharging door (61) to be closed.
6. The intelligent building wiring groove brick manufacturing equipment according to claim 5, wherein: blowing device (59) be equipped with unloading vibrating device (97), unloading vibrating device (97) include by shale shaker (98) and first vibrating motor (99), shale shaker (98) are connected with blowing groove (60) movable fit, the higher authority of blowing groove (60) is located in shale shaker (98), the frame and the blowing groove (60) fixed connection of first vibrating motor (99), the vibrating head and the shale shaker (98) of first vibrating motor (99) are connected.
7. The intelligent building wiring groove brick manufacturing equipment according to claim 6, wherein: the lower die (44) of the brick die (32) comprises a die vibration device (100), the die vibration device (100) comprises a second vibration motor (103) and a top die hydraulic cylinder (104), the die holder (47) comprises a vibration die holder (101) and a fixed die holder (102), the fixed die holder (102) is provided with a conical groove (105), and the vibration die holder (101) is provided with a conical boss (106); the fixed die holder (102) is fixedly connected with the bottom plate (41), the vibration die holder (101) is movably matched and connected with the fixed die holder (102), a conical boss (106) of the vibration die holder (101) is movably matched and connected with a conical groove (105) of the fixed die holder (102), the top die hydraulic cylinder (104) is installed on the fixed die holder (102), a driving rod of the top die hydraulic cylinder (104) is in contact with the conical boss (106) of the vibration die holder (101), a base of the second vibration motor (103) is fixedly connected with the fixed die holder (102), and a vibration head of the second vibration motor (103) is connected with the vibration die holder (101).
8. The intelligent building wiring groove brick manufacturing equipment according to claim 7, characterized in that: the initial state of the die vibration device (100) is as follows: a driving rod of the top die hydraulic cylinder (104) is in a non-extending state; the initial state of the die holder (47) is: the conical boss (106) of the vibration die holder (101) is in contact with the conical groove (105) of the fixed die holder (102), and the conical boss (106) of the vibration die holder (101) is sleeved with the conical groove (105) of the fixed die holder (102).
9. The intelligent building wiring channel brick manufacturing equipment according to claim 8, wherein: go out brick manipulator (82) be equipped with lift cylinder (107) and exhibition arm hydro-cylinder (108), the shell and the frame (38) of lift cylinder (107) are connected, the actuating lever and the shell of second rotation motor (87) of lift cylinder (107) are connected, the motor shaft of second rotation motor (87) is connected with the shell of exhibition arm hydro-cylinder (108), the actuating lever and the second rocking arm (88) of exhibition arm hydro-cylinder (108) are connected.
10. The intelligent building wiring channel brick manufacturing equipment according to claim 9, wherein: the hydraulic device (42) is connected with the driving cylinder (39), the first hydraulic cylinder (48), the second hydraulic cylinder (49), the third hydraulic cylinder (50), the fourth hydraulic cylinder (77), the fifth hydraulic cylinder (51), the top die hydraulic cylinder (104), the lifting oil cylinder (107) and the arm spreading oil cylinder (108) through pipelines.
CN202021820215.5U 2020-08-26 2020-08-26 Intelligent manufacturing equipment for building wiring groove bricks Active CN212888214U (en)

Priority Applications (1)

Application Number Priority Date Filing Date Title
CN202021820215.5U CN212888214U (en) 2020-08-26 2020-08-26 Intelligent manufacturing equipment for building wiring groove bricks

Applications Claiming Priority (1)

Application Number Priority Date Filing Date Title
CN202021820215.5U CN212888214U (en) 2020-08-26 2020-08-26 Intelligent manufacturing equipment for building wiring groove bricks

Publications (1)

Publication Number Publication Date
CN212888214U true CN212888214U (en) 2021-04-06

Family

ID=75250738

Family Applications (1)

Application Number Title Priority Date Filing Date
CN202021820215.5U Active CN212888214U (en) 2020-08-26 2020-08-26 Intelligent manufacturing equipment for building wiring groove bricks

Country Status (1)

Country Link
CN (1) CN212888214U (en)

Similar Documents

Publication Publication Date Title
CN205364147U (en) Wet forming device futilely of rostone
CN205009369U (en) Ceramic molding equipment
CN212888214U (en) Intelligent manufacturing equipment for building wiring groove bricks
CN112025963A (en) Intelligent manufacturing equipment for building wiring groove bricks
CN112171877A (en) Use method of intelligent manufacturing equipment for building wiring groove bricks
CN106626003A (en) Processing method for baking-free brick extrusion forming
CN207747210U (en) Pretensioning prestressed concrete track board assembly line pours vibrating system
CN111993537B (en) Automatic production line for refractory ceramic plates
CN102085690B (en) Full-automatic concrete board die casting machine
CN111037711A (en) Hollow brick production system
CN100569473C (en) A kind of ceramic forming press distribution device and distributing method thereof
CN211194296U (en) Automatic unloader that goes up of refractory material press robot
CN209868901U (en) Full-automatic stone-like brick machine
CN206154480U (en) Convertible concrete member make -up machine
CN111231092B (en) Use method of environment-friendly recycled brick intelligent production line
CN212736466U (en) Intelligent green brick production line for building wiring groove
CN108189209A (en) High-precision refractory material is weighed cloth integrated system and distributing method automatically
CN213288568U (en) New energy automobile power assembly sand mould 3D printer based on thing networking
CN108015884A (en) Building waste application hard board one-shaper
CN204640483U (en) A kind of automatic feeding device of refractory brick mould
CN111152354B (en) Intelligent production line for environment-friendly recycled bricks
CN211682668U (en) Automatic feeding refractory brick press
CN212331390U (en) Environment-friendly recycled brick
CN207930841U (en) A kind of automatic demoulding vibration brick making machine for producing high-alumina brick
CN206436345U (en) A kind of concrete brickmaking exciting forming machine

Legal Events

Date Code Title Description
GR01 Patent grant
GR01 Patent grant