CN112405821A - Intelligent concrete block building equipment - Google Patents

Abstract

For solving above-mentioned technical problem, an intelligence concrete block equipment, including the installation component, the transmission case, agitating unit, material feeding unit, forming device, install other device through the installation component, the transmission case distributes the transmission, agitating unit treats the powder of building block and mixes stirring and ration and sees off, material feeding unit accomplishes the transportation of powder, ration output and moist, forming device carries out automatic vibration molding and unloading in order to save time to the moist powder of ration, the human cost, accomplish the function of the automatic building block of concrete, its characterized in that: the stirring device is fixedly arranged on the mounting component, the transmission case is fixedly arranged in the mounting component, the feeding device is fixedly arranged on the transmission case, and the forming device is fixedly arranged on the mounting component.

Description

Intelligent concrete block building equipment

Technical Field

The invention relates to a building block device, in particular to an intelligent concrete building block device.

Background

With the progress of the development era of science and technology, more and more high-end equipment is introduced into our lives and works, in the building industry, concrete needs to be subjected to block forming for being used as a main material of a building in some cases, and in order to save the time cost of feeding and transportation, the raw material cost wasted due to low block quality, the labor cost and the like required in the block forming process, the intelligent concrete block equipment is invented.

Disclosure of Invention

The invention relates to a building block, in particular to intelligent concrete building block equipment.

For solving above-mentioned technical problem, an intelligence concrete block equipment, including the installation component, the transmission case, agitating unit, material feeding unit, forming device, install other device through the installation component, the transmission case distributes the transmission, agitating unit treats the powder of building block and mixes stirring and ration and sees off, material feeding unit accomplishes the transportation of powder, ration output and moist, forming device carries out automatic vibration molding and unloading in order to save time to the moist powder of ration, the human cost, accomplish the function of the automatic building block of concrete, its characterized in that: the stirring device is fixedly arranged on the mounting component, the transmission case is fixedly arranged in the mounting component, the feeding device is fixedly arranged on the transmission case, and the forming device is fixedly arranged on the mounting component.

As a further optimization of the technical scheme, the mounting assembly of the intelligent concrete block equipment comprises a stirring table, a transmission box cover, a feeding and measuring cover and a forming support.

As a further optimization of the technical scheme, the transmission case of the intelligent concrete block device comprises a first stirring belt wheel, a first spiral bevel gear, a first feeding bevel gear, a first forming belt wheel, a first sliding gear, a first spline shaft, a first gear, a second sliding gear, a first synchronous belt, a first belt wheel, a second spline shaft, a first shaft, a second synchronous belt, a third belt wheel, a first cam shaft, a third gear, a second shaft, a third sliding gear, a first shifting fork, a third shaft, a fourth gear, a fourth shaft, a fifth gear, a sixth gear, a second shifting fork, a fifth shaft, a second cam, a seventh gear, a fourth belt wheel, a third synchronous belt, a sixth shaft, a seventh shaft, an eighth shaft, a duplicate gear, a eighth gear, a fourth sliding gear, a third spline shaft, a third belt wheel, a sixth belt wheel, a fourth belt wheel, a seventh belt wheel, a first small belt wheel, a small synchronous belt and a, a spiral bevel gear I is fixedly arranged on a belt pulley V, a feeding bevel gear I is fixedly arranged on a gear VI, a forming belt pulley I is fixedly arranged on a shaft II, a sliding gear I is slidably arranged on a spline shaft I which is rotatably arranged in the transmission box cover through a bearing, the gear I is fixedly arranged on the spline shaft I, a gear II is fixedly arranged on the spline shaft I, the sliding gear II is slidably arranged on the spline shaft II, a synchronous belt I is frictionally arranged on the belt pulley I, the belt pulley I is fixedly arranged on the spline shaft II, the belt pulley II is fixedly arranged on the spline shaft II, the spline shaft II is rotatably arranged in the transmission box cover through a bearing, the shaft I is rotatably arranged in the transmission box cover through a bearing, the synchronous belt II is frictionally arranged on the belt pulley II, a belt pulley III is frictionally arranged on the synchronous belt II, a cam shaft, a shaft II is rotatably arranged inside a transmission case cover through a bearing, a third sliding gear is slidably arranged on a spline shaft II, a first shifting fork is slidably arranged on a third sliding gear, a shaft III is rotatably arranged inside the transmission case cover through the bearing, a fourth gear is fixedly arranged on a third gear, a shaft IV is rotatably arranged inside the transmission case cover through the bearing, a fifth gear is fixedly arranged on a fourth shaft, a fifth gear is meshed with a fourth gear, a sixth gear is fixedly arranged on the fourth shaft, a sixth gear is meshed with the first sliding gear, a second shifting fork is slidably arranged on the first sliding gear, the fifth shaft is rotatably arranged inside the transmission case cover through the bearing, a second cam is fixedly arranged on the fifth shaft, a seventh gear is meshed with the first sliding gear, a fourth belt pulley is fixedly arranged on the fifth shaft, a third synchronous belt is frictionally arranged on the fourth belt pulley, and a sixth shaft is rotatably arranged, the shaft seven is rotatably installed inside the transmission case cover through a bearing, the shaft eight is rotatably installed inside the transmission case cover through a bearing, the duplicate gear is installed and fixed on the shaft eight, the gear eight is installed and fixed on the shaft seven, the gear eight is meshed with the duplicate gear, the sliding gear four is slidably installed on the spline shaft three, the spline shaft three is rotatably installed inside the transmission case cover through a bearing, the shifting fork three is slidably installed on the sliding gear four, the belt wheel five is installed and fixed on the spiral bevel gear one, the cam three is installed and fixed on the shaft six, the belt wheel six is installed and fixed on the shaft six, the synchronous belt four is frictionally installed on the belt wheel five, the belt wheel seven is frictionally installed on the synchronous belt four, the small belt wheel one is installed and fixed on the shaft six, the small synchronous belt wheel one is frictionally installed on the small belt wheel one, the small belt wheel two is. .

As a further optimization of the technical scheme, the stirring device of the intelligent concrete block equipment comprises a stirring feed inlet, a feeding sliding plate, a stirring support frame, a stirring tank, a stirring blade, a tank gear I, a tank gear II, a belt pulley eight, a bearing seat I, a bevel gear shaft II, a belt pulley nine, a synchronous belt five, a bearing seat II and a gear nine, wherein the stirring feed inlet is fixedly installed on the stirring support frame, the feeding sliding plate is fixedly installed on the stirring support frame, the stirring support frame is fixedly installed on a stirring table, the stirring tank is rotatably installed on the stirring support frame through a bearing, the stirring blade is fixedly installed inside the stirring tank, the tank gear I is fixedly installed on the stirring tank, the tank gear II is fixedly installed on the stirring tank, the belt pulley eight is fixedly installed on the bevel gear shaft I, the bearing seat I is fixedly installed on the stirring table, and the bevel gear shaft I is rotatably, the bevel gear shaft II is meshed with the bevel gear shaft I, the belt wheel nine is fixedly arranged on the bevel gear shaft II, the synchronous belt five is frictionally arranged on the belt wheel nine, the bearing block II is fixedly arranged on the stirring table, and the gear nine is fixedly arranged on the bevel gear shaft II.

As a further optimization of the technical scheme, the feeding device of the intelligent concrete block equipment comprises a feeding pipe, a spiral feeding cavity, a first end cover, a pulley cover, a second end cover, a third conical gear shaft, a bevel gear, a tenth pulley, a third bearing seat, a sixth synchronous belt, a eleventh pulley, a screw rod, a pushing block, a water spraying pipe, a first bearing, a spiral feeding rod, a spiral discharging port, a spiral feeding port, a second bearing, a twelfth pulley, a seventh synchronous belt and a thirteenth pulley, wherein the feeding pipe is fixedly arranged on the spiral feeding cavity, the feeding pipe is fixedly arranged on the feeding cover, the spiral feeding cavity is fixedly arranged on a transmission box cover, the end cover is fixedly arranged on the spiral feeding cavity, the pulley cover is fixedly arranged on the second end cover, the second end cover is fixedly arranged on the spiral feeding cavity, the third conical gear shaft is rotatably arranged on the pulley cover through a bearing, and the third conical gear shaft is meshed with the first spiral conical gear, the bevel gear is installed and fixed on a screw rod, the bevel gear is meshed with a feeding bevel gear I, a belt wheel ten is installed and fixed on the screw rod, a bearing seat III is installed and fixed on a material pushing block, a synchronous belt six is installed on the belt wheel ten in a friction mode, a belt wheel eleven is installed on the synchronous belt six in a friction mode, the screw rod is installed on the material pushing block through a bearing seat III in a rotating mode, the screw rod is installed on a material feeding and measuring cover through a bearing, the material pushing block is installed inside the material feeding and measuring cover in a sliding mode, a water spraying pipe is installed and fixed on the material pushing block, a bearing I is installed and fixed inside an end cover I, a spiral feeding rod is installed inside a spiral feeding cavity through a bearing I and a bearing II in a rotating mode, a spiral discharging hole is formed in the spiral feeding cavity, a spiral feeding hole, the belt wheel thirteen is frictionally mounted on the synchronous belt seven.

As a further optimization of the technical scheme, the forming device of the intelligent concrete block equipment comprises a limit stop, a lifting table, a lower screw rod, a slide rail, a screw nut I, a bearing seat IV, a bevel gear shaft IV, a belt wheel fourteen, a synchronous belt eight, a belt wheel fifteen, a shaft nine, a cam IV, a spline shaft IV, a sliding gear V, a synchronous belt nine, a belt wheel sixteen, a shifting fork IV, a gear ten, a belt wheel seventeen, a bevel gear shaft V, a gear eleven, a gear twelve, a bevel gear shaft VI, a belt wheel eighteen, an upper screw rod, a synchronous belt ten, an upper screw rod nut, a lifting frame, a bearing seat V, an eccentric shaft, a pin, a clamping block, a forming cavity, a vibrating rod, a pressing plate clamping groove, a pressing plate, a partition plate, a lower supporting plate, a wheel shaft hole, a bevel gear shaft VII, a gear thirteen, a synchronous belt eleven, a vibrating groove, a hook, the lower screw is installed on a first screw nut in a threaded mode, the sliding rail is installed and fixed on the forming support, the first screw nut is installed and fixed on the lifting platform, a fourth bearing seat is installed and fixed on the sliding rail, and a fourth bevel gear shaft is installed on the forming support in a rotating mode through a bearing. A belt wheel fourteen is fixedly arranged on a bevel gear shaft IV, a synchronous belt eight is frictionally arranged on the belt wheel fourteen, a belt wheel fifteen is frictionally arranged on the synchronous belt eight, a shaft nine is rotatably arranged on a forming bracket through a bearing, a cam IV is fixedly arranged on the shaft nine, a spline shaft IV is rotatably arranged on the forming bracket through a bearing, a sliding gear V is slidably arranged on the spline shaft IV, the synchronous belt nine is frictionally arranged on a belt wheel sixteen, the belt wheel sixteen is fixedly arranged on the spline shaft IV, a shifting fork IV is slidably arranged on the sliding gear V, a gear is tentatively arranged and fixed on the shaft nine, a belt wheel seventeen is frictionally arranged and fixed on the shaft nine, the bevel gear shaft V is rotatably arranged on the forming bracket through a bearing, the bevel gear shaft V is meshed with the bevel gear shaft VII, a gear eleven is fixedly arranged on the bevel gear shaft IV, and the bevel gear V is fixedly arranged on a lower, the bevel gear shaft five and the bevel gear shaft four are meshed, a belt wheel eighteen is fixedly installed on an upper screw rod, an upper screw rod is installed on an upper screw rod nut in a threaded mode, a synchronous belt ten is installed on the belt wheel eighteen in a friction mode, the upper screw rod nut is fixedly installed on a lifting frame, a bearing seat five is fixedly installed on the lifting frame, an eccentric shaft is installed on the lifting frame in a rotating mode through the bearing seat five, a clamping block is installed on the eccentric shaft through a pin hinge, a forming cavity is fixedly installed on the upper screw rod, a vibrating rod is fixedly installed on the clamping block, a clamping plate clamping groove is formed in a clamping plate, the clamping plate is slidably installed on the vibrating rod, a separating plate is fixedly installed on a lower supporting plate in a sliding mode, a wheel shaft hole is formed in the lower supporting plate, a bevel gear shaft seven is fixedly installed on the upper screw rod, a gear thirteen is.

As a further optimization of the technical scheme, the number of the foot cup device bearing seats II and the number of the gears nine are four.

As a further optimization of the technical scheme, the forming device of the intelligent concrete block equipment provided by the invention is provided with two upper screw rods, two synchronous belts, two upper screw rod nuts, two bearing seats, two eccentric shafts and two wheel shafts.

The intelligent concrete block building equipment has the beneficial effects that:

the invention relates to a building block device, in particular to an intelligent concrete building block device, which realizes the purposes that other devices are installed through an installation assembly, a transmission box distributes transmission, a stirring device performs mixing stirring and quantitative sending out on powder to be built, a feeding device completes the transferring, quantitative outputting and wetting of the powder, and a forming device performs automatic vibration forming and blanking on the powder after quantitative wetting so as to save time and labor cost and complete the function of automatic building of concrete.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

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

Fig. 2 is a schematic view of the overall structure of the present invention.

Fig. 3 is a third schematic view of the overall structure of the present invention.

Fig. 4 is a fourth overall structural diagram of the present invention.

Fig. 5 is a schematic structural view of the mounting assembly of the present invention.

Fig. 6 is a first structural diagram of the transmission case of the present invention.

FIG. 7 is a second structural schematic diagram of the paint spraying and rust removing device of the present invention.

FIG. 8 is a third structural schematic diagram of the paint spraying and rust removing device of the invention.

Fig. 9 is a first structural schematic diagram of the stirring device of the present invention.

FIG. 10 is a schematic structural diagram of a stirring device according to the present invention.

Fig. 11 is a first structural schematic diagram of the feeding device of the present invention.

Fig. 12 is a second schematic structural diagram of the feeding device of the present invention.

FIG. 13 is a first schematic structural diagram of a molding apparatus of the present invention.

FIG. 14 is a second schematic structural diagram of a molding apparatus of the present invention.

FIG. 15 is a third schematic structural view of a molding apparatus of the present invention.

In the figure: mounting the assembly 1; 1-1 of a stirring table; a transmission case cover 1-2; feeding and measuring cover 1-3; forming a support 1-4; a transmission case 2; 2-1 of a stirring belt wheel; 2-2 parts of a spiral bevel gear; feeding bevel gears I2-3; forming a first belt wheel 2-4; 2-5 of a first sliding gear; 2-6 parts of a spline shaft I; 2-7 parts of a first gear; 2-8 parts of a second gear; 2-9 parts of a second sliding gear; 2-10 parts of a synchronous belt I; 2-11 of a belt wheel I; 2-12 of a second belt wheel; 2-13 of a spline shaft II; a first shaft 2-14; 2-15 parts of a synchronous belt II; belt wheels III 2-16; 2-17 parts of a camshaft I; gear three 2-18; shaft two 2-19; 2-20 parts of a third sliding gear; 2-21 parts of a shifting fork I; shaft three 2-22; gears four 2-23; shaft four 2-24; 2-25 parts of a gear; six gears 2-26; 2-27 of a second shifting fork; shaft five 2-28; 2-29 parts of a second cam; 2-30 parts of a gear wheel seven; belt wheels four 2-31; 2-32 parts of synchronous belt III; shaft six 2-33; shaft seven 2-34; shaft eight 2-35; duplicate gears 2-36; eight gears 2-37; 2-38 of a sliding gear; spline shaft III 2-39; 2-40 parts of a shifting fork III; belt wheel five 2-41; cams three 2-42; six belt wheels 2-43; 2-44 parts of synchronous belt; seven belt wheels 2-45; 2-26 of a small belt wheel I; 2-27 parts of a small synchronous belt; 2-48 of a small belt wheel II; a stirring device 3; a stirring feed port 3-1; 3-2 of a feeding sliding plate; 3-3 of a stirring support frame; 3-4 parts of a stirring tank; 3-5 parts of stirring blades; 3-6 parts of a first tank gear; 3-7 parts of a second tank gear; eight belt wheels 3-8; 3-9 parts of a first bearing seat; 3-10 parts of a bevel gear shaft I; 3-11 parts of a second bevel gear shaft; nine 3-12 pulleys; 3-13 parts of a synchronous belt; 3-14 parts of a second bearing seat; nine 3-15 parts of gear; a feeding device 4; a material conveying pipe 4-1; a spiral feeding cavity 4-2; 4-3 of a first end cover; 4-4 of a pulley cover; 4-5 parts of a second end cover; 4-6 parts of a bevel gear shaft; 4-7 of bevel gears; ten 4-8 belt wheels; 4-9 parts of a bearing block III; 4-10 parts of a synchronous belt; eleven belt wheels 4-11; 4-12 parts of a lead screw; 4-13 parts of a material pushing block; 4-14 parts of a water spraying pipe; 4-15 parts of a bearing I; 4-16 parts of a spiral feeding rod; 4-17 of a spiral discharge port; 4-18 parts of a spiral feeding port; a second bearing 4-19; twelve belt wheels 4-20; 4-21 parts of a synchronous belt; thirteen 4-22 pulleys; a molding device 5; a limit stop 5-1; a lifting platform 5-2; 5-3 parts of a lower screw rod; 5-4 of a slide rail; 5-5 parts of a first lead screw nut; bearing seats IV 5-6; a bevel gear shaft IV is 5-7; fourteen belt wheels are 5-8; eight 5-9 synchronous belts; fifteen 5-10 belt wheels; nine shafts 5-11; 5-12 parts of cam; spline shaft four 5-13; 5-14 parts of a sliding gear; 5-15 parts of a synchronous belt; sixteen belt wheels 5-16; a fourth shifting fork 5-17; ten gears 5-18; seventeen 5-19 pulleys; 5-20 parts of a bevel gear shaft; eleven gears 5-21; twelve gears 5-22; a cone gear shaft six 5-23; eighteen 5-24 pulleys; 5-25 parts of upper screw rod; 5-26 parts of synchronous belt; 5-27 parts of upper screw nut; 5-28 of a lifting frame; 5-29 parts of a bearing seat; 5-30 parts of an eccentric shaft; 5-31 parts of pin; 5-32 parts of fixture block; 5-33 parts of forming cavity; 5-34 parts of a vibrating rod; 5-35 parts of a clamp plate clamping groove; 5-36 parts of a pressing plate; 5-37 parts of partition board; 5-38 parts of lower supporting plate; 5-39 axle holes; 5-40 parts of a bevel gear shaft seven; thirteen gears 5-41; 5-42 parts of synchronous belt eleven; 5-43 parts of vibration groove; 5-44 of hook groove; 5-45 parts of wheel shaft.

Detailed Description

The first embodiment is as follows:

in order to solve the technical problems, the following intelligent concrete block equipment comprises an installation component 1, a transmission case 2, a stirring device 3, a feeding device 4, a forming device 5, and other devices are installed through the installation component 1, the transmission case 2 distributes transmission, the stirring device 3 mixes and stirs powder to be treated by the building blocks and sends out the powder quantitatively, the feeding device 4 completes the transfer, quantitative output and wetting of the powder, the forming device 5 performs automatic vibration forming and blanking on the powder after quantitative wetting so as to save time and labor cost, and the automatic concrete block equipment is characterized in that: the stirring device 3 is fixedly arranged on the mounting component 1, the transmission case 2 is fixedly arranged in the mounting component 1, the feeding device 4 is fixedly arranged on the transmission case 2, and the forming device 5 is fixedly arranged on the mounting component 1.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, and 15, and the embodiment is further described, in which the mounting assembly 1 includes a stirring table 1-1, a transmission case cover 1-2, a feeding and measuring cover 1-3, and a forming bracket 1-4.

The third concrete implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14 and 15, and the embodiment is further described, wherein the transmission case 2 comprises a stirring pulley I2-1, a spiral bevel gear I2-2, a feeding bevel gear I2-3, a forming pulley I2-4, a sliding gear I2-5, a spline shaft I2-6, a gear I2-7, a gear II 2-8, a sliding gear II 2-9, a synchronous belt I2-10, a pulley I2-11, a pulley II 2-12, a spline shaft II 2-13, a shaft I2-14, a synchronous belt II 2-15, a pulley III 2-16, a cam shaft I2-17, a gear III 2-18, a shaft II 2-19, a gear II 2-19, 2-20 parts of a third sliding gear, 2-21 parts of a first shifting fork, 2-22 parts of a third shaft, 2-23 parts of a fourth gear, 2-24 parts of a fourth shaft, 2-25 parts of a fifth gear, 2-26 parts of a sixth gear, 2-27 parts of a second shifting fork, 2-28 parts of a fifth shaft, 2-29 parts of a second cam, 2-30 parts of a seventh gear, 2-31 parts of a belt wheel, 2-32 parts of a synchronous belt, 2-33 parts of a sixth shaft, 2-34 parts of a seventh shaft, 2-35 parts of an eighth shaft, 2-36 parts of a duplicate gear, 2-37 parts of a gear, 2-38 parts of a sliding gear, 2-39 parts of a spline shaft, 2-40 parts of a third shifting fork, 2-41 parts of a fifth belt wheel, 2-42 parts of a cam, 2-43 parts of a belt wheel, 2-44 parts of a synchronous belt, 2-45 parts, turning on a motor 2-17, adding materials to be mixed into a stirring tank 3-4 through a stirring feed port 3-1 in sequence, driving a belt wheel III 2-16 by the motor 2-17, driving a belt wheel II 2-12 by the belt wheel III 2-16 through a synchronous belt II 2-15, driving a sliding gear III 2-20 to be meshed with a gear II 2-8 by a belt wheel I2-11, driving a gear I2-7 to be meshed with a gear VII 2-30, driving a belt wheel III 2-43 to rotate by a belt wheel IV 2-31 through a synchronous belt III 2-32, enabling a sliding gear IV 2-38 to be meshed with a duplicate gear 2-36, enabling a stirring belt wheel I2-1 to drive a belt wheel VIII 3-8 to rotate, and enabling a gear VII 2-30 to be meshed with a gear I2-7 to drive a sliding gear I2-5 to be meshed with a gear VI 2, the feeding bevel gear I2-3 is meshed with the bevel gear 4-7, the belt pulley eleven 4-11 is driven to rotate by the belt pulley eleven 4-8 through the synchronous belt hexagon 4-10, so that the screw rod 4-12 rotates, the sliding gear I2-5 is periodically shifted by the cam II 2-29, so that the sliding gear I2-5 is respectively meshed with the gear VI 2-26 and the gear IV 2-23, the gear IV 2-23 is meshed with the gear V2-25 to realize periodic positive and negative rotation, the shifting fork I2-21 is driven by the cam to shift the sliding gear III 2-20 to be meshed with the gear III 2-18 to drive the molding belt pulley I2-4 to rotate, the molding belt pulley I2-4 drives the gear twelve 5-22 to rotate, and the stirring belt pulley I2-1 is fixedly arranged on the shaft eight 2-35, a spiral bevel gear I2-2 is fixedly arranged on a belt wheel V2-41, a feeding bevel gear I2-3 is fixedly arranged on a gear VI 2-26, a forming belt wheel I2-4 is fixedly arranged on a shaft II 2-19, a sliding gear I2-5 is slidably arranged on a spline shaft I2-6, the spline shaft I2-6 is rotatably arranged in a transmission case cover 1-2 through a bearing, a gear I2-7 is fixedly arranged on the spline shaft I2-6, a gear II 2-8 is fixedly arranged on the spline shaft I2-6, a sliding gear II 2-9 is slidably arranged on a spline shaft II 2-13, a synchronous belt I2-10 is frictionally arranged on the belt wheel I2-11, a belt wheel I2-11 is fixedly arranged on the spline shaft II 2-13, a belt wheel II 2-12 is fixedly arranged on the spline shaft II 2-13, the second spline shaft 2-13 is rotatably arranged inside the transmission case cover 1-2 through a bearing, the first shaft 2-14 is rotatably arranged inside the transmission case cover 1-2 through a bearing, the second synchronous belt 2-15 is frictionally arranged on the second belt pulley 2-12, the third belt pulley 2-16 is frictionally arranged on the second synchronous belt 2-15, the first camshaft 2-17 is fixedly arranged on the third belt pulley 2-16, the third gear 2-18 is fixedly arranged on the second shaft 2-19, the second shaft 2-19 is rotatably arranged inside the transmission case cover 1-2 through a bearing, the third sliding gear 2-20 is slidably arranged on the second spline shaft 2-13, the first fork 2-21 is slidably arranged on the third sliding gear 2-20, the third shaft 2-22 is rotatably arranged inside the transmission case cover 1-2 through a bearing, a gear four 2-23 is fixedly arranged on a third solidified re-shaft 2-22, a shaft four 2-24 is rotatably arranged in a transmission case cover 1-2 through a bearing, a gear five 2-25 is fixedly arranged on the shaft four 2-24, the gear five 2-25 is meshed with the gear four 2-23, a gear six 2-26 is fixedly arranged on the shaft four 2-24, the gear six 2-26 is meshed with a sliding gear I2-5, a shifting fork II 2-27 is slidably arranged on the sliding gear I2-5, a shaft five 2-28 is rotatably arranged in the transmission case cover 1-2 through a bearing, a cam II 2-29 is fixedly arranged on the shaft five 2-28, a gear seven 2-30 is fixedly arranged on the shaft five 2-28, and a gear seven 2-30 is meshed with the gear I2-7, a pulley IV 2-31 is fixedly arranged on a shaft IV 2-28, a synchronous belt III 2-32 is arranged on the pulley IV 2-31 in a friction way, a shaft VI 2-33 is arranged inside a transmission case cover 1-2 in a rotating way through a bearing, a shaft VII 2-34 is arranged inside the transmission case cover 1-2 in a rotating way through a bearing, a shaft VIII 2-35 is arranged inside the transmission case cover 1-2 in a rotating way through a bearing, a duplicate gear 2-36 is arranged and fixed on the shaft VIII 2-35, a gear VIII 2-37 is arranged and fixed on the shaft VII 2-34, the gear VIII 2-37 is meshed with the duplicate gear 2-36, a sliding gear IV 2-38 is arranged on a spline shaft III 2-39 in a sliding way, the spline shaft III 2-39 is arranged inside the transmission case cover 1-2 in a rotating way through a bearing, and a shifting fork III 2-40 is arranged on, a belt wheel five 2-41 is fixedly arranged on a spiral bevel gear I2-2, a cam three 2-42 is fixedly arranged on a shaft six 2-33, a belt wheel six 2-43 is fixedly arranged on a shaft six 2-33, a synchronous belt four 2-44 is frictionally arranged on the belt wheel five 2-41, a belt wheel seven 2-45 is frictionally arranged on a synchronous belt four 2-44, a small belt wheel I2-26 is fixedly arranged on the shaft six 2-33, a small synchronous belt 2-27 is frictionally arranged on the small belt wheel I2-26, a small belt wheel II 2-48 is frictionally arranged on a dirty small synchronous belt 2-27, and a small belt wheel II 2-48 is fixedly arranged on a spline shaft three 2-39.

The fourth concrete implementation mode:

the second embodiment is further described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15. the second embodiment is further described, where the stirring device 3 includes a stirring feed port 3-1, a feed sliding plate 3-2, a stirring support frame 3-3, a stirring tank 3-4, a stirring blade 3-5, a tank gear one 3-6, a tank gear two 3-7, a belt pulley eight 3-8, a bearing seat one 3-9, a conical gear shaft one 3-10, a conical gear shaft two 3-11, a belt pulley nine 3-12, a synchronous belt five 3-13, a bearing seat two 3-14, and a gear nine 3-15, and the stirring belt pulley one 2-1 drives the belt pulley eight 3-8 to rotate to drive the conical gear shaft one 3-10 to mesh with the conical gear shaft two 3-11, the whole stirring tank 3-4 is driven to rotate forwards by the meshing of the gear nine 3-15 with the tank gear I3-6 and the tank gear II 3-7, the materials in the stirring tank 3-4 are fully mixed and stirred by the control of the transmission ratio of the cam III 2-42, the cam III 2-42 drives the small belt wheel I2-46, the small belt wheel I2-46 drives the small belt wheel II 2-48 by the small synchronous belt 2-47, the shifting fork III 2-40 drives the sliding gear IV 2-38 to be meshed with the gear eight 2-37, the gear eight 2-37 is further meshed with the duplicate gear 2-36, the stirring tank 3-4 rotates backwards, the fully stirred materials are poured out of the stirring tank 3-4 and are injected into the spiral feeding port 4-18 through the feeding sliding plate 3-2, a stirring feed port 3-1 is fixedly arranged on a stirring support frame 3-3, a feeding sliding plate 3-2 is fixedly arranged on the stirring support frame 3-3, the stirring support frame 3-3 is fixedly arranged on a stirring platform 1-1, a stirring tank 3-4 is rotatably arranged on the stirring support frame 3-3 through a bearing, a stirring blade 3-5 is fixedly arranged inside the stirring tank 3-4, a tank gear I3-6 is fixedly arranged on the stirring tank 3-4, a tank gear II 3-7 is fixedly arranged on the stirring tank 3-4, a belt wheel eight 3-8 is fixedly arranged on a conical gear shaft I3-10, a bearing seat I3-9 is fixedly arranged on the stirring platform 1-1, the conical gear shaft I3-10 is rotatably arranged on the stirring platform 1-1 through the bearing seat I3-9, the bevel gear shaft II 3-11 is meshed with the bevel gear shaft I3-10, the belt wheel nine 3-12 is fixedly arranged on the bevel gear shaft II 3-11, the synchronous belt five 3-13 is frictionally arranged on the belt wheel nine 3-12, the bearing block II 3-14 is fixedly arranged on the stirring table 1-1, and the gear nine 3-15 is fixedly arranged on the bevel gear shaft II 3-11.

The fifth concrete implementation mode:

the first embodiment is further described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15. the first embodiment is further described, where the feeding device 4 includes a feeding pipe 4-1, a spiral feeding cavity 4-2, a first end cap 4-3, a pulley cover 4-4, a second end cap 4-5, a third bevel gear shaft 4-6, a bevel gear 4-7, a pulley ten 4-8, a bearing seat three 4-9, a synchronous belt six 4-10, a pulley eleven 4-11, a lead screw 4-12, a material pushing block 4-13, a water spraying pipe 4-14, a first bearing 4-15, a spiral feeding rod 4-16, a spiral discharging port 4-17, a spiral feeding port 4-18, a second bearing 4-19, a pulley twelve 4-20, a second pulley twelve, A synchronous belt seven 4-21 and a belt wheel thirteen 4-22, a spiral bevel gear I2-2 is meshed with a bevel gear shaft III 4-6 to drive the belt wheel thirteen 4-22 to rotate, the belt wheel thirteen 4-22 drives a belt wheel twelve 4-20 to rotate through the synchronous belt seven 4-21, so that a spiral feeding rod 4-16 rotates to realize the function of spiral feeding, in addition, a gear seven 2-30 is meshed with a gear I2-7 to drive a sliding gear I2-5 to be meshed with a gear six 2-26 to drive a feeding bevel gear I2-3 to be meshed with a bevel gear 4-7, a belt wheel ten 4-8 drives a belt wheel eleven 4-11 to rotate through a synchronous belt six 4-10 to drive a screw rod 4-12 to rotate, and a cam two 2-29 can periodically stir the sliding gear I2-5, the first sliding gear 2-5 is respectively meshed with the sixth gear 2-26 and the fourth gear 2-23, the fourth gear 2-23 is meshed with the fifth gear 2-25 to realize periodic positive and negative rotation, the screw rod 4-12 also performs periodic positive and negative rotation to enable the material pushing block 4-13 to reciprocate, when materials enter the feeding and measuring cover 1-3 through the material conveying pipe 4-1, the material pushing block 4-13 pushes the materials and moistens the pushed materials through the water spraying pipe 4-14, the material conveying pipe 4-1 is fixedly arranged on the spiral feeding cavity 4-2, the material conveying pipe 4-1 is fixedly arranged on the feeding and measuring cover 1-3, the spiral feeding cavity 4-2 is fixedly arranged on the transmission box cover 1-2, and the end cover 4-3 is fixedly arranged on the spiral feeding cavity 4-2, a pulley cover 4-4 is fixedly arranged on an end cover two 4-5, the end cover two 4-5 is fixedly arranged on a spiral feeding cavity 4-2, a bevel gear shaft three 4-6 is rotatably arranged on the pulley cover 4-4 through a bearing, the bevel gear shaft three 4-6 is meshed with a spiral bevel gear I2-2, a bevel gear 4-7 is fixedly arranged on a screw rod 4-12, a bevel gear 4-7 is meshed with a feeding bevel gear I2-3, a belt pulley eleven 4-8 is fixedly arranged on the screw rod 4-12, a bearing block three 4-9 is fixedly arranged on a material pushing block 4-13, a synchronous belt six 4-10 is frictionally arranged on the belt pulley eleven 4-11 is frictionally arranged on the synchronous belt six 4-10, the screw rod 4-12 is rotatably arranged on the material pushing block 4-13 through a bearing block III 4-9, the screw rod 4-12 is rotatably arranged on the feeding and measuring cover 1-3 through a bearing, the pushing block 4-13 is slidably arranged inside the feeding and measuring cover 1-3, the water spraying pipe 4-14 is fixedly arranged on the pushing block 4-13, the bearing I4-15 is fixedly arranged inside the end cover I4-3, the spiral feeding rod 4-16 is rotatably arranged inside the spiral feeding cavity 4-2 through the bearing I4-15 and the bearing II 4-19, the spiral discharging port 4-17 is arranged on the spiral feeding cavity 4-2, the spiral feeding port 4-18 is arranged on the spiral feeding cavity 4-2, the bearing II 4-19 is fixedly arranged on the spiral feeding rod 4-16, the belt wheel twelve 4-20 is fixedly arranged on the spiral feeding rod 4-16, and the synchronous belt seven 4-21 is frictionally arranged on the belt wheel twelve 4-20, the belt wheels thirteen 4-22 are frictionally mounted on the synchronous belt seven 4-21.

The sixth specific implementation mode:

the embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14 and 15, and the embodiment further describes the embodiment, wherein the forming device comprises a limit stop 5-1, a lifting table 5-2, a lower screw 5-3, a slide rail 5-4, a screw nut I5-5, a bearing seat IV 5-6, a bevel gear shaft IV 5-7, a belt pulley IV 5-8, a synchronous belt eight 5-9, a belt pulley V5-10, a shaft IV 5-11, a cam IV 5-12, a spline shaft IV 5-13, a sliding gear V5-14, a synchronous belt V5-15, a belt pulley V5-16, a shift fork IV 5-17, a gear V5-18, a belt pulley V5-19, a bevel gear shaft V5-20, a gear V5-13, a sliding gear V5-14, a synchronous belt V5-15, 5-21 parts of eleven gear, 5-22 parts of twelve gear, 5-23 parts of six conical tooth shafts, 5-24 parts of eighteen belt wheels, 5-25 parts of upper screw rods, 5-26 parts of synchronous belts, 5-27 parts of upper screw rod nuts, 5-28 parts of lifting frames, 5-29 parts of five bearing seats, 5-30 parts of eccentric shafts, 5-31 parts of pins, 5-32 parts of fixture blocks, 5-33 parts of forming cavities, 5-34 parts of vibrating rods, 5-35 parts of clamp plate clamping grooves, 5-36 parts of clamp plates, 5-37 parts of partition plates, 5-38 parts of lower support plates, 5-39 parts of wheel shaft holes, 5-40 parts of seven conical tooth shafts, 5-41 parts of thirteen gears, 5-42 parts of synchronous belts, 5-43 parts of vibrating grooves, 5-44 parts of hook grooves and 5-45 parts of wheel shafts, wherein the 5-38 parts of the lower support plates, as the whole feeding device 4 realizes quantification, the shifting fork I2-21 is driven by the cam to shift the sliding gear III 2-20 to be meshed with the gear III 2-18, the forming belt wheel I2-4 is driven to rotate the gear twelve 5-22, the belt wheel fourteen 5-8 is driven to rotate the belt wheel fifteen 5-10 through the synchronous belt eight 5-9, at the moment, the conical gear shaft five 5-20 is meshed with the conical gear shaft seven 5-40, the belt wheel eighteen 5-24 is driven to rotate, the upper screw rod 5-25 is driven to rotate, the lifting frame 5-28 is driven to descend, when the set position is reached, the gear eleven 5-21 is meshed with the gear ten 5-18, the cam four 5-12 is driven to rotate, and the shifting fork four 5-17 is used for shifting the sliding gear five 5-14 to, the whole eccentric shaft 5-30 is eccentrically rotated to drive the vibrating rod 5-34 to swing up and down, the pressure plate 5-36 is vibrated, the materials in the whole forming cavity 5-33 are vibrated to change the internal structure of the forming cavity, thereby forming the concrete block, the belt wheel fifteen 5-10 drives the belt wheel fourteen 5-8 according to the transmission ratio, the bevel gear shaft IV 5-7 is meshed with the bevel gear shaft VI 5-23 to drive the lower screw 5-3 to rotate, thereby leading the lifting platform 5-2 to descend, a worker pulls out the whole lower supporting plate 5-38 through the hook groove 5-44 to finish blanking, then a new lower supporting plate 5-38 is installed again according to the gap on the lifting platform 5-2 and the limit stop 5-1, the limit stop 5-1 is installed and fixed on the lifting platform 5-2, the lifting platform 5-2 is slidably mounted on a sliding rail 5-4 through a sliding block, the lower lead screw 5-3 is mounted on a lead screw nut I5-5 in a threaded manner, the sliding rail 5-4 is fixedly mounted on a forming support 1-4, the lead screw nut I5-5 is fixedly mounted on the lifting platform 5-2, a bearing seat IV 5-6 is fixedly mounted on the sliding rail 5-4, and a bevel gear shaft IV 5-7 is rotatably mounted on the forming support 1-4 through a bearing. A belt wheel fourteen 5-8 is fixedly arranged on a conical gear shaft fourteen 5-7, a synchronous belt eight 5-9 is frictionally arranged on the belt wheel fourteen 5-8, a belt wheel fifteen 5-10 is frictionally arranged on the synchronous belt eight 5-9, a shaft nine 5-11 is rotatably arranged on a forming bracket 1-4 through a bearing, a cam four 5-12 is fixedly arranged on a shaft nine 5-11, a spline shaft four 5-13 is rotatably arranged on the forming bracket 1-4 through a bearing, a sliding gear five 5-14 is slidably arranged on the spline shaft four 5-13, a synchronous belt nine 5-15 is frictionally arranged on the belt wheel sixteen 5-16, the belt wheel sixteen 5-16 is fixedly arranged on the spline shaft four 5-13, a shifting fork four 5-17 is slidably arranged on the sliding gear five 5-14, a gear test 5-18 is fixedly arranged on the shaft nine 5-11, the belt wheel seventeen 5-19 is frictionally mounted on the synchronous belt nine 5-15, the belt wheel seventeen 5-19 is fixedly mounted on the shaft nine 5-11, the bevel gear shaft five 5-20 is rotatably mounted on the forming support 1-4 through a bearing, the bevel gear shaft five 5-20 is meshed with the bevel gear shaft seven 5-40, the gear eleventh 5-21 is fixedly mounted on the bevel gear shaft five 5-20, the gear twelfth 5-22 is fixedly mounted on the bevel gear shaft fourth 5-7, the bevel gear shaft five 5-27 is fixedly mounted on the lower screw rod 5-3, the bevel gear shaft five 5-2 is meshed with the bevel gear shaft fourth 5-7, the belt wheel eighteen 5-24 is fixedly mounted on the upper screw rod 5-25, the upper screw rod 5-25 is threadedly mounted on the upper screw rod nut 5-27, the synchronous belt ten 5-26 is frictionally mounted on the belt wheel eighteen 5-24, an upper screw rod nut 5-27 is fixedly arranged on a lifting frame 5-28, a bearing seat five 5-29 is fixedly arranged on the lifting frame 5-28, an eccentric shaft 5-30 is rotatably arranged on the lifting frame 5-28 through the bearing seat five 5-29, a clamping block 5-32 is arranged on the eccentric shaft 5-30 through a pin 5-31 hinge, a forming cavity 5-33 is fixedly arranged on an upper screw rod 5-25, a vibrating rod 5-34 is fixedly arranged on the clamping block 5-32, a clamping groove 5-35 of a pressing plate is arranged on the pressing plate 5-36, the pressing plate 5-36 is slidably arranged on the vibrating rod 5-34, a clapboard 5-37 is fixedly arranged on a lower supporting plate 5-38, a wheel axle hole 5-39 is arranged on the lower supporting plate 5-38, and a cone-tooth axle seven 5-40 is fixedly arranged on the upper screw rod, thirteen gears 5-41 are fixedly arranged on an eccentric shaft 5-30, an eleven synchronous belt 5-42 is frictionally arranged on an eighteen pulley 5-24, a vibration groove 5-43 is arranged on a lifting frame 5-28, a hook groove 5-44 is arranged on a lower support plate 5-38, and a wheel shaft 5-45 is rotatably arranged on the lower support plate 5-38.

The seventh embodiment:

the fourth embodiment will be further described with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, and 15, in which four bearing seats two 3 to 14 and four gears nine 3 to 15 of the stirring device 3 are provided.

The specific implementation mode is eight:

the present embodiment is described below with reference to fig. 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, and 15, and the present embodiment further describes an embodiment six, where there are two upper screws 5 to 25, two synchronous belts ten 5 to 26, two upper screw nuts 5 to 27, two bearing seats five 5 to 29, two eccentric shafts 5 to 30, and two wheel shafts 5 to 45 of the forming device 4.

The working principle of the invention is as follows:

an intelligent concrete block device has the working principle that before use, whether the connection condition between the devices meets the requirement is checked, a motor 2-17 is started, materials to be mixed are sequentially added into a stirring tank 3-4 through a stirring feed port 3-1, the motor 2-17 drives a belt wheel III 2-16, the belt wheel III 2-16 drives a belt wheel II 2-12 through a synchronous belt II 2-15, the belt wheel I2-11 drives a sliding gear III 2-20 to be meshed with a gear II 2-8, the gear I2-7 is driven to be meshed with a gear VII 2-30, the belt wheel IV 2-31 drives a belt wheel VI 2-43 to rotate through a synchronous belt III 2-32, the sliding gear IV 2-38 is meshed with a duplicate gear 2-36, and the stirring belt wheel I2-1 drives a belt wheel VIII 3-8 to rotate, driving a first bevel gear shaft 3-10 to be meshed with a second bevel gear shaft 3-11, driving the whole stirring tank 3-4 to rotate forwards through the meshing of a gear nine 3-15 with a first tank gear 3-6 and a second tank gear 3-7, fully mixing and stirring materials in the stirring tank 3-4 through the control of the transmission ratio of a cam three 2-42, driving a small belt wheel one 2-46 through the cam three 2-42, driving a small belt wheel two 2-48 through a small synchronous belt 2-47 by the small belt wheel one 2-46, driving a sliding gear four 2-38 to be meshed with a gear eight 2-37 by a shifting fork three 2-40, meshing the gear eight 2-37 with a duplicate gear 2-36 to realize the reverse rotation of the stirring tank 3-4, pouring the fully stirred materials out from the stirring tank 3-4, the material is injected into a spiral feeding port 4-18 through a feeding sliding plate 3-2, a belt pulley seven 2-45 drives a spiral bevel gear I2-2 to rotate through a synchronous belt IV 2-44, the spiral bevel gear I2-2 is meshed with a bevel gear shaft III 4-6 to drive a belt pulley thirteen 4-22 to rotate, the belt pulley thirteen 4-22 drives a belt pulley twelve 4-20 to rotate through a synchronous belt VII 4-21, so that a spiral feeding rod 4-16 rotates to realize the function of spiral feeding, in addition, the gear VII 2-30 is meshed with the gear I2-7 to drive a sliding gear I2-5 to be meshed with a gear VI 2-26 to enable the feeding bevel gear I2-3 to be meshed with a bevel gear 4-7, and the belt pulley eleven 4-8 drives a belt pulley eleven 4-11 to rotate through a synchronous belt VI 4-10, thereby leading the screw rod 4-12 to rotate, and because the cam two 2-29 can periodically stir the sliding gear one 2-5, leading the sliding gear one 2-5 to be respectively meshed with the gear six 2-26 and the gear four 2-23, and the gear four 2-23 is also meshed with the gear five 2-25 to realize periodic positive and negative rotation, leading the screw rod 4-12 to also periodically positive and negative rotation, leading the material pushing block 4-13 to carry out reciprocating motion, when the material enters the material feeding measuring cover 1-3 through the material conveying pipe 4-1, the material pushing block 4-13 pushes the material, and the water spraying pipe 4-14 wets the pushed material, at the moment, the lower supporting plate 5-38 is in the forming cavity 5-33, the material can be continuously filled in the forming cavity 5-33, and the whole feeding device 4 realizes quantification, the cam drives the shifting fork I2-21 to shift the sliding gear III 2-20 to be meshed with the gear III 2-18, the forming belt wheel I2-4 is driven to rotate, the forming belt wheel I2-4 drives the gear twelve 5-22 to rotate, the belt wheel fourteen 5-8 drives the belt wheel fifteen 5-10 to rotate through the synchronous belt eight 5-9, the bevel gear shaft five 5-20 is meshed with the bevel gear shaft seven 5-40 at the moment, the belt wheel eighteen 5-24 is driven to rotate, the upper screw rod 5-25 is driven to rotate, the lifting frame 5-28 is driven to descend, when the set position is reached, the gear eleven 5-21 is meshed with the gear thirteen 5-18 to drive the cam four 5-12 to rotate, the shifting fork four 5-17 shifts the sliding gear five 5-14 to be meshed with the gear thirteen 5-, the whole eccentric shaft 5-30 is eccentrically rotated to drive the vibrating rod 5-34 to swing up and down, the pressure plate 5-36 is vibrated, the materials in the whole forming cavity 5-33 are vibrated to change the internal structure of the concrete block, the belt wheel fifteen 5-10 drives the belt wheel fourteen 5-8, the bevel gear shaft IV 5-7 is meshed with the bevel gear shaft VI 5-23 to drive the lower screw 5-3 to rotate, so that the lifting platform 5-2 descends, a worker pulls out the whole lower supporting plate 5-38 through the hook groove 5-44 to finish blanking, and a new lower supporting plate 5-38 is reinstalled according to the notch on the lifting platform 5-2 and the limit stop 5-1, so that the material transportation and the material of the concrete block after stirring are saved, And the filling and the control operation save time and labor cost.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims (8)

1. The utility model provides an intelligence concrete block equipment, includes installation component (1), transmission case (2), agitating unit (3), material feeding unit (4), forming device (5), its characterized in that: the stirring device (3) is fixedly arranged in the mounting component (1), the transmission case (2) is fixedly arranged on the feeding device (4), the feeding device (4) is fixedly arranged on the stirring device (1), and the forming device (5) is fixedly arranged on the feeding device (4).

2. An intelligent concrete block apparatus according to claim 1, wherein: the mounting assembly (1) comprises a stirring table (1-1), a transmission case cover (1-2), a feeding and measuring cover (1-3) and a forming support (1-4).

3. An intelligent concrete block apparatus according to claim 1, wherein: the transmission case (2) comprises a stirring belt wheel I (2-1), a spiral bevel gear I (2-2), a feeding bevel gear I (2-3), a forming belt wheel I (2-4), a sliding gear I (2-5), a spline shaft I (2-6), a gear I (2-7), a gear II (2-8), a sliding gear II (2-9), a synchronous belt I (2-10), a belt wheel I (2-11), a belt wheel II (2-12), a spline shaft II (2-13), a shaft I (2-14), a synchronous belt II (2-15), a belt wheel III (2-16), a cam shaft I (2-17), a gear III (2-18), a shaft II (2-19), a sliding gear III (2-20), a shifting fork I (2-21), Shaft III (2-22), gear IV (2-23), shaft IV (2-24), gear V (2-25), gear VI (2-26), shift fork II (2-27), shaft IV (2-28), cam II (2-29), gear VII (2-30), pulley IV (2-31), synchronous belt III (2-32), shaft VI (2-33), shaft VII (2-34), shaft VIII (2-35), duplicate gear (2-36), gear VIII (2-37), sliding gear IV (2-38), spline shaft III (2-39), shift fork III (2-40), pulley V (2-41), cam III (2-42), pulley VI (2-43), synchronous belt IV (2-44), pulley IV (2-45), A small belt wheel I (2-26), a small synchronous belt (2-27) and a small belt wheel II (2-48), wherein a stirring belt wheel I (2-1) is fixedly arranged on a shaft eight (2-35), a spiral bevel gear I (2-2) is fixedly arranged on a belt wheel V (2-41), a feeding bevel gear I (2-3) is fixedly arranged on a gear six (2-26), a forming belt wheel I (2-4) is fixedly arranged on a shaft II (2-19), a sliding gear I (2-5) is slidably arranged on a spline shaft I (2-6), the spline shaft I (2-6) is rotatably arranged in a transmission case cover (1-2) through a bearing, a gear I (2-7) is fixedly arranged on the spline shaft I (2-6), a gear II (2-8) is fixedly arranged on the spline shaft I (2-6), a sliding gear II (2-9) is slidably arranged on a spline shaft II (2-13), a synchronous belt I (2-10) is arranged on a belt wheel I (2-11) in a friction way, the belt wheel I (2-11) is fixedly arranged on the spline shaft II (2-13), the belt wheel II (2-12) is fixedly arranged on the spline shaft II (2-13), the spline shaft II (2-13) is rotatably arranged inside a transmission box cover (1-2) through a bearing, a shaft I (2-14) is rotatably arranged inside the transmission box cover (1-2) through a bearing, the synchronous belt II (2-15) is arranged on the belt wheel II (2-12) in a friction way, a belt wheel III (2-16) is arranged on the synchronous belt II (2-15) in a friction way, a camshaft I (2-17) is fixedly arranged on the belt wheel III (2-16), a third gear (2-18) is fixedly arranged on a second shaft (2-19), the second shaft (2-19) is rotatably arranged inside a transmission case cover (1-2) through a bearing, a third sliding gear (2-20) is slidably arranged on a second spline shaft (2-13), a first shifting fork (2-21) is slidably arranged on the third sliding gear (2-20), a third shaft (2-22) is rotatably arranged inside the transmission case cover (1-2) through a bearing, a fourth gear (2-23) is fixedly arranged on the third sliding gear (2-22), a fourth shaft (2-24) is rotatably arranged inside the transmission case cover (1-2) through a bearing, a fifth gear (2-25) is fixedly arranged on the fourth shaft (2-24), and the fifth gear (2-25) is meshed with the fourth gear (2-23), a sixth gear (2-26) is fixedly arranged on a fourth shaft (2-24), the sixth gear (2-26) is meshed with a first sliding gear (2-5), a second shifting fork (2-27) is slidably arranged on the first sliding gear (2-5), a fifth shaft (2-28) is rotatably arranged in a transmission box cover (1-2) through a bearing, a second cam (2-29) is fixedly arranged on the fifth shaft (2-28), a seventh gear (2-30) is meshed with a first gear (2-7), a fourth belt wheel (2-31) is fixedly arranged on the fifth shaft (2-28), a third synchronous belt (2-32) is frictionally arranged on the fourth belt wheel (2-31), a sixth shaft (2-33) is rotatably arranged in the transmission box cover (1-2) through a bearing, the shaft seven (2-34) is rotatably arranged inside the transmission case cover (1-2) through a bearing, the shaft eight (2-35) is rotatably arranged inside the transmission case cover (1-2) through a bearing, the duplicate gear (2-36) is fixedly arranged on the shaft eight (2-35), the gear eight (2-37) is fixedly arranged on the shaft seven (2-34), the gear eight (2-37) is meshed with the duplicate gear (2-36), the sliding gear four (2-38) is slidably arranged on the spline shaft three (2-39), the spline shaft three (2-39) is rotatably arranged inside the transmission case cover (1-2) through a bearing, the shifting fork three (2-40) is slidably arranged on the sliding gear four (2-38), and the belt wheel five (2-41) is fixedly arranged on the spiral bevel gear one (2-2), the cam III (2-42) is fixedly arranged on the shaft VI (2-33), the belt wheel VI (2-43) is fixedly arranged on the shaft VI (2-33), the synchronous belt IV (2-44) is frictionally arranged on the belt wheel V (2-41), the belt wheel VII (2-45) is frictionally arranged on the synchronous belt IV (2-44), the small belt wheel I (2-26) is fixedly arranged on the shaft VI (2-33), the small synchronous belt (2-27) is frictionally arranged on the small belt wheel I (2-26), the small belt wheel II (2-48) is frictionally arranged on the dirty small synchronous belt (2-27), and the small belt wheel II (2-48) is fixedly arranged on the spline shaft III (2-39).

4. An intelligent concrete block apparatus according to claim 1, wherein: the stirring device (3) comprises a stirring feed port (3-1), a feeding sliding plate (3-2), a stirring support frame (3-3), a stirring tank (3-4), a stirring blade (3-5), a tank gear I (3-6), a tank gear II (3-7), a belt pulley eight (3-8), a bearing seat I (3-9), a bevel gear shaft I (3-10), a bevel gear shaft II (3-11), a belt pulley nine (3-12), a synchronous belt five (3-13), a bearing seat II (3-14) and a gear nine (3-15), wherein the stirring feed port (3-1) is fixedly arranged on the stirring support frame (3-3), the feeding sliding plate (3-2) is fixedly arranged on the stirring support frame (3-3), the stirring support frame (3-3) is fixedly arranged on the stirring table (1-1), the stirring tank (3-4) is rotatably arranged on the stirring support frame (3-3) through a bearing, the stirring blade (3-5) is fixedly arranged inside the stirring tank (3-4), the tank gear I (3-6) is fixedly arranged on the stirring tank (3-4), the tank gear II (3-7) is fixedly arranged on the stirring tank (3-4), the belt pulley eight (3-8) is fixedly arranged on the bevel gear shaft I (3-10), the bearing seat I (3-9) is fixedly arranged on the stirring table (1-1), the bevel gear shaft I (3-10) is rotatably arranged on the stirring table (1-1) through the bearing seat I (3-9), the bevel gear shaft II (3-11) is meshed with the bevel gear shaft I (3-10), and the belt pulley nine (3-12) is fixedly arranged on the bevel gear shaft II (3-11), a synchronous belt V (3-13) is arranged on a belt wheel V (3-12) in a friction mode, a bearing seat II (3-14) is fixedly arranged on the stirring table (1-1), and a gear nine (3-15) is fixedly arranged on a bevel gear shaft II (3-11).

5. An intelligent concrete block apparatus according to claim 1, wherein: the feeding device (4) comprises a feeding pipe (4-1), a spiral feeding cavity (4-2), a first end cover (4-3), a belt wheel cover (4-4), a second end cover (4-5), a third bevel gear shaft (4-6), a bevel gear (4-7), a ten belt wheel (4-8), a third bearing seat (4-9), a sixth synchronous belt (4-10), a eleventh belt wheel (4-11), a lead screw (4-12), a pushing block (4-13), a water spraying pipe (4-14), a first bearing (4-15), a spiral feeding rod (4-16), a spiral discharging hole (4-17), a spiral feeding hole (4-18), a second bearing (4-19), a twelfth belt wheel (4-20), a seventh synchronous belt (4-21) and a thirteenth belt wheel (4-22), a material conveying pipe (4-1) is fixedly arranged on a spiral feeding cavity (4-2), the material conveying pipe (4-1) is fixedly arranged on a feeding material measuring cover (1-3), the spiral feeding cavity (4-2) is fixedly arranged on a transmission box cover (1-2), an end cover (4-3) is fixedly arranged on the spiral feeding cavity (4-2), a belt wheel cover (4-4) is fixedly arranged on an end cover II (4-5), the end cover II (4-5) is fixedly arranged on the spiral feeding cavity (4-2), a bevel gear shaft III (4-6) is rotatably arranged on the belt wheel cover (4-4) through a bearing, the bevel gear shaft III (4-6) is meshed with a spiral bevel gear I (2-2), a bevel gear (4-7) is fixedly arranged on a screw rod (4-12), the bevel gear (4-7) is meshed with the feeding bevel gear I (2-3), the belt pulley ten (4-8) is fixedly arranged on the screw rod (4-12), the bearing seat III (4-9) is fixedly arranged on the material pushing block (4-13), the synchronous belt six (4-10) is frictionally arranged on the belt pulley ten (4-8), the belt pulley eleven (4-11) is frictionally arranged on the synchronous belt six (4-10), the screw rod (4-12) is rotatably arranged on the material pushing block (4-13) through the bearing seat III (4-9), the screw rod (4-12) is rotatably arranged on the material feeding and measuring cover (1-3) through a bearing, the material pushing block (4-13) is slidably arranged inside the material feeding and measuring cover (1-3), and the water spraying pipe (4-14) is fixedly arranged on the material pushing block (4-13), the bearing I (4-15) is fixedly installed inside the end cover I (4-3), the spiral feeding rod (4-16) is rotatably installed inside the spiral feeding cavity (4-2) through the bearing I (4-15) and the bearing II (4-19), the spiral discharging port (4-17) is arranged on the spiral feeding cavity (4-2), the spiral feeding port (4-18) is arranged on the spiral feeding cavity (4-2), the bearing II (4-19) is fixedly installed on the spiral feeding rod (4-16), the belt wheel twelve (4-20) is fixedly installed on the spiral feeding rod (4-16), the synchronous belt seven (4-21) is installed on the belt wheel twelve (4-20) in a friction mode, and the belt wheel thirteen (4-22) is installed on the synchronous belt seven (4-21) in a friction mode.

6. An intelligent concrete block apparatus according to claim 1, wherein: the forming device (5) comprises a limit stop (5-1), a lifting platform (5-2), a lower screw (5-3), a sliding rail (5-4), a screw nut I (5-5), a bearing seat IV (5-6), a bevel gear shaft IV (5-7), a belt wheel fourteen (5-8), a synchronous belt eight (5-9), a belt wheel fifteen (5-10), a shaft nine (5-11), a cam IV (5-12), a spline shaft IV (5-13), a sliding gear V (5-14), a synchronous belt nine (5-15), a belt wheel sixteen (5-16), a shifting fork IV (5-17), a gear Ten (5-18), a belt wheel seventeen (5-19), a bevel gear shaft V (5-20), a gear eleven (5-21), Gear twelve (5-22), bevel gear shaft six (5-23), belt wheel eighteen (5-24), upper screw rod (5-25), synchronous belt ten (5-26), upper screw rod nut (5-27), lifting frame (5-28), bearing seat five (5-29), eccentric shaft (5-30), pin (5-31), fixture block (5-32), forming cavity (5-33), vibrating rod (5-34), pressure plate clamping groove (5-35), pressure plate (5-36), partition plate (5-37), lower supporting plate (5-38), wheel shaft hole (5-39), bevel gear shaft seven (5-40), gear thirteen (5-41), synchronous belt eleven (5-42), vibrating groove (5-43), hook groove (5-44), The device comprises a wheel shaft (5-45), a limit stop block (5-1) is fixedly installed on a lifting platform (5-2), the lifting platform (5-2) is slidably installed on a sliding rail (5-4) through a sliding block, a lower lead screw (5-3) is installed on a lead screw nut I (5-5) in a threaded mode, the sliding rail (5-4) is fixedly installed on a forming support (1-4), the lead screw nut I (5-5) is fixedly installed on the lifting platform (5-2), a bearing seat IV (5-6) is fixedly installed on the sliding rail (5-4), and a bevel gear shaft IV (5-7) is rotatably installed on the forming support (1-4) through a bearing. A belt wheel fourteen (5-8) is fixedly arranged on a conical gear shaft four (5-7), a synchronous belt eight (5-9) is arranged on the belt wheel fourteen (5-8) in a friction mode, a belt wheel fifteen (5-10) is arranged on the synchronous belt eight (5-9) in a friction mode, a shaft nine (5-11) is rotatably arranged on a forming bracket (1-4) through a bearing, a cam four (5-12) is fixedly arranged on the shaft nine (5-11), a spline shaft four (5-13) is rotatably arranged on the forming bracket (1-4) through a bearing, a sliding gear five (5-14) is slidably arranged on the spline shaft four (5-13), a synchronous belt nine (5-15) is arranged on a belt wheel sixteen (5-16) in a friction mode, a belt wheel sixteen (5-16) is fixedly arranged on the spline shaft four (5-13), a shifting fork IV (5-17) is slidably arranged on a sliding gear V (5-14), a gear trial (5-18) is fixedly arranged on a shaft nine (5-11), a belt wheel seventeen (5-19) is frictionally arranged on a synchronous belt nine (5-15), a belt wheel seventeen (5-19) is fixedly arranged on the shaft nine (5-11), a bevel gear shaft V (5-20) is rotatably arranged on a forming bracket (1-4) through a bearing, a bevel gear shaft V (5-20) is meshed with the bevel gear shaft VII (5-40), a gear eleven (5-21) is fixedly arranged on the bevel gear shaft V (5-20), a gear twelve (5-22) is fixedly arranged on the bevel gear shaft IV (5-7), the bevel gear shaft V (5-27) is fixedly arranged on a lower screw rod (5-3), a fifth conical-toothed shaft (5-2) is meshed with a fourth conical-toothed shaft (5-7), a eighteen belt wheel (5-24) is fixedly arranged on an upper screw rod (5-25), the upper screw rod (5-25) is arranged on an upper screw rod nut (5-27) in a threaded manner, a tenth synchronous belt (5-26) is frictionally arranged on the eighteen belt wheel (5-24), the upper screw rod nut (5-27) is fixedly arranged on a lifting frame (5-28), a fifth bearing seat (5-29) is fixedly arranged on the lifting frame (5-28), an eccentric shaft (5-30) is rotatably arranged on the lifting frame (5-28) through the fifth bearing seat (5-29), a fixture block (5-32) is hinged on the eccentric shaft (5-30) through a pin (5-31), and a forming cavity (5-33) is fixedly arranged on the upper screw rod (5-25), the vibrating rod (5-34) is fixedly arranged on the clamping block (5-32), the clamping groove (5-35) of the pressure plate is arranged on the pressure plate (5-36), the pressure plate (5-36) is slidably arranged on the vibrating rod (5-34), the partition plate (5-37) is fixedly arranged on the lower supporting plate (5-38), the axle hole (5-39) of the wheel is arranged on the lower supporting plate (5-38), the bevel gear shaft seven (5-40) is fixedly arranged on the upper screw rod (5-25), the gear thirteen (5-41) is fixedly arranged on the eccentric shaft (5-30), the synchronous belt eleven (5-42) is frictionally arranged on the eighteen (5-24) of the belt wheel, the vibrating groove (5-43) is arranged on the lifting frame (5-28), and the hook groove (5-44) is arranged on the lower supporting plate (5-38), the wheel shafts (5-45) are rotatably arranged on the lower supporting plates (5-38).

7. An intelligent concrete block apparatus according to claim 4, wherein: and four stirring devices (3) are provided, namely a second bearing seat (3-14) and a ninth gear (3-15).

8. An intelligent concrete block apparatus according to claim 6, wherein: two upper screw rods (5-25), two synchronous belts (5-26), two upper screw rod nuts (5-27), two bearing seats (5-29), two eccentric shafts (5-30) and two wheel shafts (5-45) are arranged on the forming device (5).

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