Disclosure of Invention
The invention aims to provide automatic hollow slab manufacturing equipment, which can freely control the length of a hollow slab, automatically finish discharging and stop discharging by controlling, automatically compact concrete, and reduce gaps among the concrete by vibrating a mould.
The purpose of the invention is realized by the following technical scheme:
the utility model provides an automatic hollow slab preparation equipment, includes walking assembly, ejection of compact assembly, control assembly and mould vibration assembly, ejection of compact assembly, control assembly, mould vibration assembly all are connected with walking assembly, and ejection of compact assembly is connected with the control assembly.
As a further optimization of the technical scheme, the walking assembly comprises a bottom plate, a pressing chamber, a sliding support, a motor I shaft, a walking transmission case upper cover, a turning gear I, a gear II, a turning control lever, a turning control chute, a turning control support, a ball stirring I, a ball groove sleeve I, a sliding gear I chute, a sliding gear I shaft, a bevel gear I, a bevel gear II shaft, a belt wheel I, a belt I, a walking wheel shaft and walking wheels, wherein the bottom plate is connected with the pressing chamber, the sliding support is in sliding connection with the pressing chamber, the motor I is connected with the motor I shaft, the motor I shaft is in rotating connection with the walking transmission case, the walking transmission case is connected with the sliding support, the walking transmission case upper cover is connected with the walking transmission case, the shaft of a motor I is connected with a direction changing gear I and a gear I, the gear I is meshed with a gear II, the gear II is connected with a gear II, the gear II is rotatably connected with a walking transmission box, the direction changing gear II is connected with a gear II, a direction changing control rod is connected with a direction changing control support, the direction changing control rod is hinged with an upper cover of the walking transmission box, the direction changing control chute is positioned on the direction changing control rod, the direction changing control support is connected with two shifting balls I, the two shifting balls I are both in sliding connection with a ball groove of a ball groove sleeve I, the ball groove sleeve I is connected with a sliding gear I, the sliding gear I is in sliding connection with a sliding gear I chute, the sliding gear I chute is positioned on the shaft of the sliding gear I, the shaft of the sliding gear I is rotatably connected with the walking transmission box, the shaft of the sliding gear I is connected with a bevel gear I, the bevel gear I is meshed with the bevel gear II, the bevel gear II is connected with the shaft of the bevel gear II, II axles of bevel gear rotate with the sliding support and are connected, II axles of bevel gear are connected with a band pulley I, and two band pulleys I pass through belt I and connect, and a band pulley I is connected with a walking axle, and three walking wheel axle all rotates with the sliding support to be connected, and three walking wheel axle, II axles of bevel gear are connected with four walking wheels respectively, and four walking wheels all contact with the pressing chamber.
As a further optimization of the technical scheme, the discharging assembly comprises a motor II, a motor II shaft, a discharging transmission case upper cover, a clutch control rod, a clutch control chute, a clutch control bracket, a ball shifting II, a ball groove sleeve II, a sliding gear II chute, a worm, a clutch gear, a worm wheel shaft, a belt wheel II, a belt wheel III, a hopper, a spherical discharging port, a discharging fan blade shaft, a discharging fan blade, a hopper bracket, a telescopic rod sliding cylinder, a pressing roller shaft, a pressing roller, a pressing spring, a pressing ring, a pressurizing inclined plane and a connecting column, wherein the motor II is connected with the motor II shaft, the motor II shaft is connected with the sliding bracket, the discharging transmission case is rotationally connected with the sliding bracket, the discharging transmission case is connected with the discharging transmission case upper cover, the clutch control rod is hinged with the discharging transmission case upper cover, the clutch control chute is positioned on the clutch control lever, the clutch control lever is connected with the clutch control bracket, the clutch control bracket is connected with two drive balls II, the two drive balls II are both connected with a ball groove sleeve II in a sliding way, the ball groove sleeve II is connected with a sliding gear II, the sliding gear II is connected with a sliding gear II chute in a sliding way, the sliding gear II chute is positioned on a motor II shaft, a worm is connected with a discharge transmission box in a rotating way, the worm is connected with two clutch gears, the worm is meshed with the worm gear, the worm gear is connected with a worm gear shaft, the worm gear shaft is connected with a discharge transmission box in a rotating way, the worm gear shaft is connected with a belt wheel II, the belt wheel II is connected with a belt wheel III through a belt II, the belt wheel III is connected with a discharge fan blade shaft, the discharge fan blade shaft is connected with a discharge fan blade, the discharge fan shaft is connected with a spherical discharge port, the spherical discharge port is connected with a hopper, and the hopper is connected with a hopper bracket, hopper support is connected with sliding bracket, two spliced poles all rotate with the hopper and are connected, two spliced poles are connected with two telescopic links respectively, two telescopic links respectively with two telescopic link sliding barrel sliding connection, two telescopic link sliding barrels all rotate with the compression roller axle and are connected, the compression roller axle is connected with the compression roller, two pressure spring cup joint respectively on two telescopic links, two pressure spring both ends respectively with two telescopic link sliding barrel, two clamp rings are connected, two pressure spring all are in compression state, two clamp rings contact with two pressure boost inclined planes respectively, two telescopic links respectively with two pressure boost inclined plane sliding connection, two pressure boost inclined planes all are connected with the hopper.
As a further optimization of the technical scheme, the control assembly comprises a gear lever, a gear switching cover, a gear support, a switching ball, a spherical sliding groove, a ball head connecting frame, a discharging control lever and a traveling control lever, wherein the gear lever is connected with the gear switching cover in a sliding manner, the gear switching cover is connected with the gear support, the gear support is connected with the sliding support, the gear lever is connected with the switching ball, the spherical sliding groove is positioned at the bottom of the switching ball, the ball head connecting frame is connected with the spherical sliding groove in a sliding manner, the ball head connecting frame is connected with the discharging control lever, the discharging control lever is connected with a clutch control sliding groove in a sliding manner, the discharging control lever is connected with the gear support in a rotating manner, the traveling control lever is connected with the switching ball and the gear support in a rotating manner, and the traveling control lever is connected with a turning control sliding groove in a sliding manner.
As a further optimization of the technical scheme, the mold vibration assembly comprises a bevel gear III, a bevel gear IV shaft, a hammer, a striking plate, a sliding column, a spring I, a fixed plate, a hollow mold, a spring II, a sliding plate and a striking ball, wherein the shaft of a motor I is connected with the bevel gear III, the bevel gear III is in meshed connection with the bevel gear IV, the bevel gear IV is connected with the bevel gear IV shaft, the bevel gear IV shaft is in rotary connection with a sliding support, the bevel gear IV shaft is connected with the hammer, the striking plate is connected with the sliding column, the sliding column is in sliding connection with the fixed plate, two ends of the spring I are respectively connected with the striking plate and the fixed plate, the spring I is sleeved on the sliding column, the spring I is in a normal state, the fixed plate is connected with the sliding support, the hollow mold is connected with the fixed plate, the sliding column is in sliding connection with the hollow mold, the spring II is connected with the sliding plate, spring II is in the normality, and slide and hollow mould sliding connection, batting all are located inside the hollow mould.
The automatic hollow slab manufacturing equipment has the beneficial effects that: select different gears through control gear pole and can control the hopper to advance respectively, retreat, the ejection of compact, stop the ejection of compact, the hopper is with the compaction of repeatedly paving through the compression roller after the concrete is discharged, the concrete bedding is thicker, the compression roller is bigger to the concrete, at the concrete pressing in-process, hollow mould can produce slight vibration, make tiny gap between the concrete disappear the back by the compression roller flatten, control equipment can release the hollow slab behind the completion hollow slab suppression and suppress indoor and continue the suppression, can easily adjust the length of every hollow slab.
Detailed Description
The present invention will be described in further detail with reference to the accompanying drawings.
The fixed connection in the device is realized by fixing in modes of welding, thread fixing and the like, and different fixing modes are used in combination with different use environments; the rotary connection means that the bearing is arranged on the shaft in a drying mode, a spring retainer ring groove is formed in the shaft or the shaft hole, and the elastic retainer ring is clamped in the retainer ring groove to achieve axial fixation of the bearing and achieve rotation; the sliding connection refers to the connection through the sliding of the sliding block in the sliding groove or the guide rail, and the sliding groove or the guide rail is generally in a step shape, so that the sliding block is prevented from falling off in the sliding groove or the guide rail; the hinge joint is a movable connection mode on connecting parts such as a hinge, a pin shaft, a short shaft and the like; the required sealing positions are sealed by sealing rings or O-shaped rings.
The first embodiment is as follows:
the following describes the present embodiment with reference to fig. 1 to 20, and an automated hollow slab manufacturing apparatus includes a traveling assembly 1, a discharging assembly 2, a control assembly 3, and a mold vibrating assembly 4, where the discharging assembly 2, the control assembly 3, and the mold vibrating assembly 4 are all connected to the traveling assembly 1, and the discharging assembly 2 is connected to the control assembly 3.
The second embodiment is as follows:
the embodiment is described below with reference to fig. 1-20, and the embodiment is further described, wherein the walking assembly 1 comprises a bottom plate 1-1, a pressing chamber 1-2, a sliding support 1-3, a motor I1-4, a motor I shaft 1-5, a walking transmission case 1-6, a walking transmission case upper cover 1-7, a change gear I1-8, a gear I1-9, a gear II 1-10, a gear II shaft 1-11, a change gear II 1-12, a change control lever 1-13, a change control chute 1-14, a change control support 1-15, a shifting ball I1-16, a ball groove sleeve I1-17, a sliding gear I1-18, a sliding gear I chute 1-19, a sliding gear I shaft 1-20, 1-21 parts of bevel gears I, 1-22 parts of bevel gears II, 1-23 parts of bevel gear II shafts, 1-24 parts of belt wheels, 1-25 parts of belts I, 1-26 parts of walking wheel shafts and 1-27 parts of walking wheels, wherein a bottom plate 1-1 is connected with a pressing chamber 1-2, a sliding support 1-3 part is connected with the pressing chamber 1-2 part in a sliding manner, 1-4 parts of a motor I are connected with the pressing chamber 1-2 part, 1-4 parts of the motor I are connected with 1-5 parts of the motor I shafts, 1-5 parts of the motor I are rotationally connected with 1-6 parts of a walking transmission box, 1-6 parts of the walking transmission box are connected with 1-3 parts of the sliding support, 1-6 parts of the walking transmission box are connected with 1-7 parts of an upper cover of the walking transmission box, 1-5 parts of the motor I shafts are connected with 1-8 parts of a change gear I and 1-9 parts of a gear I, the gear I1-9 is meshed with the gear II 1-10, the gear II 1-10 is connected with the gear II shaft 1-11, the gear II shaft 1-11 is rotatably connected with the walking transmission case 1-6, the change gear II 1-12 is connected with the gear II shaft 1-11, the change control lever 1-13 is connected with the change control support 1-15, the change control lever 1-13 is hinged with the walking transmission case upper cover 1-7, the change control chute 1-14 is positioned on the change control lever 1-13, the change control support 1-15 is connected with two shifting balls I1-16, the two shifting balls I1-16 are both in sliding connection with the ball groove of the ball groove sleeve I1-17, the ball groove sleeve I1-17 is connected with the sliding gear I1-18, the sliding gear I1-18 is in sliding connection with the sliding gear I chute 1-19, the sliding gear I chutes 1-19 are positioned on the sliding gear I shaft 1-20, the sliding gear I shaft 1-20 is rotatably connected with the walking transmission case 1-6, the sliding gear I shaft 1-20 is connected with the bevel gear I1-21, the bevel gear I1-21 is meshed with the bevel gear II 1-22, the bevel gear II 1-22 is connected with the bevel gear II shaft 1-23, the bevel gear II shaft 1-23 is rotatably connected with the sliding support 1-3, the bevel gear II shaft 1-23 is connected with one belt wheel I1-24, the two belt wheels I1-24 are connected through a belt I1-25, one belt wheel I1-24 is connected with one walking wheel shaft 1-26, the three walking wheel shafts 1-26 are rotatably connected with the sliding support 1-3, and the three walking wheel shafts 1-26, The shafts 1 to 23 of the bevel gears II are respectively connected with four travelling wheels 1 to 27, the four travelling wheels 1 to 27 are all contacted with the pressing chamber 1 to 2, and the length of the hollow slab can be controlled by controlling the forward and backward movement of the travelling assembly 1.
The third concrete implementation mode:
the following describes the present embodiment with reference to fig. 1-20, and the present embodiment further describes the first embodiment, where the discharging assembly 2 includes a motor ii 2-1, a motor ii shaft 2-2, a discharging transmission case 2-3, a discharging transmission case upper cover 2-4, a clutch control lever 2-5, a clutch control chute 2-6, a clutch control bracket 2-7, a ball-poking ball ii 2-8, a ball-groove sleeve ii 2-9, a sliding gear ii 2-10, a sliding gear ii chute 2-11, a worm 2-12, a clutch gear 2-13, a worm gear 2-14, a worm-gear shaft 2-15, a belt pulley ii 2-16, a belt ii 2-17, a belt pulley iii 2-18, a hopper 2-19, a spherical discharging port 2-20, a discharging fan shaft 2-21, 2-22 parts of discharge fan blades, 2-23 parts of a hopper support, 2-24 parts of telescopic rods, 2-25 parts of telescopic rod sliding cylinders, 2-26 parts of press roll shafts, 2-27 parts of press rolls, 2-28 parts of press springs, 2-29 parts of press rings, 2-30 parts of pressurizing inclined planes and 2-31 parts of connecting columns, 2-1 parts of a motor II is connected with 2-2 parts of a motor II shaft, 2-1 parts of the motor II is connected with 1-3 parts of a sliding support, 2-2 parts of the motor II shaft is rotationally connected with 2-3 parts of a discharge transmission box, 2-3 parts of the discharge transmission box are connected with 1-3 parts of the sliding support, 2-3 parts of the discharge transmission box are connected with 2-4 parts of the discharge transmission box, 2-5 parts of a clutch operating lever are hinged with 2-4 parts of the upper cover of the discharge transmission box, 2-6 parts of a clutch operating chute are positioned on 2-5 parts of the clutch operating lever, the clutch control lever 2-5 is connected with a clutch control bracket 2-7, the clutch control bracket 2-7 is connected with two shifting balls II 2-8, the two shifting balls II 2-8 are both connected with a ball groove sleeve II 2-9 in a sliding way, the ball groove sleeve II 2-9 is connected with a sliding gear II 2-10, the sliding gear II 2-10 is connected with a sliding gear II sliding groove 2-11 in a sliding way, the sliding gear II sliding groove 2-11 is positioned on a motor II shaft 2-2, a worm 2-12 is rotationally connected with a discharging transmission box 2-3, the worm 2-12 is connected with two clutch gears 2-13, the worm 2-12 is meshed with a worm wheel 2-14, the worm wheel 2-14 is connected with a worm wheel shaft 2-15, the worm wheel shaft 2-15 is rotationally connected with the discharging transmission box 2-3, the worm wheel shaft 2-15 is connected with the belt wheel II 2-16, the belt wheel II 2-16 is connected with the belt wheel III 2-18 through a belt II 2-17, the belt wheel III 2-18 is connected with the discharging fan blade shaft 2-21, the discharging fan blade shaft 2-21 is connected with the discharging fan blade 2-22, the discharging fan blade shaft 2-21 is rotatably connected with the spherical discharging port 2-20, the spherical discharging port 2-20 is connected with the hopper 2-19, the hopper 2-19 is connected with the hopper bracket 2-23, the hopper bracket 2-23 is connected with the sliding bracket 1-3, two connecting columns 2-31 are both rotatably connected with the hopper 2-19, the two connecting columns 2-31 are respectively connected with two telescopic rods 2-24, the two telescopic rods 2-24 are respectively connected with two telescopic rod sliding cylinders 2-25 in a sliding way, the two telescopic rod sliding cylinders 2-25 are rotatably connected with the compression roller shafts 2-26, the compression roller shafts 2-26 are connected with compression rollers 2-27, the two compression springs 2-28 are respectively sleeved on the two telescopic rods 2-24, two ends of the two compression springs 2-28 are respectively connected with the two telescopic rod sliding cylinders 2-25 and the two compression rings 2-29, the two compression springs are in a compression state, the two compression rings 2-29 are respectively contacted with the two supercharging inclined planes 2-30, the two telescopic rods 2-24 are respectively in sliding connection with the two supercharging inclined planes 2-30, the two supercharging inclined planes 2-30 are respectively connected with the hopper 2-19, discharging and stopping discharging can be automatically completed by controlling, and concrete can be automatically compacted.
The fourth concrete implementation mode:
the present embodiment is described below with reference to fig. 1-20, and the present embodiment further describes the first embodiment, where the control assembly 3 includes a gear lever 3-1, a gear shift cover 3-2, a gear bracket 3-3, a shift ball 3-4, a ball chute 3-5, a ball joint 3-6, a discharging control lever 3-7, and a walking control lever 3-8, the gear lever 3-1 is slidably connected to the gear shift cover 3-2, the gear shift cover 3-2 is connected to the gear bracket 3-3, the gear bracket 3-3 is connected to the sliding bracket 1-3, the gear lever 3-1 is connected to the shift ball 3-4, the ball chute 3-5 is located at the bottom of the shift ball 3-4, and the ball joint 3-6 is slidably connected to the ball chute 3-5, the ball head connecting frame 3-6 is connected with the discharging control rod 3-7, the discharging control rod 3-7 is in sliding connection with the clutch control chute 2-6, the discharging control rod 3-7 is in rotating connection with the gear support 3-3, the walking control rod 3-8 is in rotating connection with the switching ball 3-4 and the gear support 3-3, and the walking control rod 3-8 is in sliding connection with the direction-changing control chute 1-14, so that the operation of the gear-shifting control equipment can be completed.
The fifth concrete implementation mode:
the embodiment is described below with reference to fig. 1-20, and the embodiment further describes the first embodiment, wherein the mold vibration assembly 4 comprises a bevel gear iii 4-1, a bevel gear iv 4-2, a bevel gear iv shaft 4-3, a hammer 4-4, a striking plate 4-5, a sliding column 4-6, a spring i 4-7, a fixing plate 4-8, a hollow mold 4-9, a spring ii 4-10, a sliding plate 4-11 and a striking ball 4-12, a motor i shaft 1-5 is connected with the bevel gear iii 4-1, the bevel gear iii 4-1 is meshed with the bevel gear iv 4-2, the bevel gear iv 4-2 is connected with the bevel gear iv shaft 4-3, the bevel gear iv shaft 4-3 is rotatably connected with a sliding support 1-3, the bevel gear iv shaft 4-3 is connected with the hammer 4-4, the striking plate 4-5 is connected with the sliding column 4-6, the sliding column 4-6 is connected with the fixed plate 4-8 in a sliding mode, two ends of the spring I4-7 are respectively connected with the striking plate 4-5 and the fixed plate 4-8, the spring I4-7 is sleeved on the sliding column 4-6, the spring I4-7 is in a normal state, the fixed plate 4-8 is connected with the sliding support 1-3, the hollow mold 4-9 is connected with the fixed plate 4-8, the sliding column 4-6 is connected with the hollow mold 4-9 in a sliding mode, the spring II 4-10 is connected with the hollow mold 4-9, the spring II 4-10 is connected with the sliding plate 4-11, the spring II 4-10 is in a normal state, the sliding plate 4-11 is connected with the hollow mold 4-9 in a sliding mode, and the striking balls 4-12 are located inside the hollow mold 4-9, the mould can generate vibration to reduce the gap between the concretes.
The invention relates to automatic hollow slab manufacturing equipment, which has the working principle that: adding the stirred concrete into the hopper 2-19, starting a motor I1-4 and a motor II 2-1, driving a motor I shaft 1-5 to rotate by the motor I shaft 1-4, driving a change gear I1-8 and a gear I1-9 to rotate by the motor I shaft 1-5, driving a gear II 1-10 to rotate by the gear I1-9, driving a gear II shaft 1-11 to rotate by the gear II shaft 1-11, driving a change gear II 1-12 to rotate by the gear II shaft 1-11, wherein a sliding gear I1-18 is not meshed with the change gear I1-8 and the change gear II 1-12, the equipment does not act, driving a motor II shaft 2-2 to rotate by the motor II 2-2, driving a sliding gear II chute 2-11 to drive a sliding gear II 2-10 to rotate, at the moment, the sliding gear II 2-10 is not meshed with the two clutch gears 2-13, the equipment does not discharge materials, the gear rod 3-1 is pushed forwards and backwards or backwards, the gear rod 3-1 cannot drive the walking control rod 3-8 to move, the gear rod 3-1 drives the ball head connecting frame 3-6 to rotate through the spherical chute 3-5, the ball head connecting frame 3-6 drives the discharging control rod 3-7 to rotate, the discharging control rod 3-7 drives the clutch control rod 2-5 through the clutch control chute 2-6, the walking control rod 3-8 is rotationally connected with the switching ball 3-4, the walking control rod 3-8 does not move, the gear rod 3-1 is pushed leftwards or rightwards, the ball head connecting frame 3-6 slides in the spherical chute 3-5, the ball head connecting frame 3-6 does not move with the discharging control rod 3-7, the switching ball 3-4 drives the walking control rod 3-8 to shift the direction-changing control rod 1-13 by shifting the direction-changing control chute 1-14, if the gear rod 3-1 is shifted back and forth and then shifted left and right first, the switching ball 3-4 drives the discharging control rod 3-7 and the walking control rod 3-8 to simultaneously shift the clutch control rod 2-5 and the direction-changing control rod 1-13, when the direction-changing control rod 1-13 is shifted left and right, the direction-changing control rod 1-13 rotates around the hinge shaft, the direction-changing control rod 1-13 drives the direction-changing control bracket 1-15 to move, the direction-changing control bracket 1-15 drives the two shifting balls I1-16 to move, the two shifting balls I1-16 drive the ball-groove sleeve I1-17 to move, the ball-groove sleeve I1-17 drives the sliding gear I1-18 to slide in the sliding gear I chute 1-19, thus, the engagement of the sliding gears I1-18 with the direction changing gears I1-8 or the direction changing gears II 1-12 is controlled by controlling the direction changing control levers 1-13, the direction changing gears I1-8 and the direction changing gears II 1-12 have opposite rotating directions, the rotating directions of the sliding gears I1-18 are changed by controlling the engagement relationship of the sliding gears I1-18, the sliding gears I1-18 drive the sliding gears I1-20 to rotate by driving the sliding gears I chutes 1-19, the sliding gears I1-20 drive the bevel gears I1-21 to rotate, the bevel gears I1-21 drive the bevel gears II 1-22 to rotate, the bevel gears II 1-22 drive the bevel gears II shafts 1-23 to rotate, and the bevel gears II shafts 1-23 drive the belt pulleys I1-24 to rotate, the belt wheels I1-24 drive the other belt wheel I1-24 to rotate through belts I1-25, the other belt wheel I1-24 drives the traveling wheel shaft 1-26 to rotate, the bevel gear II shaft 1-23 and the traveling wheel shaft 1-26 respectively drive the two traveling wheels 1-27 to rotate, the traveling wheels 1-27 are all contacted with the pressing chamber 1-2, the traveling wheels 1-27 rotate forward or reversely to drive the equipment to move forward or backward, when the clutch control lever 2-5 is shifted forward or backward, the clutch control lever 2-5 rotates around a hinge shaft, the clutch control lever 2-5 drives the clutch control bracket 2-7 to rotate, the clutch control bracket 2-7 drives the ball groove sleeve II 2-9 to move forward and backward through the two shifting balls II 2-8, the ball groove sleeve II 2-9 drives the sliding gear II 2-10 to slide in the sliding gear II sliding groove 2-11, therefore, the sliding gear II 2-10 is controlled to be meshed with the two clutch gears 2-13 by operating the clutch operating lever 2-5, the motor II 2-1 drives the motor II shaft 2-2 to rotate, and the motor II shaft 2-2 drives the sliding gear II 2-10 to rotate through the sliding groove 2-11 of the sliding gear II. The sliding gear II 2-10 drives the clutch gear 2-13 to rotate, the clutch gear 2-13 drives the worm 2-12 to rotate, the worm 2-12 drives the worm wheel 2-14 to rotate, the worm wheel 2-14 drives the worm wheel shaft 2-15 to rotate, the worm wheel shaft 2-15 drives the belt wheel II 2-16 to rotate, the belt wheel II 2-16 drives the belt wheel III 2-18 to rotate through the belt II 2-17, the belt wheel III 2-18 drives the discharging fan blade shaft 2-21 to rotate, the discharging fan blade shaft 2-21 drives the discharging fan blade 2-22 to rotate to discharge concrete, the concrete in the hopper 2-19 is blocked by the discharging fan blade 2-22 under the action of gravity when the discharging fan blade 2-22 does not rotate, because of the self-locking action of the worm wheel 2-14 and the worm 2-12, the discharging fan blades 2-22 can not rotate under the pressure of concrete, so that discharging is finished, if the gear rod 3-1 is firstly shifted forwards and backwards and then shifted left and right, the spherical discharging port 2-20 can move forwards or backwards and discharge the concrete, the concrete falls into the pressing chamber 1-2 on the hollow mould 4-9, the hopper 2-19 drives the two connecting columns 2-31 to move, the two connecting columns 2-31 drive the two telescopic rods 2-24 to move, the two telescopic rods 2-24 drive the two telescopic rod sliding cylinders 2-25 to move, the two telescopic rod sliding cylinders 2-25 drive the pressing roll shafts 2-26 to move, the pressing roll shafts 2-26 drive the pressing rolls 2-27 to contact with the concrete to press the concrete, and as the concrete is higher and higher, the pressing rolls 2-27 drive the connecting columns 2-31 to rotate through the transmission, the telescopic rod 2-24 rotates to drive the compression spring 2-28 and the compression ring 2-29 to rotate, the compression ring 2-29 slides upwards along the pressurizing inclined plane 2-30, the compression spring 2-28 is further compressed, the pressure of the compression spring 2-28 on the telescopic rod sliding barrel 2-25 is increased, the pressure of the compression roller 2-27 on the concrete is increased through the transmission process, so that the concrete is completely compacted by the compression roller 2-27, the quality of the hollow plate is ensured, the motor I shaft 1-5 drives the bevel gear III 4-1 to be increased, the bevel gear III 4-1 drives the bevel gear IV 4-2 to rotate, the bevel gear IV 4-2 drives the bevel gear IV shaft 4-3 to rotate, the bevel gear IV shaft 4-3 drives the hammer 4-4 to rotate to strike the plate 4-5, the strike plate 4-5 drives the sliding column 4-6 to rotate on the fixing plate 4-8 and the hollow mould 4-9 Sliding to knock a ball 4-12, knocking the ball 4-12 to collide with each other in a hollow mould 4-9, knocking the ball 4-12 to collide with a sliding plate 4-11 to drive a spring II 4-10 to compress, rebounding to rebound the ball 4-12 to continue to collide with the hollow mould 4-9, so that the hollow mould 4-9 is driven to generate slight vibration in a reciprocating way, small gaps of concrete around the hollow mould 4-9 disappear and then are compacted by a press roller, the quality of the hollow plate is better, after the compaction is finished, a sliding support 1-3 is controlled to advance, the sliding support 1-3 drives a fixing plate 4-8 to advance to push the hollow plate in a compaction chamber 1-2 to a bottom plate 1-1, then retreating to draw the hollow mould 4-9 out of the concrete to finish the manufacture of the hollow plate, at this time, the hollow plate can be cut off to finish the compaction or continue to be connected with a front section hollow plate, the hollow slab can be operated according to the length requirement of the hollow slab.
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.