阅读说明：本技术 多工位自动旋转盘压榨线 (Multi-station automatic rotating disc squeezing line ) 是由 沈琪 徐俊伟 赵庆隆 苏鸿志 罗鸿顺 陆夏 章法江 沈丹云 罗清元 于 2021-08-31 设计创作，主要内容包括：本发明公开了多工位自动旋转盘压榨线,布料装置与压榨装置连接,压榨装置与出渣漂洗叠布装置连接,压榨装置包括压榨机、底盘和不少于三个压榨笼,底盘用于切换压榨笼与布料装置、压榨机和出渣漂洗叠布装置连接；压榨笼内设置有多功能升降板,与布料装置或出渣漂洗叠布装置连接的压榨笼内的多功能升降板与升举装置连接,升举装置能够在布料或出渣阶段使多功能升降板上的物料高度在所需高度,同时多功能升降板在压榨笼底部时能够对压榨笼底部密封达到液体不外溢。该种压榨流水线通过优化压榨笼结构,使压榨笼能够满足布料、压榨和出渣漂洗叠布工序的要求,同时压榨装置能够同时对不同压榨笼进行布料、压榨和出渣漂洗叠布,大幅提高了效率。(The invention discloses a multi-station automatic rotating disc pressing line, wherein a material distribution device is connected with a pressing device, the pressing device is connected with a slag-tapping rinsing and cloth-stacking device, the pressing device comprises a presser, a chassis and at least three pressing cages, and the chassis is used for switching the connection of the pressing cages with the material distribution device, the presser and the slag-tapping rinsing and cloth-stacking device; be provided with multi-functional lifter plate in the press cage, the multi-functional lifter plate in the press cage of being connected with distributing device or slag discharge rinsing overlapping device is connected with the lifting device, and the lifting device can make the material height on the multi-functional lifter plate at required height in cloth or slag discharge stage, and multi-functional lifter plate can be sealed the reaching liquid of press cage bottom when squeezing the cage bottom simultaneously and not excessive. This kind of squeeze assembly line squeezes the cage structure through optimizing, makes and squeezes the cage and can satisfy the cloth, squeeze and the requirement of slagging tap rinsing overlapping cloth process, squeezes the device simultaneously and can carry out the cloth, squeeze and the rinsing overlapping cloth of slagging tap to different press cages, has improved efficiency by a wide margin.)

1. Line is squeezed to automatic rotary disk of multistation, distributing device (1) with squeeze device (2) and be connected, squeeze device (2) and go out the slag rinsing and fold cloth device (3) and be connected its characterized in that: the squeezing device (2) comprises a squeezer (5), a chassis (6) and at least three squeezing cages (7), and the chassis (6) connected with the squeezing cages (7) and the distributing device (1), the squeezer (5) and the slag-discharging rinsing and cloth-overlapping device (3) are switched to be connected with the squeezing cages (7).

2. The multi-station automatic rotating disc press line according to claim 1, wherein: the multifunctional lifting plate (21) is arranged in the squeezing cage (7), and the multifunctional lifting plate (21) in the squeezing cage (7) connected with the distributing device (1) and the slag-discharging rinsing and cloth-folding device (3) is connected with the lifting device (20).

3. The multi-station automatic rotating disc press line according to claim 2, wherein: a lifting frame (22) is arranged at the joint of the squeezing cage (7) and the chassis (6), and the lifting device (20) penetrates through the lifting frame (22) when the multifunctional lifting plate (21) is connected with the lifting device (20).

4. A multi-station automatic rotating disc press line according to claim 3, wherein: when the multifunctional lifting plate (21) is positioned at the bottom of the pressing cage (7), the multifunctional lifting plate (21) is hermetically connected with the lifting frame (22), the bottom of the pressing cage (7) is connected with the liquid receiving disc (26), and the liquid receiving disc (26) is connected with the liquid discharge pipe (28).

5. The multi-station automatic rotating disc press line according to claim 4, wherein: the edge of the lifting frame (22) is provided with a female groove (27) which faces the opening of the squeezing cage (7), the bottom surface of the multifunctional lifting plate (21) is provided with a male groove (29) matched with the female groove (27), and the outer edge of the male groove (29) is provided with a drip-proof backflow groove (33).

6. The multi-station automatic rotating disc press line according to claim 2, wherein: a gap is arranged between the edge of the multifunctional lifting plate (21) and the inner wall of the squeezing cage (7), and a moving guide device is arranged at the edge of the multifunctional lifting plate (21).

7. The multi-station automatic rotating disc press line according to claim 1, wherein: the side wall of the chassis (6) is provided with an annular edge groove (23), a plurality of pin shafts (24) are uniformly distributed in the edge groove (23), a gap between every two adjacent pin shafts (24) is meshed with teeth of the driving wheel (17), and the driving wheel (17) is in transmission connection with the driver (15).

8. The multi-station automatic rotating disc press line according to claim 7, wherein: the height of the pin shaft (24) is larger than the thickness of the driving wheel (17), a plurality of lifting wheel sets (9) used for adjusting the height of the chassis (6) are uniformly distributed below the chassis (6), and a base (11) used for bearing pressure is arranged below the chassis (6).

Technical Field

The invention relates to the technical field of solid-liquid separation equipment for materials in environment-friendly sludge dewatering (food) processing, in particular to a multi-station automatic rotating disc squeezing line.

Background

Traditional cloth technology adopts the mode of cloth piece manual operation formula, uses the different sola filter cloth of many two kinds of specifications, and many people are repeated, pursue a successive layer, manual parcel, upset cover, folding pile up neatly, and inefficiency is wasted time and energy, and current patent "automatic brute force of sauce form material squeezes line" application number: CN201410588802.9 discloses a press line, but the feeding, pressing and discharging of the press line are all operated in a fixed press cage, resulting in high time consumption and low efficiency of the process.

Disclosure of Invention

The purpose of the invention is as follows: the invention aims to improve the overall efficiency of a squeezing production line and realize intermittent automatic flow operation.

The technical scheme is as follows: the invention aims to realize the aim, and discloses a multi-station automatic rotating disc pressing line, wherein a material distribution device is connected with a pressing device, the pressing device is connected with a slag-tapping rinsing and cloth-folding device, the pressing device comprises a presser, a chassis and at least three pressing cages, and the chassis used for switching the connection of the pressing cages with the material distribution device and the connection of the presser and the slag-tapping rinsing and cloth-folding device is connected with the pressing cages.

Preferably, a multifunctional lifting plate is arranged in the squeezing cage, and the multifunctional lifting plate in the squeezing cage connected with the distributing device and the slag discharging, rinsing and cloth stacking device is connected with the lifting device.

Furthermore, a lifting frame is arranged at the joint of the squeezing cage and the chassis, and the lifting device penetrates through the lifting frame when the multifunctional lifting plate is connected with the lifting device.

Furthermore, when the multifunctional lifting plate is positioned at the bottom of the squeezing cage, the multifunctional lifting plate is hermetically connected with the lifting frame, the bottom of the squeezing cage is connected with the liquid receiving disc, and the liquid receiving disc is connected with the liquid discharge pipe.

Further, lift frame edge setting towards the female groove of squeezing cage open-ended, multi-functional lifter plate bottom surface sets up the public groove of suiting with female groove, and public groove outward flange is provided with the antidrip refluence groove.

Furthermore, a gap is arranged between the edge of the multifunctional lifting plate and the inner wall of the squeezing cage, and a moving guide device is arranged at the edge of the multifunctional lifting plate.

Preferably, the side wall of the chassis is provided with an annular edge groove, a plurality of pin shafts are uniformly distributed in the edge groove, gaps between adjacent pin shafts are meshed with teeth of the driving wheel, and the driving wheel is in transmission connection with the driver.

Furthermore, the height of the pin shaft is larger than the thickness of the driving wheel, a plurality of lifting wheel sets used for adjusting the height of the chassis are uniformly distributed below the chassis, and a base used for bearing pressure is arranged below the chassis.

The base plate rotates under the driving of the transmission mechanism, and is connected with the base plate through simultaneously switching different squeezing cages, a distributing device, a squeezer and a deslagging rinsing and cloth folding device, so that the distributing device can distribute materials into the squeezing cage connected with the distributing device layer by layer uniformly at the same time, the squeezer squeezes the materials in the squeezing cage connected with the squeezer, and the deslagging rinsing and cloth folding device discharges the materials in the squeezing cage connected with the squeezing cage and cleans and bears filter cloth; three squeezing cages are no less than arranged to rotate so as to ensure that the distributing device, the squeezer and the residue-discharging rinsing and cloth-stacking device can work simultaneously. The specific structures of the distributing device and the slag-tapping rinsing and cloth-stacking device are both in the prior art.

The multi-functional lifter plate in the pressing cage is used for piling up the material of piling up the multilayer setting, because the pressing cage opening upwards vertically sets up, need through the high position of the multi-functional lifter plate of lifting device adjustment in the pressing cage, the multi-functional lifter plate of lifting device adjustment reduces the height gradually along with the increase that the material piled up the number of piles at the cloth in-process, and the multi-functional lifter plate of lifting device adjustment is piling up the reduction that the number of piles increased gradually along with the material at the in-process of slagging tap.

Furthermore, because the height of the multifunctional lifting plate does not need to be adjusted in the squeezing process, the cloth distributing device and the joint of the slag-out rinsing stacking device and the squeezing device are respectively provided with an independent lifting device, the lifting device is positioned below the chassis and is mutually independent with the chassis, when the squeezing cage is connected with the cloth distributing device or the slag-out rinsing stacking device, the lifting device is positioned under the squeezing cage, and the lifting device can penetrate through a lifting frame preset on the chassis to be connected with the multifunctional lifting plate to complete the adjustment of the height of the multifunctional lifting plate. When the lifting device is separated from the multifunctional lifting plate, the rotation of the chassis is not influenced.

When the squeezing cage is connected with the squeezer, the squeezing end of the squeezer stretches into the squeezing cage from top to bottom, squeezing of materials stacked on the surface of the multifunctional lifting plate is completed, the multifunctional lifting plate is located at the bottom of the squeezing cage in the squeezing process, the multifunctional lifting plate is connected with the lifting frame in a sealing mode, juice generated by squeezing is guaranteed to flow into the liquid receiving disc and cannot leak out of the lifting frame, and the closed liquid receiving disc is arranged at the bottom of each squeezing cage. Furthermore, the juice that squeezes the production flows into the liquid receiving dish of below by the clearance between multi-functional lifter plate and the squeezing cage inner wall in, sets up guider in multi-functional lifter plate edge and is used for eliminating rocking, the skew when multi-functional lifter plate that leads to because the clearance goes up and down. The edge of the base plate is also provided with an annular liquid collecting groove, and juice flowing out of the liquid discharge pipe can be collected no matter the pressing cage moves to any position on the annular path.

Further, multi-functional lifter plate edge sets up the oblique decurrent water conservancy diversion slope that heels outwards, squeeze the multi-functional lifter plate of juice outflow that produces with higher speed, multi-functional lifter plate lower surface still is provided with the bearing beam that is used for improving bearing capacity, when multi-functional lifter plate is located the press cage bottom, the male slot embedding that multi-functional lifter plate bottom surface set up lifts the female inslot at frame edge, the location of multi-functional lifter plate has been accomplished promptly, simultaneously will lift sealedly, male slot and female groove are uncovered external slope structure, even after the male slot falls into the female inslot, the lateral wall of female groove slope can be fixed a position multi-functional lifter plate automatically. The drip-proof reverse flow groove on the bottom surface of the multifunctional lifting plate ensures that the flowing juice cannot flow into the lifting frame.

The tooth of drive mechanism's action wheel can imbed in the clearance of adjacent round pin axle in proper order when rotating, forms the form of meshing, and on the basis of this structure, the chassis can rotate under the drive of action wheel, and the action wheel is used for controlling the direction of rotation and the slew velocity on chassis.

Furthermore, the outside parcel of round pin axle has rotatable cylinder, reduces the wearing and tearing between round pin axle and the action wheel through setting up the cylinder.

Further, a plurality of lifting wheel groups jointly form a multipoint hydraulic synchronous lifting system, the multipoint hydraulic synchronous lifting system comprises a hydraulic system group oil cylinder lifting frame, supporting rollers are arranged between the hydraulic system group oil cylinder and the lower surface of the chassis, the system can adjust the height of the chassis, and the supporting rollers can rotate along with the chassis when the chassis rotates. When the squeezer squeezes materials in the squeezing cage, the lifting wheel set drives the chassis to be reduced in height, and the bottom surface of the chassis is supported by the base, so that the lifting wheel set can be prevented from being damaged, and the deformation caused by overlarge stress on the chassis can be eliminated; when the position of the squeezing cage needs to be adjusted in a rotating mode, the lifting wheel set lifts the chassis, and the chassis is supported by the base after being rotated to a set position and then lowered.

In the process of converting the station of the squeezing cage by the chassis, the chassis is located on the positioning point after reaching the set position, so that the simultaneous positioning of multiple points is achieved, and the respective work is developed.

Further, the chassis is of an annular structure, and the chassis center positioning device is arranged on the inner annular wall of the chassis to limit in the horizontal direction, so that the chassis can stably rotate around the central shaft when the driving wheel drives. And meanwhile, when the chassis rotates to the position, the chassis is controlled by the limiter, falls on the conical positioning pin fixed on the plane of the base and is positioned in a matching way with the positioning hole of the chassis, so that the chassis can work accurately and stably.

Has the advantages that: compared with the prior art, the invention has the following remarkable advantages:

1. through set up a plurality of press cages on rotatable chassis, make cloth, squeeze and go on in the press cage that corresponds simultaneously with slagging tap, utilize the rotation on chassis to adjust the press cage station, greatly improved work efficiency on automatic basis.

2. The multifunctional lifting plate structure in the pressing cage can guarantee the sealing of the bottom of the pressing cage in the pressing process, and can also be matched and connected with a distributing device and a slag discharging and rinsing stacking device in the material distribution and slag discharging processes, so that the functional requirements of the system can be met.

Drawings

FIG. 1 is a schematic view of a press line configuration of the present invention.

FIG. 2 is a schematic view of the press apparatus of the present invention.

Fig. 3 is a schematic structural diagram of a transmission mechanism, a lifting device and a lifting wheel set in the invention.

Fig. 4 is a schematic structural view of the multifunctional lifting plate lifted by the lifting device of the present invention.

Fig. 5 is a top view of the chassis of the present invention.

Fig. 6 is a schematic view of the engagement structure of the driving wheel and the pin shaft in the invention.

Fig. 7 is a side view of the press apparatus of the present invention.

FIG. 8 is a schematic diagram of the position structure of the multifunctional lifting plate, the lifting frame and the liquid receiving tray in the invention.

Fig. 9 is a plan view of the multi-function lifter plate of the present invention.

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

Fig. 11 is a schematic view of the structure of the horizontal wheel in the present invention.

FIG. 12 is a schematic view of the structure of a tapered locating pin on the upper surface of a base in the present invention.

FIG. 13 is a schematic view showing a construction of a multi-stage cylinder used in the lifting apparatus of the present invention.

Detailed Description

The technical solution of the present invention is further described in detail with reference to the accompanying drawings and examples.

As shown in fig. 1 and 2, in the multi-station automatic rotating disc press line, a material distribution device 1 is connected with a press device 2, the press device 2 is connected with a slag-out rinsing and cloth-folding device 3, a single-arm rotating crane 4 is arranged around the press device 2, and the working range of the single-arm rotating crane 4 can cover the press device 2; the squeezing device 2 comprises a squeezer 5, a chassis 6 and four squeezing cages 7, the chassis 6 is driven by a transmission mechanism 8 to rotate and is used for switching the connection of the squeezing cages 7 with the distributing device 1, the squeezer 5 and the slag-tapping rinsing and cloth-folding device 3, the distributing device 1 distributes the materials into the squeezing cages 7 connected with the distributing device layer by layer uniformly at the same time, the squeezer 5 squeezes the materials in the squeezing cages 7 connected with the squeezer 5, and the slag-tapping rinsing and cloth-folding device 3 discharges the materials in the squeezing cages 7 connected with the squeezer and cleans and bears the filter cloth; the four squeezing cages 7 are arranged for rotation so as to ensure that the distributing device 1, the squeezer 5 and the slag-tapping rinsing and cloth-stacking device 3 can work simultaneously; each squeezing cage 7 is driven by the chassis 6 to realize the circulation of distributing, squeezing and discharging slag.

In this embodiment, chassis 6 is the ring circular structure, and 6 levels on chassis set up, and a plurality of lifting wheelsets 9 of circumference evenly distributed are all followed to the outward flange below and the inward flange below of chassis 6, and every lifting wheelset 9 includes raiser 19 and supporting roller 18, and raiser 19's lift portion supports chassis 6 through supporting roller 18. The lifter 19 adopts a short-range hydraulic oil cylinder, and the lifting of the lifter 19 can drive the chassis to ascend or descend in the vertical direction. When the chassis 6 rotates under the drive of the transmission mechanism 8, the supporting rollers 18 rotate along with the chassis 6, so that the chassis 6 can be limited in the vertical direction, and the stability of the system is improved. Meanwhile, the inner wall of the chassis 6 is connected with a chassis center positioning device, and the chassis center positioning device can limit the chassis 6 in the horizontal direction, so that the chassis 6 can rotate around the center of the chassis when rotating.

In this embodiment, as shown in fig. 3, the transmission mechanism 8 includes a driver 15, an output shaft of the driver 15 is in transmission connection with a driving wheel 17 through a transmission 16, and the driving wheel 17 is in transmission connection with the chassis 6 and is used for driving the chassis 6 to rotate and controlling the rotation speed and the rotation direction of the chassis 6; because the diameter of the chassis 6 is large, the machining of teeth on the outer wall of the chassis 6 is complex, and therefore the machining of the teeth is replaced by the pin shafts 24, as shown in fig. 6, annular edge grooves 23 are formed on the outer side wall of the chassis 6 by utilizing channel steel machining, the pin shafts 24 are uniformly and vertically arranged in the edge grooves 23 according to a set interval, so that the gear teeth of the driving wheel 17 can be meshed with gaps between adjacent pin shafts 24, and the chassis 6 can be driven to rotate when the driving wheel 17 rotates; furthermore, the outer surface of each pin shaft 24 is wrapped with a roller 25, the rollers 25 and the pin shafts 24 are coaxially arranged, and the rollers 25 can rotate relative to the pin shafts 24, so that friction between driving gear teeth and the pin shafts when the driving gear 17 drives the chassis 6 to rotate is reduced. Further, the length of the pin shaft 24 in the edge groove 23 is larger than the thickness of the gear teeth of the driving wheel 17, and when the chassis 6 is driven by the lifting wheel set 9 to move in the vertical direction, the chassis 6 can be engaged with the driving wheel 17 in a transmission manner all the time.

In this embodiment, the chassis center positioning device includes a plurality of horizontal wheels 10, the plurality of horizontal wheels 10 are distributed along the central circumference of the chassis, each horizontal wheel 10 is in close contact with the inner side wall of the chassis 6, and the central axes of the horizontal wheels 10 are fixed by the rack, as shown in fig. 11. When the chassis 6 rotates, the horizontal wheel 10 rotates along with the rotation, and the horizontal wheel 10 is fixed in position and is in close contact with the inner side wall of the chassis 6 from different directions, so that the chassis 6 is limited in the horizontal direction; when the chassis 6 is driven by the lifting wheel set 9 to move in the vertical direction, the horizontal wheels 10 can be in close contact with the inner side wall of the chassis 6.

In this embodiment, four squeezing cages 7 are mounted on the upper surface of a horizontally arranged chassis 6, the four groups of squeezing cages 7 are uniformly distributed along the circumference of the chassis 6, the openings of the squeezing cages 7 are vertically arranged upwards, and lifting frames 22 are arranged at the joints of the chassis 6 and the squeezing cages 7, as shown in fig. 5; lifting devices 20 are arranged below the connection part of the pressing cage 7 and the distributing device 1 and below the connection part of the pressing cage 7 and the automatic cloth stacking device 3 for residue discharge rinsing, as shown in fig. 3, the lifting devices 20 are fixed below the chassis 6, and when the pressing cage 7 needs to be distributed or residue discharged, the lifting devices 20 are lifted and penetrate through a lifting frame 22 for adjusting the height of a multifunctional lifting plate 21 in the pressing cage 7, as shown in fig. 4. When the lifting device 20 is separated from the contact with the multifunctional lifting plate 21, the highest point of the lifting device 20 is lower than the bottom surface of the chassis 6, and the rotation of the chassis 6 is not interfered. Further, the lifting device 20 may also be a multi-stage cylinder, as shown in fig. 13.

In this embodiment, as shown in fig. 8, the edge of the upper surface of the lifting frame 22 is provided with a female slot 27 with an opening inclined outward, and when the male slot 29 arranged on the lower surface of the multifunctional lifting plate 21 falls into the bottom of the squeezing cage 7, the male slot 29 can be completely embedded into the female slot 27; because the opening size of the female slot 27 gradually increases towards the opening direction, when the male slot 29 deviates in a small range and falls into the female slot, the inclined outer wall of the female slot 27 can enable the male slot 29 to be automatically aligned, and meanwhile, the female slot 27 and the male slot 29 are embedded to form stable support of the multifunctional lifting plate 21. The lower surface of the multifunctional lifting plate 21 is provided with a bearing beam 30, the bearing beam 30 is of an annular rib plate structure, the strength of the multifunctional lifting plate 21 can be improved, and the deformation of the multifunctional lifting plate in the squeezing process is reduced. The bottom of the squeezing cage 7 is provided with a liquid receiving disc 26, the liquid receiving disc 26 is connected with a liquid discharge pipe 28, when the female groove 27 is embedded with the male groove 29, juice generated by squeezing flows into the liquid receiving disc 26 from the surface of the multifunctional lifting plate 21 and is discharged by the liquid discharge pipe 28, each liquid discharge pipe 28 rotates along with the chassis 6, therefore, an annular liquid collecting groove is arranged around the chassis 6, and the juice flowing out of the liquid discharge pipe 28 can be collected no matter the squeezing cage 7 moves to any position on an annular path. The joint of the female groove 27 and the chassis 6 is welded to form a liquid-tight weld, the joint of the bottom of the pressing cage 7 and the chassis 6 is welded to form a liquid-tight weld, and the liquid-tight weld ensures the liquid-tightness of the liquid receiving plate 26.

In this embodiment, as shown in fig. 9, the cross section of the squeezing cage 7 and the multifunctional lifting plate 21 are both quadrilateral, a gap is provided between the edge of the multifunctional lifting plate 21 and the inner wall of the squeezing cage 7, the juice generated by squeezing flows into the liquid receiving tray 26 through the gap, the edge of the upper surface of the multifunctional lifting plate 21 is provided with the flow guiding slope 32, the flow guiding slope 32 inclines outwards and downwards, the juice can flow out with higher speed, the lower surface of the multifunctional lifting plate 21 is provided with the anti-dripping and anti-flowing groove 33, the anti-dripping and anti-flowing groove 33 is provided at the outer side of the bottom of the male groove 29, the embedded part can be sealed after the female groove 27 and the male groove 29 are embedded, the flow path of the liquid can be cut after the multifunctional lifting plate 21 is lifted, and the juice is prevented from dropping into the lifting frame 22 along the male groove 29. The drip-proof counter flow groove 33 is formed by being surrounded by a groove with an opening facing downward. Because a gap is arranged between the edge of the multifunctional lifting plate 21 and the inner wall of the squeezing cage 7, the multifunctional lifting plate 21 is guided by arranging guide wheels 31 at four corners of the multifunctional lifting plate 21. As shown in fig. 10, the edge of the guide roller 31 is chamfered to improve the stability of contact with the corner of the press cage 7.

In this embodiment, the presser 5 is disposed between the discharging end of the distributing device 1 and the feeding end of the slag-discharging rinsing and cloth-folding device 3, the presser 5 includes a base 11, a column 12, an upper beam 13 and a press 14, the base 11 is fixed below the chassis 6, the press 14 mounted on the upper beam 13 is located above the chassis 6, after the pressing cage 7 moves to the pressing station, the base 11 is located under the pressing cage 7, and the pressing part of the press 14 is located over the top opening of the pressing cage 7. The upper beam 13 is connected to the base 11 via the upright 12. Before the press machine 14 presses the materials on the multifunctional lifting plate 21 in the pressing cage 7 through the pressing part, the lifting wheel set 9 drives the chassis 6 to move downwards to be in contact with the base 11, the base 11 bears the pressing force of the press machine 14, the deformation of the chassis 6 is reduced, and after the pressing is completed, the lifting wheel set 9 drives the chassis 6 to move upwards to be separated from the contact with the base 11, and the rotation of the pressing cage 7 is prepared. When the base plate 11 supports the base plate 6, the base plate 6 is placed on the tapered positioning pin 34 fixed on the plane of the base plate 11 and is positioned in the matching manner with the positioning hole of the base plate, as shown in fig. 12.

In this embodiment, when the material is distributed by the press device 2, the chassis 6 drives a press cage 7 to move below the discharge end of the material distribution device 1, at this time, the lifting device 20 passes through the lifting frame 22 to lift the multifunctional lifting plate 21 to the top of the press cage 7, the material distribution device 1 spreads and conveys the wrapped and leveled material to the multifunctional lifting plate 21 in a reciprocating manner, the lifting device 20 drives the multifunctional lifting plate 21 to gradually descend along with the increase of the material until the press cage 7 is filled, at this time, the male groove 29 at the bottom of the multifunctional lifting plate 21 is embedded into the female groove 27, the lifting device 20 is separated from the multifunctional lifting plate 21, and the material distribution is finished.

After the squeezing cage 7 finishes material distribution, the lifting wheel set 9 synchronously rises to lift the chassis 6 upwards, the transmission mechanism 8 drives the chassis 6 to rotate to move the squeezing cage 7 which finishes material distribution to the lower part of the press machine 14, after the squeezing cage 7 is positioned, the lifting wheel set 9 synchronously descends until the chassis 6 is supported by the base 11, and the press machine 14 starts to work until squeezing is finished.

After squeezing, lift wheelset 9 rises in step once more and upwards lifts chassis 6, drive chassis 6 by drive mechanism 8 and rotate and will accomplish the squeezing cage 7 that squeezes and remove to 3 feed end tops of rinsing laminating device of slagging tap, lifting device 20 passes lift frame 22 again and goes on to slag tap rinsing laminating device 3 automation to multi-functional lifter plate 21 this moment and slag tap, wash the cloth, the laminating operation, along with the change of material height, lifting device 20 lifts multi-functional lifter plate 21, with the material height with 3 feed end parallel and level of the rinsing laminating device of slagging tap, until slagging tap, the laminating operation finishes.

In conclusion, the squeezing assembly line provided by the invention is provided with the plurality of squeezing cages capable of rotating stations, so that the material distribution, squeezing and slag discharge overlapping can be synchronously carried out, meanwhile, the structure of the squeezing cages can simultaneously adapt to the work flow and the work requirements of the material distribution, squeezing and slag discharge overlapping, the structure is simplified and stable, the labor is reduced, the automation is realized, and the squeezing efficiency is improved.