CN117644093A - Recovery processing device of printing waste container - Google Patents

Abstract

The application provides a printing waste container's recovery processing device belongs to printing waste treatment technical field, includes: the base is provided with a first cylinder on the side wall, and a lifting frame is arranged at the execution end of the first cylinder; the hollow shaft is rotationally connected to the base, the lower end of the hollow shaft is rotationally connected with a rotary joint, the side wall of the hollow shaft is fixedly connected with a sleeve, an air pipe is slidingly connected inside the sleeve, a hollow box is fixedly connected to the air outlet of the air pipe, the upper end of the hollow shaft is fixedly connected with a hollow plate, exhaust holes are formed in the outer wall of the hollow box and the outer wall of the hollow plate in an array manner, and wiping gaskets are arranged on the outer wall of the hollow box and the outer wall of the hollow plate; the telescopic rod is rotationally connected between the hollow shaft and the air pipe, and a built-in sucker is hinged on an extension arm of the telescopic rod in a spherical manner; a driving mechanism; an inner wall cleaning mechanism; an outer wall cleaning mechanism; the application can promote the adsorption effect of the built-in sucking disc on the inner wall of the printing waste container.

Description

Recovery processing device of printing waste container

Technical Field

The application relates to the technical field of printing waste treatment, in particular to a recycling device for a printing waste container.

Background

The printing waste container is used for collecting and storing printing waste, and is convenient for treating and recycling the printing waste. Such containers typically have sufficient strength and durability to contain various types of printing waste. In the recycling process of the printing waste container, the container is polluted by the printing waste, so that the inner and outer surfaces of the printing waste container are required to be cleaned so as to clean the printing waste remained on the printing waste container.

With reference to the chinese patent publication No. CN112090907B, entitled a printing waste recycling system, the printing waste container can be positioned from the outside by using an external suction cup during cleaning of the inner wall of the printing waste container, and then can be positioned from the inside by using an internal suction cup during cleaning of the outer wall of the printing waste container.

With reference to the above technical scheme, after finishing the cleaning work of the inner wall of the printing waste container, the inner wall of the printing waste container can have the condition of water drop residue, and when the subsequent cleaning work of the outer wall of the printing waste container is carried out, the adsorption effect of the built-in sucking disc on the printing waste container can be affected to a certain extent.

Disclosure of Invention

In view of this, the application provides a printing waste container's recovery processing device, after accomplishing printing waste container's inner wall cleaning work, can weather printing waste container's inner wall's water droplet with the help of outside hot air current, reduces the probability that the slip condition appears when built-in sucking disc adsorbs printing waste container inner wall for printing waste container's outer wall cleaning work normally launch in the follow-up step.

In order to solve the above technical problem, the present application provides a recycling device for a printing waste container, comprising: the base is provided with a first air cylinder on the side wall, and a lifting frame is arranged at the execution end of the first air cylinder; the hollow shaft is rotationally connected to the base and extends to the inside of the base, the lower end of the hollow shaft is rotationally connected with a rotary joint which is communicated with the hollow shaft and used for introducing external hot air, the side wall of the hollow shaft is fixedly communicated with a sleeve, the inside of the sleeve is slidingly connected with an air pipe which is communicated with the hollow shaft, an air outlet of the air pipe is fixedly communicated with a hollow box, the upper end of the hollow shaft is fixedly communicated with a hollow plate, the outer wall of the hollow box and the outer wall of the hollow plate are provided with exhaust holes which are used for drying residual water drops on the inner wall of a printing waste container in an array manner, and the outer wall of the hollow box and the outer wall of the hollow plate are provided with wiping gaskets which are covered on the exhaust holes; the telescopic rod is rotationally connected between the hollow shaft and the air pipe, and an extension arm of the telescopic rod is provided with a built-in sucker in a spherical hinge manner, and the built-in sucker is used for adsorbing the inner wall of the printing waste container; the driving mechanism is arranged between the base and the hollow shaft and is used for driving the hollow shaft to rotate; the inner wall cleaning mechanism is arranged on the hollow shaft and is used for cleaning the inner wall of the printing waste container; the outer wall cleaning mechanism is arranged on the lifting frame and is used for cleaning the outer wall of the printing waste container and adsorbing and positioning the printing waste container when the outer wall is matched with the inner wall to clean.

Through adopting above-mentioned technical scheme, when wasing printing waste container, first cylinder operation promotes the crane and moves upwards, and after personnel detained the printing waste container with open posture down and put above the hollow shaft, first cylinder drives the crane and moves down and reset. After the outer wall cleaning mechanism adsorbs and positions the printing waste container, the hollow shaft and the inner wall cleaning mechanism rotate together and cooperate with the wiping pad to clean the inner wall of the printing waste container through the cooperation of the driving mechanism. And then, external hot air flows are respectively led into the hollow box and the hollow plate through the rotary joint, the hollow shaft, the sleeve and the air pipe, and finally, the hot air flows are discharged into the printing waste container through the exhaust hole to blow-dry water drops on the inner wall of the printing waste container, and the wiping gasket covered on the exhaust hole in the process is blown-dried. After the cleaning of the inner wall of the printing waste container is finished, the printing waste container is adsorbed and fixed from the inside by means of the built-in sucker, and at the moment, the driving mechanism can drive the hollow shaft to rotate together with the printing waste container, so that the outer wall cleaning mechanism can clean the outer wall of the printing waste container.

After the cleaning work of the inner wall of the printing waste container is finished, water drops on the inner wall of the printing waste container can be dried by means of external hot air flow, the probability of slipping when the built-in sucking disc adsorbs the inner wall of the printing waste container is reduced, and the cleaning work of the outer wall of the printing waste container in the subsequent step is normally carried out. And in the process of drying the inner wall of the printing waste container, the wiping gasket can be dried along with the drying process, so that the cleaning work of personnel on the wiping gasket is avoided.

Optionally, the driving mechanism includes: the motor base is arranged on the top wall of the base; the first motor is arranged on the motor base, gears are fixedly sleeved on the output shaft of the first motor and the outside of the hollow shaft, and the two gears are meshed with each other.

Through adopting above-mentioned technical scheme, when first motor operation, can make the hollow shaft take place the rotation through the meshing transmission between two gears.

Optionally, the inner wall cleaning mechanism includes: the water inlet end of the water supply pipe penetrates through the rotary joint and extends into the base, and the water outlet end of the water supply pipe penetrates through the side wall of the hollow shaft; and the inner spray pipe is fixedly communicated with the water outlet end of the water supply pipe and is used for spraying the inner wall of the printing waste container.

Optionally, the outer wall cleaning mechanism includes: the outer spray pipe is arranged on the lifting frame and is used for spraying the outer wall surface of the printing waste container; the top spraying pipe is arranged on the top wall of the lifting frame and used for spraying the upper surface of the printing waste container; the cleaning brush is connected to the lifting frame in a sliding manner and is used for brushing the outer wall surface of the printing waste container; the rolling brush is rotationally connected to the lifting frame and is used for brushing the upper surface of the printing waste container; the second cylinder is arranged on the top wall of the lifting frame, and an external sucker for adsorbing the outer wall of the printing waste container is arranged at the execution end of the second cylinder.

Optionally, the hollow shaft lateral wall is provided with the third cylinder, the outside fixed cover of telescopic link is equipped with the synchronizing wheel, and two that vertically are adjacent the transmission is connected with the hold-in range between the synchronizing wheel, the execution end of third cylinder with hold-in range fixed connection, the hollow shaft the telescopic link with be provided with between the sleeve pipe and be used for seal protection the third cylinder the synchronizing wheel with the protecting crust of hold-in range.

Through adopting above-mentioned technical scheme, when the third cylinder operation drives the synchronizing wheel and takes place the displacement, synchronizing wheel and telescopic link can rotate along with this and make built-in sucking disc take place the position change, should shrink built-in sucking disc before carrying out printing waste container inner wall cleaning work, make built-in sucking disc support tightly hollow box lateral wall and avoid the water droplet to be infected with to this further promote built-in sucking disc's adsorption stability.

Optionally, the outside movable sleeve of hollow shaft is equipped with drive sleeve and sliding sleeve, the drive sleeve with be provided with between the sliding sleeve and be used for promoting the spring of drive sleeve upward movement, be provided with on the sliding sleeve and be used for limiting the drive sleeve upward movement distance and drive the hook plate that the drive sleeve moved down, the drive sleeve with articulated between the hollow box has the connecting rod, the outside swivelling joint of sliding sleeve has the guide disc with the vertical sliding connection of base, the inside fourth cylinder that is provided with of base, the execution end of fourth cylinder runs through the base and with guide disc fixed connection.

Optionally, a linear driver is arranged on the lifting frame, and an execution end of the linear driver is fixedly connected with the cleaning brush.

Through adopting above-mentioned technical scheme, when fourth cylinder operation drove the vertical displacement of leading truck and sliding sleeve, the drive sleeve also can take place the position change and change the inclination of connecting rod thereupon, and the hollow box can take place radial displacement taking the hollow shaft as the benchmark this moment, and linear drive operation then can drive the cleaning brush and take place lateral displacement to satisfy the printing waste container of different bore and use.

Optionally, be provided with on the crane and be used for extruding the inside moisture's of cleaning brush extrusion pole, be provided with on the crane and be used for driving the rotatory second motor of round brush, be provided with on the crane and be used for can extrude its inside moisture's scraper blade when the round brush is rotatory.

Through adopting above-mentioned technical scheme, when the cleaning brush is because of linear drive's drive and extrusion pole butt, the inside moisture of cleaning brush can be extruded by the extrusion pole, and when the second motor drove the round brush rotation, the scraper blade can extrude the inside moisture of round brush, avoids cleaning brush and round brush to reach saturation and cause the influence to follow-up cleaning.

In summary, compared with the prior art, the present application includes at least one of the following beneficial technical effects:

1. after the cleaning work of the inner wall of the printing waste container is finished, water drops on the inner wall of the printing waste container can be dried by means of external hot air flow, the probability of slipping when the built-in sucking disc adsorbs the inner wall of the printing waste container is reduced, and the cleaning work of the outer wall of the printing waste container in the subsequent step is normally carried out.

2. When the third cylinder runs to drive the synchronizing wheel to displace, the synchronizing wheel and the telescopic rod rotate along with the synchronizing wheel to change the position of the built-in sucker, and the built-in sucker is contracted before the cleaning work of the inner wall of the printing waste container is carried out, so that the built-in sucker abuts against the side wall of the hollow box to avoid water drop contamination, and the adsorption stability of the built-in sucker is further improved.

3. When the fourth cylinder runs to drive the guide disc and the sliding sleeve to vertically displace, the driving sleeve also changes the inclined state of the connecting rod due to the position change, the hollow box can radially displace by taking the hollow shaft as a reference, and the linear driver can drive the cleaning brush to transversely displace, so that the printing waste containers with different calibers can be used.

4. In the process of drying the inner wall of the printing waste container, the wiping pad can be dried along with the inner wall of the printing waste container, so that the cleaning work of personnel on the wiping pad is avoided. When the cleaning brush is abutted with the extrusion rod due to the driving of the linear driver, moisture in the cleaning brush can be extruded by the extrusion rod, and when the second motor drives the rolling brush to rotate, the scraping plate can extrude the moisture in the rolling brush, so that the cleaning brush and the rolling brush are prevented from reaching a saturated state to influence the subsequent cleaning work.

Drawings

FIG. 1 is a schematic view of a recycling apparatus for printing waste containers according to the present application;

FIG. 2 is a schematic structural view of the driving mechanism and the inner wall cleaning mechanism of the present application;

FIG. 3 is a schematic view showing the structure of the outer wall cleaning mechanism from the bottom to the top;

fig. 4 is a partial enlarged view of the area a in fig. 2 of the present application.

Reference numerals illustrate: 1. a base; 11. a first cylinder; 12. a lifting frame; 2. a hollow shaft; 21. a rotary joint; 22. a sleeve; 23. an air pipe; 24. a hollow box; 25. a hollow slab; 26. an exhaust hole; 27. wiping the pad; 3. a telescopic rod; 31. a suction cup is arranged in the cup; 32. a third cylinder; 33. a synchronizing wheel; 34. a synchronous belt; 35. a protective shell; 4. a driving mechanism; 41. a motor base; 42. a first motor; 43. a gear; 5. an inner wall cleaning mechanism; 51. a water supply pipe; 52. an inner shower; 6. an outer wall cleaning mechanism; 61. an outer shower; 62. a top shower; 63. a cleaning brush; 64. a rolling brush; 65. a second cylinder; 66. an external sucking disc; 7. a drive sleeve; 71. a sliding sleeve; 72. a spring; 73. a hook plate; 74. a connecting rod; 75. a guide disc; 76. a fourth cylinder; 8. a linear driver; 9. an extrusion rod; 91. a second motor; 92. a scraper.

Detailed Description

For the purposes, technical solutions and advantages of the embodiments of the present application to be more apparent, the technical solutions of the embodiments of the present application will be clearly and completely described below with reference to fig. 1 to 4 of the embodiments of the present application. It will be apparent that the described embodiments are some, but not all, of the embodiments of the present application. All other embodiments obtained by a person of ordinary skill in the art based on the described embodiments of the present application are within the scope of the protection of the present application.

Referring to fig. 1 and 2, the present embodiment provides a recycling device for a printing waste container, including a base 1, a first cylinder 11 is disposed on a side wall of the base 1, and a lifting frame 12 is disposed at an execution end of the first cylinder 11; the hollow shaft 2 is rotationally connected to the base 1, the hollow shaft 2 extends to the inside of the base 1, the lower end of the hollow shaft 2 is rotationally connected with a rotary joint 21 which is communicated with the hollow shaft 2 and used for introducing external hot air, the side wall of the hollow shaft 2 is fixedly communicated with a sleeve 22, the inside of the sleeve 22 is slidingly connected with an air pipe 23 which is communicated with the hollow shaft, the air outlet of the air pipe 23 is fixedly communicated with a hollow box 24, the upper end of the hollow shaft 2 is fixedly communicated with a hollow plate 25, the outer wall of the hollow box 24 and the outer wall of the hollow plate 25 are both provided with exhaust holes 26 which are used for drying residual water drops on the inner wall of a printing waste container in an array manner, and the outer wall of the hollow box 24 and the outer wall of the hollow plate 25 are both provided with wiping gaskets 27 which are covered on the exhaust holes 26; a telescopic rod 3 is rotatably connected between the hollow shaft 2 and the air pipe 23, and an extension arm of the telescopic rod 3 is provided with a ball hinge with an internal sucker 31 for adsorbing the inner wall of the printing waste container; a driving mechanism 4 for driving the hollow shaft 2 to rotate is arranged between the base 1 and the hollow shaft 2; an inner wall cleaning mechanism 5 is arranged on the hollow shaft 2 and is used for cleaning the inner wall of the printing waste container; the lifting frame 12 is provided with an outer wall cleaning mechanism 6 for cleaning the outer wall of the printing waste container and adsorbing and positioning the printing waste container in cooperation with the inner wall cleaning operation.

When the printing waste container is cleaned, the first air cylinder 11 operates to push the lifting frame 12 to move upwards, and after personnel buckle the printing waste container above the hollow shaft 2 in an open downward posture, the first air cylinder 11 drives the lifting frame 12 to move downwards to reset.

After the outer wall cleaning mechanism 6 adsorbs and positions the printing waste container, the hollow shaft 2 and the inner wall cleaning mechanism 5 rotate together and cooperate with the wiping pad 27 to clean the inner wall of the printing waste container through the cooperation of the driving mechanism 4.

The external hot air flow is then led to the inside of the hollow box 24 and the hollow plate 25 through the rotary joint 21, the hollow shaft 2, the sleeve 22 and the air pipe 23 respectively, and finally the hot air flow is discharged to the inside of the printing waste container through the exhaust hole 26 to blow-dry the water drops on the inner wall of the printing waste container, and the wiping pad 27 covered on the exhaust hole 26 in the process is blown-dried accordingly.

After the cleaning of the inner wall of the printing waste container is completed, the printing waste container is adsorbed and fixed from the inside by means of the built-in sucking disc 31, and at this time, the driving mechanism 4 can drive the hollow shaft 2 and the printing waste container to rotate together, so that the outer wall cleaning mechanism 6 cleans the outer wall of the printing waste container.

Referring to fig. 2, the driving mechanism 4 includes a motor base 41, and the motor base 41 is disposed on the top wall of the base 1; the motor seat 41 is provided with a first motor 42, the output shaft of the first motor 42 and the outside of the hollow shaft 2 are fixedly sleeved with gears 43, and the two gears 43 are meshed with each other.

When the first motor 42 is operated, the hollow shaft 2 can be rotated by the meshing transmission between the two gears 43.

Referring to fig. 1 and 2, the inner wall cleaning mechanism 5 includes a water supply pipe 51 provided inside the hollow shaft 2, a water inlet end of the water supply pipe 51 penetrating the rotary joint 21 and extending into the inside of the base 1, and a water outlet end of the water supply pipe 51 penetrating the side wall of the hollow shaft 2; the water outlet end of the water supply pipe 51 is fixedly communicated with an inner spray pipe 52 for spraying the inner wall of the printing waste container.

The external cleaning liquid is introduced into the inner shower pipe 52 through the water supply pipe 51, and then can be sprayed onto the inner wall of the printing waste container.

Referring to fig. 3, the outer wall cleaning mechanism 6 includes an outer shower pipe 61 provided on the lifting frame 12 for spraying the outer wall surface of the printing waste container; the top wall of the lifting frame 12 is provided with a top spray pipe 62 for spraying the upper surface of the printing waste container; the lifting frame 12 is connected with a cleaning brush 63 in a sliding way and is used for brushing the outer wall surface of the printing waste container; the lifting frame 12 is rotatably connected with a rolling brush 64 for brushing the upper surface of the printing waste container; the lifting frame 12 top wall is provided with a second air cylinder 65, and the execution end of the second air cylinder 65 is provided with an external sucker 66 for adsorbing the outer wall of the printing waste container.

The external cleaning liquid can spray the outer wall of the printing waste container after being discharged by the outer shower pipe 61 and the top shower pipe 62, and then the outer wall cleaning work of the printing waste container is completed by the cooperation brushing of the cleaning brush 63 and the rolling brush 64.

In the inner wall cleaning process, the second air cylinder 65 should drive the external suction cup 66 to move downwards, so that the external suction cup 66 contacts the outer wall of the printing waste container before the rolling brush 64 to perform the adsorption fixing work. During the outer wall cleaning process, the second air cylinder 65 should drive the external suction cup 66 to move upwards, so as to prevent water drops on the outer wall of the printing waste container from being stained on the external suction cup 66.

Referring to fig. 2 and 4, a third cylinder 32 is arranged on the side wall of the hollow shaft 2, synchronizing wheels 33 are fixedly sleeved outside the telescopic rod 3, a synchronous belt 34 is connected between two vertically adjacent synchronizing wheels 33 in a transmission manner, the execution end of the third cylinder 32 is fixedly connected with the synchronous belt 34, and a protective shell 35 for sealing and protecting the third cylinder 32, the synchronizing wheels 33 and the synchronous belt 34 is arranged among the hollow shaft 2, the telescopic rod 3 and the sleeve 22.

When the third cylinder 32 operates to drive the synchronizing wheel 33 to displace, the synchronizing wheel 33 and the telescopic rod 3 rotate along with the synchronizing wheel to change the position of the built-in sucker 31, and before the cleaning work of the inner wall of the printing waste container is carried out, the built-in sucker 31 should be contracted, so that the built-in sucker 31 abuts against the side wall of the hollow box 24 to avoid water drop contamination, and the adsorption stability of the built-in sucker 31 is further improved.

Referring to fig. 2, a driving sleeve 7 and a sliding sleeve 71 are movably sleeved outside the hollow shaft 2, a spring 72 for promoting the driving sleeve 7 to move upwards is arranged between the driving sleeve 7 and the sliding sleeve 71, a hook plate 73 for limiting the upward moving distance of the driving sleeve 7 and driving the driving sleeve 7 to move downwards is arranged on the sliding sleeve 71, a connecting rod 74 is hinged between the driving sleeve 7 and the hollow box 24, a guide disc 75 which is vertically and slidingly connected with the base 1 is rotatably connected with the outside of the sliding sleeve 71, a fourth air cylinder 76 is arranged inside the base 1, and the execution end of the fourth air cylinder 76 penetrates through the base 1 and is fixedly connected with the guide disc 75.

Referring to fig. 1, a linear driver 8 is provided on the lifting frame 12, and an execution end of the linear driver 8 is fixedly connected with the cleaning brush 63.

When the fourth cylinder 76 operates to drive the guide disc 75 and the sliding sleeve 71 to vertically displace, the driving sleeve 7 also changes in position to change the inclined state of the connecting rod 74, at this time, the hollow box 24 radially displaces with reference to the hollow shaft 2, and the linear driver 8 operates to drive the cleaning brush 63 to laterally displace, so that the printing waste containers with different calibers can be satisfied.

During the cleaning of the inner wall of the printing waste container, if there is any solidified printing waste on the inner wall of the printing waste container, the driving sleeve 7 will move down moderately against the spring force of the spring 72, so that the hollow box 24 can be moved close to the hollow shaft 2 moderately to avoid damaging the wiping pad 27.

During the cleaning of the outer wall of the printing waste container, the hollow box 24 is prevented from approaching the hollow shaft 2 due to the centrifugal force generated by the rotation of the hollow shaft 2, so that the built-in sucking disc 31 is prevented from being separated from the inner wall of the printing waste container.

Referring to fig. 3, the elevating frame 12 is provided with a pressing rod 9 for pressing out moisture inside the cleaning brush 63, the elevating frame 12 is provided with a second motor 91 for driving the rolling brush 64 to rotate, and the elevating frame 12 is provided with a scraping plate 92 capable of pressing out moisture inside the rolling brush 64 when it rotates.

When the cleaning brush 63 is abutted against the extrusion rod 9 due to the driving of the linear driver 8, moisture in the cleaning brush 63 can be extruded by the extrusion rod 9, and when the second motor 91 drives the rolling brush 64 to rotate, the scraping plate 92 can extrude the moisture in the rolling brush 64, so that the cleaning brush 63 and the rolling brush 64 are prevented from reaching a saturated state to influence the subsequent cleaning work.

The implementation principle of the recycling device of the printing waste container in the embodiment of the application is as follows: when the printing waste container is cleaned, the first air cylinder 11 operates to push the lifting frame 12 to move upwards, and after personnel buckle the printing waste container above the hollow shaft 2 in an open downward posture, the first air cylinder 11 drives the lifting frame 12 to move downwards to reset.

When the inner wall of the printing waste container is cleaned, the second air cylinder 65 should drive the external sucking disc 66 to move downwards, so that the external sucking disc 66 contacts the outer wall of the printing waste container before the rolling brush 64 to perform adsorption fixing work. When the first motor 42 is operated, the hollow shaft 2 is rotated through the meshing transmission between the two gears 43, the water supply pipe 51 and the inner spray pipe 52 can uniformly spray the external cleaning liquid on the inner wall of the printing waste container when rotating along with the hollow shaft 2, and the wiping pad 27 can also wipe and clean the inner wall of the printing waste container when rotating along with the hollow shaft 2.

After the cleaning of the inner wall is completed, the external hot air flow is respectively led into the hollow box 24 and the hollow plate 25 through the rotary joint 21, the hollow shaft 2, the sleeve 22 and the air pipe 23, and finally the hot air flow is discharged into the printing waste container through the exhaust hole 26 to blow-dry the water drops on the inner wall of the printing waste container, and the wiping pad 27 covered on the exhaust hole 26 in the process is blown-dry.

After the cleaning of the inner wall of the printing waste container is completed, the printing waste container is sucked and fixed from the inside by the built-in suction cup 31, and in this state, the printing waste container can rotate together with the hollow shaft 2.

The external cleaning liquid is sprayed on the outer wall of the printing waste container in a rotating state after being discharged by the outer spray pipe 61 and the top spray pipe 62, and then the cleaning work of the outer wall of the printing waste container can be completed by the matched brushing of the cleaning brush 63 and the rolling brush 64.

When the fourth cylinder 76 operates to drive the guide disc 75 and the sliding sleeve 71 to vertically displace, the driving sleeve 7 also changes in position to change the inclined state of the connecting rod 74, at this time, the hollow box 24 radially displaces with reference to the hollow shaft 2, and the linear driver 8 operates to drive the cleaning brush 63 to laterally displace, so that the printing waste containers with different calibers can be satisfied.

When the cleaning brush 63 is abutted against the extrusion rod 9 due to the driving of the linear driver 8, moisture in the cleaning brush 63 can be extruded by the extrusion rod 9, and when the second motor 91 drives the rolling brush 64 to rotate, the scraping plate 92 can extrude the moisture in the rolling brush 64, so that the cleaning brush 63 and the rolling brush 64 are prevented from reaching a saturated state to influence the subsequent cleaning work.

Furthermore, it should be noted that, in the description of the present application, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the terms in this application will be understood by those skilled in the art as the case may be.

While the foregoing is directed to the preferred embodiments of the present application, it should be noted that modifications and adaptations to those embodiments may occur to one skilled in the art and that such modifications and adaptations are intended to be comprehended within the scope of the present application without departing from the principles set forth herein.

Claims (8)

1. A recycling apparatus for a printing waste container, comprising:

the base (1) is provided with a first air cylinder (11) on the side wall, and a lifting frame (12) is arranged at the execution end of the first air cylinder (11);

the hollow shaft (2) is rotationally connected to the base (1) and extends to the inside of the base (1), a rotary joint (21) communicated with the hollow shaft (2) and used for introducing external hot air is rotationally connected to the lower end of the hollow shaft, a sleeve (22) is fixedly communicated with the side wall of the hollow shaft (2), an air pipe (23) communicated with the hollow shaft (23) is slidingly connected to the inside of the sleeve (22), a hollow box (24) is fixedly communicated with the air outlet of the air pipe (23), a hollow plate (25) is fixedly communicated to the upper end of the hollow shaft (2), vent holes (26) used for drying residual water drops on the inner wall of a printing waste container are formed in the outer wall of the hollow box (24) and the outer wall of the hollow plate (25) in an array mode, and wiping gaskets (27) are arranged on the vent holes (26) in a covering mode.

The telescopic rod (3) is rotatably connected between the hollow shaft (2) and the air pipe (23), and an extension arm of the telescopic rod (3) is provided with a built-in sucker (31) for adsorbing the inner wall of the printing waste container in a spherical hinge manner;

the driving mechanism (4) is arranged between the base (1) and the hollow shaft (2) and is used for driving the hollow shaft (2) to rotate;

the inner wall cleaning mechanism (5) is arranged on the hollow shaft (2) and is used for cleaning the inner wall of the printing waste container;

the outer wall cleaning mechanism (6) is arranged on the lifting frame (12) and is used for cleaning the outer wall of the printing waste container and adsorbing and positioning the printing waste container when the printing waste container is matched with the inner wall to clean.

2. A recycling apparatus for printing waste containers according to claim 1, characterized in that the driving mechanism (4) comprises:

the motor base (41) is arranged on the top wall of the base (1);

the first motor (42) is arranged on the motor base (41), a gear (43) is fixedly sleeved on the output shaft of the first motor (42) and the outside of the hollow shaft (2), and the two gears (43) are in meshed connection with each other.

3. A recycling apparatus for printing waste containers according to claim 1, characterized in that the inner wall cleaning mechanism (5) comprises:

the water supply pipe (51) is arranged inside the hollow shaft (2), the water inlet end of the water supply pipe (51) penetrates through the rotary joint (21) and extends into the base (1), and the water outlet end of the water supply pipe (51) penetrates through the side wall of the hollow shaft (2);

and the inner spray pipe (52) is fixedly communicated with the water outlet end of the water supply pipe (51) and is used for spraying the inner wall of the printing waste container.

4. A recycling apparatus for printing waste containers according to claim 1, characterized in that the outer wall cleaning mechanism (6) comprises:

an outer shower pipe (61) provided on the lifting frame (12) for spraying the outer wall surface of the printing waste container;

a top shower pipe (62) arranged on the top wall of the lifting frame (12) and used for spraying the upper surface of the printing waste container;

a cleaning brush (63) which is connected to the lifting frame (12) in a sliding manner and is used for brushing the outer wall surface of the printing waste container;

a rolling brush (64) rotatably connected to the lifting frame (12) for brushing the upper surface of the printing waste container;

the second air cylinder (65) is arranged on the top wall of the lifting frame (12), and an external sucker (66) for sucking the outer wall of the printing waste container is arranged at the execution end of the second air cylinder (65).

5. A recycling apparatus for printing waste containers according to claim 1, wherein: the side wall of the hollow shaft (2) is provided with a third air cylinder (32), a synchronizing wheel (33) is fixedly sleeved outside the telescopic rod (3), a synchronous belt (34) is connected between two vertically adjacent synchronizing wheels (33) in a transmission mode, the execution end of the third air cylinder (32) is fixedly connected with the synchronous belt (34), and a protective shell (35) for sealing and protecting the third air cylinder (32), the synchronizing wheels (33) and the synchronous belt (34) is arranged between the telescopic rod (3) and the sleeve (22).

6. A recycling apparatus for printing waste containers according to claim 1, wherein: the novel hollow shaft is characterized in that a driving sleeve (7) and a sliding sleeve (71) are movably sleeved outside the hollow shaft (2), a spring (72) for promoting the driving sleeve (7) to move upwards is arranged between the driving sleeve (7) and the sliding sleeve (71), a hook plate (73) for limiting the upward moving distance of the driving sleeve (7) and driving the driving sleeve (7) to move downwards is arranged on the sliding sleeve (71), a connecting rod (74) is hinged between the driving sleeve (7) and the hollow box (24), a guide disc (75) connected with the base (1) in a vertical sliding mode is connected to the outside of the sliding sleeve (71) in a rotating mode, a fourth air cylinder (76) is arranged inside the base (1), and the execution end of the fourth air cylinder (76) penetrates through the base (1) and is fixedly connected with the guide disc (75).

7. The recycling apparatus for printing waste containers according to claim 4, wherein: the lifting frame (12) is provided with a linear driver (8), and the execution end of the linear driver (8) is fixedly connected with the cleaning brush (63).

8. The recycling apparatus for printing waste containers according to claim 4, wherein: the cleaning brush is characterized in that an extrusion rod (9) for extruding water in the cleaning brush (63) is arranged on the lifting frame (12), a second motor (91) for driving the rolling brush (64) to rotate is arranged on the lifting frame (12), and a scraping plate (92) capable of extruding water in the rolling brush (64) when the rolling brush rotates is arranged on the lifting frame (12).