CN111111818A

CN111111818A - Waste ceramic fragment treatment equipment

Info

Publication number: CN111111818A
Application number: CN202010087306.0A
Authority: CN
Inventors: 不公告发明人
Original assignee: Fuzhou Minhou Yangxian Crafts Co ltd
Current assignee: NANJING RONGJIAN MAGNETIC INDUSTRY Co.,Ltd.
Priority date: 2020-02-11
Filing date: 2020-02-11
Publication date: 2020-05-08
Anticipated expiration: 2040-02-11
Also published as: CN111111818B; GB202007952D0

Abstract

The invention discloses waste ceramic fragment treatment equipment which comprises a machine shell, wherein a transmission cavity is arranged at the lower end in the machine shell, a crushing cavity is arranged at the upper end in the machine shell, a timing mechanism for knocking waste ceramics at regular time is arranged at the upper right end in the machine shell, a crushing mechanism for crushing the waste ceramics is arranged in the crushing cavity, a shaking mechanism for accelerating the discharge of the crushed ceramics is arranged in the transmission cavity, the waste ceramics can be knocked and crushed during working, the crushing process adopts a timing crushing method, the repeated crushing process is avoided, the crushed ceramic fragments can be automatically discharged by a device, the shaking method is adopted to discharge the ceramic fragments, and the efficiency of the whole treatment process is improved.

Description

Waste ceramic fragment treatment equipment

Technical Field

The invention relates to the field of ceramics, in particular to a waste ceramic fragment treatment device.

Background

The ceramic product is often produced in the process of manufacturing the ceramic product, the ceramic product is also broken into the waste product in the process of improper use, and the ceramic of waste gas needs to be treated to prevent the broken part from causing accidental injury to people.

At present, when waste ceramics are treated, the ceramics are usually knocked by manual knocking, the efficiency of the method is low, and fragments generated when the ceramics are knocked can also cause harm to people.

Disclosure of Invention

The invention aims to solve the technical problem of providing a waste ceramic fragment treatment device, which overcomes the problems of low efficiency, high risk coefficient and the like, improves the treatment efficiency and reduces the risk coefficient.

The invention is realized by the following technical scheme.

The invention discloses waste ceramic fragment treatment equipment which comprises a machine shell, wherein a transmission cavity is arranged at the lower end in the machine shell, a crushing cavity is arranged at the upper end in the machine shell, a timing mechanism for knocking waste ceramics at regular time is arranged at the upper right end in the machine shell, a crushing mechanism for crushing the waste ceramics is arranged in the crushing cavity, and a shaking mechanism for accelerating the discharge of the crushed ceramics is arranged in the transmission cavity;

the smashing mechanism comprises a knocking block which is positioned in the smashing cavity and can move up and down in the smashing cavity, two reset springs are connected between the upper end surface of the knocking block and the upper wall of the smashing cavity, a first rack is fixedly arranged on the upper end surface of the knocking block, a first driven cavity is collected on the right side of the smashing cavity, a rotating shaft is rotatably arranged between the right wall of the first driven cavity and the left wall of the smashing cavity, a first sector gear meshed with the front wall of the first rack is arranged at the left end of the rotating shaft, a rotating cavity is arranged in the cavity wall at the lower end of the smashing cavity, a rotating block capable of rotating in the cavity is arranged in the rotating cavity, two stirring rods are arranged on the upper end surface and the lower end surface of the rotating block in a penetrating manner, a fixing plate is fixedly arranged on the lower end surface of each stirring rod, a tension spring is connected between the upper end surface of the fixing plate, a lifting plate capable of moving up and down in the cavity is arranged in the lower opening, a rotating cavity with a downward opening is arranged at the lower end in the lifting plate, a fixing rod is fixedly arranged on the front cavity wall and the rear cavity wall of the rotating cavity, the fixing rod is provided with a transmission gear with a lower end extending into the transmission cavity, a torsion spring is connected between the transmission gear and the fixing rod, a motor is fixedly arranged on the lower cavity wall of the transmission cavity, the upper end of the motor is in power connection with a transmission shaft with an upper end rotatably connected with the upper cavity wall of the rotating cavity, the upper end of the transmission shaft is provided with a rotating gear positioned in the rotating cavity and engaged with the outer wall of the rotating block, a displacement cavity is arranged in the upper cavity wall of the transmission cavity, a fixing block positioned in the displacement cavity is fixedly arranged on the right end face, an extension spring is connected, the dog intracavity is equipped with the dog that can remove about in the intracavity, the dog right-hand member face with it is equipped with elastic spring to connect between the dog chamber right side chamber wall, the dog right-hand member face is connected and is equipped with the stay cord, the left side chamber wall is equipped with the feed inlet in the external space of control intercommunication.

Further, the timing mechanism comprises a driven shaft rotating on the right cavity wall of the transmission cavity, a first bevel gear is arranged at the left end of the driven shaft, a second bevel gear meshed with the first bevel gear is arranged at the lower end of the transmission shaft, a driving pulley is arranged at the right end of the driven shaft, a driven pulley positioned in the first driven cavity is arranged at the right end of the rotating shaft, a belt is connected between the driven pulley and the driving pulley, a second sector gear is further arranged at the right end of the rotating shaft, a rotating rod is rotatably arranged on the right cavity wall at the lower end of the first driven cavity, a rotating gear meshed with the second sector gear is arranged at the left end of the rotating rod, a cam is arranged at the right end of the rotating rod, a pressing block cavity with an upward opening is arranged on the lower cavity wall at the right end of the first driven cavity, a pressing block capable of moving up and down in the cavity is arranged in the pressing block cavity, the right end face of the pressing block is connected with one end of the pull rope and the rope.

Furthermore, the shaking mechanism comprises a feed opening which is positioned on the lower cavity wall of the smashing cavity and has a leftward opening, a bearing plate which can move up and down in the cavity is arranged in the feed opening, a pressure spring is connected between the lower end surface of the bearing plate and the lower cavity wall of the feed opening, a second driven cavity is arranged at the lower side of the feed opening, a rotating shaft with the right end extending into the transmission cavity is rotatably arranged on the left cavity wall of the second driven cavity, a third bevel gear which is meshed with the second bevel gear is arranged at the right end of the rotating shaft, a third fan-shaped gear which is positioned in the second driven cavity is arranged at the left end of the rotating shaft, a third rack with the lower end extending into the second driven cavity and the front end surface meshed with the third fan-shaped gear is fixedly arranged on the lower end surface of the bearing plate, a sliding gear which has a leftward opening is also connected to the right end of the rotating shaft through a, the sliding gear is characterized in that a sliding block capable of sliding in the sliding cavity is arranged in the sliding cavity, the left end face of the sliding block is connected with one end of the rope, a rotating plate located on the right side of the sliding gear is arranged at the right end of the rotating shaft, and two elastic springs are connected between the left end face of the rotating plate and the right end face of the sliding gear.

Further, the tension of the two elastic springs is larger than the friction force received when the sliding gear slides on the rotating shaft.

Furthermore, the pulling force of the two return springs is greater than the sum of the friction force borne by the knocking block when the knocking block slides in the breaking cavity and the self weight of the knocking block.

The invention has the beneficial effects that: the ceramic chip smashing device is simple in structure and convenient and fast to operate, waste ceramic can be knocked and smashed during working, a timed smashing method is adopted in the smashing process, repeated smashing processes are avoided, ceramic chips after smashing are automatically discharged by the device, ceramic chips are discharged by a shaking method, and the efficiency of the whole processing process is improved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the invention, and it is obvious for those skilled in the art that other drawings can be obtained based on these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic diagram of the structure at A in FIG. 1 according to an embodiment of the present invention;

FIG. 3 is a schematic diagram of the structure at B in FIG. 1 according to an embodiment of the present invention;

FIG. 4 is a schematic structural diagram at C-C in FIG. 1 according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of the structure at D in FIG. 1 according to an embodiment of the present invention

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, wherein for ease of description the orientations described hereinafter are now defined as follows: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

With reference to the accompanying drawings 1-5, the waste ceramic fragment processing device comprises a casing 10, a transmission cavity 46 is arranged at the lower end in the casing 10, a crushing cavity 25 is arranged at the upper end in the casing 10, a timing mechanism 71 for regularly knocking the waste ceramic is arranged at the upper right end in the casing 10, a crushing mechanism 70 for crushing the waste ceramic is arranged in the crushing cavity 25, a shaking mechanism 72 for discharging the ceramic after being crushed with higher speed is arranged in the transmission cavity 46, the crushing mechanism 70 comprises a knocking block 26 which is positioned in the crushing cavity 25 and can move up and down in the cavity, two reset springs 29 are connected and arranged between the upper end surface of the knocking block 26 and the upper end surface of the crushing cavity 25, a first rack 27 is fixedly arranged on the upper end surface of the knocking block 26, a first driven cavity 33 is collected on the right side of the crushing cavity 25, a rotating shaft 31 is arranged between the right cavity wall of the first driven cavity 33 and the left cavity wall of the crushing cavity, the left end of the rotating shaft 31 is provided with a first sector gear 28 engaged and connected with the front cavity wall of the first rack 27, the crushing cavity 25 is internally provided with a rotating cavity 20 at the lower end thereof, the rotating cavity 20 is internally provided with a rotating block 21 capable of rotating in the cavity, the upper end face and the lower end face of the rotating block 21 are provided with two stirring rods 22 in a penetrating manner, the lower end face of each stirring rod 22 is fixedly provided with a fixed plate 18, a tension spring 19 is connected between the upper end face of the fixed plate 18 and the lower end face of the rotating block 21, the rotating block 21 is also internally provided with a feed opening 75 which is communicated up and down, the feed opening 75 is internally provided with a lifting plate 60 capable of moving up and down in the cavity, the lower end of the lifting plate 60 is provided with a rotating cavity 62 with a downward opening, the front cavity wall and the rear cavity of the rotating cavity 62 are fixedly provided with a fixed rod 61, the fixed rod, a motor 51 is fixedly arranged on the lower cavity wall of the transmission cavity 46, the upper end of the motor 51 is in power connection with a transmission shaft 43 the upper end of which is in rotary connection with the upper cavity wall of the rotating cavity 20, the upper end of the transmission shaft 43 is provided with a rotating gear 42 which is positioned in the rotating cavity 20 and is meshed and connected with the outer wall of the rotating block 21, a displacement cavity 66 is arranged in the upper cavity wall of the transmission cavity 46, a fixed block 64 positioned in the displacement cavity 66 is fixedly arranged on the right end face of the transmission shaft 54, an extension spring 65 is connected between the upper end surface of the fixed block 64 and the upper cavity wall of the displacement cavity 66, a block cavity 67 with a leftward opening is arranged on the right cavity wall of the displacement cavity 66, a block 69 which can move left and right in the cavity is arranged in the block cavity 67, an elastic spring 68 is connected between the right end surface of the stop block 69 and the right cavity wall of the stop block cavity 67, the right end face of the stop block 69 is connected with a pull rope 39, and the wall of the left cavity of the 5 th cylinder is provided with a feed inlet 24 for controlling and communicating an external space.

Advantageously, the timing mechanism 71 comprises a driven shaft 45 rotating on the right cavity wall of the transmission cavity 46, the left end of the driven shaft 45 is provided with a first bevel gear 49, the lower end of the transmission shaft 43 is provided with a second bevel gear 50 engaged with the first bevel gear 49, the right end of the driven shaft 45 is provided with a driving pulley 47, the right end of the rotating shaft 31 is provided with a driven pulley 30 positioned in the first driven cavity 33, a belt 44 is connected between the driven pulley 30 and the driving pulley 47, the right end of the rotating shaft 31 is further provided with a second sector gear 32, the right cavity wall at the lower end of the first driven cavity 33 is rotatably provided with a rotating rod 35, the left end of the rotating rod 35 is provided with a rotating gear 36 engaged with the second sector gear 32, the right end of the rotating rod 35 is provided with a cam 34, the lower cavity wall at the right end of the first driven cavity 33 is provided with a, a pressing block 37 capable of moving up and down in the pressing block cavity 41 is arranged in the pressing block cavity 41, a compression spring 40 is connected between the lower end face of the pressing block 37 and the lower cavity wall of the pressing block cavity 41, and one end of the pull rope 39 and the rope 38 are connected to the right end face of the pressing block 37.

Beneficially, the shaking mechanism 72 includes a feed opening 16 located on the lower cavity wall of the crushing cavity 25 and having a left opening, an accepting plate 15 capable of moving up and down in the cavity is arranged in the feed opening 16, a pressure spring 14 is connected between the lower end surface of the accepting plate 15 and the lower cavity wall of the feed opening 16, a second driven cavity 11 is arranged on the lower side of the feed opening 16, a rotating shaft 53 with a right end extending into the transmission cavity 46 is arranged on the left cavity wall of the second driven cavity 11 in a rotating manner, a third bevel gear 52 in meshed connection with the second bevel gear 50 is arranged on the right end of the rotating shaft 53, a third sector gear 12 located in the second driven cavity 11 is arranged on the left end of the rotating shaft 53, a third rack 13 with a lower end extending into the second driven cavity 11 and a front end surface meshed connection with the third sector gear 12 is fixedly arranged on the lower end surface of the accepting plate 15, and a sliding gear 56 located in the transmission cavity 46 is further splined connected to the right end of the rotating, a sliding cavity 59 with a leftward opening is arranged in the sliding gear 56, a sliding block 55 capable of sliding in the cavity is arranged in the sliding cavity 59, one end of the rope 38 is connected to the left end face of the sliding block 55, a rotating plate 57 positioned on the right side of the sliding gear 56 is arranged at the right end of the rotating shaft 53, and two elastic springs 58 are connected between the left end face of the rotating plate 57 and the right end face of the sliding gear 56.

Advantageously, the tension of the two spring springs 58 is greater than the friction to which the sliding gear 56 is subjected when sliding on the rotating shaft 53.

Advantageously, the tension of the two return springs 29 is greater than the sum of the friction undergone by the striking block 26 when it slides inside the breaking cavity 25 and the weight of the striking block 26 itself.

In the initial state, the slide gear 56 is located on the right side of the pulley 54, the slide gear 56 is disengaged from the pulley 54, and the rope 38 and the pulling rope 39 are in a slack state.

When the ceramic breaking device works, the feeding hole 24 is opened, the waste ceramic blocks are placed into the breaking cavity 25, the feeding hole 24 is closed, the motor 51 is started, the motor 51 works to drive the transmission shaft 43 to rotate, so as to drive the second bevel gear 50 and the rotating gear 42 to rotate, the second bevel gear 50 rotates to drive the third bevel gear 52 and the first bevel gear 49 which are in meshed connection with the second bevel gear to rotate, the first bevel gear 49 rotates to drive the driving pulleys 47 at the right ends of the driven shafts 45 and 78 to rotate, so as to drive the driven pulleys 30 which are in rotatable connection with the driven shafts through the belt 44 to rotate, the driven pulleys 30 rotate to drive the rotating shafts 31 and the second sector gears 32 and the first sector gears 28 on the rotating shafts 31 to rotate, when the first sector gears 28 rotate to be in meshed connection with the belt 7, the first racks 27 and the breaking blocks 26 move downwards to strike the ceramic in the breaking cavity 25, and when the first sector, the first rack 27 and the knocking block 26 are moved upward to be reset by the pulling force of the reset spring 29, thereby realizing repeated knocking on the ceramics, the second sector gear 32 is rotated one turn to drive the rotary gear 36 to rotate one tenth of a turn, thereby driving the rotary rod 35 and the cam 34 at the right end of the rotary rod 35 to rotate one tenth of a turn, when the cam 34 is rotated to push the pressing block 37 downward, the rope 38 and the pulling rope 39 are tensioned, the stopper 69 is moved rightward by the pulling force of the pulling rope 39 to separate from the stopper fixing block 64, the sliding gear 56 is moved leftward by the pulling force of the rope 38 to be engaged with the sliding gear 54, the third bevel gear 52 is rotated to drive the rotary shaft 53 and the sliding gear 56 on the rotary shaft 53 and the third sector gear 12 to rotate, the sliding gear 56 rotates the sliding shaft 54 and the lifting plate 60 downward, when the lifting plate 60 moves downward to the lowest end, the lifting plate 60 rotates leftward, the ceramic on the lifting plate 60 slides leftwards into the upper surface of the bearing plate 15, when the third sector gear 12 rotates to be meshed with the third rack 13, the bearing plate 15 moves downwards, when the third sector gear 12 rotates to be disengaged from the third rack 13, the bearing plate 15 moves upwards under the action of the pressure spring 14, the efficiency that the vibration of the bearing plate 15 accelerates the leftward output of the ceramic is realized, the rotating gear 42 rotates to drive the rotating block 21 which is meshed and connected with the rotating block 21 to rotate, so that the two stirring rods 22 are driven to rotate, the ceramic in the crushing cavity 25 is stirred, and the crushing comprehensiveness is improved;

when the cam 34 is rotated to leave the pressing block 37, the pressing block 37 moves upwards to reset under the action of the compression spring 40, the rope 38 and the pull rope 39 are loosened, the sliding gear 56 moves rightwards to reset under the action of the elastic spring 58, the 54 and the lifting plate 60 move upwards to reset the stop block 69 under the action of the tension of the extension spring 65, the tension of the pull rope 39 is lost, the return block moves leftwards to reset under the action of the elastic spring 68, the motor 51 is turned off, and the operation process is completed.

The above embodiments are merely illustrative of the technical ideas and features of the present invention, and the purpose thereof is to enable those skilled in the art to understand the contents of the present invention and implement the present invention, and not to limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered within the protection scope of the present invention.

Claims

1. The utility model provides a waste ceramic chip treatment facility, includes the casing, its characterized in that: the inner lower end of the shell is provided with a transmission cavity, the inner upper end of the shell is provided with a crushing cavity, the right upper end of the inner upper end of the shell is provided with a timing mechanism for knocking the waste ceramics at regular time, the crushing cavity is internally provided with a crushing mechanism for crushing the waste ceramics, and the transmission cavity is internally provided with a shaking mechanism for accelerating the discharge of the crushed ceramics;

2. The apparatus for treating waste ceramic chips as set forth in claim 1, wherein: the timing mechanism comprises a driven shaft rotating on the right cavity wall of the transmission cavity, a first bevel gear is arranged at the left end of the driven shaft, a second bevel gear meshed with the first bevel gear is arranged at the lower end of the transmission shaft, a driving pulley is arranged at the right end of the driven shaft, a driven pulley positioned in the first driven cavity is arranged at the right end of the rotating shaft, a belt is connected between the driven pulley and the driving pulley, a second sector gear is further arranged at the right end of the rotating shaft, a rotating rod is rotatably arranged on the right cavity wall at the lower end of the first driven cavity, a rotating gear meshed with the second sector gear is arranged at the left end of the rotating rod, a cam is arranged at the right end of the rotating rod, a pressing block cavity with an upward opening is arranged on the lower cavity wall at the right end of the first driven cavity, a pressing block capable of moving up and down in the pressing block cavity is arranged in the, the right end face of the pressing block is connected with one end of the pull rope and the rope.

3. The apparatus for treating waste ceramic chips as set forth in claim 1, wherein: the shaking mechanism comprises a feed opening which is positioned on the lower cavity wall of the smashing cavity and has a leftward opening, a bearing plate which can move up and down in the cavity is arranged in the feed opening, a pressure spring is connected between the lower end surface of the bearing plate and the lower cavity wall of the feed opening, a second driven cavity is arranged at the lower side of the feed opening, a rotating shaft with the right end extending into the transmission cavity is arranged in the left cavity wall of the second driven cavity in a rotating manner, a third bevel gear which is meshed with the second bevel gear is arranged at the right end of the rotating shaft, a third fan-shaped gear which is positioned in the second driven cavity is arranged at the left end of the rotating shaft, a third rack with the lower end extending into the second driven cavity and the front end surface meshed with the third fan-shaped gear is fixedly arranged on the lower end surface of the bearing plate, a sliding gear with an opening which is leftward is arranged in the sliding gear, the sliding gear is characterized in that a sliding block capable of sliding in the sliding cavity is arranged in the sliding cavity, the left end face of the sliding block is connected with one end of the rope, a rotating plate located on the right side of the sliding gear is arranged at the right end of the rotating shaft, and two elastic springs are connected between the left end face of the rotating plate and the right end face of the sliding gear.

4. The apparatus for treating waste ceramic chips as set forth in claim 3, wherein: the pulling force of the two elastic springs is larger than the friction force applied to the sliding gear when the sliding gear slides on the rotating shaft.

5. The apparatus for treating waste ceramic chips as set forth in claim 1, wherein: the pulling force of the two return springs is greater than the sum of the friction force borne by the knocking block when the knocking block slides in the breaking cavity and the self weight of the knocking block.