阅读说明：本技术 一种利用废料进行破碎处理后喷洒驱动的模压机装置 (Utilize waste material to carry out spray driven moulding press device after broken handle ) 是由 陈言 于 2020-12-22 设计创作，主要内容包括：本发明公开的一种利用废料进行破碎处理后喷洒驱动的模压机装置,包括模压机箱,所述模压机箱内设有开口向前的加工腔,所述加工腔上壁上固定连接有固定板,所述固定板下端设有开口向下的滑动槽,所述滑动槽上壁上滑动连接有两个对称滑杆,本发明能够在进行模压的过程中对产生的废料进行破碎处理,在废料进行破碎处理利用过滤泵以及气泵将细小的废料进行喷洒并驱动相关的模压装置来进行下一步的模压工艺,而当停止生产时可以人工去除产生的废料,这样既提高了模压机整体利用率也免去了人工处理废料的工序。(The invention discloses a mould pressing machine device for spraying and driving after crushing by using waste materials, which comprises a mould pressing machine box, wherein a processing cavity with a forward opening is arranged in the mould pressing machine box, a fixed plate is fixedly connected to the upper wall of the processing cavity, a sliding groove with a downward opening is arranged at the lower end of the fixed plate, and two symmetrical sliding rods are connected to the upper wall of the sliding groove in a sliding manner.)

1. The utility model provides an utilize waste material to carry out spray driven moulding press device after broken handle, includes the mould pressing quick-witted case, its characterized in that: a processing cavity with a forward opening is arranged in the die pressing machine box, a fixed plate is fixedly connected to the upper wall of the processing cavity, a sliding groove with a downward opening is arranged at the lower end of the fixed plate, two symmetrical sliding rods are connected to the upper wall of the sliding groove in a sliding manner, the two symmetrical sliding rods are distributed and arranged in a bilateral symmetry manner by taking the center line of the sliding groove as the symmetry center, stabilizing springs are fixedly connected between the symmetrical sliding rods and the side wall of the sliding groove which is away from each other left and right, a rotating wheel is rotationally connected to the rear end face of the symmetrical sliding rods, a light-weight impact plate is rotationally connected to the outer peripheral face of the rotating wheel, a swinging wheel is rotationally connected to the front end face of the light-weight impact plate, an oblique rod is rotationally connected to the outer, the rear end face of the lower moving rod is rotationally connected with a lower moving wheel, the rear wall of the processing cavity is rotationally connected with two front shafts, the two front shafts are arranged in a bilateral symmetry mode by taking the center line of the processing cavity as a symmetry center, the outer peripheral face of the front shaft is fixedly connected with a rotary oscillating wheel, the rear end of the lower moving wheel is rotationally connected into the front end face of the rotary oscillating wheel, the front end face of the rotary oscillating wheel is rotationally connected with an upper moving wheel, the outer peripheral face of the upper moving wheel is rotationally connected with a gravity rod, the rear wall of the processing cavity is fixedly connected with a crushing box, a crushing cavity is arranged in the crushing box, two crushing shafts are rotationally connected between the front wall and the rear wall of the crushing cavity, the two crushing shafts are arranged in a bilateral symmetry mode by taking the center line of the crushing cavity as a symmetry center, the outer peripheral face of the, the grinding machine is characterized in that a grinding box is fixedly connected to the rear wall of the processing cavity, a grinding cavity with an opening opposite to the left and right is arranged in the grinding box, two embedding shafts and grinding shafts are rotatably connected between the front wall and the rear wall of the grinding cavity, the two embedding shafts and the grinding shafts are symmetrically distributed in the left and right direction by taking the center line of the grinding cavity as the symmetric center, grinding wheels are fixedly connected to the outer peripheral surface of the grinding shaft, five grinders are fixedly connected to the outer peripheral surface of the grinding wheels, conveying ports with openings opposite to each other are formed in one ends of the grinders, a grinding belt pulley is fixedly connected to the outer peripheral surface of the grinding shaft, an embedding belt pulley is fixedly connected to the outer peripheral surface of the embedding shaft, a grinding belt is rotatably connected between the embedding belt pulley and the grinding belt pulley, two embedding shafts are rotatably connected to the rear wall of the, the outer peripheral surface of the embedding shaft is fixedly connected with a winding belt pulley, an embedding belt is rotatably connected between the winding belt pulley and the embedding belt pulley, a crushing belt pulley is fixedly connected on the outer peripheral surface of the front side of the crushing shaft, an oblique belt is rotatably connected between the crushing belt pulley and the winding belt pulley, four lubricating ports with back-to-back openings are arranged in the left and right mutually-far side wall of the crushing cavity, the four lubricating ports are symmetrically distributed and arranged in the left and right direction by taking the central line of the crushing cavity as a symmetric center, the outer peripheral surface of the oblique belt is slidably connected on the inner wall of the lubricating ports, a filtering air pump is fixedly connected on the rear wall of the processing cavity, one end of the filtering air pump, which is far away from the left and right sides of the filtering air pump, is fixedly connected with two spray pipes, the two, the lower end of the filtering air pump is fixedly connected with an absorption pipe, an absorption opening with a downward opening is formed in the absorption pipe, one end of the crushing box, which is away from the upper end of the crushing box, one end of the grinding box, which is away from the upper end of the grinding box, are fixedly connected between the absorption pipes, and the crushing cavity, the grinding cavity and the absorption opening are communicated with one another.

2. A spray-driven molding press apparatus for crushing waste material as defined in claim 1, wherein: the processing chamber rear wall internal rotation is connected with two rearmounted axles, two the rearmounted axle use the processing chamber central line sets up as symmetrical center bilateral symmetry distribution, fixedly connected with side belt pulley on the rearmounted bevel gear outer peripheral face, fixedly connected with leading belt pulley on the leading axle front side outer peripheral face, leading belt pulley with rotate between the side belt pulley and be connected with cross belt, leading belt pulley with rotate between the winding belt pulley and be connected with middle belt, rotate between the side belt pulley and be connected with the transportation belt.

3. A spray-driven molding press apparatus for crushing waste material as defined in claim 1, wherein: the processing cavity comprises a processing cavity back wall and is characterized in that two die placing plates are fixedly connected to the processing cavity back wall, the two die placing plates are arranged with the processing cavity center line in a bilateral symmetry mode, a clamping groove with an upward opening is formed in each die placing plate, a dropping opening with a downward opening is formed in the lower wall of the clamping groove, the dropping opening is communicated with the clamping groove and the processing cavity, two sliding openings with opposite openings are formed in the side wall of the clamping groove, and the sliding openings are arranged with the processing cavity center line in a bilateral symmetry mode.

4. A spray-driven molding press apparatus for crushing waste material as defined in claim 1, wherein: the machining cavity comprises a machining cavity body, a machining cavity body and a machining cavity lower wall, wherein two vertical shafts are rotatably connected to the machining cavity lower wall, the two vertical shafts are arranged in a bilateral symmetry mode by taking the machining cavity center line as a symmetry center, a rear bevel gear is fixedly connected to the front end of the rear shaft, a driving bevel gear is fixedly connected to the outer peripheral surface of each vertical shaft, the rear end of the driving bevel gear is meshed with the lower end of the rear bevel gear, an overhead bevel gear is fixedly connected to the upper end of each vertical shaft, two extension shafts are rotatably connected to the left side wall and the right side wall of the machining cavity body, the two extension shafts are arranged in a bilateral symmetry mode by taking the machining cavity center line as a symmetry center, one ends.

5. A device for spray-driven moulding press after comminution treatment of waste material according to claim 4, in which: the side bevel gear is close to one end fixedly connected with threaded shaft each other, the threaded shaft is close to one end each other and is rotationally connected in the clamping groove is close to the lateral wall each other, the outer peripheral face of the threaded shaft is connected on the inner wall of the sliding opening in a sliding mode, two clamping plates with opposite internal threads are in threaded connection on the outer peripheral face of the threaded shaft, and the two clamping plates are arranged in a bilateral symmetry mode by taking the central line of the clamping groove as a symmetry center.

6. A device for spray-driven moulding press after comminution treatment of waste material according to claim 5, in which: two T shape poles of fixedly connected with between the grip block, two the T shape pole with centre gripping groove central line distributes the setting for symmetry center bilateral symmetry, sliding connection has the buffer beam between the T shape pole, keep away from one end each other about the buffer beam and be equipped with the cushion chamber that the opening was carried on the back mutually, T shape pole outer peripheral face sliding connection in on the cushion chamber inner wall.

7. A device for spray-driven moulding press after comminution treatment of waste material according to claim 5, in which: the left clamping plates are magnetically connected with the left concave template, one end of the left clamping plate is far away from the left concave template, and the lower end of the left gravity rod is magnetically connected with the lower end of the left convex template.

Technical Field

The invention relates to the relevant field of molding presses, in particular to a molding press device which is driven by spraying after crushing treatment is carried out on waste materials.

Background

In some molding production workshops, the produced waste materials are manually collected and then uniformly processed, so that the cost of manually processing the waste materials is increased, the process of processing the waste materials is complicated, the produced waste materials can only be discarded after being transported, and the utilization rate of the waste materials in the molding production is reduced.

Disclosure of Invention

In order to solve the problems, the embodiment designs a die press device which utilizes waste materials to carry out crushing treatment and then is driven by spraying, and the die press device which utilizes waste materials to carry out crushing treatment and then is driven by spraying comprises a die press case, a processing cavity with a forward opening is arranged in the die press case, a fixed plate is fixedly connected on the upper wall of the processing cavity, a sliding groove with a downward opening is arranged at the lower end of the fixed plate, two symmetrical sliding rods are connected on the upper wall of the sliding groove in a sliding way, the two symmetrical sliding rods are symmetrically distributed and arranged by taking the central line of the sliding groove as a symmetrical center, stabilizing springs are fixedly connected between the symmetrical sliding rods and the side walls of the sliding groove which are far away from each other from each, the device comprises a swinging wheel, a middle wheel, a lower moving rod, a lower moving wheel, two front shafts, a gravity rod, a crushing box, a crushing cavity, two crushing shafts, an upper shifting wheel, a lower shifting wheel, a front end face of the swinging wheel, a rear end face of the processing cavity, two gravity rods, a crushing box and a crushing cavity, wherein the swinging wheel is rotatably connected to the peripheral face of the swinging wheel, the middle wheel is rotatably connected to the rear end face of the middle wheel, the lower shifting wheel is rotatably connected to the rear end face of the processing cavity, the two front shafts are rotatably connected to the front end face of the processing cavity, the two front shafts are symmetrically arranged around the center line of the crushing cavity, the grinding device is characterized in that a crushing wheel is fixedly connected to the outer peripheral surface of the crushing wheel, ten crushers are fixedly connected to the outer peripheral surface of the crushing wheel, a grinding box is fixedly connected to the rear wall of the processing cavity, a grinding cavity with an opening opposite to the left and right is arranged in the grinding box, two embedding shafts and grinding shafts are rotatably connected between the front wall and the rear wall of the grinding cavity, the two embedding shafts and the grinding shafts are symmetrically distributed on the left and right sides by taking the center line of the grinding cavity as a symmetric center, a grinding wheel is fixedly connected to the outer peripheral surface of the grinding shaft, five grinders are fixedly connected to the outer peripheral surface of the grinding wheel, a conveying port with an opening opposite to the opening is formed in one end, away from each other, a grinding belt pulley is fixedly connected to the outer peripheral surface of the grinding shaft, an embedding belt, the rear wall of the processing cavity is rotationally connected with two embedded shafts, the two embedded shafts are arranged in a bilateral symmetry mode by taking the central line of the processing cavity as a symmetry center, a winding belt pulley is fixedly connected to the outer peripheral surface of the embedded shaft, an embedded belt is rotationally connected between the winding belt pulley and the embedded belt pulley, a crushing belt pulley is fixedly connected to the outer peripheral surface of the front side of the crushing shaft, an oblique belt is rotationally connected between the crushing belt pulley and the winding belt pulley, the left side and the right side of the crushing cavity are mutually far away from a lubricating port with four opposite openings in the side wall, the four lubricating ports are symmetrically arranged in a bilateral symmetry mode by taking the central line of the crushing cavity as a symmetry center, the outer peripheral surface of the oblique belt is connected to the inner wall of the lubricating port in a sliding mode, a filtering air pump is fixedly connected to the rear, the two spraying pipes are symmetrically distributed in the left and right direction by taking the central line of the filtering air pump as a symmetric center, spraying ports with opposite openings are arranged in the spraying pipes, the lower end of the filtering air pump is fixedly connected with an absorbing pipe, the absorbing pipe is internally provided with an absorbing port with a downward opening, one end of the crushing box, which is away from the upper end of the crushing box, one end of the grinding box, which is away from the upper end of the grinding box, is fixedly connected between the absorbing pipes, the crushing cavity, the grinding cavity and the absorbing port are communicated with each other, when the die pressing machine is used for performing die pressing work by utilizing generated waste materials, the filtering air pump is started at the moment, the waste materials in the processing cavity are absorbed through the absorbing pipe, the waste materials are absorbed into the absorbing port, and the filtering air pump fills some waste materials generated in the spraying ports at the moment, and then sprays towards the, thereby driving the lightweight impact plates to swing away from each other, further driving the rotating wheel to rotate, further driving the symmetrical slide bars to slide on the slide grooves, further compressing or stretching the stabilizing springs, further driving the swinging wheel to rotate, further driving the slant bar to swing, further driving the middle wheel to rotate, further driving the down-moving bar to swing up and down, further driving the down-moving wheel to rotate, further driving the rotary swing wheel to rotate, further driving the front axle to rotate, further driving the front belt pulley to rotate, further driving the up-moving wheel to rotate, further driving the gravity bar to move up, further driving the gravity bar to move, further driving the mold to mold, and the front belt pulley to rotate, further driving the middle belt pulley to rotate, further driving the winding belt pulley to rotate, further driving the embedding belt to rotate, and further drive the oblique belt to rotate, and further drive the crushing belt pulley to rotate, and further drive the crushing shaft, the crushing wheel and the crusher to rotate, the rotation of the crusher crushes the waste materials absorbed in the crushing cavity, the embedding belt drives the embedding belt pulley and the embedding shaft to rotate, and further drives the grinding belt, the grinding shaft and the grinding belt pulley to rotate, and further drives the grinding wheel, the grinder and the transportation port to rotate, the grinder further grinds the crushed waste materials, the transportation port re-inputs the ground waste materials into the filtering air pump for spraying, and the waste material particles sprayed by the filtering air pump fall on the upper end surface of the embedding belt again after the light weight impact plates approach one end to each other and are transported to the grinding cavity again for re-transportation, at the moment, the filtering air pump can reutilize the generated waste materials in an environment-friendly way.

Preferably, the rear wall of the processing cavity is rotationally connected with two rear shafts, the two rear shafts are symmetrically distributed with the center line of the processing cavity as the symmetrical center, the outer peripheral surface of the rear bevel gear is fixedly connected with side belt pulleys, the outer peripheral surface of the front side of the front shaft is fixedly connected with a front belt pulley, a cross belt is rotationally connected between the front belt pulley and the side belt pulley, an intermediate belt is rotationally connected between the front belt pulley and the winding belt pulley, a transport belt is rotationally connected between the side belt pulleys, when the waste materials need to be transported to be close to each other, the side belt pulley rotationally drives the transport belt to rotate, when the die pressing operation needs to be carried out, the side belt pulley drives the cross belt to rotate, further drives the front belt pulley to rotate, and when the waste materials need to be crushed and ground, the front belt pulley rotates to drive the middle belt to rotate, and then drives the winding belt pulley to rotate, so that the waste materials are treated.

Preferably, two mold placing plates are fixedly connected to the rear wall of the machining cavity, the two mold placing plates are arranged with the center line of the machining cavity as the symmetrical center in a bilateral symmetrical mode, a clamping groove with an upward opening is formed in each mold placing plate, a dropping opening with a downward opening is formed in the lower wall of the clamping groove, the dropping opening is communicated with the clamping groove and the machining cavity, two sliding openings with opposite openings are formed in the side wall of the clamping groove in a left-right mode, the sliding openings are arranged with the center line of the machining cavity as the symmetrical center in a bilateral symmetrical mode, when the mold pressing work needs to be carried out, the mold is placed in the clamping groove, and waste materials generated after mold pressing contact are discharged through the dropping opening, the clamping groove and the machining cavity are used for next step of waste material utilization.

Preferably, the lower wall of the processing cavity is rotationally connected with two vertical shafts, the two vertical shafts are arranged in a bilateral symmetry manner by taking the center line of the processing cavity as a symmetry center, the front end of the rear shaft is fixedly connected with a rear bevel gear, the peripheral surface of the vertical shaft is fixedly connected with a driving bevel gear, the rear end of the driving bevel gear is meshed with the lower end of the rear bevel gear, the upper end of the vertical shaft is fixedly connected with an overhead bevel gear, the left side and the right side of the processing cavity are mutually far away from the side wall and are rotationally connected with two extension shafts, the two extension shafts are arranged in a bilateral symmetry manner by taking the center line of the processing cavity as a symmetry center, the ends of the extension shafts close to each other are fixedly connected with side bevel gears, the lower ends of the side bevel gears and the overhead, at the moment, the vertical shaft rotates to drive the driving bevel gear to rotate so as to drive the rear bevel gear to rotate and further drive the top bevel gear to rotate so as to drive the side bevel gear and the extension shaft to rotate, and at the moment, the operation treatment is further carried out on the mould pressing and the waste material treatment.

Preferably, one end of the side bevel gear, which is close to each other, is fixedly connected with a threaded shaft, one end of the threaded shaft, which is close to each other, is rotatably connected to the inside of the side wall of the clamping groove, the outer peripheral surface of the threaded shaft is slidably connected to the inner wall of the sliding opening, the outer peripheral surface of the threaded shaft is in threaded connection with two clamping plates with opposite internal threads, the two clamping plates are arranged in a bilateral symmetry manner by taking the central line of the clamping groove as a symmetry center, when the mold needs to be clamped, the side bevel gear rotates at the moment to drive the threaded shaft to rotate, so that the clamping plates are driven to move close to each other, and the required mold is manually placed between the clamping plates for clamping.

Preferably, two T shape poles of fixedly connected with between the grip block, two the T shape pole with the centre gripping groove central line sets up for the bilateral symmetry distribution of centre of symmetry center, sliding connection has the buffer beam between the T shape pole, keep away from one end each other about the buffer beam and be equipped with the cushion chamber that the opening was carried on the back mutually, T shape pole outer peripheral face sliding connection in on the cushion chamber inner wall, work as when the grip block is close to the removal each other, and then right T shape pole forms the extrusion and makes T shape pole is close to the removal each other, the buffer beam is avoided the grip block removes nearly also prevents that the mould from being crowded bad.

Preferably, a convex mold plate is magnetically connected between the clamping plates on the right side, a convex mold is fixedly connected to the upper end of the convex mold plate, a concave mold plate is magnetically connected to the lower end of the gravity rod on the right side, a concave mold with a downward opening is arranged at the lower end of the concave mold plate, the clamping plates on the left side are magnetically connected to the concave mold plate on the left side, one ends of the gravity rod on the left side and the other ends of the gravity rod on the left side are mutually far away from each other, the gravity rod on the right side is magnetically connected to the lower end of the convex mold plate on the left side, when mold pressing operation is required, the gravity rod on the right side moves downwards, the concave mold plate on the right side and the concave mold plate on the right side.

The invention has the beneficial effects that: the waste material that can produce at the in-process that carries out the mould pressing carries out broken handle, carries out broken handle at the waste material and utilizes filter pump and air pump to spray tiny waste material and drive relevant molding device and carry out next step's mould pressing technology, and can the manual work get rid of the waste material that produces when stopping production, has so both improved the whole utilization ratio of moulding press and has removed the process of manual handling waste material from.

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.

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic view showing the overall structure of a spray-driven molding machine apparatus for crushing waste materials according to the present invention.

Fig. 2 is an enlarged schematic view of a in fig. 1.

Fig. 3 is an enlarged schematic view of B in fig. 1.

Fig. 4 is an enlarged schematic view of C in fig. 1.

Fig. 5 is an enlarged schematic view of D in fig. 1.

Fig. 6 is an enlarged schematic view of E in fig. 1.

Fig. 7 is a schematic view of the structure of F-F in fig. 5.

Detailed Description

The invention will now be described in detail with reference to fig. 1-7, wherein for ease of description the orientations described below 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.

The invention relates to a die press device for carrying out crushing treatment by using waste materials and then spraying driving, which comprises a die press case 11, wherein a processing cavity 12 with a forward opening is arranged in the die press case 11, a fixed plate 21 is fixedly connected on the upper wall of the processing cavity 12, a sliding groove 24 with a downward opening is arranged at the lower end of the fixed plate 21, two symmetrical sliding rods 61 are connected on the upper wall of the sliding groove 24 in a sliding way, the two symmetrical sliding rods 61 are distributed and arranged in a bilateral symmetry way by taking the central line of the sliding groove 24 as a symmetry center, stabilizing springs 20 are fixedly connected between the symmetrical sliding rods 61 and the side walls of the sliding groove 24 which are far away from each other from, an inclined rod 26 is rotatably connected to the outer peripheral surface of the oscillating wheel 60, an intermediate wheel 29 is rotatably connected to the rear end surface of the inclined rod 26, a downward moving rod 15 is rotatably connected to the outer peripheral surface of the intermediate wheel 29, a downward moving wheel 14 is rotatably connected to the rear end surface of the downward moving rod 15, two front shafts 31 are rotatably connected to the rear wall of the processing cavity 12, the two front shafts 31 are arranged in bilateral symmetry with the center line of the processing cavity 12 as a symmetry center, a rotary oscillating wheel 30 is fixedly connected to the outer peripheral surface of the front shaft 31, the rear end of the downward moving wheel 14 is rotatably connected to the front end surface of the rotary oscillating wheel 30, an upward moving wheel 38 is rotatably connected to the front end surface of the rotary oscillating wheel 30, a gravity rod 40 is rotatably connected to the outer peripheral surface of the upward moving wheel 38, a crushing box 45 is fixedly connected to the rear wall of the processing cavity 12, a crushing cavity 46 is arranged in the crushing box 45, the two crushing shafts 47 are distributed symmetrically left and right with the central line of the crushing cavity 46 as the symmetrical center, the crushing wheels 48 are fixedly connected to the outer peripheral surface of the crushing shaft 47, ten crushers 43 are fixedly connected to the outer peripheral surface of the crushing wheels 48, the grinding box 58 is fixedly connected to the rear wall of the processing cavity 12, the grinding box 58 is internally provided with a grinding cavity 49 with an opening opposite left and right, two embedded shafts 51 and grinding shafts 52 are rotatably connected between the front and rear walls of the grinding cavity 49, the two embedded shafts 51 and the grinding shafts 52 are distributed symmetrically left and right with the central line of the grinding cavity 49 as the symmetrical center, the grinding wheels 53 are fixedly connected to the outer peripheral surface of the grinding shaft 52, five grinders 54 are fixedly connected to the outer peripheral surface of the grinding wheels 53, one end of each grinder 54, which is far away from each other, is provided with a transportation port 59 with an opening opposite back, and, an embedded belt pulley 50 is fixedly connected to the outer peripheral surface of the embedded shaft 51, a grinding belt 56 is rotatably connected between the embedded belt pulley 50 and the grinding belt pulley 55, two embedded shafts 18 are rotatably connected to the rear wall of the processing chamber 12, the two embedded shafts 18 are arranged in a bilateral symmetry manner with the central line of the processing chamber 12 as a symmetry center, a winding belt pulley 28 is fixedly connected to the outer peripheral surface of the embedded shaft 18, an embedded belt 27 is rotatably connected between the winding belt pulley 28 and the embedded belt pulley 50, a crushing belt pulley 42 is fixedly connected to the outer peripheral surface of the front side of the crushing shaft 47, an oblique belt 17 is rotatably connected between the crushing belt pulley 42 and the winding belt pulley 28, four lubricating ports 44 with opposite openings are arranged in the side wall of the crushing chamber 46, and the four lubricating ports 44 are arranged in a bilateral symmetry manner with the central line of the crushing chamber 46 as a symmetry center, the outer peripheral surface of the inclined belt 17 is slidably connected to the inner wall of the lubricating port 44, the rear wall of the processing chamber 12 is fixedly connected with a filtering air pump 22, one end of the filtering air pump 22, which is away from the left side and the right side, is fixedly connected with two spraying pipes 23, the two spraying pipes 23 are symmetrically distributed and arranged with the center line of the filtering air pump 22 as the symmetry center, spraying ports 25 with opposite openings are arranged in the spraying pipes 23, the lower end of the filtering air pump 22 is fixedly connected with an absorbing pipe 36, an absorbing port 34 with a downward opening is arranged in the absorbing pipe 36, one end of the crushing box 45, which is away from the upper side and the lower side, and one end of the grinding box 58, which is away from the upper side and the lower side, are fixedly connected between the absorbing pipes 36, the crushing chamber 46, the grinding chamber 49 and the absorbing port 34 are communicated with each other, when the, the waste in the processing chamber 12 is further sucked through the suction pipe 36 and sucked into the suction port 34, and then the filtering air pump 22 fills some of the waste generated previously into the spraying port 25, so as to spray and impact on the end surfaces of the light weight impact plates 63 close to each other, so as to drive the light weight impact plates 63 to swing away from each other, so as to drive the rotating wheel 62 to rotate, so as to drive the symmetrical sliding rods 61 to slide on the sliding grooves 24, so as to compress or stretch the stabilizing springs 20, so as to drive the swinging wheel 60 to rotate, so as to drive the inclined rod 26 to swing, so as to drive the intermediate wheel 29 to rotate, so as to drive the down moving rod 15 to swing up and down, so as to drive the down moving wheel 14 to rotate, so as to drive the rotary swinging wheel 30 to rotate, so as to drive the front shaft 31 to rotate, thereby driving the leading pulley 13 to rotate, further driving the upper pulley 38 to rotate, further driving the gravity rod 40 to move upwards, the movement of the gravity rod 40 further driving the mold to perform the mold pressing, and the leading pulley 13 to rotate, further driving the intermediate belt 16 to rotate, further driving the winding pulley 28 to rotate, further driving the embedding belt 27 to rotate, further driving the inclined belt 17 to rotate, further driving the crushing pulley 42 to rotate, further driving the crushing shaft 47, the crushing wheel 48, and the crusher 43 to rotate, the rotation of the crusher 43 crushing the waste material sucked in the crushing cavity 46, and the embedding belt 27 driving the embedding pulley 50, the embedding shaft 51 to rotate, further driving the grinding belt 56, the grinding shaft 52, and the grinding pulley 55 to rotate, and then the grinding wheel 53, the grinder 54 and the transportation port 59 are driven to rotate, the grinder 54 further grinds the broken scraps of the waste materials, the transportation port 59 feeds the ground waste materials into the filtering air pump 22 again for spraying, the waste material particles sprayed by the filtering air pump 22 fall on the upper end surface of the embedded belt 27 again after the light-weight impact plates 63 are contacted with one end of each other, and are transported to the grinding cavity 49 again for transportation, and at the moment, the filtering air pump 22 recycles the generated waste materials in an environment-friendly way.

Beneficially, two rear shafts 71 are rotatably connected to the rear wall of the processing chamber 12, the two rear shafts 71 are symmetrically distributed with the center line of the processing chamber 12 as the symmetrical center, the outer peripheral surface of the rear bevel gear 70 is fixedly connected with side belt pulleys 64, the outer peripheral surface of the front side of the front shaft 31 is fixedly connected with a front belt pulley 13, cross belts 32 are rotatably connected between the front belt pulley 13 and the side belt pulleys 64, an intermediate belt 16 is rotatably connected between the front belt pulley 13 and the winding belt pulley 28, a conveying belt 35 is rotatably connected between the side belt pulleys 64, when the wastes are required to be transported to be close to each other, the side belt pulleys 64 rotate to drive the conveying belt 35 to rotate, and when the molding operation is required, the side belt pulleys 64 drive the cross belts 32 to rotate to further drive the front belt pulleys 13 to rotate, when the waste material crushing and grinding operation is required, the front belt pulley 13 rotates to drive the intermediate belt 16 to rotate, and then drives the winding belt pulley 28 to rotate, so that the waste material is treated.

Advantageously, two mold placing plates 33 are fixedly connected to the rear wall of the processing cavity 12, the two mold placing plates 33 are distributed and arranged in bilateral symmetry with the central line of the processing cavity 12 as the symmetry center, a clamping groove 39 with an upward opening is arranged in the mould placing plate 33, a dropping opening 37 with a downward opening is arranged in the lower wall of the clamping groove 39, the falling port 37 is communicated with the clamping groove 39 and the processing cavity 12, two sliding ports 41 with opposite openings are arranged in the left and right side walls of the clamping groove 39, the two sliding ports 41 are symmetrically distributed with the center line of the processing cavity 12 as the symmetrical center, when the mould pressing work is required, the mould is placed in the clamping groove 39, and the waste produced after the coining contact is discharged out of the holding groove 39 through the drop opening 37 and into the processing cavity 12 for further waste utilization.

Beneficially, two vertical shafts 69 are rotatably connected to the lower wall of the processing chamber 12, the two vertical shafts 69 are symmetrically arranged with respect to the center line of the processing chamber 12, the rear shaft 71 is fixedly connected to a rear bevel gear 70 at the front end thereof, a driving bevel gear 72 is fixedly connected to the outer peripheral surface of the vertical shaft 69, the rear end of the driving bevel gear 72 is engaged with the lower end of the rear bevel gear 70, an overhead bevel gear 68 is fixedly connected to the upper end of the vertical shaft 69, two extension shafts 67 are rotatably connected to the left and right sides of the processing chamber 12 away from the side wall, the two extension shafts 67 are symmetrically arranged with respect to the center line of the processing chamber 12, a side bevel gear 66 is fixedly connected to one end of the extension shaft 67 close to each other, and the lower end of the side bevel gear 66 is engaged with one end, when the mold needs to be subjected to clamping and mold pressing and the waste materials need to be crushed and transported, the vertical shaft 69 rotates at the moment, so that the driving bevel gear 72 is driven to rotate, the rear bevel gear 70 is driven to rotate, the top bevel gear 68 is driven to rotate, the side bevel gear 66 and the extension shaft 67 are driven to rotate, and the mold pressing and the waste materials are further processed.

Beneficially, the side bevel gears 66 are fixedly connected with threaded shafts 65 at ends close to each other, the threaded shafts 65 are connected with ends close to each other and rotatably connected in the side walls close to each other of the clamping grooves 39, the outer peripheral surfaces of the threaded shafts 65 are slidably connected to the inner wall of the sliding port 41, two clamping plates 75 with opposite internal threads are connected to the outer peripheral surfaces of the threaded shafts 65 in a threaded manner, the two clamping plates 75 are arranged in a bilateral symmetry manner with the center line of the clamping groove 39 as a symmetry center, when a mold needs to be clamped, the side bevel gears 66 rotate at the moment to drive the threaded shafts 65 to rotate, further drive the clamping plates 75 to move close to each other, and at the moment, a required mold is manually placed between the clamping plates 75 to be clamped.

Beneficially, two T-shaped rods 81 are fixedly connected between the clamping plates 75, the two T-shaped rods 81 are symmetrically distributed with the center line of the clamping groove 39 as the symmetric center, the buffer rods 73 are slidably connected between the T-shaped rods 81, the buffer cavities 74 with opposite openings are arranged at the left and right ends of the buffer rods 73, which are away from each other, the outer peripheral surfaces of the T-shaped rods 81 are slidably connected to the inner wall of the buffer cavities 74, when the clamping plates 75 move close to each other, the T-shaped rods 81 are further squeezed to move close to each other, and the buffer rods 73 prevent the clamping plates 75 from moving too close to prevent the mold from being damaged by squeezing.

Advantageously, a male mold plate 77 is magnetically connected between the right-hand clamping plates 75, a male mold 76 is fixedly connected to the upper end of the male mold plate 77, a female mold plate 78 is magnetically connected to the lower end of the right-hand gravity rod 40, a female mold 79 with a downward opening is arranged at the lower end of the female mold plate 78, the left-hand clamping plates 75 are magnetically connected to the left-hand female mold plate 78, the left end and the right end are away from each other, the lower end of the left-hand gravity rod 40 is magnetically connected to the lower end of the left-hand male mold plate 77, when a molding operation needs to be performed, the right-hand gravity rod 40 moves downward to drive the right-hand female mold plate 78 and the female mold 79 to move downward, and then the right-hand male mold 76 and the male mold plate 77 are subjected to a.

The steps of using a spray-driven press device for crushing waste material according to the present invention will be described in detail with reference to fig. 1 to 7:

initially, the air filter pump 22 is in a closed state, the lightweight impact plate 63, the symmetrical slide rod 61, and the rotating wheel 62 are in positions close to each other, and the T-bar 81 and the clamp plate 75 are in positions away from each other.

When the molding press is used to perform a molding operation using the generated waste, the filtering air pump 22 is activated to suck the waste in the processing chamber 12 through the suction pipe 36, the waste is sucked into the suction port 34, the filtering air pump 22 charges some of the waste generated previously into the spraying port 25, the spraying is directed toward the end surfaces of the lightweight impact plates 63 close to each other, the lightweight impact plates 63 are driven to swing away from each other, the rotating wheel 62 is driven to rotate, the symmetrical sliding rods 61 are driven to slide on the sliding grooves 24, the stabilizing spring 20 is compressed or stretched, the swinging wheel 60 is driven to rotate, the diagonal rod 26 is driven to swing, the intermediate wheel 29 is driven to rotate, the down moving rod 15 is driven to swing up and down, the down moving wheel 14 is driven to rotate, the rotary swinging wheel 30 is driven to rotate, the front shaft 31 is driven to rotate, and the front belt pulley 13 is driven to rotate, then the upper moving wheel 38 is driven to rotate, and further the gravity rod 40 is driven to move upwards, the movement of the gravity rod 40 further drives the mold to mold, and the front belt pulley 13 rotates, and further drives the middle belt 16 to rotate, and further drives the winding belt pulley 28 to rotate, and further drives the embedding belt 27 to rotate, and further drives the inclined belt 17 to rotate, and further drives the crushing belt pulley 42 to rotate, and further drives the crushing shaft 47, the crushing wheel 48, and the crusher 43 to rotate, the rotation of the crusher 43 crushes the waste material sucked in the crushing cavity 46, and the embedding belt 27 drives the embedding belt pulley 50, the embedding shaft 51 to rotate, and further drives the grinding belt 56, the grinding shaft 52, and the grinding belt pulley 55 to rotate, and further drives the grinding wheel 53, the grinder 54, and the transportation port 59 to rotate, the grinder 54 further grinds the crushed waste material, and the transportation port 59 feeds the ground waste material into the filtering air pump 22 again to, and the waste particles sprayed by the filtering air pump 22 fall on the upper end surface of the embedding belt 27 again after the light impact plates 63 are contacted with one end of each other and are transported to the grinding chamber 49 again for transportation, and at the moment, the filtering air pump 22 recycles the generated waste materials in an environment-friendly way.

When the waste materials need to be mutually close to each other for transportation, the side belt pulley 64 rotates to drive the transportation belt 35 to rotate, when the die pressing operation needs to be carried out, the side belt pulley 64 drives the cross belt 32 to rotate so as to drive the front belt pulley 13 to rotate, when the waste materials need to be crushed and ground, the front belt pulley 13 rotates to drive the middle belt 16 to rotate so as to drive the winding belt pulley 28 to rotate, so that the waste materials are treated, when the die pressing operation needs to be carried out, the die is placed in the clamping groove 39, the waste materials generated after the die pressing contact are discharged out of the clamping groove 39 through the dropping port 37 and enter the processing cavity 12 for next waste material utilization, when the die is required to be clamped and pressed and the waste materials need to be crushed and transported, the vertical shaft 69 rotates so as to drive the bevel gear 72 to rotate so as to drive the rear bevel gear 70 to rotate, which in turn drives the top bevel gear 68 to rotate and in turn drives the side bevel gear 66 and the extension shaft 67 to rotate, at which point further processing of the molding and waste material is performed.

When the mold needs to be clamped, the side bevel gear 66 rotates at the moment, and further the threaded shaft 65 is driven to rotate, and further the clamping plate 75 is driven to move close to each other, at the moment, the required mold is manually placed between the clamping plates 75 to be clamped, when the clamping plates 75 move close to each other, the T-shaped rods 81 are extruded to enable the T-shaped rods 81 to move close to each other, the buffer rods 73 prevent the clamping plates 75 from moving too close to each other and prevent the mold from being damaged by extrusion, when the mold pressing operation needs to be carried out, the gravity rods 40 on the right side move downwards at the moment, and further the concave mold plates 78 and the concave molds 79 on the right side are driven to move downwards, and further the convex molds 76 and the convex molds 77 on the right side are subjected to the mold pressing operation which is concave up and convex.

The invention has the beneficial effects that: the invention can crush the generated waste in the process of die pressing, spray fine waste by using the filter pump and the air pump and drive the related die pressing device to perform the next die pressing process in the process of crushing the waste, and can manually remove the generated waste when the production is stopped, thereby improving the overall utilization rate of the die pressing machine and avoiding the process of manually processing the waste.

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.