CN215464614U - Be applied to broken mechanism of mould cell body cement - Google Patents

Abstract

The utility model discloses a crushing mechanism applied to cement crushing of a die groove body, relates to the technical field of tubular pile processing equipment, and solves the problems that a large amount of solidified cement is attached to the position of a side groove of a lower die after demoulding, workers need to clean the cement at the position of the side groove of the lower die in order to ensure the subsequent recycling of the lower die, but the efficiency is low by adopting a manual cleaning mode, and a large amount of labor cost needs to be consumed; the first crushing column is connected to the crushing mounting frame in a sliding manner; first broken sword, sliding connection reaches the clearance that can be convenient for carry out automation to the side trench position of lower mould on the lateral wall of broken mounting bracket to in the clearance efficiency and subsequent circulation after the improvement lower mould uses use, through the broken mode of substep step by step, carry out high-efficient broken purpose to setting cement.

Description

Be applied to broken mechanism of mould cell body cement

Technical Field

The utility model relates to the technical field of pipe pile processing equipment, in particular to a crushing mechanism applied to cement crushing of a die groove body.

Background

The tubular pile is mainly used in the field of construction and is composed of a cylindrical cement body and a reinforcing mesh in the cement body. The existing method for manufacturing the tubular pile is to adopt a tubular pile forming die (pipe die for short) comprising an upper die and a lower die, place a reinforcing mesh in the lower die, pour cement into the lower die, cover the upper die on the lower die, fix the lower die by bolts, rotate the pipe die by a centrifugal machine to enable the tubular pile to be centrifugally formed in the pipe die, then disassemble the bolts to demould, uncover the upper die and take out the tubular pile.

Because last mould and lower mould are closing the back at the lid, have a small amount of cement to spill over the back and remain on the side groove position of lower mould, consequently after the drawing of patterns, can adhere to the cement that has solidified in a large number on the side groove position of lower mould, in order to guarantee the subsequent circulation use of lower mould, the workman need clear up the cement of the side groove position of lower mould, nevertheless adopts artificial clearance mode inefficiency, still need consume a large amount of costs of labor.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a crushing mechanism applied to cement crushing of a die groove body, which has the advantages that the side groove position of a die can be conveniently and automatically cleaned, the cleaning efficiency and subsequent recycling after the die is used are conveniently improved, and the solidified cement is efficiently crushed in a step-by-step crushing mode.

The technical purpose of the utility model is realized by the following technical scheme: be applied to broken mechanism of mould cell body cement includes:

the crushing mounting rack is used for mounting and fixing;

the first crushing column is connected to the crushing mounting frame in a sliding mode and can be close to or far away from the die;

the first crushing knife is connected to the side wall of the crushing mounting frame in a sliding mode and can be close to or far away from the die;

the moving axial direction of the first crushing column is parallel to the moving axial direction of the first crushing knife.

By adopting the technical scheme, when the first crushing column continuously moves towards the direction close to the surface of the mould, the first crushing column can be used for primarily crushing the set cement on the side groove of the mould; then, along with the continuous feeding and moving of the mould, the first crushing knife also moves towards the direction close to the surface of the mould until the first crushing knife carries out secondary crushing on the solidified cement crushed by the first crushing column, so that the side groove position of the mould can be automatically cleaned, and the cleaning efficiency and the subsequent recycling after the mould is used can be improved; this scheme is earlier through the less (comparatively sharp-pointed) first broken post of area of contact to the cement that solidifies on the summer end side groove tentatively broken, then carries out the large tracts of land breakage to the cement that solidifies through the great first broken sword of area of contact again, carries out high-efficient breakage to the cement that solidifies through the broken mode of substep step by step promptly.

The crushing device further comprises a first crushing moving device, the first crushing moving device is arranged on the crushing mounting frame, and the first crushing column is arranged on the movable end of the first crushing moving device.

Through adopting above-mentioned technical scheme, first broken mobile device carries out reciprocating motion with the drive first broken post toward the mould direction through self reciprocating motion.

According to the further arrangement of the utility model, a first connecting block is arranged at the movable end of the first crushing moving device, and the first crushing column is detachably arranged on the first connecting block.

Through adopting above-mentioned technical scheme, can make first broken post can install and dismantle conveniently through first connecting block, and then the change of the first broken post of being convenient for.

The crushing device further comprises a second crushing moving device, the second crushing moving device is arranged on the side wall of the crushing mounting frame, and the first crushing knife is detachably mounted on the movable end of the second crushing moving device; the second crushing moving device can drive the first crushing knife to be close to or far away from the die.

Through adopting above-mentioned technical scheme, broken mobile device of second carries out reciprocating motion with the drive first broken sword of drive toward the mould direction through self reciprocating motion.

According to the further arrangement of the crushing device, a second connecting block is arranged at the movable end of the second crushing moving device, and the first crushing knife is detachably arranged on the second connecting block.

Through adopting above-mentioned technical scheme, can make first broken sword can install and dismantle conveniently through the second connecting block, and then the change of the first broken sword of being convenient for.

The crushing mounting frame is further provided with a sliding connecting cylinder which is arranged along the moving axial direction of the first crushing column, and the first crushing column is arranged in the sliding connecting cylinder in a sliding mode in a penetrating mode.

According to the further arrangement, the first crushing column comprises a rod body and a pick head arranged at the end part of the rod body, and the rod body is connected to the crushing mounting frame in a sliding mode.

Through adopting above-mentioned technical scheme, the body of rod slides and wears to locate in the sliding connection section of thick bamboo, and the sliding connection section of thick bamboo can make the slip of first broken post more smooth and easy.

According to the further arrangement of the utility model, the section of the pick head along the length direction of the first crushing column is trapezoidal.

Through adopting above-mentioned technical scheme, the cross-section is trapezoidal pick head, and it can be convenient for improve the broken ability of pick head to cement.

In a further arrangement of the present invention, the first crushing blade includes a first body and a chopping blade portion disposed on the first body, and the first body is slidably connected to the side wall of the crushing mounting frame.

In a further aspect of the present invention, a cross section of the chopping knife portion along a moving axial direction of the first crushing knife is trapezoidal.

By adopting the technical scheme, the section of the chopping knife part is trapezoidal, so that the crushing capacity of the chopping knife part on cement can be improved conveniently.

According to the further arrangement, a first rotating support is rotatably connected to the side of the crushing mounting frame, a third moving device is rotatably connected to the first rotating support, and the movable end of the third moving device is rotatably connected to the crushing mounting frame.

In conclusion, the automatic side groove cleaning device can be used for automatically cleaning the side groove position of the mold, so that the cleaning efficiency and the subsequent recycling after the mold is used are improved, and the set cement is efficiently crushed in a step-by-step crushing mode.

Drawings

FIG. 1 is a schematic structural view of the present embodiment;

FIG. 2 is an enlarged view at A in FIG. 1;

FIG. 3 is an enlarged view at B in FIG. 1;

FIG. 4 is a schematic structural diagram of a multi-axis position adjustment mechanism according to the present embodiment;

FIG. 5 is a schematic view showing the structure of the crushing mechanism in this embodiment;

FIG. 6 is a schematic view of a cleaning mechanism of the present embodiment;

FIG. 7 is a schematic view of another perspective structure of the trough cleaning mechanism in the present embodiment;

fig. 8 is a schematic view of a positional relationship between the sliding through groove and the communicating groove in the present embodiment;

FIG. 9 is an enlarged view at C in FIG. 8;

fig. 10 is a schematic view of a perspective structure of the rolling brush mechanism in the embodiment;

FIG. 11 is a schematic structural view of another perspective of the roller brush mechanism in the present embodiment;

fig. 12 is a view schematically illustrating a structure of one of the oil applying mechanisms according to the present embodiment;

fig. 13 is a schematic view of another perspective structure of the oiling mechanism in the present embodiment;

fig. 14 is a schematic structural view of a mounting shaft in the oiling mechanism in the present embodiment;

FIG. 15 is a schematic structural view of a slider in the oil applying mechanism in the present embodiment;

fig. 16 is a schematic structural view of a floating sleeve in the oiling mechanism in the present embodiment;

fig. 17 is a schematic structural view of the mold in the present embodiment.

Reference numerals: 1. a conveying line; 2. fixing the position; 3. a crushing mechanism; 31. crushing the mounting rack; 32. a first crushing column; 321. crushing the rod body; 322. a pick head; 33. a first crushing knife; 331. a first body; 332. a chopper portion; 34. a second connecting block; 35. a sliding connection cylinder; 36. a first rotating bracket; 37. a first connection block; 4. a groove cleaning mechanism; 41. cleaning the groove mounting frame; 401. a second rotating bracket; 42. cleaning a groove part; 421. clearing the groove rod body; 422. cleaning the groove; 43. a sliding through groove; 44. a communicating groove; 45. clearing the groove bump; 46. a first inclined surface; 47. a second inclined surface; 48. a third inclined surface; 49. a cooling tube; 5. a rolling brush mechanism; 51. a rolling brush mounting part; 52. a roll brush assembly; 53. an adjusting seat; 54. a fixed block; 55. adjusting the column; 6. an oiling mechanism; 61. mounting a plate; 62. installing a shaft; 63. oiling a roller; 64. an oiling layer; 65. a gland; 66. connecting sleeves; 67. an elastic member; 68. a limiting bulge; 69. oiling the mobile device; 601. a guide pair; 6011. a guide bar; 602. lifting the positioning plate; 603. a floating sleeve; 604. a first slide hole; 605. a slider; 606. a floating stop block; 7. a multi-axis position adjustment mechanism; 72. a Y-axis linear moving device; 73. a Z-axis linear moving device; 8. a connecting frame; 9. a total mounting frame; 10. a first crushing moving device; 11. a second crushing moving device; 12. a third mobile device; 13. a mold; 14. a first cleaning moving device; 15. a fourth mobile device; 16. and a rolling brush moving device.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

To better explain this embodiment, reference is made to the concept of X, Y, Z axes, where three spatial axes orthogonal to each other are taken as an X axis, a Y axis, and a Z axis, and the + X axis direction is the advancing direction of the side groove of the mold 13 and the-Z axis direction is the gravity direction. The movement in the back-and-forth or up-and-down direction or the movement in the X-axis, Y-axis, and Z-axis directions in the embodiments are not limited to the movement in the vertical, horizontal, or parallel direction, and the movement having an inclination angle may be calculated as long as there is a component movement in the direction.

In this embodiment, the mold 13 is a lower mold of the pipe pile mold, and both sides of the lower mold are provided with groove structures, so the groove structures are called side grooves. This embodiment is used for cleaning the side groove, but is not limited thereto.

Example (b): as shown in fig. 1 to 17, an automatic mold cleaning machine includes a mold 13 and the following mechanisms:

a conveyor line 1 configured to convey the mold 13;

a crushing mechanism 3 configured to crush cement on the side groove of the mold 13;

the groove cleaning mechanism 4 is configured to clean the side groove of the mold 13 for the first time;

the rolling brush mechanism 5 is configured to perform secondary cleaning on the side groove of the die 13;

an oiling mechanism 6 configured to perform an oiling process on the side groove of the mold 13;

the crushing mechanism 3, the groove cleaning mechanism 4, the rolling brush mechanism 5 and the oiling mechanism 6 are matched with the conveying line and are sequentially arranged along the conveying direction (namely the direction of the X axis) of the conveying line.

Be equipped with the fixed position 2 that is used for fixed mould 13 on the transfer chain 1, crushing mechanism 3, clear scouring machine construct 4, round brush mechanism 5 arrange in proper order in the top of fixed position 2 along the direction of delivery of transfer chain 1.

In this embodiment, the number of the crushing mechanism 3, the groove cleaning mechanism 4, the rolling brush mechanism 5, and the oil coating mechanism 6 is two and are respectively and correspondingly disposed on the side grooves at two sides of the mold 13, but not limited thereto, the four numbers can be a plurality of simple and free combinations, and the protection scope of this scheme is also included.

To the cement that solidifies on 13 side trench positions of mould, this scheme adopts automatic processing mode, this scheme designs through the cement that solidifies to 13 side trench surfaces of mould formation pertinence, utilize the longer characteristics of 13 self lengths of mould, cooperate ground with broken mechanism 3, clear groove mechanism 4, round brush mechanism 5, fat liquoring mechanism 6 arranges in proper order to make the clearance of mould 13 can realize conveniently automaticly, efficient machining efficiency still has, so that reduce the cost of artifical clearance effectively.

Before the clearance processing, install mould 13 on the fixed position 2 of transfer chain 1, realize through transfer chain 1 that crushing mechanism 3, clear groove mechanism 4, round brush mechanism 5, oiling machine construct 6's cooperation, and then realize the automated processing of this scheme, mould 13 advances along with advancing of transfer chain 1, and then passes through crushing mechanism 3, clear groove mechanism 4, round brush mechanism 5, oiling machine construct 6's clearance and processing in proper order.

The working process is as follows: the surface of the set cement is crushed firstly, so that the set cement solidified in the side groove position of the mould 13 is crushed into a plurality of blocks; then, along with the advance of the mould 13, the groove cleaning mechanism 4 can clean the set cement in the side groove of the mould 13, and because the set cement on the side groove of the front mould 13 is basically crushed, the groove cleaning mechanism 4 only needs to bear the resistance caused by the set cement in the side groove of the mould 13, so that the cleaning of the mould 13 is smoother; next, as the crushing mechanism 3 and the groove cleaning mechanism 4 crush and clean the side groove of the die 13, a large amount of crushed cement is formed on the surface of the side groove of the die 13, and the rolling brush mechanism 5 can quickly clean the crushed cement on the side groove of the die 13 along with the further advance of the side groove of the die 13; and finally, the oiling process can be quickly and conveniently finished through the oiling mechanism 6, and the oiling process is immediately carried out after the side groove of the die 13 is cleaned, so that the oiling effect can be conveniently improved, and the oiling efficiency can also be conveniently improved.

The embodiment further comprises a multi-axis position adjusting mechanism 7 and a connecting frame 8, wherein the multi-axis position adjusting mechanism 7 is arranged above the transportation line, the crushing mechanism 3, the groove cleaning mechanism 4 and the rolling brush mechanism 5 are arranged on the connecting frame 8, and the connecting frame 8 is arranged on the movable end of the multi-axis position adjusting mechanism 7. The crushing mechanism 3, the groove cleaning mechanism 4, the rolling brush mechanism 5 and the oiling mechanism 6 realize position adjustment relative to the die 13 through the multi-shaft position adjusting mechanism 7.

The embodiment includes the overall mounting frame 9, and the multi-axis position adjusting mechanism 7 includes a Y-axis linear movement device 72 and a Z-axis linear movement device 73; the Y-axis linear moving device 72 is movable on the overall mounting frame 9 along the width direction of the mold 13, the Z-axis linear moving device 73 is disposed on the movable end of the Y-axis linear moving device 72, and the connecting frame 8 is disposed on the movable end of the Z-axis linear moving device 73. The present embodiment provides a specific embodiment of the multi-axis position adjustment mechanism 7.

As shown in fig. 10 and 11, the rolling brush mechanism 5 includes a rolling brush mounting part 51 and a rolling brush assembly 52, the rolling brush mounting part 51 is adjustably disposed on the connecting frame 8, and the rolling brush assembly 52 is rotatably connected to the rolling brush mounting part 51.

The adjustable adjustment seat 53 is installed to adjustable on the round brush installation department 51, and round brush subassembly 52 rotates to be connected on adjustment seat 53, is equipped with fixed block 54 on the round brush installation department 51, and the screw thread is worn to be equipped with on the fixed block 54 can be contradicted in the adjustment post 55 on the adjustment seat 53, is equipped with round brush mobile device 16 on the link 8, and the expansion end of round brush mobile device 16 is connected on round brush installation department 51.

The angle adjustment of the brush mounting portion 51 is achieved by controlling the protruding distance of the movable end of the brush moving device 16. The adjusting column 55 is adjusted to penetrate through the adjusting seat 53 by adjusting the length of the adjusting column, so as to control the position of the adjusting seat 53 on the rolling brush installation part 51, and further realize the adjustment of the position of the rolling brush component 52.

As shown in fig. 1 to 5, the crushing mechanism 3 includes:

a crushing mount 31 for mounting and fixing;

a first crushing column 32, slidably connected to crushing mounting frame 31, capable of moving closer to or farther away from mold 13;

a first crushing blade 33 slidably attached to a side wall of the crushing mount 31 and capable of moving toward or away from the mold 13;

the moving axial direction of the first crushing column 32 and the moving axial direction of the first crushing knife 33 are parallel to each other.

When the first crushing column 32 continuously moves towards the direction close to the surface of the mould 13 (namely, the-Z-axis direction), the first crushing column 32 can perform primary crushing on the set cement on the side groove of the mould 13; then, with the continuous feeding and moving of the mold 13, the first crushing cutter 33 also moves in a direction (i.e., -Z-axis direction) close to the surface of the mold 13 until the first crushing cutter 33 performs secondary crushing on the set cement crushed by the first crushing column 32, so as to automatically clean the side groove position of the mold 13, and improve the cleaning efficiency and subsequent recycling of the mold 13 after use; this scheme is earlier through the less (comparatively sharp-pointed) first broken post 32 of area of contact to the cement that solidifies on the 13 side grooves of mould preliminary broken, then carries out the large tracts of land breakage to the cement that solidifies through the great first broken sword 33 of area of contact again, through the broken mode of substep step by step promptly, carries out high-efficient breakage to the cement that solidifies.

The crushing mechanism 3 further includes a first crushing moving device 10 that is capable of reciprocating in a direction in which the mold 13 approaches (i.e., -Z-axis direction), the first crushing moving device 10 is disposed on the crushing mounting frame 31, and a first crushing column 32 is disposed on a movable end of the first crushing moving device 10. The first crushing moving device 10 reciprocates to drive the first crushing column 32 to reciprocate toward the die 13.

The movable end of the first breaking mobile device 10 is provided with a first connecting block 37, and the first breaking column 32 is detachably mounted on the first connecting block 37. The first crushing column 32 can be conveniently mounted and dismounted through the first connecting block 37, and therefore replacement of the first crushing column 32 is facilitated.

The crushing mechanism 3 further comprises a second crushing and moving device 11, the second crushing and moving device 11 is arranged on the side wall of the crushing mounting frame 31, and the first crushing knife 33 is detachably mounted on the movable end of the second crushing and moving device 11; the second crushing moving device 11 can drive the first crushing blade 33 closer to or farther from the die 13. The second crushing moving device 11 drives the first crushing blade 33 to reciprocate in a direction in which the mold 13 approaches (i.e., -Z-axis direction) by its own reciprocating motion.

The movable end of the second crushing and moving device 11 is provided with a second connecting block 34, and the first crushing knife 33 is detachably mounted on the second connecting block 34. The first crushing knife 33 can be conveniently mounted and dismounted through the second connecting block 34, and therefore the first crushing knife 33 can be conveniently replaced.

The crushing mounting frame 31 is provided with a sliding connecting cylinder 35 arranged along the moving axial direction of the first crushing column 32, and the first crushing column 32 is slidably arranged in the sliding connecting cylinder 35 in a penetrating manner.

The first crushing column 32 comprises a crushing rod 321 and a pick 322 arranged at the end of the crushing rod 321, and the crushing rod 321 is slidably connected to the crushing mounting frame 31. This embodiment provides a specific embodiment of the first crushing column 32.

The rod body is slidably arranged in the sliding connecting cylinder 35 in a penetrating manner, and the sliding connecting cylinder 35 can enable the first crushing column 32 to slide more smoothly. The pick head 322 has a trapezoidal cross section along the length direction of the first crushing column 32, and the trapezoidal cross section of the pick head 322 may facilitate the improvement of the cement crushing capacity of the pick head 322.

The first crushing blade 33 includes a first body 331 and a chopping portion 332 disposed on the first body 331, and the first body 331 is slidably coupled to a sidewall of the crushing mounting frame 31. The section of the chopper portion 332 along the moving axial direction (i.e., the-Z-axis direction) of the first crushing blade 33 is trapezoidal, and the chopper portion 332 having a trapezoidal section facilitates to improve the crushing capability of the chopper portion 332 for cement.

The side of the crushing mounting frame 31 is rotatably connected with a first rotating bracket 36, the first rotating bracket 36 is rotatably connected with a third moving device 12, and the movable end of the third moving device 12 is rotatably connected to the crushing mounting frame 31.

As shown in fig. 6 to 7, the groove cleaning mechanism 4 includes a groove cleaning mounting frame 41 disposed beside the mold 13;

a groove cleaning part 42 matched with the groove body of the mold 13;

a sliding through groove 43 is arranged on the groove cleaning mounting frame 41, a groove cleaning part 42 is slidably arranged on the groove cleaning mounting frame 41, and the groove cleaning part 42 can penetrate through the sliding through groove 43 and is close to the mold 13.

The groove cleaning part 42 slides down along the sliding through groove 43 to the groove (the side groove of the lower mold in the embodiment) abutting against the surface of the mold 13, and the groove cleaning part 42 is matched with the groove (the side groove of the lower mold in the embodiment) on the surface of the mold 13, so that the groove cleaning part 42 can clean the cement in the groove on the surface of the mold 13 along with the advance of the mold 13, so as to clean the groove on the surface of the mold 13, the process is convenient and fast, and the working efficiency is higher.

The groove cleaning mechanism 4 further comprises a first groove cleaning moving device 14 capable of reciprocating in the approaching direction (namely-Z-axis direction) of the mold 13, the first groove cleaning moving device 14 is arranged on the groove cleaning mounting frame 41, the groove cleaning portion 42 is arranged on the movable end of the first groove cleaning moving device 14, and the first groove cleaning moving device 14 can drive the groove cleaning portion 42 to approach the mold 13. The first cleaning moving device 14 can be used to drive the cleaning portion 42 to move along the vertical direction, so that the cleaning portion 42 moves to abut against the surface groove of the mold 13 or move to separate from the surface groove of the mold 13.

As shown in fig. 8 and 9, a communication groove 44 is formed on the inner wall of the sliding through groove 43 on the circumferential side in parallel with the axial direction of the sliding through groove 43. The groove cleaning part 42 comprises a rod body and a groove cleaning jig 422, the rod body is connected in the sliding through groove 43 in a sliding mode, the groove cleaning jig 422 is arranged at the end portion of the rod body, and the groove cleaning jig 422 is matched with a groove on the surface of the mold 13.

The communicating grooves 44 are disposed at four corners of the inner wall of the sliding through groove 43, and since the sliding of the cleaning rod 421 in the sliding through groove 43 may be difficult due to the change of air pressure, the communicating grooves 44 can make the cleaning rod 421 slide more smoothly in the sliding through groove 43.

As shown in fig. 6 and 7, the groove cleaning jig 422 is provided with a groove cleaning protrusion 45 which is matched with the groove on the surface of the mold 13 and used for cleaning the groove, one side of the groove cleaning jig 422 is provided with a first inclined surface 46, the other opposite side of the groove cleaning jig 422 is provided with a second inclined surface 47, and the groove cleaning protrusion 45 is formed between the first inclined surface 46 and the second inclined surface 47.

The first inclined surface 46 is arranged obliquely upward (upward, i.e., + Z-axis direction) from the side close to the groove cleaning projection 45 toward the side away from the groove cleaning projection 45, and the second inclined surface 47 is arranged obliquely upward (upward, i.e., + Z-axis direction) from the side close to the groove cleaning projection 45 toward the side away from the groove cleaning projection 45.

The first inclined surface 46 and the second inclined surface 47 can prevent cement in the groove on the surface of the mold 13 from being excessively accumulated on the outer wall of the groove cleaning part 42, so as to avoid the situation that the groove cleaning part 42 is difficult to slide on the groove on the surface of the mold 13 due to excessive accumulation.

The groove cleaning jig 422 is provided with a third inclined surface 48 for reducing resistance, and the third inclined surface 48 is arranged obliquely upward (upward, i.e., + Z-axis direction) from a side close to the groove cleaning projection 45 to a side far away from the groove cleaning projection 45. The third inclined surface 48 may facilitate reducing resistance of the chamfer portion 42 to the groove sliding process on the surface of the mold 13.

And a cooling pipe 49 for conveying cooling liquid is arranged on the side wall of the groove cleaning mounting frame 41, and the output end of the cooling pipe 49 faces to the bottom of the groove cleaning part 42. The cooling pipe 49 can output cooling liquid to the contact position of the groove cleaning part 42 and the surface groove of the die 13, which not only can facilitate reducing the temperature generated by the sliding friction of the groove cleaning part 42, but also can facilitate improving the sliding fluency of the groove cleaning part 42.

The side of clear groove mounting bracket 41 rotates and is connected with second runing rest 401, rotates on the second runing rest 401 and is connected with fourth mobile device 15, and the expansion end of fourth mobile device 15 rotates and connects on clear groove mounting bracket 41. The fourth movement means 15 can be used to drive the angular adjustment of the chute cleaning mounting 41.

As shown in fig. 12 to 16, the oiling mechanism 6 includes a mounting plate 61, and further includes the following components:

the oil coating moving device 69, wherein the mounting plate 61 is arranged on the movable end of the oil coating moving device 69;

a mounting shaft 62 passing through the mounting plate 61;

the oiling roller 63 is rotationally connected to the mounting shaft 62;

the oiling roller 63 is elastically connected to the mounting plate 61, and an oiling layer 64 is wound on the oiling roller 63.

After the side groove of the die 13 is cleaned, the oiling roller 63 drives the oiling layer 64 to rotate, so that the side groove of the die 13 can quickly and conveniently finish an oiling process, and the oiling process is carried out immediately after the side groove of the die 13 is cleaned, so that the oiling effect can be improved, the oiling efficiency can be improved, and the oiling processing cost can be reduced; secondly, fat liquoring gyro wheel 63 adopts elastic connection's mode to contradict to connect on mounting panel 61, can be convenient for improve the deformability of fat liquoring gyro wheel 63 in unevenness's mould 13 side groove rotation in-process to be convenient for improve fat liquoring gyro wheel 63's life.

The number of the oiling layers 64 is several, and the oiling layers are uniformly distributed along the circumferential side wall of the oiling roller 63.

The end of the oiling roller 63 is detachably provided with a gland 65 which can press the oiling layer 64 on the oiling roller 63.

The oiling layer 64 is a felt layer.

During installation, the pressing cover 65 is firstly detached, then the plurality of oiling layers 64 are installed on the oiling roller 63, and finally the pressing cover 65 is installed and fixed on the oiling roller 63, so that the plurality of oiling layers 64 and the oiling roller 63 are integrated.

The mounting plate 61 is provided with a connecting sleeve 66 in a penetrating manner, one end of the mounting shaft 62 is fixed in the connecting sleeve 66 in a penetrating manner, and the oiling roller 63 is rotatably connected to the other end of the mounting shaft 62. The connecting sleeve 66 is a copper sleeve.

The cover is equipped with elastic component 67 on the outer wall of installation axle 62, is equipped with spacing arch 68 on the outer wall of installation axle 62, and the one end of elastic component 67 is contradicted on mounting panel 61, and the other end is contradicted on spacing arch 68.

The elastic member 67 is a spring member to elastically connect the oiling roller 63 to the mounting plate 61.

The present embodiment includes an oil applying moving device 69 located above the mold 13, and the mounting plate 61 is provided on the movable end of the oil applying moving device 69.

The oiling moving device 69 can be used for adjusting the height adjustment of the mounting plate 61 in the vertical direction (i.e., the Z-axis direction) so as to adjust the oiling layer 64 to be attached to the side groove of the mold 13 or to be away from the side groove of the mold 13.

The mounting plate 61 is provided with a guide pair 601 which is arranged along the moving axial direction of the oiling moving device 69, the guide pair 601 is connected with a lifting positioning plate 602 in a sliding manner, and the fixed end of the oiling moving device 69 is arranged on the lifting positioning plate 602; the movable end of the oiling moving device 69 passes through the lifting positioning plate 602 and is connected with the mounting plate 61.

The guide pair 601 includes a plurality of guide rods 6011, one end of each guide rod 6011 is disposed on the mounting plate 61, and the other ends of the plurality of guide rods 6011 are connected into a whole through a connecting guide plate.

A floating sleeve 603 is arranged on the mounting plate 61, a first sliding hole 604 is formed in the floating sleeve 603, a floating block 605 is arranged at the movable end of the oiling moving device 69, and a floating limit block 606 is arranged at the end part of the floating block 605; the floating block 605 passes through the first sliding hole 604 and is slidably connected in the floating sleeve 603, and slides on the floating stopper 606 and the bottom of the floating sleeve 603.

The float stop 606 may allow the float 605 to limit its movement within the float sleeve 603, making the distance of elevation of the oiling moving device 69 more targeted.

In the present embodiment, the first crushing and moving device 10, the second crushing and moving device 11, the first cleaning and moving device 14, the rolling brush moving mechanism, the third moving device 12, and the fourth moving device 15 all move linearly, which may be linear cylinders or other commonly used linear moving devices.

The present embodiment is only for explaining the present invention, and it is not limited to the present invention, and those skilled in the art can make modifications of the present embodiment without inventive contribution as needed after reading the present specification, but all of them are protected by patent law within the scope of the claims of the present invention.

Claims (10)

1. Be applied to broken mechanism of mould cell body cement, its characterized in that includes:

the crushing mounting rack is used for mounting and fixing;

the first crushing column is connected to the crushing mounting frame in a sliding mode and can be close to or far away from the die;

the first crushing knife is connected to the side wall of the crushing mounting frame in a sliding mode and can be close to or far away from the die;

the moving axial direction of the first crushing column is parallel to the moving axial direction of the first crushing knife.

2. The crushing mechanism applied to cement crushing of the die tank body as claimed in claim 1, further comprising a first crushing moving device, wherein the first crushing moving device is arranged on the crushing mounting frame, and the first crushing column is arranged on a movable end of the first crushing moving device.

3. The crushing mechanism applied to cement crushing of the die tank body as claimed in claim 2, wherein a first connecting block is arranged at the movable end of the first crushing moving device, and the first crushing column is detachably mounted on the first connecting block.

4. The crushing mechanism applied to cement crushing of the die tank body according to claim 1, further comprising a second crushing moving device, wherein the second crushing moving device is arranged on the side wall of the crushing mounting frame, and the first crushing knife is detachably mounted on the movable end of the second crushing moving device; the second crushing moving device can drive the first crushing knife to be close to or far away from the die.

5. The crushing mechanism applied to cement crushing of the die tank body as claimed in claim 4, wherein a second connecting block is arranged on a movable end of the second crushing moving device, and the first crushing knife is detachably mounted on the second connecting block.

6. The crushing mechanism applied to cement crushing of the die tank body as claimed in claim 1, wherein a sliding connecting cylinder arranged along the moving axial direction of the first crushing column is arranged on the crushing mounting frame, and the first crushing column is slidably arranged in the sliding connecting cylinder in a penetrating manner.

7. The crushing mechanism applied to cement crushing of the die tank body as claimed in claim 1, wherein the first crushing column comprises a rod body and a pick head arranged at the end of the rod body, and the rod body is slidably connected to the crushing mounting frame.

8. The crushing mechanism applied to the die groove body cement crushing as claimed in claim 7, wherein the section of the pick head along the length direction of the first crushing column is trapezoidal.

9. The crushing mechanism applied to die slot cement crushing according to claim 1, wherein the first crushing knife comprises a first main body and a chopping knife part arranged on the first main body, and the first main body is slidably connected to the side wall of the crushing mounting frame.

10. The crushing mechanism applied to cement crushing of the die tank body as claimed in claim 1, wherein a first rotating support is rotatably connected to the side of the crushing mounting frame, a third moving device is rotatably connected to the first rotating support, and a movable end of the third moving device is rotatably connected to the crushing mounting frame.

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