A rosin quick crushing device for rosin paste production
By designing a rosin rapid pulverizing device with feeding, dust blocking, and back-blowing mechanisms, the problems of inconvenient rosin block handling, dust scattering, and filter plate clogging in rosin paste production have been solved, achieving convenient feeding and efficient pulverization.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- ANYUAN COUNTY SONGYUAN FORESTRY CHEM CO LTD
- Filing Date
- 2026-03-19
- Publication Date
- 2026-06-26
AI Technical Summary
Existing pulverizing equipment for rosin paste production has several problems, including the inconvenience of having to move the rosin blocks to be pulverized to a high place for loading, the inability to easily control the feeding rate, the scattering of rosin dust, and the easy clogging of the annular filter plate.
A rapid rosin pulverizing device was designed, which includes a feeding mechanism, a dust blocking mechanism, and a back-blowing mechanism. The feeding mechanism enables convenient feeding of rosin blocks from a high position to a low position, the dust blocking mechanism intercepts dust, and the back-blowing mechanism prevents the filter plate from clogging.
It enables convenient feeding control of rosin blocks, avoids dust scattering and filter plate clogging, and improves operational convenience and equipment operating efficiency.
Smart Images

Figure CN122273641A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of rosin paste production technology, specifically to a rapid rosin pulverizing device for rosin paste production. Background Technology
[0002] Rosin ointment is a traditional external ointment made with rosin as the main base and added medicinal materials or excipients. It has the effects of dispelling wind and dampness, reducing swelling and relieving pain, and promoting tissue regeneration and wound healing.
[0003] Rosin paste production requires the use of a pulverizing device to crush the rosin blocks, but existing rapid rosin pulverizing devices for rosin paste production still have certain shortcomings:
[0004] 1. The staff need to move the rosin blocks to be crushed to a high place for loading, which is inconvenient for the staff to operate and wastes manpower. In addition, it is not easy to control the feeding rate of the rosin blocks to be crushed.
[0005] 2. Rosin dust is easily scattered during the crushing process, which can affect the workers.
[0006] 3. It is not easy to clean the annular filter plate thoroughly and effectively, which can easily lead to sludge accumulation and blockage.
[0007] To address the aforementioned problems, this application proposes a rapid rosin pulverizing device for rosin paste production. Summary of the Invention
[0008] To address the problems of existing technologies, such as the need for workers to move rosin blocks to a high place for feeding, the inability to easily control the feeding rate of rosin blocks, the easy scattering of rosin dust during rosin block crushing which affects workers, and the difficulty in effectively cleaning the annular filter plate, the present invention aims to provide a rapid rosin crushing device for rosin paste production.
[0009] To solve the above-mentioned technical problems, the present invention adopts the following technical solution: a rosin rapid pulverizing device for rosin paste production, including a supporting base frame, a pulverizing mechanism fixedly installed at the top of the supporting base frame, and a feeding mechanism for use with the pulverizing mechanism on one side of the supporting base frame. A dust-blocking mechanism for use is provided at the top of the feeding mechanism, and a back-blowing mechanism and an auxiliary mechanism for use with the dust-blocking mechanism are provided on the pulverizing mechanism. The feeding mechanism can transfer the feeding operation of rosin blocks to be pulverized from a high position to a low position, and can conveniently control the feeding rate of the rosin blocks to be pulverized. The dust-blocking mechanism can intercept the dust generated during the pulverization of rosin blocks. The combined use of the back-blowing mechanism and the auxiliary mechanism can prevent the pulverizing mechanism from accumulating and clogging.
[0010] Preferably, the crushing mechanism includes a crushing cylinder and a first motor. Both the crushing cylinder and the first motor are fixedly mounted on the top of a support frame. A discharge conduit is connected to the bottom of the crushing cylinder. A support base is fixedly mounted on one side of the support frame, and the first motor is fixedly mounted on the top of the support base. A matching collection bag is fixedly connected to the end of the discharge conduit. A matching annular filter plate is integrally formed in the inner cavity of the crushing cylinder. A crushing rod is rotatably inserted into the middle of the crushing cylinder. A crushing blade is fixedly fitted at one end of the crushing rod, and a scraper pusher plate that cooperates with the annular filter plate is fixedly connected to the end of the crushing blade. A first wheel is fixedly fitted at the other end of the crushing rod. A second wheel is fixedly fitted on the outer side of the output end of the first motor, and two transmission belts are driven by the outer sides of the second wheel and the first wheel. The feeding mechanism includes a feeding bracket, which is fixedly mounted... Mounted on a supporting base, the feeding bracket is connected to a connecting conduit that communicates with the crushing cylinder. Feeding screws are rotatably inserted into both sides of the feeding bracket, and a first synchronous pulley is fixedly sleeved at the top of each feeding screw. Feeding slides are threaded onto both feeding screws and slidably mounted on the feeding bracket. A V-shaped conduit, which works in conjunction with the connecting conduit, is connected to the feeding slide, and a feeding frame is fixedly connected to the top of the V-shaped conduit. Symmetrically arranged stabilizing rods are fixedly inserted into the feeding slide, and the ends of the stabilizing rods are fixedly connected to the feeding frame. A second motor is fixedly installed at the top center of the feeding bracket, and a second synchronous pulley is fixedly sleeved at the output end of the second motor. A mounting bracket is fixedly inserted into the top of the feeding bracket, and the second motor is fixedly inserted into the mounting bracket. A transmission synchronous belt meshes with the outer sides of the second and first synchronous pulleys.
[0011] Preferably, the dust-blocking mechanism includes a dust-blocking top frame, which is fixedly installed on one side of the top of the feeding bracket, and the upper end of the feeding frame can be slidably inserted into the dust-blocking top frame. A dust-blocking cylinder is connected to the dust-blocking top frame, and an inner grid plate and a dust-blocking filter plate are fixedly installed inside the dust-blocking cylinder. A dual-axis motor is fixedly inserted into the middle of the inner grid plate, and the output end of the dual-axis motor rotates through the dust-blocking filter plate and is fixedly fitted with a cleaning scraper at its end. A guide fan blade is fixedly fitted at the end of the output end of the dual-axis motor. An L-shaped exhaust pipe is connected to the middle of the top of the dust-blocking cylinder, and a first solenoid valve is fixedly installed at the end of the L-shaped exhaust pipe. A side exhaust pipe is connected to the L-shaped exhaust pipe, and a second solenoid valve is fixedly installed on the side exhaust pipe.
[0012] Preferably, the backflushing mechanism includes an L-shaped guide tube, one end of which is fixedly connected to the end of an L-shaped exhaust pipe, and the other end of which is connected to an arc-shaped guide tube. An array of backflushing diverter tubes are connected to the arc-shaped guide tube, and the ends of the backflushing diverter tubes are fixedly mounted on the crushing cylinder. An array of connecting through holes are opened through the crushing cylinder, and these connecting through holes are connected to the backflushing diverter tubes. The backflushing diverter tubes near the discharge guide tube are fixedly inserted into the support base. The auxiliary mechanism includes a rotary cylinder and a driven gear ring. The rotary cylinder is fixedly mounted on the upper side of the crushing cylinder, and its output end rotates through the crushing cylinder. The body has a drive gear fixedly sleeved at its end. The driven gear ring is rotatably mounted on the inner wall of the crushing cylinder near the rotating cylinder, and the driven gear ring meshes with the drive gear. An annular baffle is fixedly connected to the outer wall of the end of the annular filter plate near the rotating cylinder, and the driven gear ring is rotatably connected to the annular baffle. An arc-shaped rotating plate is integrally formed on the driven gear ring, and the arc-shaped rotating plate slides against the inner wall of the crushing cylinder. An arc-shaped baffle is integrally formed at the end of the arc-shaped rotating plate, and the outer wall of the arc-shaped baffle slides against the inner wall of the crushing cylinder. An array of through holes are opened through the arc-shaped baffle, and the through holes can be connected to the connecting through holes.
[0013] Compared with the prior art, the beneficial effects of the present invention are as follows:
[0014] 1. The feeding mechanism facilitates the synchronous forward and reverse rotation of the two feeding screws, thereby facilitating the lifting and lowering of the feeding carriage and the synchronous lifting and lowering of the V-shaped guide tube and the feeding frame. This allows the feeding operation of rosin blocks to be crushed to be carried out from a high position to a low position, making it easier for workers to operate and saving manpower. In addition, the upward height of the feeding frame can be easily controlled, thereby facilitating the control of the size of the connection between the V-shaped guide tube and the connecting guide tube, and thus facilitating the control of the feeding rate of the rosin blocks to be crushed.
[0015] 2. The dust-blocking mechanism can drive the guide fan blades and cleaning scraper to rotate synchronously, thereby gradually drawing out the air in the feeding frame and the dust-blocking top frame and discharging it through the side exhaust pipe. At this time, the dust-blocking filter plate can intercept the dust generated during the crushing of rosin blocks, thus preventing the rosin dust from flying and affecting the workers. The cleaning scraper can scrape and clean the intercepted rosin dust, further preventing the dust-blocking filter plate from becoming clogged.
[0016] 3. The combined use of the backflushing mechanism and auxiliary mechanism facilitates the rotation and reset of the arc-shaped baffle, thereby facilitating the docking and misalignment of the connecting through holes and the connecting holes. This prevents the backflushing of rosin powder after crushing during non-cleaning periods of the annular filter plate. Furthermore, when the annular filter plate needs cleaning, air can be introduced into the arc-shaped guide tube. Subsequently, the air will be introduced into the backflushing diversion pipe and guided to the outer wall of the annular filter plate through the connecting through holes and the docking through holes. This allows the air to blow from the outside of the annular filter plate to the inside, thereby forming a backflushing thrust with the crushed rosin powder filtered out. This further facilitates thorough and effective cleaning of the annular filter plate and prevents it from accumulating and clogging. Attached Figure Description
[0017] To more clearly illustrate the technical solutions in the embodiments of the present invention or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of the present invention. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0018] Figure 1 This is a schematic diagram of the structure of the present invention.
[0019] Figure 2 This is a schematic diagram of the installation of the crushing mechanism in this invention.
[0020] Figure 3 For the present invention Figure 2 Enlarged schematic diagram of the structure at point A in the middle.
[0021] Figure 4 For the present invention Figure 2 Enlarged schematic diagram of the structure at point B.
[0022] Figure 5 For the present invention Figure 2 Enlarged schematic diagram of the structure at point C.
[0023] Figure 6 This is a schematic diagram of the installation of the backflush mechanism in this invention.
[0024] Figure 7 For the present invention Figure 6 Enlarged schematic diagram of the structure at point D.
[0025] Figure 8 For the present invention Figure 6 Enlarged schematic diagram of the structure at point E in the middle.
[0026] In the diagram: 1. Support base; 2. Crushing mechanism; 21. Crushing cylinder; 22. First motor; 23. Discharge guide pipe; 24. Collection bag; 25. Annular filter plate; 26. Crushing rotor; 27. Crushing blade; 28. Scraper push plate; 29. First wheel; 210. Second wheel; 211. Conveyor belt; 212. Support base; 213. Connecting through hole; 3. Feeding mechanism; 31. Feeding bracket; 32. Connecting guide pipe; 33. Feeding screw; 34. First synchronous pulley; 35. Feeding slide; 36. V-shaped guide pipe; 37. Feeding frame; 38. Second motor; 39. Second synchronous pulley; 310. Conveyor synchronous belt 311. Stable support rod; 312. Mounting bracket; 4. Dust trapping mechanism; 41. Dust trapping top frame; 42. Dust trapping cylinder; 43. Inner grid plate; 44. Dust trapping filter plate; 45. Dual-shaft motor; 46. Cleaning scraper; 47. Guide fan blade; 48. L-shaped exhaust pipe; 49. First solenoid valve; 410. Side exhaust pipe; 411. Second solenoid valve; 5. Back-blowing mechanism; 51. L-shaped duct; 52. Arc-shaped duct; 53. Back-blowing diverter pipe; 6. Auxiliary mechanism; 61. Rotary cylinder; 62. Driven gear ring; 63. Drive gear; 64. Arc-shaped rotating plate; 65. Arc-shaped baffle; 66. Butt joint perforation; 67. Annular baffle. Detailed Implementation
[0027] The technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments. Based on the embodiments of the present invention, all other embodiments obtained by those skilled in the art without creative effort are within the scope of protection of the present invention.
[0028] Example: Figures 1-8 As shown, the present invention provides a rapid rosin pulverizing device for rosin paste production, including a support base 1, a pulverizing mechanism 2 fixedly installed at the top of the support base 1, and a feeding mechanism 3 for use with the pulverizing mechanism 2 on one side of the support base 1. A dust-blocking mechanism 4 for use is provided at the top of the feeding mechanism 3, and a back-blowing mechanism 5 and an auxiliary mechanism 6 for use with the dust-blocking mechanism 4 are provided on the pulverizing mechanism 2. The feeding mechanism 3 can transfer the feeding operation of the rosin blocks to be pulverized from a high position to a low position, and can conveniently control the feeding rate of the rosin blocks to be pulverized. The dust-blocking mechanism 4 can intercept the dust generated during the pulverization of the rosin blocks. The use of the back-blowing mechanism 5 and the auxiliary mechanism 6 can prevent the pulverizing mechanism 2 from accumulating and clogging.
[0029] The crushing mechanism 2 includes a crushing cylinder 21 and a first motor 22. Both the crushing cylinder 21 and the first motor 22 are fixedly mounted on the top of the support base 1. The bottom end of the crushing cylinder 21 is connected to a discharge conduit 23. A support base 212 is fixedly mounted on the top of one side of the support base 1, and the first motor 22 is fixedly mounted on the top of the support base 212. The support base 212 ensures the stable installation of the first motor 22. A matching material collection bag 24 is fixedly connected to the end of the discharge conduit 23. A matching annular filter plate 25 is integrally formed in the inner cavity of the crushing cylinder 21, and a rotating insert is connected to the middle of the crushing cylinder 21. The crushing rotor 26 has a crushing blade 27 fixedly fitted at one end, and a scraper pusher 28 for use with the annular filter plate 25 is fixedly connected to the end of the crushing blade 27. A first wheel 29 is fixedly fitted at the other end of the crushing rotor 26. A second wheel 210 is fixedly fitted on the outer side of the output end of the first motor 22, and two transmission belts 211 are driven by the outer sides of the second wheel 210 and the first wheel 29. The feeding mechanism 3 includes a feeding bracket 31, which is fixedly installed on the support base 1. A connecting conduit 32 connected to the crushing cylinder 21 is provided on the feeding bracket 31. Both sides of the feeding bracket 31 are... A feeding screw 33 is rotatably inserted, and a first synchronous pulley 34 is fixedly sleeved on the top of the feeding screw 33. Feeding slides 35 are threaded onto the two feeding screws 33, and the feeding slides 35 are slidably mounted on the feeding bracket 31. A V-shaped guide tube 36, which mates with the connecting guide tube 32, is connected to the feeding slide 35, and a feeding frame 37 is fixedly connected to the top of the V-shaped guide tube 36. Symmetrically arranged stabilizing support rods 311 are fixedly inserted into the feeding slide 35, and the ends of the stabilizing support rods 311 are fixedly connected to the feeding frame 37. The stabilizing support rods 311 provide a stable connection between the feeding frame 37 and the feeding slide 35. To ensure stability, a second motor 38 is fixedly installed at the top center of the feeding bracket 31, and a second synchronous pulley 39 is fixedly sleeved at the output end of the second motor 38. A mounting bracket 312 is fixedly inserted into the top of the feeding bracket 31, and the second motor 38 is fixedly inserted into the mounting bracket 312. The mounting bracket 312 provides a guarantee for the stable installation of the second motor 38. The second synchronous pulley 39 and the outer side of the first synchronous pulley 34 are meshed with a transmission synchronous belt 310. A stop bar is provided at the top of the feeding bracket 31 for cooperation, which can prevent the transmission synchronous belt 310 from derailing. This is existing technology and will not be described in detail here.
[0030] By adopting the above technical solution, in use, the second motor 38 is started, which drives the second synchronous pulley 39 to rotate. This, in turn, drives the two first synchronous pulleys 34 to rotate synchronously via the transmission synchronous belt 310. Furthermore, it drives the two feeding screws 33 to rotate synchronously, thereby causing the feeding carriage 35 to move downward. This, in turn, causes the V-shaped guide tube 36 and the feeding frame 37 to move downward, and the V-shaped guide tube 36 to be misaligned and separated from the connecting guide tube 32. When the feeding frame 37 moves to its lowest point, the second motor 38 is paused. Then, an appropriate amount of rosin blocks to be crushed is introduced into the feeding frame 37. The second motor 38 is then started again, causing it to drive the second synchronous pulley 39 to reverse. This drives the two feeding screws 33 to reverse synchronously, thereby causing the feeding frame 37 and the rosin blocks to be crushed inside to move upward synchronously. As the V-shaped guide tube 36 gradually connects with the connecting guide tube... When the V-shaped guide tube 36 and the connecting guide tube 32 are connected, the rosin blocks to be crushed will be gradually guided into the crushing cylinder 21 by the V-shaped guide tube 36 and the connecting guide tube 32. During this period, the upward movement height of the feeding frame 37 can be controlled, so as to conveniently control the size of the connection between the V-shaped guide tube 36 and the connecting guide tube 32, and thus conveniently control the feeding rate of the rosin blocks to be crushed. At the same time, the first motor 22 will drive the second wheel 210 to rotate, which in turn will drive the first wheel 29 to rotate through the transmission belt 211, and further drive the crushing rotating rod 26 to rotate, which will drive the crushing blade 27 and the scraper push plate 28 to rotate, so as to crush the introduced rosin blocks to be crushed and push the incompletely crushed rosin blocks back to the crushing blade 27 for crushing. The crushed rosin powder will pass through the annular filter plate 25 and be introduced into the collection bag 24 for temporary storage through the discharge guide tube 23.
[0031] The dust-blocking mechanism 4 includes a dust-blocking top frame 41, which is fixedly installed on one side of the top of the feeding bracket 31. The upper end of the feeding frame 37 can be slidably inserted into the dust-blocking top frame 41. A dust-blocking cylinder 42 is connected to the dust-blocking top frame 41, and a matching inner grid disk 43 and a dust-blocking filter plate 44 are fixedly installed inside the dust-blocking cylinder 42. A dual-axis motor 45 is fixedly inserted into the middle of the inner grid disk 43, and the output end of the dual-axis motor 45 rotates through the dust-blocking filter plate 44 and a matching cleaning scraper 46 is fixedly sleeved at its end. The output end of the dual-axis motor 45 is located at the top. The end of the dust collection cylinder 42 is fixedly fitted with a matching guide fan blade 47. The top middle of the dust collection cylinder 42 is connected to a matching L-shaped exhaust pipe 48, and the end of the L-shaped exhaust pipe 48 is fixedly installed with a matching first solenoid valve 49. The L-shaped exhaust pipe 48 is connected to a side exhaust pipe 410, and the side exhaust pipe 410 is fixedly installed with a matching second solenoid valve 411. The first solenoid valve 49 and the second solenoid valve 411 can respectively control the connectivity of the end of the L-shaped exhaust pipe 48 and the end of the side exhaust pipe 410. This is the prior art and will not be described in detail here.
[0032] By adopting the above technical solution, during use, the dual-axis motor 45 will drive the guide fan blades 47 and the cleaning scraper 46 to rotate synchronously, thereby gradually extracting the air from the feeding frame 37 and the dust-blocking top frame 41 and discharging it through the side exhaust pipe 410. At this time, the dust-blocking filter plate 44 can intercept the dust generated during the crushing of rosin blocks, thereby preventing the phenomenon of rosin dust flying and affecting the staff. Furthermore, the cleaning scraper 46 can scrape and clean the intercepted rosin dust, further preventing the dust-blocking filter plate 44 from becoming clogged.
[0033] The backflushing mechanism 5 includes an L-shaped conduit 51, one end of which is fixedly connected to the end of an L-shaped exhaust pipe 48, and the other end of which is connected to an arc-shaped conduit 52. An array of backflushing diversion pipes 53 are connected to the arc-shaped conduit 52, and the end of each backflushing diversion pipe 53 is fixedly mounted on the crushing cylinder 21. An array of connecting through holes 213 are opened through the crushing cylinder 21, and these through holes 213 are connected to the backflushing diversion pipes 53. The backflushing diversion pipes 53 near the discharge conduit 23 are fixedly inserted into the support base 1. The auxiliary mechanism 6 includes a rotary cylinder 61 and a driven gear ring 62. The rotary cylinder 61 is fixedly mounted on the upper side of the crushing cylinder 21, and the output end of the rotary cylinder 61 rotates through the crushing cylinder 21, with a drive gear 63 fixedly fitted at its end. The driven gear ring 62 rotates... The driven gear ring 62 is mounted on the inner wall of the crushing cylinder 21 near the rotary cylinder 61, and meshes with the drive gear 63. An annular filter plate 25 is fixedly connected to the outer wall of one end near the rotary cylinder 61, and the driven gear ring 62 is rotatably connected to the annular baffle 67. The use of the annular baffle 67 can prevent the rosin powder after crushing from affecting the transmission between the driven gear ring 62 and the drive gear 63. An arc-shaped rotating plate 64 is integrally formed on the driven gear ring 62, and the arc-shaped rotating plate 64 slides and fits against the inner wall of the crushing cylinder 21. An arc-shaped baffle 65 is integrally formed at the end of the arc-shaped rotating plate 64, and the outer wall of the arc-shaped baffle 65 slides and fits against the inner wall of the crushing cylinder 21. An array of docking holes 66 are opened through the arc-shaped baffle 65, and the docking holes 66 can communicate with the connecting through hole 213.
[0034] By adopting the above technical solution, after the crushing device is used, the rotary cylinder 61 needs to be started, which can drive the drive gear 63 to rotate, which in turn can drive the driven gear ring 62 to rotate, and further drive the arc-shaped rotating plate 64 and the arc-shaped baffle 65 to rotate, thereby driving the docking through hole 66 to rotate. When the docking through hole 66 aligns with the connecting through hole 213, the rotary cylinder 61 is closed, then the second solenoid valve 411 will close, and the first solenoid valve 49 will open. After that, the dual-shaft motor 45 will be restarted, thereby enabling the empty... Air is introduced into L-shaped duct 51 through L-shaped exhaust pipe 48, then into arc-shaped duct 52, and then into backflush diverter pipe 53. The air is then guided to the outer wall of the annular filter plate 25 by connecting through hole 213 and docking through hole 66. This allows the air to blow from the outside of the annular filter plate 25 to the inside, thereby forming a backflush thrust with the filtered and discharged pulverized rosin powder. This further facilitates thorough and effective cleaning of the annular filter plate 25, preventing it from becoming clogged. After cleaning, the arc-shaped baffle 65 and other components can be reset.
[0035] Working principle: In use, the second motor 38 is started, which drives the second synchronous pulley 39 to rotate. This, in turn, drives the two first synchronous pulleys 34 to rotate synchronously via the transmission synchronous belt 310. Furthermore, this drives the two feeding screws 33 to rotate synchronously, thereby causing the feeding slide 35 to move downwards. This, in turn, causes the V-shaped guide tube 36 and the feeding frame 37 to move downwards, causing the V-shaped guide tube 36 to separate from the connecting guide tube 32. The second motor 38 is paused when the feeding frame 37 reaches its lowest point. Then, an appropriate amount of rosin blocks to be crushed is introduced into the feeding frame 37. The second motor 38 is then restarted and its operation is resumed. The second synchronous wheel 39 is reversed, which in turn drives the two feeding screws 33 to reverse synchronously, thereby driving the feeding frame 37 and the rosin blocks to be crushed inside to move upward synchronously. When the upper end of the feeding frame 37 is inserted into the dust-blocking top frame 41, the V-shaped guide tube 36 will gradually connect with the connecting guide tube 32. At this time, the rosin blocks to be crushed will be gradually guided into the crushing cylinder 21 by the V-shaped guide tube 36 and the connecting guide tube 32. During this period, the upward height of the feeding frame 37 can be controlled, thereby conveniently controlling the size of the connection between the V-shaped guide tube 36 and the connecting guide tube 32, and thus conveniently controlling the feeding rate of the rosin blocks to be crushed.
[0036] At the same time, the first motor 22, the dual-shaft motor 45 and the second solenoid valve 411 will be opened, and the first solenoid valve 49 will be closed. At this time, the first motor 22 will drive the second wheel 210 to rotate, which in turn can drive the first wheel 29 to rotate through the transmission belt 211, and further drive the crushing rod 26 to rotate, thereby driving the crushing blade 27 and the scraper push plate 28 to rotate, thereby crushing the introduced rosin blocks to be crushed and pushing the incompletely crushed rosin blocks back to the crushing blade 27 for crushing. The crushed rosin powder will pass through the annular filter plate 25 and be temporarily stored in the collection bag 24 through the discharge conduit 23.
[0037] During this period, the dual-axis motor 45 will drive the guide fan blades 47 and the cleaning scraper 46 to rotate synchronously, thereby gradually drawing out the air in the feeding frame 37 and the dust-blocking top frame 41 and discharging it through the side exhaust pipe 410. At this time, the dust-blocking filter plate 44 can intercept the dust generated during the crushing of rosin blocks, thereby preventing the phenomenon of rosin dust flying and affecting the staff. The cleaning scraper 46 can scrape and clean the intercepted rosin dust, further preventing the dust-blocking filter plate 44 from becoming clogged.
[0038] After the crushing device is finished, the rotary cylinder 61 needs to be started, which will drive the drive gear 63 to rotate, which in turn will drive the driven gear ring 62 to rotate, which will further drive the arc-shaped rotating plate 64 and the arc-shaped baffle 65 to rotate, thereby driving the docking through hole 66 to rotate. When the docking through hole 66 aligns with the connecting through hole 213, the rotary cylinder 61 is closed, then the second solenoid valve 411 will close, and the first solenoid valve 49 will open. After that, the dual-shaft motor 45 will start again, thereby allowing air to pass through the L-shaped... The exhaust pipe 48 leads into the L-shaped duct 51, then the air is introduced into the arc-shaped duct 52, and then into the back-blowing diversion pipe 53. The air is then guided to the outer wall of the annular filter plate 25 by the connecting through hole 213 and the docking through hole 66. This allows the air to blow from the outside of the annular filter plate 25 to the inside, thereby forming a back-blowing thrust with the filtered and discharged pulverized rosin powder. This further facilitates thorough and effective cleaning of the annular filter plate 25, preventing it from becoming clogged. After cleaning, the arc-shaped baffle 65 and other components can be reset.
[0039] Obviously, those skilled in the art can make various modifications and variations to this invention without departing from its spirit and scope. Therefore, if these modifications and variations fall within the scope of the claims of this invention and their equivalents, this invention also intends to include these modifications and variations.
Claims
1. A rapid rosin pulverizing device for rosin paste production, comprising a supporting base (1), characterized in that: The top of the support frame (1) is fixedly installed with a crushing mechanism (2), and a feeding mechanism (3) is provided on one side of the support frame (1) to cooperate with the crushing mechanism (2). The top of the feeding mechanism (3) is provided with a dust blocking mechanism (4) to cooperate with it. The crushing mechanism (2) is provided with a back-blowing mechanism (5) and an auxiliary mechanism (6) to cooperate with the dust blocking mechanism (4). The feeding mechanism (3) can transfer the feeding operation of the rosin block to be crushed from a high place to a low place, and can conveniently control the feeding rate of the rosin block to be crushed. The dust blocking mechanism (4) can intercept the dust generated during the crushing of the rosin block. The cooperation between the back-blowing mechanism (5) and the auxiliary mechanism (6) can prevent the crushing mechanism (2) from accumulating and blocking.
2. The rosin rapid pulverizing device for rosin paste production as described in claim 1, characterized in that, The crushing mechanism (2) includes a crushing cylinder (21) and a first motor (22). Both the crushing cylinder (21) and the first motor (22) are fixedly installed on the top of the support base (1). The bottom end of the crushing cylinder (21) is connected to a discharge conduit (23). The end of the discharge conduit (23) is fixedly connected to a matching material collection bag (24). The inner cavity of the crushing cylinder (21) is integrally formed with a matching annular filter plate (25). A powder is rotatably inserted into the middle of the crushing cylinder (21). The crushing rotating rod (26) has a crushing blade (27) fixedly sleeved at one end, and a scraper pusher (28) for use with the annular filter plate (25) is fixedly connected at the end of the crushing blade (27). The other end of the crushing rotating rod (26) is fixedly sleeved with a first wheel (29). A second wheel (210) is fixedly sleeved on the outer side of the output end of the first motor (22), and two transmission belts (211) are sleeved on the outer side of the second wheel (210) and the first wheel (29).
3. The rosin rapid pulverizing device for rosin paste production as described in claim 2, characterized in that, A support base (212) is fixedly installed on one side of the support frame (1), and the first motor (22) is fixedly installed on the top of the support base (212).
4. The rosin rapid pulverizing device for rosin paste production as described in claim 2, characterized in that, The feeding mechanism (3) includes a feeding bracket (31), which is fixedly installed on the support base (1). A connecting conduit (32) connected to the crushing cylinder (21) is provided on the feeding bracket (31). Feeding screws (33) are rotatably inserted on both sides of the feeding bracket (31), and a first synchronous wheel (34) is fixedly sleeved on the top of the feeding screws (33). Feeding slides (35) are threaded onto the two feeding screws (33), and the feeding slides (35) are slidably locked on the upper part. On the material support (31), the feeding slide (35) is connected to a V-shaped conduit (36) that works with the connecting conduit (32), and the top end of the V-shaped conduit (36) is fixedly connected to a feeding frame (37) that works with it. A second motor (38) is fixedly installed in the middle of the top end of the feeding support (31), and a second synchronous pulley (39) is fixedly sleeved at the end of the output end of the second motor (38). The second synchronous pulley (39) and the outer side of the first synchronous pulley (34) are meshed with a transmission synchronous belt (310).
5. The rosin rapid pulverizing device for rosin paste production as described in claim 4, characterized in that, The loading slide (35) is fixedly connected with symmetrically arranged stabilizing support rods (311), and the ends of the stabilizing support rods (311) are fixedly connected to the loading frame (37).
6. The rosin rapid pulverizing device for rosin paste production as described in claim 4, characterized in that, The top of the feeding bracket (31) is fixedly connected to the mounting bracket (312), and the second motor (38) is fixedly inserted into the mounting bracket (312).
7. The rosin rapid pulverizing device for rosin paste production as described in claim 4, characterized in that, The dust-blocking mechanism (4) includes a dust-blocking top frame (41), which is fixedly installed on one side of the top of the feeding bracket (31). The upper end of the feeding frame (37) can be slidably inserted into the dust-blocking top frame (41). A dust-blocking cylinder (42) is connected to the dust-blocking top frame (41), and an inner grid disk (43) and a dust-blocking filter plate (44) are fixedly installed inside the dust-blocking cylinder (42). A dual-axis motor (45) is fixedly inserted into the middle of the inner grid disk (43), and the output end of the dual-axis motor (45) rotates through the dust-blocking filter plate. (44) and a cleaning scraper (46) for use is fixedly fitted at its end. A guide fan blade (47) for use is fixedly fitted at the output end of the dual-axis motor (45). An L-shaped exhaust pipe (48) for use is connected to the middle of the top of the dust-collecting cylinder (42). A first solenoid valve (49) for use is fixedly installed at the end of the L-shaped exhaust pipe (48). A side exhaust pipe (410) for use is connected to the L-shaped exhaust pipe (48). A second solenoid valve (411) for use is fixedly installed on the side exhaust pipe (410).
8. The rosin rapid pulverizing device for rosin paste production as described in claim 7, characterized in that, The backflush mechanism (5) includes an L-shaped conduit (51), one end of which is fixedly connected to the end of an L-shaped exhaust pipe (48), and the other end of which is connected to an arc-shaped conduit (52). The arc-shaped conduit (52) is connected to an array of backflush diverter pipes (53), and the end of the backflush diverter pipe (53) is fixedly installed on the crushing cylinder (21). The crushing cylinder (21) is provided with an array of connecting through holes (213), and the connecting through holes (213) are connected to the backflush diverter pipe (53). The backflush diverter pipe (53) near the discharge conduit (23) is fixedly inserted on the support base (1).
9. The rosin rapid pulverizing device for rosin paste production as described in claim 8, characterized in that, The auxiliary mechanism (6) includes a rotary cylinder (61) and a driven gear ring (62). The rotary cylinder (61) is fixedly installed on the upper side of the crushing cylinder (21), and the output end of the rotary cylinder (61) rotates through the crushing cylinder (21) and a drive gear (63) is fixedly sleeved at its end. The driven gear ring (62) is rotatably installed on the inner wall of the crushing cylinder (21) near the rotary cylinder (61), and the driven gear ring (62) meshes with the drive gear (63). An arc-shaped rotating plate (64) is integrally formed on the driven gear ring (62), and the arc-shaped rotating plate (64) slides against the inner wall of the crushing cylinder (21). An arc-shaped baffle (65) is integrally formed at the end of the arc-shaped rotating plate (64), and the outer wall of the arc-shaped baffle (65) slides against the inner wall of the crushing cylinder (21). An array of docking through holes (66) are provided through the arc-shaped baffle (65), and the docking through holes (66) can be connected to the connecting through hole (213).
10. The rosin rapid pulverizing device for rosin paste production as described in claim 9, characterized in that, The annular filter plate (25) is fixedly connected to an annular baffle (67) on the outer wall of one end near the rotary cylinder (61), and the driven gear ring (62) is rotatably connected to the annular baffle (67).