Automatic unpacking and crushing device for rosin resin

Abstract

This invention relates to the field of rosin resin unpacking and crushing technology, specifically to an automatic rosin resin unpacking and crushing device, comprising a base, a one-way gear, a transmission shaft, an energy storage shaft, a drive screw, a rotating shaft, and a cassette. A push side plate is slidably connected to one end of the base, and a rotating side plate is fixedly connected to the other end of the base. A sliding frame is slidably connected between the push side plate and the rotating side plate. The sliding frame is driven by the one-way gear, which is unidirectionally driven by the transmission shaft. The transmission shaft is driven by the energy storage shaft. The beneficial effects of this invention are: the weight of the rosin resin itself drives the energy storage shaft to store energy. When unpacking rosin resin barrels is required, the device can be driven by the stored weight energy, thereby crushing the rosin resin barrels without manual unpacking, greatly improving the production efficiency of the device.

Description

Technical Field

[0001] This invention relates to the field of rosin resin unpacking and crushing technology, specifically to an automatic rosin resin unpacking and crushing device. Background Technology

[0002] Rosin resin is a light-colored, highly polymerized (dimerized) resin with a high softening point, high viscosity, and better oxidation resistance. It is completely resistant to crystallization in liquid or solution. Its various uses include paints, desiccants, synthetic resins, automotive inks, floor tiles, rubber compounds, fluxes, solder pastes, and various adhesives and protective coatings. Currently, rosin resin requires processing such as crushing before use.

[0003] Chinese Patent (CN 217313185 U) discloses a rosin resin pulverizing and dissolving device, including a dissolving reactor. The device is characterized by: four sets of support frames at the top edge of the dissolving reactor; a crushing chamber being mounted on the top of the four sets of support frames; a feed hopper extending into the interior of the crushing chamber being located in the middle of the top of the crushing chamber; a centrally controlled feeding pump being mounted on one side of the top of the crushing chamber; the output end of the centrally controlled feeding pump being connected to the feed hopper; a storage silo being located at the bottom of one side of the crushing chamber; a suction pipe being mounted at the input end of the centrally controlled feeding pump; and the other end of the suction pipe extending into the interior of the storage silo; and two sets of drive shafts extending outwards from the top of the interior of the crushing chamber being symmetrically arranged.

[0004] Although the aforementioned patent can screen the crushed rosin resin, with large rosin resin particles being vibrated and conveyed to the inside of the storage silo, and then pumped back to the top for secondary screening by the central control feeding pump, thus achieving the functions of automatic screening and secondary crushing, it cannot automatically open the rosin resin packaging barrels before crushing the rosin resin. When unpacking the rosin resin, it is often done manually, which is not only inefficient, but also requires transporting the unpacked rosin resin to the crushing barrel after unpacking, resulting in a decrease in the overall efficiency of the device.

[0005] Therefore, an automatic unpacking and crushing device for rosin resin is needed to solve the above problems. Summary of the Invention

[0006] To address the aforementioned problems, namely, to automate the unpacking process and improve production efficiency, this invention provides an automatic unpacking and crushing device for rosin resin.

[0007] An automatic unpacking and crushing device for rosin resin includes a base, a one-way gear, a drive shaft, an energy storage shaft, a drive screw, a rotating shaft, and a cassette. A push side plate is slidably connected to one end of the base, and a rotating side plate is fixedly connected to the other end of the base. A sliding frame is slidably connected between the push side plate and the rotating side plate. The sliding frame is driven by the one-way gear, which is unidirectionally driven by the drive shaft. The drive shaft is driven by the energy storage shaft, which is driven by the drive screw. The drive screw is driven by the push side plate, and the drive screw is driven by the rotating shaft and the rotating side plate. The outer wall of the energy storage shaft is engaged with the cassette, and a spiral spring is installed at one end of the energy storage shaft.

[0008] In the aforementioned automatic unpacking and crushing device for rosin resin, an extension plate is fixedly and slidably installed inside the sliding frame. One end of the extension plate located outside the sliding frame abuts against the inner wall of the push side plate, and the other end of the extension plate is fixedly connected to one end of a telescopic spring, the other end of which is fixedly connected to the inner wall of the sliding frame.

[0009] The aforementioned automatic unpacking and crushing device for rosin resin includes a sliding frame whose bottom end is fixedly connected to one end of a toothed plate. The outer wall of the toothed plate is fixedly connected to one end of a return spring, and the other end of the return spring is fixedly connected to the side wall of the top of the base. The toothed plate meshes with a one-way gear. The bottom of the toothed plate engages with a limiting box, which is fixedly installed on the inner bottom wall of the base. A first locking block is slidably connected to the inner side wall of the limiting box. The top of the first locking block is curved, and the bottom is straight. The first locking block matches a second locking block, which is fixedly installed on the side wall of the bottom of the toothed plate. The top of the second locking block is straight, and the bottom is curved. The outer wall of the first locking block is fixedly connected to one end of a limiting spring, and the other end of the limiting spring is fixedly connected to the inner side wall of the limiting box. The end of the first locking block away from the curved surface is fixedly connected to one end of a release line, and the other end of the release line is located outside the base.

[0010] The aforementioned automatic unpacking and crushing device for rosin resin includes an inner groove inside the drive shaft, a one-way block slidably connected inside the inner groove, the one-way block being a right-angled triangle, a one-way spring fixedly installed at one end of the one-way block inside the inner groove, the other end of the one-way spring being fixedly connected to the inner wall of the inner groove, and a one-way groove on the inner wall of the one-way gear matching the one-way block.

[0011] The aforementioned automatic unpacking and crushing device for rosin resin includes a first transmission bevel gear installed on the outer wall of one end of the transmission shaft, a second transmission bevel gear installed on the outer wall of one end of the energy storage shaft, the first transmission bevel gear meshing with the second transmission bevel gear, a first rotating bevel gear unidirectionally driven connected to the outer wall of the other end of the energy storage shaft, the first rotating bevel gear meshing with the second rotating bevel gear, and the second rotating bevel gear installed on the outer wall of one end of the drive screw.

[0012] The aforementioned automatic unpacking and crushing device for rosin resin includes an arc block fixedly installed on the outer wall of the energy storage shaft, a card box installed inside a control box, the control box installed on the side wall of the base, a card plate slidably connected inside the card box, one side of the card plate having an arc surface and the other side having a straight surface, the arc surface of the card plate matching the arc block, the other end of the card plate being fixedly connected to one end of a snap-fit ​​spring, the other end of the snap-fit ​​spring being fixedly connected to the inner wall of the card box, and the other end of the card plate also being fixedly connected to one end of a stretching wire.

[0013] In the aforementioned automatic unpacking and crushing device for rosin resin, a pressing box is fixedly installed on the side wall of the control box. One end of the stretching wire passes through the card box and is fixedly connected to the inside of the pressing box. A pressing block is slidably connected inside the pressing box. The bottom of the pressing block abuts against the outer wall of the stretching wire. One side of the bottom of the pressing block is fixedly connected to one end of a compression spring, and the other end of the compression spring is fixedly connected to the inner bottom wall of the pressing box.

[0014] The aforementioned automatic unpacking and crushing device for rosin resin includes a threaded plate threadedly connected to the outer wall of a drive screw, the threaded plate being fixedly connected to one side of the bottom of a pusher side plate. An adjusting shaft is installed inside one end of the drive screw, and an inner ring is formed inside the drive screw. A first limiting block is slidably connected inside the inner ring. The first limiting block is fixedly installed on the outer wall of one end of the adjusting shaft and is in communication with a first limiting groove. The other end of the adjusting shaft is located inside one end of a rotating shaft, and a second limiting groove is formed on the inner wall of one end of the rotating shaft. A second limiting block is fixedly installed on the outer wall of the other end of the adjusting shaft, the second limiting block matching the second limiting groove. An adjusting plate is installed on the outer wall of the adjusting shaft.

[0015] The aforementioned automatic unpacking and crushing device for rosin resin includes a third rotating bevel tooth installed on the outer wall of one end of the rotating shaft. The third rotating bevel tooth meshes with a fourth rotating bevel tooth. The fourth rotating bevel tooth is installed on the outer wall of one end of the driven shaft. A first driving bevel tooth is installed on the outer wall of the other end of the driven shaft. The first driving bevel tooth meshes with a second driving bevel tooth. The second driving bevel tooth is installed on the outer wall of one end of the driving shaft. The driving shaft is rotatably connected to the inner wall of the rotating side plate. The other end of the driving shaft is connected to a rotating disk. The rotating disk is rotatably connected to the side wall of the rotating side plate.

[0016] The aforementioned automatic unpacking and crushing device for rosin resin includes an extrusion disc rotatably connected to the side wall of the pusher side plate, an extrusion column installed on the side wall of the extrusion disc, and a baffle installed on the side wall of the base.

[0017] The beneficial effects of this invention are as follows:

[0018] 1. This invention uses the weight of the rosin resin itself to drive an energy storage shaft for energy storage. When it is necessary to unpack the rosin resin barrels, the energy stored in the weight can be used to drive the device to operate, thereby breaking the rosin resin barrels. This allows the device to use its own energy first, achieving unpacking without the need for electricity, saving a lot of resources, realizing automatic unpacking without manual unpacking, and greatly improving the production efficiency of the device.

[0019] 2. When the side plate is pushed and squeezed, the present invention can drive the extension plate to extend and retract, avoiding the phenomenon of the sliding frame being stuck in the pushing side plate. This prevents the pushing side plate from being unable to move, thus preventing the rosin resin barrel from being squeezed open. It can store energy through its own weight. At the same time, after the toothed plate descends to the limit position, it can limit the toothed plate, preventing the phenomenon of the sliding frame resetting while releasing energy, which would result in the rosin resin barrel not being completely removed. This ensures that the rosin resin is completely removed before the sliding frame resets.

[0020] 3. The invention, through the design of the card box, ensures that the device only releases energy after the tension line is pulled, thus avoiding automatic energy release and energy storage failure. The card box design facilitates energy release, and the device has two energy storage states: gravity and external drive. These two methods can be used individually or in combination, greatly increasing the applicability and flexibility of the device.

[0021] 4. When the drive screw drives the rotating shaft to rotate, the rotating shaft, through the driven shaft and the driving shaft, drives the rotating disk to rotate. At this time, the rotation of the drive screw can drive the push side plate to push the rosin resin barrel. At the same time, the rotating disk and the rosin resin barrel rotate, realizing the integrated completion of squeezing, unpacking and rotating the rosin resin barrel. This device can automate the process by rotating the drive screw, automatically dismantling the rosin resin barrel and achieving all-round pouring, avoiding the leakage of rosin resin and ensuring the dismantling effect. Attached Figure Description

[0022] Figure 1 This is a schematic diagram of the three-dimensional main view of the present invention;

[0023] Figure 2 This is a schematic diagram of the structure of the present invention after the baffle has been removed;

[0024] Figure 3 This is a cross-sectional structural schematic diagram of the base of the present invention;

[0025] Figure 4 This is a schematic diagram of the internal structure of the sliding frame of the present invention;

[0026] Figure 5 This is a schematic diagram of the internal structure of the limiting box of the present invention;

[0027] Figure 6 This is a schematic diagram showing the cross-sectional view of the end face of the one-way gear and the transmission shaft of the present invention;

[0028] Figure 7 This is a cross-sectional structural schematic diagram of the card box of the present invention;

[0029] Figure 8 This is a cross-sectional structural schematic diagram of the pressing box of the present invention;

[0030] Figure 9 This is a cross-sectional structural schematic diagram of the drive screw and rotating shaft of the present invention;

[0031] Figure 10 This is a schematic diagram of the driven shaft and driving shaft of the present invention;

[0032] Figure 11 This is a schematic diagram of the structure of the side plate of the present invention.

[0033] In the picture:

[0034] 1. Base; 2. Push side plate; 3. Rotating side plate; 4. Sliding frame; 5. One-way gear; 6. Drive shaft; 7. Energy storage shaft; 8. Drive screw; 9. Rotating shaft; 10. Locking box; 11. Spiral spring; 12. Extending plate; 13. Telescopic spring; 14. Gear plate; 15. Return spring; 16. Limiting box; 17. First locking block; 18. Second locking block; 19. Limiting spring; 20. Disengagement line; 21. Inner groove; 22. One-way block; 23. One-way spring; 24. One-way groove; 25. First transmission bevel gear; 26. Second transmission bevel gear; 27. First rotating bevel gear; 28. Second rotating bevel gear. 29. Bevel gear; 30. Arc block; 31. Clamping plate; 32. Clamping spring; 33. Stretching line; 34. Pressing box; 35. Control box; 36. Pressing block; 37. Compression spring; 38. Threaded plate; 39. Adjusting shaft; 40. Inner ring; 41. First limiting block; 42. First limiting groove; 43. Second limiting groove; 44. Adjusting plate; 45. Third rotating bevel gear; 46. Fourth rotating bevel gear; 47. Driven shaft; 48. First driving bevel gear; 49. Second driving bevel gear; 50. Drive shaft; 51. Rotating disk; 52. Extrusion disk; 53. Extrusion column; 54. Baffle. Detailed Implementation

[0035] Preferred embodiments of the present invention will now be described with reference to the accompanying drawings. Those skilled in the art should understand that these embodiments are merely illustrative of the technical principles of the present invention and are not intended to limit the scope of protection of the present invention.

[0036] like Figure 1-3 As shown in the figure, an embodiment of the present invention discloses an automatic unpacking and crushing device for rosin resin, including a base 1, a one-way gear 5, a transmission shaft 6, an energy storage shaft 7, a drive screw 8, a rotating shaft 9, and a cassette 10. A push side plate 2 is slidably connected to one end of the base 1, and a rotating side plate 3 is fixedly connected to the other end of the base 1. A sliding frame 4 is slidably connected between the push side plate 2 and the rotating side plate 3. The sliding frame 4 is driven by the one-way gear 5. The one-way gear 5 is unidirectionally driven and connected to the outer wall of the transmission shaft 6. The transmission shaft 6 is driven by the energy storage shaft 7. The energy storage shaft 7 is driven by the drive screw 8. The drive screw 8 is driven by the push side plate 2. The rotating shaft 9 is driven and connected to the rotating side plate 3. The outer wall of the energy storage shaft 7 is engaged with the card box 10. A spiral spring 11 is installed at one end of the energy storage shaft 7. This device uses the weight of the rosin resin itself to drive the energy storage shaft 7 to store energy. When it is necessary to unpack the rosin resin barrel, the device can be driven by the weight energy storage to run, thereby crushing the rosin resin barrel. When the device is in use, it first uses its own energy to achieve unpacking without the need for electricity, saving a lot of resources and realizing the function of automatic unpacking. It does not require manual unpacking and greatly improves the production efficiency of the device.

[0037] like Figure 4 As shown, an extension plate 12 is fixedly and slidably installed inside the sliding frame 4. One end of the extension plate 12 located outside the sliding frame 4 abuts against the inner side wall of the push side plate 2, and the other end of the extension plate 12 is fixedly connected to one end of the telescopic spring 13. The other end of the telescopic spring 13 is fixedly connected to the inner wall of the sliding frame 4. When the push side plate 2 is pushed and squeezed, this device can drive the extension plate 12 to extend and retract, avoiding the phenomenon of the sliding frame 4 being limited and stuck to the push side plate 2, and preventing the push side plate 2 from being unable to move, thus preventing the rosin resin barrel from being squeezed open.

[0038] like Figure 3-5 As shown, the bottom of one end of the sliding frame 4 is fixedly connected to one end of the toothed plate 14, the outer wall of the toothed plate 14 is fixedly connected to one end of the return spring 15, the other end of the return spring 15 is fixedly connected to the side wall of the top of the base 1, and the toothed plate 14 is meshed with the one-way gear 5.

[0039] The bottom of the toothed plate 14 is engaged with the limiting box 16, which is fixedly installed on the inner bottom wall of the base 1. A first locking block 17 is slidably connected to the inner side wall of the limiting box 16. The top of the first locking block 17 is curved, and the bottom is straight. The first locking block 17 matches a second locking block 18, which is fixedly installed on the side wall of the bottom of the toothed plate 14. The top of the second locking block 18 is straight, and the bottom is curved. The outer wall of the first locking block 17 is fixedly connected to one end of the limiting spring 19. The other end of the limiting spring 19... One end is fixedly connected to the inner wall of the limiting box 16, and the end of the first locking block 17 away from the arc surface is fixedly connected to one end of the disengagement line 20. The other end of the disengagement line 20 is located outside the base 1. The toothed plate 14 of this device is not engaged with the one-way gear 5 in the initial state. When in use, the unpacked rosin resin bucket is first placed on the top of the sliding frame 4. At this time, under the action of gravity, the sliding frame 4 will descend, and the toothed plate 14 will engage with the one-way gear 5, causing the one-way gear 5 to descend. At this time, the storage... Energy is stored in the energy shaft 7. When it descends to the limit position, the upper part of the toothed plate 14 is a bare plate, and the toothed plate 14 disengages from the one-way gear 5 again. The toothed plate 14 is no longer connected to the one-way gear 5. At the same time, after the toothed plate 14 descends to the limit position, it will descend into the interior of the limit box 16. At this time, the second locking block 18 on the bottom side wall of the toothed plate 14 abuts against the first locking block 17. The first locking block 17 is compressed by force, and the second locking block 18 is located at the bottom of the first locking block 17. The first locking block 17 exerts force on the toothed plate 14. The device serves as a limit switch. When it needs to disengage from the limit switch, pulling the release line 20 causes the toothed plate 14 to reset under the action of the return spring 15. This device can store energy using its own weight. At the same time, after the toothed plate 14 descends to its limit position, it can limit the toothed plate 14, preventing the phenomenon that the sliding frame 4 resets while releasing energy, which would result in the rosin resin barrel not being completely removed. This ensures that the sliding frame 4 will only reset after the rosin resin has been completely removed from the device.

[0040] like Figure 6 As shown, the drive shaft 6 has an inner groove 21 inside, and a one-way block 22 is slidably connected inside the inner groove 21. The one-way block 22 is a right-angled triangle. A one-way spring 23 is fixedly installed at one end of the one-way block 22 inside the inner groove 21, and the other end of the one-way spring 23 is fixedly connected to the inner wall of the inner groove 21. A one-way groove 24 is opened on the inner wall of the one-way gear 5, and the one-way groove 24 matches the one-way block 22. When the gear plate 14 descends, the device will drive the one-way gear 5 to rotate. At this time, the drive shaft 6 is in a rotational energy storage state. Under the action of the one-way spring 23, the one-way block 22 extends into the one-way groove 24. Since the cross-sections of the one-way block 22 and the one-way groove 24 are triangular, the straight surface of the one-way groove 24 is opposite to the straight surface of the one-way block 22. The one-way gear 5 can drive the drive shaft 6 to rotate.

[0041] like Figure 3 As shown, a first transmission bevel gear 25 is installed on the outer wall of one end of the transmission shaft 6, and a second transmission bevel gear 26 is installed on the outer wall of one end of the energy storage shaft 7. The first transmission bevel gear 25 and the second transmission bevel gear 26 are meshed together. A first rotating bevel gear 27 is unidirectionally driven connected to the outer wall of the other end of the energy storage shaft 7. The first rotating bevel gear 27 and the second rotating bevel gear 28 are meshed together. The second rotating bevel gear 28 is installed on the outer wall of one end of the drive screw 8.

[0042] like Figure 7 As shown, an arc block 29 is fixedly installed on the outer wall of the energy storage shaft 7. The card box 10 is installed inside the control box 34, which is installed on the side wall of the base 1. A card plate 30 is slidably connected inside the card box 10. One side of one end of the card plate 30 is set with an arc surface, and the other end is set with a straight surface. The arc surface of the card plate 30 matches the arc block 29. The other end of the card plate 30 is fixedly connected to one end of the snap-fit ​​spring 31. The other end of the snap-fit ​​spring 31 is fixedly connected to the inner wall of the card box 10. The other end of the card plate 30 is also fixedly connected to one end of the tension line 32. When using this device, when the drive shaft 6 rotates, it will drive the energy storage shaft 7 to rotate under the action of the first drive bevel gear 25 and the second drive bevel gear 26. At this time, the arc surface of the arc block 29 will be opposite to the arc surface of the card plate 30. The card plate 30 will be compressed and contracted, which facilitates the energy storage shaft 7 to store energy. When it is not released autonomously, the card box 10 can play a limiting role. The device serves to prevent energy loss. After the tension line 32 is stretched, the energy storage shaft 7 will rotate and reset under the action of the spiral spring 11, thus enabling the device to operate. Simultaneously, the device can manually store energy by connecting the motor to the energy storage shaft 7, etc. During manual energy storage, the toothed plate 14 will not be displaced. Because the first rotating bevel tooth 27 is a unidirectional drive connection, it will not drive the drive screw 8 to rotate. The device uses a retaining box 10 to ensure that energy is only released after the tension line 32 is pulled, preventing automatic energy release and energy storage failure. The retaining box 10 facilitates energy release. The device has two energy storage states: gravity and external drive. These can be used individually or in combination, greatly increasing the device's applicability and flexibility.

[0043] like Figure 8 As shown, a pressing box 33 is fixedly installed on the side wall of the control box 34. One end of the tension line 32 passes through the card box 10 and is fixedly connected to the inside of the pressing box 33. A pressing block 35 is slidably connected inside the pressing box 33. The bottom of the pressing block 35 abuts against the outer wall of the tension line 32. One side of the bottom of the pressing block 35 is fixedly connected to one end of the compression spring 36. The other end of the compression spring 36 is fixedly connected to the inner bottom wall of the pressing box 33.

[0044] like Figure 9 As shown, a threaded plate 37 is threaded onto the outer wall of the drive screw 8. The threaded plate 37 is fixedly connected to one side of the bottom of the push side plate 2. An adjusting shaft 38 is installed inside one end of the drive screw 8. An inner ring 39 is formed inside the drive screw 8. A first limiting block 40 is slidably connected inside the inner ring 39. The first limiting block 40 is fixedly installed on the outer wall of one end of the adjusting shaft 38 and is in communication with the first limiting groove 41. The other end of the adjusting shaft 38 is located inside one end of the rotating shaft 9. A second limiting groove 42 is formed on the inner wall of one end of the rotating shaft 9. A second limiting block 42 is fixedly installed on the outer wall of the other end of the adjusting shaft 38. 3. The second limiting block 43 matches the second limiting groove 42, and an adjusting plate 44 is installed on the outer wall of the adjusting shaft 38. The limiting groove port of this device is arc-shaped, which facilitates the sliding of the limiting block into the inside of the limiting groove. When the drive screw 8 rotates, the first limiting block 40 slides inside the inner ring 39, and the second limiting block 43 does not engage with the second limiting groove 42. In the initial state, it will not drive the adjusting shaft 38 to rotate. At this time, by sliding the adjusting plate 44, the first limiting block 40 is located inside the first limiting groove 41, and the second limiting block 43 is located inside the second limiting groove 42. The rotation of the drive screw 8 can drive the second limiting groove 42 to rotate.

[0045] like Figure 10 As shown, a third rotating bevel gear 45 is installed on the outer wall of one end of the rotating shaft 9. The third rotating bevel gear 45 is meshed with a fourth rotating bevel gear 46. The fourth rotating bevel gear 46 is installed on the outer wall of one end of the driven shaft 47. A first driving bevel gear 48 is installed on the outer wall of the other end of the driven shaft 47. The first driving bevel gear 48 is meshed with a second driving bevel gear 49. The second driving bevel gear 49 is installed on the outer wall of one end of the driving shaft 50. The driving shaft 50 is rotatably connected to the inner wall of the rotating side plate 3. The other end of the driving shaft 50 is connected to the rotating disk 51. The rotating disk 51 is rotatably connected to the side wall of the rotating side plate 3. When the drive screw 8 drives the rotating shaft 9 to rotate, the rotating shaft 9, through the driven shaft 47 and the driving shaft 50, drives the rotating disk 51 to rotate. At this time, the rotation of the drive screw 8 can drive the push side plate 2 to push the rosin resin barrel. At the same time, the rotating disk 51 rotates the rosin resin barrel, realizing the integrated completion of squeezing, unpacking and rotating the rosin resin barrel. This device can achieve automation by driving the rotation of the drive screw 8, automatically dismantling the rosin resin barrel and realizing all-round pouring to avoid the leakage of rosin resin and ensure the dismantling effect.

[0046] like Figure 1 and Figure 11As shown, an extrusion plate 52 is rotatably connected to the side wall of the push side plate 2, an extrusion column 53 is installed on the side wall of the extrusion plate 52, and a baffle 54 is installed on the side wall of the base 1; the extrusion plate 52 can extrude rosin resin barrel and rotate with the rotating side plate 3, and the baffle 54 can prevent rosin resin from spilling to the outside.

[0047] It should be noted that in the description of this invention, terms such as "center," "upper," "lower," "left," "right," "vertical," "horizontal," "inner," and "outer," which indicate direction or positional relationships, are based on the direction or positional relationships shown in the accompanying drawings. These are used merely for ease of description and do not indicate or imply that the device or element must have a specific orientation, or be constructed and operated in a specific orientation; therefore, they should not be construed as limitations on this invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and should not be construed as indicating or implying relative importance.

[0048] Furthermore, it should be noted that, in the description of this invention, unless otherwise explicitly specified and limited, the terms "installation," "connection," and "linking" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this invention according to the specific circumstances.

[0049] The term "comprising" or any other similar term is intended to cover non-exclusive inclusion, such that a process, article, or apparatus / device that comprises a list of elements includes not only those elements but also other elements not expressly listed, or elements inherent to those processes, articles, or apparatus / devices.

[0050] The technical solution of the present invention has been described above with reference to the preferred embodiments shown in the accompanying drawings. However, it will be readily understood by those skilled in the art that the scope of protection of the present invention is obviously not limited to these specific embodiments. Without departing from the principles of the present invention, those skilled in the art can make equivalent changes or substitutions to the relevant technical features, and the technical solutions after such changes or substitutions will all fall within the scope of protection of the present invention.

Claims

1. An automatic unpacking and crushing device for rosin resin, characterized in that, The system includes a base (1), a one-way gear (5), a drive shaft (6), an energy storage shaft (7), a drive screw (8), a rotating shaft (9), and a card box (10). One end of the base (1) is slidably connected to a push side plate (2), and the other end of the base (1) is fixedly connected to a rotating side plate (3). A sliding frame (4) is slidably connected between the push side plate (2) and the rotating side plate (3). The sliding frame (4) is driven by the one-way gear (5). A one-way drive is connected to the outer wall of the drive shaft (6). The drive shaft (6) is driven to the energy storage shaft (7). The energy storage shaft (7) is driven to the drive screw (8). The drive screw (8) is driven to the push side plate (2). The drive screw (8) is driven to the rotating side plate (3) through the rotating shaft (9). The outer wall of the energy storage shaft (7) is engaged with the card box (10). A spiral spring (11) is installed at one end of the energy storage shaft (7). A first transmission bevel gear (25) is installed on the outer wall of one end of the transmission shaft (6), and a second transmission bevel gear (26) is installed on the outer wall of one end of the energy storage shaft (7). The first transmission bevel gear (25) and the second transmission bevel gear (26) are meshed together. A first rotating bevel gear (27) is unidirectionally driven connected to the outer wall of the other end of the energy storage shaft (7). The first rotating bevel gear (27) and the second rotating bevel gear (28) are meshed together. The second rotating bevel gear (28) is installed on the outer wall of one end of the drive screw (8). An arc block (29) is fixedly installed on the outer wall of the energy storage shaft (7). The card box (10) is installed inside the control box (34). The control box (34) is installed on the side wall of the base (1). A card plate (30) is slidably connected inside the card box (10). One side of one end of the card plate (30) is provided with an arc surface, and the other end is provided with a straight surface. The arc surface of the card plate (30) matches the arc block (29). The other end of the card plate (30) is fixedly connected to one end of the snap-fit ​​spring (31). The other end of the snap-fit ​​spring (31) is fixedly connected to the inner wall of the card box (10). The other end of the card plate (30) is also fixedly connected to one end of the tension line (32). A pressing box (33) is fixedly installed on the side wall of the control box (34). One end of the tension line (32) passes through the card box (10) and is fixedly connected to the inside of the pressing box (33). A pressing block (35) is slidably connected inside the pressing box (33). The bottom of the pressing block (35) abuts against the outer wall of the tension line (32). One side of the bottom of the pressing block (35) is fixedly connected to one end of the compression spring (36). The other end of the compression spring (36) is fixedly connected to the inner bottom wall of the pressing box (33). A threaded plate (37) is threadedly connected to the outer wall of the drive screw (8). The threaded plate (37) is fixedly connected to one side of the bottom of the push side plate (2). An adjusting shaft (38) is installed inside one end of the drive screw (8). An inner ring (39) is opened inside the drive screw (8). A first limiting block (40) is slidably connected inside the inner ring (39). The first limiting block (40) is fixedly installed on the outer wall of one end of the adjusting shaft (38). The first limiting block (40) is connected to the first limiting groove (41). The other end of the adjusting shaft (38) is located inside one end of the rotating shaft (9). A second limiting groove (42) is opened on the inner wall of one end of the rotating shaft (9). A second limiting block (43) is fixedly installed on the outer wall of the other end of the adjusting shaft (38). The second limiting block (43) matches the second limiting groove (42). An adjusting plate (44) is installed on the outer wall of the adjusting shaft (38). A third rotating bevel tooth (45) is installed on the outer wall of one end of the rotating shaft (9). The third rotating bevel tooth (45) is meshed with a fourth rotating bevel tooth (46). The fourth rotating bevel tooth (46) is installed on the outer wall of one end of the driven shaft (47). A first driving bevel tooth (48) is installed on the outer wall of the other end of the driven shaft (47). The first driving bevel tooth (48) is meshed with a second driving bevel tooth (49). The second driving bevel tooth (49) is installed on the outer wall of one end of the driving shaft (50). The driving shaft (50) is rotatably connected to the inner wall of the rotating side plate (3). The other end of the driving shaft (50) is connected to the rotating disk (51). The rotating disk (51) is rotatably connected to the side wall of the rotating side plate (3). An extrusion plate (52) is rotatably connected to the side wall of the push side plate (2), an extrusion column (53) is installed on the side wall of the extrusion plate (52), and a baffle (54) is installed on the side wall of the base (1).

2. The automatic unpacking and crushing device for rosin resin according to claim 1, characterized in that, An extension plate (12) is fixedly and slidably installed inside the sliding frame (4). One end of the extension plate (12) located outside the sliding frame (4) abuts against the inner wall of the push side plate (2). The other end of the extension plate (12) is fixedly connected to one end of the telescopic spring (13), and the other end of the telescopic spring (13) is fixedly connected to the inner wall of the sliding frame (4).

3. An automatic unpacking and crushing device for rosin resin according to claim 2, characterized in that, The bottom of one end of the sliding frame (4) is fixedly connected to one end of the toothed plate (14), the outer wall of the toothed plate (14) is fixedly connected to one end of the return spring (15), the other end of the return spring (15) is fixedly connected to the side wall of the top of the base (1), and the toothed plate (14) is meshed with the one-way gear (5). The bottom of the toothed plate (14) is engaged with the limiting box (16), which is fixedly installed on the inner bottom wall of the base (1). A first locking block (17) is slidably connected to the inner side wall of the limiting box (16). The top of the first locking block (17) is set as an arc surface and the bottom is a straight surface. The first locking block (17) is matched with a second locking block (18). The second locking block (18) is fixedly installed on the side wall of the bottom of the toothed plate (14). The top of the second locking block (18) is set as a straight surface and the bottom is an arc surface. The outer wall of the first locking block (17) is fixedly connected to one end of the limiting spring (19). The other end of the limiting spring (19) is fixedly connected to the inner side wall of the limiting box (16). The end of the first locking block (17) away from the arc surface is fixedly connected to one end of the release line (20). The other end of the release line (20) is located outside the base (1).

4. The automatic unpacking and crushing device for rosin resin according to claim 3, characterized in that, The transmission shaft (6) has an inner groove (21) inside, and a one-way block (22) is slidably connected inside the inner groove (21). The one-way block (22) is a right-angled triangle. A one-way spring (23) is fixedly installed at one end of the one-way block (22) inside the inner groove (21). The other end of the one-way spring (23) is fixedly connected to the inner wall of the inner groove (21). The one-way gear (5) has a one-way groove (24) on its inner wall, and the one-way groove (24) matches the one-way block (22).

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