Background
Chemical engineering is a short term for "chemical process", "chemical industry", "chemical engineering", etc., and all techniques of changing the composition, structure or synthesizing new substances by using chemical methods belong to chemical production techniques, i.e., chemical processes, and the obtained products are called chemicals or chemical products.
At present, in the chemical production industry, wherein need pulverize the partial shipment with the chemical industry granule, but in the production process, all lead to the rubbing crusher earlier and pulverize the chemical industry granule, then collect the granule that pulverizes through the machine, then carry out quantitative partial shipment through quantitative partial shipment machine, because each link all is independent existence, have independent power supply to it is more loaded down with trivial details to know the process of production like this, is convenient for the mill to carry out production fast.
Disclosure of Invention
Technical problem to be solved
Aiming at the defects of the prior art, the invention provides a chemical particle crushing and packaging machine, which has the advantage of automatic crushing and quantitative packaging, and solves the problems that production processes are complicated and rapid production in factories is inconvenient because production links are independent.
(II) technical scheme
In order to realize the purpose of automatic grinding quantitative packaging, the invention provides the following technical scheme: a chemical particle crushing and subpackaging machine comprises a base supporting seat, wherein the top of the base supporting seat is connected with a support, the top of the support is fixedly connected with a cylinder, the bottom of an output shaft of the cylinder is fixedly connected with a buffer plate, the bottom of the left side and the bottom of the right side of the buffer plate are fixedly connected with buffer springs, one side of each buffer spring, far away from the buffer plate, is fixedly connected with a slide seat, the bottom of each slide seat is fixedly connected with the inside of the base supporting seat, the inside of each slide seat is slidably connected with an extrusion plate, the top of each extrusion plate is fixedly connected with the center of the bottom of the buffer plate, the inside of each extrusion plate is slidably connected with a fixed rod, the back of each fixed rod is fixedly connected with the slide seat, the right side of each slide seat is fixedly connected with a slide rail, the inside of each slide rail is slidably, and the left side of the feeding hopper is fixedly connected with one side of the sliding rail far away from the sliding seat, the outer surface of the feeding hopper is fixedly connected with the base supporting seat, the bottom of the feeding hopper is slidably connected with a second inserting piece, the right side of the second inserting piece is fixedly connected with a sliding block, the bottom of the sliding block is fixedly connected with a first baffle plate, the right side of the sliding block is fixedly connected with a first return spring, the right side of the first return spring is fixedly connected with a closed seat, the left side of the closed seat is fixedly connected with the feeding hopper, the right side of the closed seat is fixedly connected with the base supporting seat, the left side of the sliding plate is fixedly connected with a second return spring, the second return spring is positioned in the sliding rail, the left side of the second return spring is fixedly connected with a push rod, one side of the push rod close to the second return spring is slidably, one side of the push rod, which is far away from the second reset spring, is fixedly connected with a hollow seat, a sliding groove is formed in the sliding seat, a plurality of rollers are arranged in the sliding groove, the outer surface of the hollow seat is in sliding connection with the inner part of the sliding groove of the sliding seat, a rolling wheel is rotated in the hollow seat and is positioned below the extrusion plate, a push block is fixedly connected with the top of the right side of the hollow seat, the top of the inner wall of the right side of the hollow seat is hinged with an expansion plate, the bottom of the expansion plate is hinged with the sliding seat, an extrusion seat is arranged at the bottom of the rolling wheel, the outer surface of the extrusion seat is in sliding connection with the sliding seat, a groove matched with the size of the rolling wheel is formed in the top of the extrusion seat, the rolling wheel is positioned in the groove in sliding connection, a discharge port is formed in the left side of the groove, a sliding cavity is formed in one side, one end of the fixed spring, which is far away from the inner wall of the sliding cavity, is fixedly connected with a second baffle plate, the second baffle plate is positioned in the sliding cavity and is in sliding connection with the inner part of the sliding cavity, the bottom of the second baffle plate is fixedly connected with a telescopic baffle plate, the telescopic baffle plate is in sliding connection with the extrusion seat, the telescopic baffle plate is positioned on the right side of the discharge hole, the bottom of the telescopic baffle plate is fixedly connected with a discharge plate, the outer surface of the discharge plate is fixedly connected with a base support seat, the bottom of the sliding seat is provided with a discharge hole matched with the size of the discharge hole, the inner wall of the discharge hole is fixedly connected with the telescopic baffle plate, the discharge hole is positioned under the discharge hole, the bottom of the extrusion seat is fixedly connected with a sliding rod, the outer surface of the sliding rod is in sliding connection with the bottom of the sliding seat, the bottom of the extrusion seat is fixedly, the bottom of the slide bar is fixedly connected with a limiting block.
Preferably, the top of the hollow seat is provided with a feeding groove matched with the size of the extrusion plate, and the inside of the extrusion plate is provided with a sliding rail matched with the size of the fixed rod.
Preferably, the front and the back of the rotating rod of the rolling wheel are fixedly connected with each other and are located at the top of the extrusion seat, and the distance between the top of the extrusion seat and the groove is matched with the length of the groove.
Preferably, the cross-sectional shape of the extrusion seat is trapezoidal, the inclined plane of the extrusion seat faces upwards, and the cross-sectional shape of the bottom of the extrusion plate is wedge-shaped.
Preferably, the push rod is Z-shaped, the first baffle and the push block are located on the same horizontal line, and the length of the slide rail is matched with the moving distance of the push block.
Preferably, the angle from the top extension line of the discharge port to the inner wall of the left side of the sliding seat is larger than the angle from the bottom extension line of the groove in the extrusion seat to the inner wall of the left side of the sliding seat, and the telescopic baffle plate, the inner wall of the sliding seat, the discharge port and the discharge port form a discharge channel.
(III) advantageous effects
Compared with the prior art, the invention provides a chemical particle crushing and packaging machine, which has the following beneficial effects:
1. the chemical particle crushing and subpackaging machine realizes the matched use of the cylinder, the buffer plate, the extrusion plate, the rolling wheel, the groove, the extrusion seat, the slide rod, the discharge port, the buffer spring III, the baffle II, the telescopic baffle plate, the hollow seat, the push rod, the reset spring II, the reset spring I, the slide block, the baffle I, the telescopic plate, the push block and the feed hopper, and realizes that the cylinder drives the extrusion plate to move downwards through the buffer plate, the extrusion plate moves downwards to push the rolling wheel to move rightwards, the rolling wheel moves rightwards simultaneously not only to roll particles in the groove, the rolled particles slide to the discharge port through the inclined plane of the groove, then the powdered particles pass through the discharge port and the channels formed on the right side of the inner wall of the telescopic baffle plate and the slide seat, then the powdered particles fall on the discharge plate to slide out to enter the subpackaging bag to complete the subpackaging of the particles, and simultaneously the, the extrusion seat moves downwards to pass through a baffle plate two compression telescopic baffle plate and a compression buffer spring three, meanwhile, the rolling wheel moves rightwards to drive the hollow seat to enable the push rod to push the reset spring to move rightwards, the reset spring two moves rightwards to push the sliding plate to enable the first insertion piece to be inserted into the feeding hopper, particles between the first insertion piece and the second insertion piece in the feeding hopper are divided, meanwhile, the hollow seat further drives the sliding block to drive the sliding block to compress the first reset spring through the push block, the second insertion piece is driven to separate from the inside of the feeding hopper, the particles at the discharging port of the feeding hopper are opened to enter the inside of the groove, at the moment, the first insertion piece closes the upper part of the feeding hopper, the second insertion piece is in a state of opening the feeding hopper, the purpose of quantifying the particles is achieved, finally, the particles enable the expansion plate to rotate rightwards through the movement of the hollow seat, Split charging and quantifying.
2. This chemical industry granule pulverizes racking machine uses through cylinder, buffer board, buffer spring's cooperation and has realized making the cylinder promote the buffer board downstream, and buffer board downstream compression buffer spring, then buffer spring promotes the buffer board through reverse acting force and reduces the impulsive force to the cylinder to the device, reaches the effect that increases the life of device.
Drawings
Fig. 1 is a schematic view of the inner structure of the rolling wheel at the leftmost end of the rolling wheel of the present invention;
FIG. 2 is a schematic front view of the extrusion seat of the present invention;
FIG. 3 is an enlarged view of the structure of the feeding mechanism of the apparatus of the present invention;
FIG. 4 is a schematic diagram of the left side of the slider of the present invention;
FIG. 5 is a schematic view of the left side internal cross-sectional view of the slider of the present invention;
FIG. 6 is a schematic perspective view of the interior of the slider according to the present invention;
fig. 7 is a schematic view of the inner structure of the rolling wheel at the rightmost end of the device.
In the figure: 1-base supporting seat, 2-bracket, 3-cylinder, 4-buffer plate, 41-extrusion plate, 5-buffer spring, 6-sliding seat, 61-sliding groove, 7-fixing rod, 8-sliding rail, 9-sliding plate, 10-insert I, 11-feeding hopper, 12-insert II, 13-sliding block, 131-baffle I, 14-reset spring I, 15-sealing seat, 16-reset spring II, 17-push rod, 171-through hole, 18-hollow seat, 181-feeding groove, 182-push block, 19-rolling wheel, 20-expansion plate, 21-extrusion seat, 22-groove, 23-discharge hole, 24-baffle II, 241-sliding cavity, 242-fixing spring, 25-expansion plate, 26-a discharge plate, 27-a discharge opening, 28-a slide bar, 29-a buffer spring III and 30-a limiting block.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1-7, a chemical particle crushing and subpackaging machine comprises a base supporting seat 1, a support 2 is connected to the top of the base supporting seat 1, a cylinder 3 is fixedly connected to the top of the support 2, a buffer plate 4 is fixedly connected to the bottom of an output shaft of the cylinder 3, and buffer springs 5 are fixedly connected to the bottoms of both the left side and the right side of the buffer plate 4, the chemical particle crushing and subpackaging machine realizes that the cylinder 3 pushes the buffer plate 4 to move downwards through the cooperation of the cylinder 3, the buffer plate 4 moves downwards to compress the buffer spring 5, then the buffer spring 5 pushes the buffer plate 4 to reduce the impact force on the cylinder 3 to the device through the reverse acting force, so as to achieve the effect of prolonging the service life of the device, a sliding seat 6 is fixedly connected to one side of the buffer spring 5 away from the buffer plate 4, and the bottom of the sliding seat 6 is fixedly connected to the inside, an extrusion plate 41 is connected inside the sliding seat 6 in a sliding manner, the top of the extrusion plate 41 is fixedly connected with the bottom center of the buffer plate 4, a fixed rod 7 is connected inside the extrusion plate 41 in a sliding manner, the back surface of the fixed rod 7 is fixedly connected with the sliding seat 6, a sliding rail 8 is fixedly connected on the right side of the sliding seat 6, a sliding plate 9 is connected inside the sliding rail 8 in a sliding manner, an insertion piece I10 is fixedly connected on the right side of the sliding plate 9, a feeding hopper 11 is connected on the outer surface of one side of the insertion piece I10 away from the sliding plate 9 in a sliding manner, the left side of the feeding hopper 11 is fixedly connected with one side of the sliding rail 8 away from the sliding seat 6, the outer surface of the feeding hopper 11 is fixedly connected with the base supporting seat 1, an insertion piece II 12 is connected on the bottom of the feeding hopper 11 in a sliding manner, a sliding block 13 is fixedly, the left side of the closed seat 15 is fixedly connected with the feed hopper 11, the right side of the closed seat 15 is fixedly connected with the base support seat 1, the left side of the sliding plate 9 is fixedly connected with a second return spring 16, the second return spring 16 is positioned in the sliding rail 8, the left side of the second return spring 16 is fixedly connected with a push rod 17, one side of the push rod 17 close to the second return spring 16 is slidably connected with the sliding rail 8, a through hole 171 matched with the size of the push rod 17 is formed in the sliding seat 6, the push rod 17 is slidably connected in the through hole 171 of the sliding seat 6, one side of the push rod 17 far away from the second return spring 16 is fixedly connected with a hollow seat 18, a sliding groove 61 is formed in the sliding seat 6, a plurality of rollers are arranged in the sliding groove 61, the outer surface of the hollow seat 18 is slidably connected in the sliding groove 61 of the sliding seat 6, a rolling wheel 19 is, a pushing block 182 is fixedly connected to the top of the right side of the hollow seat 18, an expansion plate 20 is hinged to the top of the inner wall of the right side of the hollow seat 18, the bottom of the expansion plate 20 is hinged to the sliding seat 6, a squeezing seat 21 is arranged at the bottom of the squeezing wheel 19, the outer surface of the squeezing seat 21 is in sliding connection with the sliding seat 6, a groove 22 matched with the size of the squeezing wheel 19 is formed in the top of the squeezing seat 21, the squeezing wheel 19 is located in the groove 22 and in sliding connection, a discharging port 23 is formed in the left side of the groove 22, a sliding cavity 241 is formed in one side, close to the discharging port 23, of the inside of the squeezing seat 21, a fixed spring 242 is fixedly connected to the top of the inner wall of the sliding cavity 241, a second baffle 24 is fixedly connected to one end, far away from the inner wall of the sliding cavity 241, of the fixed spring 242, the second baffle 24 is located in sliding connection with, the telescopic baffle plate 25 is positioned at the right side of the discharge port 23, the bottom of the telescopic baffle plate 25 is fixedly connected with a discharge plate 26, the outer surface of the discharge plate 26 is fixedly connected with the base supporting seat 1, the bottom of the sliding seat 6 is provided with a discharge port 27 matched with the discharge port 23 in size, the inner wall of the discharge port 27 is fixedly connected with the telescopic baffle plate 25, the discharge port 27 is positioned right below the discharge port 23, the bottom of the extrusion seat 21 is fixedly connected with a sliding rod 28, the outer surface of the sliding rod 28 is slidably connected with the bottom of the sliding seat 6, the bottom of the extrusion seat 21 is fixedly connected with a buffer spring III 29, the sliding rod 28 is positioned inside the buffer spring III 29, the bottom of the buffer spring III 29 is fixedly connected with the sliding seat 6, the bottom of the sliding rod 28 is fixedly connected with a limiting block 30, and the particle crushing and subpackaging machine passes through a cylinder 3, a buffer plate 4, an, The sliding rod 28, the discharge port 23, the buffer spring III 29, the baffle II 24, the telescopic baffle plate 25, the hollow seat 18, the push rod 17, the return spring II 16, the return spring I14, the sliding block 13, the baffle I131, the telescopic plate 20, the push block 182 and the feed hopper 11 are matched for use, so that the cylinder 3 drives the extrusion plate 41 to move downwards through the buffer plate 4, the extrusion plate 41 moves downwards to push the rolling wheel 19 to move rightwards, meanwhile, the rolling wheel 19 moves rightwards to roll particles in the groove 22, the rolled particles slide to the discharge port 23 through the inclined surface of the groove 22, then the powdered particles pass through a channel formed by the discharge port 23, the telescopic baffle plate 25 and the right side of the inner wall of the sliding seat 6, then the powdered particles fall on the discharge plate 26 to slide out into a subpackage bag to complete subpackage of the particles, meanwhile, the extrusion seat 21 moves downwards to drive the sliding rod 28 to move downwards, the extrusion seat 21 moves downwards to compress the telescopic baffle plate 25 and the buffer spring III 29 through the, meanwhile, the rolling wheel 19 moves rightwards to drive the hollow seat 18 to enable the push rod 17 to push the second reset spring 16 to move rightwards, the second reset spring 16 moves rightwards to push the sliding plate 9 to enable the first insert piece 10 to be inserted into the feed hopper 11 to divide particles between the first insert piece 10 and the second insert piece 12 in the feed hopper 11, meanwhile, the hollow seat 18 also pushes the baffle plate 131 to drive the sliding block 13 to compress the first reset spring 14 through the pushing block 182, meanwhile, the second insert piece 12 is also driven to be separated from the inner part of the feed hopper 11, the particles at the discharge port of the feed hopper 11 enter the inner part of the groove 22, at the moment, the first insert piece 10 closes the upper part of the feed hopper 11, the second insert piece 12 is in a state of opening the feed hopper 11, and therefore the purpose of quantifying the particles is achieved, finally, the particles move through the hollow seat 18 to enable, meanwhile, the effects of automatic grinding, subpackaging and quantifying of the particles are achieved.
The top of the hollow seat 18 is provided with a feed chute 181 matched with the size of the extrusion plate 41, and the inside of the extrusion plate 41 is provided with a slide rail matched with the size of the fixed rod 7.
The front and the back of the rotating rod of the rolling wheel 19 are fixedly connected with 191, the 191 is positioned at the top of the extrusion seat 21, and the distance between the top of the extrusion seat 21 and the groove 22 is matched with the length of the 191.
The cross-sectional shape of extrusion seat 21 is trapezoidal, and the inclined plane of extrusion seat 21 is up, the bottom cross-sectional shape of stripper plate 41 is wedge.
The push rod 17 is Z-shaped, the first baffle 131 and the push block 182 are positioned on the same horizontal line, and the length of the slide rail 8 is matched with the moving distance of the push block 182.
The angle of the top extension line of the discharge port 23 to the inner wall of the left side of the slide seat 6 is larger than the angle of the bottom extension line of the groove in the extrusion seat 21 to the inner wall of the left side of the slide seat 6, so that the powder conveniently crushed enters the interior of the discharge port 23, the crushed particles are prevented from blocking the discharge port 23, and the telescopic baffle plate 25 and the inner wall of the slide seat 6, the discharge port 23 and the discharge port 27 form a discharge channel.
When in use, the buffer plate 4 is pushed to move downwards by the cylinder 3, the buffer plate 4 moves downwards to compress the buffer spring 5, then the buffer spring 5 pushes the buffer plate 4 to reduce the impact force on the cylinder 3 to the device by a reverse acting force, the service life of the device is prolonged, meanwhile, the buffer plate 4 moves downwards to drive the extrusion plate 41 to move downwards, the extrusion plate 41 moves downwards to extrude the rolling wheel 19 to move rightwards, the rolling wheel 19 moves rightwards to drive the hollow seat 18 to move rightwards simultaneously, the rolling wheel 19 moves rightwards to roll the particles in the groove 22 in the extrusion seat 21, then the particles rolled by the rolling wheel 19 are in a powder shape, then the powder-shaped particles slide to the discharge port 23 through the inclined surface of the groove 22, then the powder-shaped particles pass through the discharge port 23 and the telescopic baffle plate 25 and the right side of the inner wall of the sliding seat 6, then the powder-shaped particles fall on the discharge plate 26, then the material sliding plate 26 is slid into the packaging bag, thereby completing the purpose of packaging particles, simultaneously the rolling wheel 19 also extrudes the pressing seat 21 to move downwards, the extruding seat 21 moves downwards to drive the sliding rod 28 to move downwards and compress the buffer spring III 29 and the telescopic baffle plate 25, simultaneously the rolling wheel 19 moves rightwards to drive the hollow seat 18 to move rightwards, the hollow seat 18 moves rightwards to drive the pushing rod 17 to move rightwards, the pushing rod 17 moves rightwards to drive the sliding plate 9 to move rightwards through the elasticity of the return spring II 16, the sliding plate 9 moves rightwards to drive the inserting sheet I10 to move rightwards, the inserting sheet I10 moves rightwards to be inserted into the feeding hopper 11, the inserting sheet I10 is inserted into the feeding hopper 11, particles between the inserting sheet I10 and the inserting sheet II 12 in the feeding hopper 11 are divided, simultaneously the pushing block 182 at the top of the right side of the hollow seat 18 is contacted with the baffle, meanwhile, the hollow seat 18 moves rightwards to also pull the expansion plate 20 to rotate rightwards and extend, so that the expansion plate 20 forms a material guide plate, auxiliary particles enter the inside of the groove 22, then the extrusion plate 41 extrudes the rolling wheel 19 to move rightwards to the highest position of the extrusion seat 21, meanwhile, the extrusion seat 21 slides to the inside of the lower half sliding seat 6, the hollow seat 18 moves rightwards to drive the expansion plate 20 to rotate and extend, so that the expansion plate 20 completely forms a feed plate sliding plate, meanwhile, the hollow seat 18 moves rightwards to drive the push block 182 to push the baffle plate one 131 to move rightwards, the baffle plate one 131 moves rightwards to drive the insert piece two 12 to move rightwards to separate from the inside of the feed hopper 11, the insert piece two 12 moves rightwards to separate from the inside of the feed hopper 11, then the particles fall on the expansion plate 20 through the feed hopper 11 and the feed chute 181, then the particles slide to one end, close to the expansion plate 20, of the rolling, then the slide plate 9 is pushed by the reverse acting force of the return spring II 16 to drive the insert I10 to be stably inserted into the feed hopper 11, at the moment, the insert I10 closes the upper part of the feed hopper 11, the insert II 12 is in a state of opening the feed hopper 11, thereby the purpose of quantifying the particles is completed, then the air cylinder 3 retracts to drive the extrusion plate 41 to move upwards through the buffer plate 4, simultaneously the compressed buffer spring III 29 pushes the extrusion seat 21 to move upwards, the extrusion seat 21 moves upwards to pull the telescopic baffle plate 25 to extend through the baffle plate II 24, simultaneously the extrusion seat 21 moves upwards to push the rolling wheel 19 to move leftwards, the rolling wheel 19 moves leftwards to drive the hollow seat 18 to move leftwards, the hollow seat 18 moves leftwards to drive the telescopic plate 20 to rotate leftwards and retract, simultaneously the hollow seat 18 moves leftwards to drive the push block 182 to move leftwards, and the push block 182 moves left, then the return spring I14 pushes the slide block 13 to drive the baffle I131 and the insert II 12 to move leftwards, the insert II 12 moves leftwards and is inserted into the feed hopper 11 to close the discharge port, meanwhile, the hollow seat 18 moves leftwards to drive the push rod 17 to move leftwards to release the pressure on the return spring II 16, when the insert II 12 closes the discharge port, the push rod 17 moves leftwards to pull the slide plate 9 to move leftwards through the elasticity of the return spring II 16, the slide plate 9 moves leftwards to drive the insert I10 to move leftwards to separate from the inside of the feed hopper 11, then the particles in the hopper 11 fall on the top of the insert II 12 again, then the extrusion plate 41 returns to the original position, meanwhile, the buffer spring III 29 pushes the extrusion seat 21 to enable the rolling wheel 19 to move to the left side of the outer surface of the top of the extrusion seat 21, and the hollow seat 18 drives the expansion plate, simultaneously the surface on the right side of the top of the hollow seat 18 coincides with the inner wall of the sliding seat 6, thereby completing the sealing of the device, preventing extruded particles from jumping out from the feeding groove 181, and completing the purposes of automatic quantification, rolling and split charging of the particles.
In conclusion, the buffer plate 4 is pushed by the cylinder 3 to move downwards, the buffer plate 4 moves downwards to compress the buffer spring 5, then the buffer spring 5 pushes the buffer plate 4 to reduce the impact force on the cylinder 3 to the device through a reverse acting force, the service life of the device is prolonged, the buffer plate 4 moves downwards to drive the extrusion plate 41 to move downwards, the extrusion plate 41 moves downwards to push the rolling wheel 19 to move rightwards, meanwhile, the rolling wheel 19 moves rightwards to roll the particles in the groove 22, the rolled particles slide to the discharge hole 23 through the inclined surface of the groove 22, then the powdery particles pass through the discharge hole 23 and the channels formed by the telescopic baffle plate 25 and the right side of the inner wall of the sliding seat 6, then the powdery particles fall on the discharge plate 26 to slide out into the subpackage bag, the subpackage of the particles is completed, meanwhile, the extrusion seat 21 moves downwards to drive the slide rod 28 to move downwards, the extrusion seat 21 moves downwards to compress the telescopic baffle plate 25 and the compression buffer spring three 29 through the baffle plate, meanwhile, the rolling wheel 19 moves rightwards to drive the hollow seat 18 to enable the push rod 17 to push the second reset spring 16 to move rightwards, the second reset spring 16 moves rightwards to push the sliding plate 9 to enable the first insert piece 10 to be inserted into the feed hopper 11 to divide particles between the first insert piece 10 and the second insert piece 12 in the feed hopper 11, meanwhile, the hollow seat 18 also pushes the baffle plate 131 to drive the sliding block 13 to compress the first reset spring 14 through the pushing block 182, meanwhile, the second insert piece 12 is also driven to be separated from the inner part of the feed hopper 11, the particles at the discharge port of the feed hopper 11 enter the inner part of the groove 22, at the moment, the first insert piece 10 closes the upper part of the feed hopper 11, the second insert piece 12 is in a state of opening the feed hopper 11, and therefore the purpose of quantifying the particles is achieved, finally, the particles move through the hollow seat 18 to enable, meanwhile, the purposes of automatically rolling, subpackaging and quantifying the particles are also achieved.
It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.
Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.