CN116944029B - Activated carbon particle screening and classifying labeling machine - Google Patents

Abstract

The invention discloses an activated carbon particle screening and classifying label machine, which belongs to the technical field of packaging and labels and comprises a screening device placed on the ground, wherein the screening device is used for screening activated carbon according to particle size, a packaging device is arranged on the screening device and used for packaging and labeling the screened activated carbon, a timing device is arranged on the packaging device and used for timing and switching the screening action and the packaging action. The screening device provided by the invention can effectively realize that activated carbon particles are classified according to the size through the shaking mechanism, unqualified particles are eliminated, and then the screened activated carbon particles are pumped into the packaging device for packaging; the packaging device is matched with the weighing mechanism to trigger the pushing mechanism and the label mechanism according to the weight of the activated carbon in each packaging box, performs label printing action and pushes out the packaged packaging box, and the next empty packaging box enters the filling box to realize continuous operation.

Description

Activated carbon particle screening and classifying labeling machine

Technical Field

The invention relates to the technical field of packaging and labeling, in particular to an activated carbon particle screening, classifying and labeling machine.

Background

The active carbon particles are mainly prepared from coconut shells, fruit shells and other substances serving as raw materials through a series of processing, and have wide application in the fields of water purification, gas drying and the like. However, due to the reasons of raw materials and processes, the produced activated carbon particles are different in size and shape, which has a certain influence on the use process. After the activated carbon particles are classified, the activated carbon particles need to be packaged and labeled, so that the activated carbon particles are convenient to use subsequently.

The Chinese patent application with publication number of CN108405308A discloses a screening machine for granular materials, wherein the prior art classifies the materials into size by a vibration disc, and then flows into respective screening discs by respective runner grooves to realize the screening function. But this prior art can only work at the rough screening condition, and too little granule accessible large-scale screening piece also gets into qualified passageway, and can't realize the active carbon packing after the screening and seal the label function, inconvenient use.

Disclosure of Invention

Aiming at the technical problems, the invention adopts the following technical scheme: the utility model provides a label machine is categorized in screening of active carbon granule, includes the sieving mechanism of placing subaerial, sieving mechanism include fertilizer base and little discharge opening, fertilizer base places subaerial, sieving mechanism be used for screening active carbon according to the granule size, sieving mechanism on be provided with packing plant, packing plant includes packing feeding case and little material inlet pipe, packing feeding case is placed subaerial, little material inlet pipe and little discharge opening fixed mounting, packing plant be used for packing and seal the label to the active carbon after the screening, packing plant on be provided with timing device, timing device include the mount, mount fixed mounting is on packing feeding case, timing device be used for timing and switch screening action and packing action.

Adding activated carbon into a screening device, classifying the activated carbon according to the size of activated carbon particles by the screening device, respectively introducing the activated carbon into a packaging device for packaging and labeling, stopping the screening device once every time a period of time passes by a timing device, starting the packaging device, stopping the packaging device, and starting the screening device to reciprocate.

Further, sieving mechanism include fixed mounting in fertilizer base side's relief hole, fixed mounting has the bottom hose on the fertilizer base, bottom hose other end fixed mounting has a bottom section of thick bamboo, fixed mounting has a bottom slide column on the bottom section of thick bamboo, be provided with vibration spring between bottom section of thick bamboo and the fertilizer base, fixed mounting has a little screening section of thick bamboo on the bottom section of thick bamboo, fixed mounting has a well screening section of thick bamboo on the little screening section of thick bamboo, fixed mounting has the feeder hopper on the big screening section of thick bamboo, little screening section of thick bamboo, well screening section of thick bamboo, big screening section of thick bamboo and feeder hopper pass through long bolt and nut fixed mounting together, fixed mounting has the big hole screen cloth in the big screening section of thick bamboo, fixed mounting has the well hole screen cloth in the well screening section of thick bamboo, fixed mounting has the well hole in the big screening section of thick bamboo side, little screening section of thick bamboo side fixed mounting has the little hole, shake mechanism outside the bottom section of thick bamboo, all be provided with unidirectional mechanism in big hole, well hole and the little hole.

Further, the shaking mechanism comprises a shaking frame which is slidably arranged outside the bottom cylinder, a shaking motor is arranged on the ground, an eccentric disc is fixedly arranged on a motor shaft of the shaking motor, a rotating connecting rod is rotatably arranged on the eccentric disc, and the rotating connecting rod is rotatably arranged with the shaking frame.

Further, the unidirectional mechanism include slidable mounting in big discharge opening, well discharge opening and little discharge opening slide the stopper, slide and all be provided with certain clearance between stopper outer wall and the inner wall of big discharge opening, well discharge opening and little discharge opening, be provided with compression spring between stopper and big discharge opening, well discharge opening, the little discharge opening, all be provided with the export board on big discharge opening, well discharge opening and the little discharge opening.

Further, the diameters of the holes on the macroporous screen mesh, the middle-pore screen mesh and the small-pore screen mesh are from large to small.

The active carbon is put into the feed hopper through the feed inlet at the top of the feed hopper, the holes are formed in the macroporous screen, the mesoporous screen and the microporous screen, the diameters of the holes become smaller from top to bottom, the vibration motor rotates to drive the eccentric disc to rotate, thereby driving the rotating connecting rod to rotate, the shaking frame is driven to lift along the bottom cylinder, thereby driving the small screening cylinder, the middle screening cylinder and the large screening cylinder to lift, thereby shaking and screening the active carbon on the macroporous screen, the mesoporous screen and the microporous screen, larger active carbon particles can be left on the macroporous screen, medium-sized active carbon particles can be left on the mesoporous screen, small active carbon particles or active carbon powder can fall into the bottom cylinder from the microporous screen, and enter the fertilizer base through the bottom hose.

After screening is completed, the packing device can extract active carbon particles in the large screening cylinder, the middle screening cylinder and the small screening cylinder, at the moment, under the pumping action of the pump, the sliding plug can slide in the large discharging hole, the middle discharging hole and the small discharging hole, the compression spring is compressed, the active carbon particles are extracted into the packing device, and when the packing device is not started, the sliding plug is attached to the outlet plate, so that the active carbon particles are prevented from being buffed out in the screening process.

Further, packing device include fixed mounting the packing case on packing feeding case, fixed mounting has little material pump, well material pump and big material pump on the packing case, fixed mounting has little material inlet pipe on the little material pump, fixed mounting has well material inlet pipe on the well material pump, fixed mounting has big material inlet pipe on the big material pump, well material inlet pipe and well discharge opening fixed mounting, big material inlet pipe and big discharge opening fixed mounting are provided with the support by the packing case, rotate on the support and install the drive belt, fixed mounting has the release frame on the packing feeding case, is provided with the spout on the release frame, is provided with the packing box in the packing feeding case, is provided with weighing machine and label mechanism on the packing case, is provided with release mechanism on the packing feeding case.

Further, the weighing mechanism comprises a pressing column which is slidably arranged at the bottom of the filling box, a pressing disc is fixedly arranged on the pressing column, a packing box is placed on the pressing disc, a pressing spring is arranged between the pressing disc and the bottom of the filling box, a pressing rack is fixedly arranged below the pressing column, a bottom gear frame is fixedly arranged at the bottom of the filling box, an external gear is rotatably arranged on the bottom gear frame, an internal gear is fixedly arranged on the external gear, and the external gear is meshed with the pressing rack.

Further, the label mechanism comprises a lifting rod which is slidably arranged on the filling box, an ink pad piece is fixedly arranged on the lifting rod, a label rack is fixedly arranged at the bottom of the lifting rod, and the label rack is meshed with the external gear.

Further, the pushing mechanism comprises a transverse rack which is slidably arranged at the bottom of the packaging feeding box, the transverse rack is meshed with the inner gear, a pushing column is fixedly arranged on the transverse rack and slides in the chute, a blocking block is fixedly arranged on the pushing frame, a bottom push rod is slidably arranged in the packaging feeding box, a pushing spring is arranged between the bottom push rod and the pushing frame, a shrinkage triangular block is slidably arranged in the bottom push rod, and a shrinkage spring is arranged between the shrinkage triangular block and the bottom push rod.

A plurality of packing boxes are placed on a push rod at the bottom in a packing feeding box, a small material pump is started, small granular activated carbon on a small-hole sieve is pumped into a corresponding packing box through a small discharge hole and a small material feeding pipe and falls into a corresponding packing box, a medium material pump is started, medium granular activated carbon on a medium-hole sieve is pumped into a corresponding packing box through a medium discharge hole and a medium material feeding pipe and falls into a corresponding packing box, a large material pump is started, large granular activated carbon on a large-hole sieve is pumped into a corresponding packing box through a large discharge hole and a large material feeding pipe and falls into a corresponding packing box, the packing boxes in the packing box are placed on a lower pressing disc, and a lower pressing disc, a lower pressing column and a lower pressing rack are driven to descend along with the continuous increase of the weight of the packing boxes, so that the lower pressing spring is compressed, the lower pressing rack descends to drive an external gear to rotate at first, the label rack is driven to rise, the lifting rod and the inkpad sheet are driven to rise, the inkpad sheet slowly lifts up the packaging box on the driving belt after finishing printing labels of the last packaging box, meanwhile, the rack is pressed down to drive the internal gear to rotate, the transverse rack is driven to rotate, the pushing post is driven to slide along the sliding groove, the pushing post pushes the shrinkage triangular block and the bottom push rod to move towards the pushing frame, the pushing spring is compressed, when the pushing post brings the shrinkage triangular block into contact with the blocking block, the pushing post continuously moves, the shrinkage triangular block can slide inwards along the bottom push rod under the action of the blocking block, the shrinkage spring is compressed, finally the shrinkage triangular block enters the bottom push rod, at the moment, the bottom push rod below the packaging box is completely separated, the pushing post cannot continuously push the shrinkage triangular block, and the gap below the blocking block passes, the bottom push rod is driven to pop out forward by the rebound of the push spring, and therefore the packing box just falling from the top of the bottom push rod is pushed out, and the packing box above the lower pressing plate is pushed out, meanwhile, the packing box originally located in the filling box reaches the top of the lower pressing plate, the packing box originally located above the lower pressing plate and filled with activated carbon is located below the ink box, the packing box originally located below the ink box and filled with activated carbon is pushed out to move forward along the driving belt, the driving belt is rotatable relative to the support, pushing operation of the packing box is facilitated, the packing box filled with activated carbon above the lower pressing plate is pushed out to become an empty packing box, the spring rebound is pushed down to drive the lower pressing column, the lower pressing plate and the lower pressing rack to ascend, and accordingly the outer gear and the inner gear are reversed, the lifting rod and the ink box are moved down, the packing box just below the ink box is stamped, the label is pushed simultaneously, the column and the transverse rack are pushed back to the initial position in the process of pushing column, the triangle block is contacted with the shrinkage triangle block, the shrinkage triangle block is pushed to slide in the bottom push rod, the shrinkage triangle block is pushed down to shrink the triangle block, the shrinkage block is pushed down to shrink the triangle block is pushed down, and the shrinkage block is pushed down to make a shrinkage, and the label is ready to be packed after the shrinkage package.

Further, the timing device comprises a timing motor fixedly arranged on the packaging feeding box, a main connecting rod is rotatably arranged on the timing motor, an auxiliary connecting rod is rotatably arranged on the main connecting rod, a moving column is rotatably arranged on the auxiliary connecting rod, a moving frame is slidably arranged on a fixing frame, a left sensing piece and a right sensing piece are fixedly arranged on the moving frame, and the moving column slides in the fixing frame.

The timing motor rotates at a certain speed to drive the main connecting rod to rotate so as to drive the auxiliary connecting rod to rotate so as to drive the movable column to slide in the fixed frame, when the movable column is contacted with the left sensing piece, the movable frame is driven to slide leftwards in the fixed frame, the left sensing piece is pushed into a hole of the fixed frame, the right sensing piece slides out of the hole of the fixed frame, the small material pump, the middle material pump and the large material pump start to act at the moment, the vibration motor stops acting, when the timing motor continues to rotate, the movable column is driven to continue to slide in the fixed frame, and when the movable column is contacted with the right sensing piece, the movable frame is driven to slide rightwards in the fixed frame, the right sensing piece is pushed into the hole of the fixed frame, the left sensing piece slides out of the hole of the fixed frame at the moment, the small material pump, the middle material pump and the large material pump stop moving at the moment, and the vibration motor starts moving, so that the alternate starting of the shaking mechanism and the packaging device is realized, namely, when the shaking mechanism moves, the small material pump, the middle material pump and the large material pump can not pump out active carbon in the screening device, and when the shaking mechanism stops, the small material pump, the middle material pump and the large material pump out active carbon in the screening device to the packaging box of the filling box.

Compared with the prior art, the invention has the beneficial effects that: (1) The screening device provided by the invention can effectively realize that activated carbon particles are classified according to the size through the shaking mechanism, unqualified too small particles or powder are eliminated, and then the screened activated carbon particles are pumped into the packaging device for packaging; (2) According to the invention, the packaging device is matched with the weighing mechanism to trigger the pushing mechanism and the label mechanism according to the weight of the activated carbon in each packaging box, so as to perform label printing and pushing actions on the packaged packaging boxes, and then the next empty packaging box enters the filling box, thereby realizing continuous operation and having high efficiency; (3) The timing device provided by the invention enables each pump and the vibration motor of the packaging device to work in turn every fixed period of time, when the vibration motor works, the pump stops working, and when the pump starts working, the vibration motor stops working, and the automation degree of screening, packaging and label printing actions is high.

Drawings

Fig. 1 is a schematic view of the whole structure of the present invention (first view angle).

Fig. 2 is a schematic diagram of the overall structure of the present invention (second view angle).

Fig. 3 is a schematic diagram of a screening apparatus according to the present invention.

Fig. 4 is a schematic diagram of a screening apparatus according to the second embodiment of the present invention.

Fig. 5 is an enlarged partial schematic view of fig. 4 a in accordance with the present invention.

Fig. 6 is a schematic view of a packaging device according to the present invention.

Fig. 7 is a schematic structural view of a packaging device according to the second embodiment of the present invention.

Fig. 8 is a schematic view of a third embodiment of the packaging device of the present invention.

Fig. 9 is a schematic view of a packaging unit according to the present invention.

Fig. 10 is a schematic structural view of the push-out mechanism of the present invention.

FIG. 11 is a schematic view of the structure of the retractable triangular block and the bottom push rod of the present invention.

FIG. 12 is a schematic view of a timing device according to the present invention.

FIG. 13 is a schematic diagram of a timing device according to the second embodiment of the present invention.

Reference numerals: 101-a fertilizer base; 102, a discharge hole; 103-vibrating motor; 104-eccentric disc; 105-rotating the connecting rod; 106-dithering the frame; 107-nuts; 108-a long bolt; 109-small screen cartridges; 110-middle screening cylinder; 111-large screening cylinder; 112-feeding hopper; 113-small discharge holes; 114-a middle discharging hole; 115-large discharge hole; 116-small pore screen; 117-mesoporous screen; 118-a large pore screen; 119-sliding plugs; 120-compressing the spring; 121-a bottom hose; 122-bottom spool; 123-vibration springs; 124-a bottom cylinder; 125-outlet plate; 201-packaging a feeding box; 202-filling a tank; 203-a stent; 204-a drive belt; 205-packaging box; 206-a small material feeding pipe; 207-a medium feeding pipe; 208-a bulk feed pipe; 209-a small material pump; 210-a middle material pump; 211-a large material pump; 212-pushing out rack; 2121-sliding grooves; 213-a blocking block; 214-push-out spring; 215-bottom push rod; 216-shrinking triangular blocks; 217-retraction spring; 218-lower platen; 219-pressing down a column; 220-pressing down the spring; 221-pressing down a rack; 222-an external gear; 223-internal gear; 224-a tag rack; 225-lifting rod; 226-inkpad tablets; 227-a transverse rack; 228-push column; 229-bottom carrier; 301-fixing frame; 302-a timing motor; 303—a main link; 304-a secondary link; 305-moving a frame; 306-moving the column; 307-left sensing piece; 308-right sense piece.

Detailed Description

The following describes the embodiments of the present invention further with reference to the drawings.

Examples: referring to fig. 1-13, an activated carbon particle screening and classifying label machine comprises a screening device placed on the ground, wherein the screening device comprises a fertilizer base 101 and a small discharging hole 113, the fertilizer base 101 is placed on the ground, the screening device is used for screening activated carbon according to particle size, a packaging device is arranged on the screening device and comprises a packaging feeding box 201 and a small material feeding pipe 206, the packaging feeding box 201 is placed on the ground, the small material feeding pipe 206 is fixedly installed with the small discharging hole 113, the packaging device is used for packaging and labeling the screened activated carbon, a timing device is arranged on the packaging device and comprises a fixing frame 301, the fixing frame 301 is fixedly installed on the packaging feeding box 201, and the timing device is used for timing and switching screening actions and packaging actions.

Adding activated carbon into a screening device, classifying the activated carbon according to the size of activated carbon particles by the screening device, respectively introducing the activated carbon into a packaging device for packaging and labeling, stopping the screening device once every time a period of time passes by a timing device, starting the packaging device, stopping the packaging device, and starting the screening device to reciprocate.

As shown in fig. 3 to 5, the screening device comprises a discharge hole 102 fixedly installed on the side surface of a fertilizer base 101, a bottom hose 121 is fixedly installed on the fertilizer base 101, a bottom barrel 124 is fixedly installed at the other end of the bottom hose 121, a bottom sliding column 122 is fixedly installed on the bottom barrel 124, a vibration spring 123 is arranged between the bottom barrel 124 and the fertilizer base 101, a small screening barrel 109 is fixedly installed on the bottom barrel 124, a middle screening barrel 110 is fixedly installed on the small screening barrel 109, a large screening barrel 111 is fixedly installed on the middle screening barrel 110, a feed hopper 112 is fixedly installed on the large screening barrel 111, the small screening barrel 109, the middle screening barrel 110, the large screening barrel 111 and the feed hopper 112 are fixedly installed together through long bolts 108 and nuts 107, a large-hole screen 118 is fixedly installed in the large screening barrel 111, a middle-hole screen 117 is fixedly installed in the middle screening barrel 110, a small-hole screen 116 is fixedly installed in the small screening barrel 109, a large-discharge hole 115 is fixedly installed on the side surface of the middle screening barrel 110, a middle discharge hole 114 is fixedly installed on the side surface of the small screening barrel 109, a small screening barrel 109 is fixedly installed on the side surface of the large screening barrel 111, a small screening mechanism is provided with a small discharge hole 113, and the middle screening barrel 124 and the middle screening hole 114 are fixedly installed outside the small screening mechanism is provided with a single-way discharge hole 114.

As shown in fig. 3 and 4, the shaking mechanism includes a shaking frame 106 slidably mounted outside a bottom cylinder 124, a shaking motor 103 is placed on the ground, an eccentric disc 104 is fixedly mounted on a motor shaft of the shaking motor 103, a rotating connecting rod 105 is rotatably mounted on the eccentric disc 104, and the rotating connecting rod 105 and the shaking frame 106 are rotatably mounted.

As shown in fig. 5, the unidirectional mechanism includes a sliding plug 119 slidably installed in the large discharge hole 115, the middle discharge hole 114 and the small discharge hole 113, a certain gap is provided between the outer wall of the sliding plug 119 and the inner walls of the large discharge hole 115, the middle discharge hole 114 and the small discharge hole 113, a compression spring 120 is provided between the sliding plug 119 and the large discharge hole 115, the middle discharge hole 114 and the small discharge hole 113, and an outlet plate 125 is provided on each of the large discharge hole 115, the middle discharge hole 114 and the small discharge hole 113.

As shown in fig. 4, the large pore screen 118, the medium pore screen 117 and the small pore screen 116 have holes with diameters ranging from large to small.

The activated carbon is placed into the feed hopper 112 through the feed inlet at the top of the feed hopper 112, holes are formed in the large-hole screen 118, the medium-hole screen 117 and the small-hole screen 116, the diameters of the holes are sequentially reduced from top to bottom, the vibration motor 103 rotates to drive the eccentric disc 104 to rotate so as to drive the rotating connecting rod 105 to rotate, the shaking frame 106 is driven to lift along the bottom cylinder 124, the bottom cylinder 124 is driven to lift, the small-hole screen 109, the medium-hole screen 110 and the large-hole screen 111 are driven to lift, shaking screening is carried out on the activated carbon on the large-hole screen 118, the medium-hole screen 117 and the small-hole screen 116, larger activated carbon particles are left on the medium-hole screen 118, the activated carbon particles with the small size are left on the small-hole screen 116, the small activated carbon particles or activated carbon powder falls into the bottom cylinder 124 from the small-hole screen 116, and enters the fertilizer base 101 through the bottom hose, and can be taken out from the discharge hole 102 as fertilizer, and the shaking frame 106 and the bottom cylinder 124 are slidably arranged by the motor 103, and the shaking frame 106 is driven to move down by the bottom cylinder 124, and the shaking frame 106 is driven by the bottom cylinder 124, the medium-hole screen 110 and the large-hole screen 110 is driven to move, the shaking frame 109 and the large-hole screen 110 can be driven to move, the large-hole screen 110 is driven, and the shaking screen 110 is driven to move, and the large-hole screen 110 is greatly screened.

When screening is completed, the packing device extracts the activated carbon particles in the large screening cylinder 111, the middle screening cylinder 110 and the small screening cylinder 109, at this time, under the pumping force of the pump, the sliding plug 119 slides in the large discharging hole 115, the middle discharging hole 114 and the small discharging hole 113, the compression spring 120 is compressed, the activated carbon particles are extracted into the packing device, and when the packing device is not started, the sliding plug 119 is attached to the outlet plate 125, so that the activated carbon particles are prevented from being shaken out in the screening process.

As shown in fig. 6 to 11, the packing device comprises a packing box 202 fixedly mounted on a packing feeding box 201, a small material pump 209, a medium material pump 210 and a large material pump 211 are fixedly mounted on the packing box 202, a small material feeding pipe 206 is fixedly mounted on the small material pump 209, a medium material feeding pipe 207 is fixedly mounted on the medium material pump 210, a large material feeding pipe 208 is fixedly mounted on the large material pump 211, the medium material feeding pipe 207 is fixedly mounted with the medium discharging hole 114, the large material feeding pipe 208 is fixedly mounted with the large discharging hole 115, a support 203 is arranged beside the packing box 202, a driving belt 204 is rotatably mounted on the support 203, a push-out frame 212 is fixedly mounted on the packing feeding box 201, a chute 2121 is arranged on the push-out frame 212, a packing box 205 is arranged in the packing feeding box 201, a weighing mechanism and a label mechanism are arranged on the packing feeding box 202, and a push-out mechanism is arranged on the packing feeding box 201.

As shown in fig. 6 to 9, the weighing mechanism comprises a pressing column 219 slidably mounted at the bottom of the filling box 202, a pressing plate 218 is fixedly mounted on the pressing column 219, a packing box 205 is placed on the pressing plate 218, a pressing spring 220 is arranged between the pressing plate 218 and the bottom of the filling box 202, a pressing rack 221 is fixedly mounted below the pressing column 219, a bottom gear frame 229 is fixedly mounted at the bottom of the filling box 202, an external gear 222 is rotatably mounted on the bottom gear frame 229, an internal gear 223 is fixedly mounted on the external gear 222, and the external gear 222 is meshed with the pressing rack 221.

As shown in fig. 6 to 9, the label mechanism includes a lifting rod 225 slidably mounted on the filling box 202, an ink pad sheet 226 is fixedly mounted on the lifting rod 225, a label rack 224 is fixedly mounted on the bottom of the lifting rod 225, and the label rack 224 is meshed with the external gear 222.

As shown in fig. 6 to 11, the push-out mechanism includes a rack 227 slidably mounted on the bottom of the package feed box 201, the rack 227 is engaged with the internal gear 223, a push post 228 is fixedly mounted on the rack 227, the push post 228 slides in the slide groove 2121, a stopper 213 is fixedly mounted on the push-out frame 212, a bottom push rod 215 is slidably mounted in the package feed box 201, a push-out spring 214 is disposed between the bottom push rod 215 and the push-out frame 212, a shrinkage triangular block 216 is slidably mounted in the bottom push rod 215, and a shrinkage spring 217 is disposed between the shrinkage triangular block 216 and the bottom push rod 215.

A plurality of packing boxes 205 are placed on a push rod 215 at the bottom in a packing feeding box 201, a small material pump 209 is started, small granular activated carbon on a small-hole sieve 116 is pumped into a corresponding packing box 202 through a small material outlet 113 and a small material feeding pipe 206, falls into the corresponding packing box 205, a middle material pump 210 is started, middle granular activated carbon on a middle-hole sieve 117 is pumped into the corresponding packing box 202 through a middle material outlet 114 and a middle material feeding pipe 207, falls into the corresponding packing box 205, a large material pump 211 is started, large granular activated carbon on a large-hole sieve 118 is pumped into the corresponding packing box 202 through a large material outlet 115 and a large material feeding pipe 208, falls into the corresponding packing box 205, the packing box 205 in the packing box 202 is placed on a lower pressure plate 218, the lower pressure plate 218 and a lower pressure column 219 and a lower pressure rack 221 are driven to descend along with the continuous increase of the weight of the packing box 205, so that the lower pressure spring 220 is compressed, the downward pressing rack 221 firstly drives the external gear 222 to rotate so as to drive the label rack 224 to rise, thereby driving the lifting rod 225 and the inkpad sheet 226 to rise, so that the inkpad sheet 226 slowly lifts the packaging box 205 on the driving belt 204 after finishing printing labels, namely the last packaging box 205, simultaneously the downward pressing rack 221 descends to drive the internal gear 223 to rotate so as to drive the transverse rack 227 to rotate so as to drive the pushing column 228 to slide along the sliding groove 2121, thereby the pushing column 228 pushes the shrinkage triangular block 216 and the bottom push rod 215 to move towards the push-out frame 212, the push-out spring 214 is compressed, when the pushing column 228 brings the shrinkage triangular block 216 into contact with the blocking block 213, the pushing column 228 continues to advance, the shrinkage triangular block 216 slides inwards along the bottom push rod 215 under the action of the blocking block 213, the shrinkage spring 217 is compressed, and finally the shrinkage triangular block 216 enters the bottom push rod 215, at this time, the bottom push rod 215 below the packing box 205 is completely separated, the pushing column 228 cannot continuously push the shrinkage triangular block 216, the bottom push rod 215 is driven to pop forward by the clearance below the blocking block 213, at this time, the pushing spring 214 starts to rebound to drive the bottom push rod 215 to pop out, thereby pushing out the packing box 205 just fallen from above the bottom push rod 215, and pushing out the packing box 205 above the lower pressure plate 218, simultaneously pushing out the packing box 205 below the seal plate 226, at this time, the packing box 205 originally located in the filling box 202 reaches above the lower pressure plate 218, the packing box 205 originally located above the lower pressure plate 218 and filled with active carbon is located below the seal plate 226, the packing box 205 originally located below the seal plate 226 is pushed out to move forward along the driving belt 204, the driving belt 204 rotates relative to the support 203, so that the packing box 205 is pushed out conveniently, because the packing box 205 just filled with active carbon above the lower pressure plate 218 is pushed out, the rebound of the lower pressure spring 220, the lower column 219 and the lower pressure rack 221 are driven to rise, thereby the inner gear 222 and the inner gear 223 are reversed, thereby the pressure plate 226 and the pressure plate 226 are pushed down by the pressure plate 225, the seal plate 216 and the seal plate 216 are pushed down, the triangular block 216 is pushed back to the three-up by the driving belt 204, the three-up side of the shrinkage triangular block 216 is pushed up by the driving belt 204, the three-down shrinkage triangular block 216 is pushed up by the driving belt, the three-up shrinkage triangular block 216 is pushed by the driving belt, at this time, the pushing operation is pushed by the pushing operation of the driving belt is convenient for pushing out the pushing operation is convenient for pushing push operation of the pushing out, so as to push box 205 is convenient to push out.

As shown in fig. 12 and 13, the timing device includes a timing motor 302 fixedly mounted on the package feeding box 201, a main link 303 is rotatably mounted on the timing motor 302, an auxiliary link 304 is rotatably mounted on the main link 303, a moving post 306 is rotatably mounted on the auxiliary link 304, a moving frame 305 is slidably mounted on the fixed frame 301, a left sensing piece 307 and a right sensing piece 308 are fixedly mounted on the moving frame 305, and the moving post 306 slides in the fixed frame 301.

The timing motor 302 rotates at a certain speed to drive the main connecting rod 303 to rotate so as to drive the auxiliary connecting rod 304 to rotate, thereby driving the movable column 306 to slide in the fixed frame 301, when the movable column 306 contacts with the left sensing piece 307, the movable frame 305 is driven to slide left in the fixed frame 301, the left sensing piece 307 is pushed into the hole of the fixed frame 301, the right sensing piece 308 slides out of the hole of the fixed frame 301, the small material pump 209, the middle material pump 210 and the large material pump 211 start to act at the moment, the vibration motor 103 stops acting, when the timing motor 302 continues to rotate, the movable column 306 is driven to slide continuously in the fixed frame 301, when the movable column 306 contacts with the right sensing piece 308, the movable frame 305 is driven to slide right in the fixed frame 301, and the right sensing piece 308 is pushed into the hole of the fixed frame 301, at the moment, the left sensing piece 307 slides out of the hole of the fixed frame 301, at the moment, the small material pump 209, the middle material pump 210 and the large material pump 211 stop to act, and the vibration motor 103 starts to act, namely, when the vibration mechanism acts, the small material pump 209, the middle material pump 210 and the large material pump 205 stop the large material pump 211 and the activated material pump 211 do not shake out of the active material pump 211, and the active material pump 210 in the packing box can shake the device, and the active material pump 211 stop when the vibration mechanism is pumped in the small material pump 209 and the active material pump 205 and the active material pump box.

The invention discloses an active carbon particle screening and classifying labelling machine, which has the working principle that: a plurality of packing boxes 205 are placed on a push rod 215 at the bottom in a packing feeding box 201, activated carbon is placed in the feeding hopper 112 through a feeding hole at the top of the feeding hopper 112, holes are formed in the large-hole sieve 118, the medium-hole sieve 117 and the small-hole sieve 116, diameters of the holes become smaller from top to bottom, the vibration motor 103 rotates to drive the eccentric disc 104 to rotate, thereby driving the rotating connecting rod 105 to rotate, driving the shaking frame 106 to lift along the bottom drum 124, driving the bottom drum 124 to lift, driving the small-hole sieve drum 109, the medium-hole sieve drum 110 and the large-hole sieve drum 111 to lift, thereby realizing shaking sieving of the activated carbon on the large-hole sieve 118, the medium-hole sieve 117 and the small-hole sieve 116, larger activated carbon particles can be remained on the large-hole sieve 118, medium-size activated carbon particles can be remained on the medium-hole sieve 117, small-particle activated carbon particles can be remained on the small-hole sieve 116, and the small-sized activated carbon particles or activated carbon powder can fall into the bottom drum 124 from the small-hole sieve 116, and enter the bottom drum 124 through the bottom drum 124, thereby driving the bottom drum 124 to lift, thereby driving the small-drum 124 to lift, driving the small-hole sieve drum 109 and the large-sieve drum 110 to move from the bottom drum 106 when the fertilizer, and the shaking frame 102 can be removed from the bottom drum 106, the shaking frame is driven by the shaking frame 106, and the large-hole sieve drum 110 is driven to move, and the large-hole sieve drum 110 is driven, and the shaking sieving is realized, and the shaking sieving effect is realized, and the sieving is realized. The timing motor 302 rotates at a certain speed to drive the main connecting rod 303 to rotate so as to drive the auxiliary connecting rod 304 to rotate, thereby driving the movable column 306 to slide in the fixed frame 301, when the movable column 306 contacts with the left sensing piece 307, the movable frame 305 is driven to slide leftwards in the fixed frame 301, the left sensing piece 307 is pushed into the hole of the fixed frame 301, the right sensing piece 308 slides out of the hole of the fixed frame 301, at the moment, the small material pump 209, the middle material pump 210 and the large material pump 211 start to act, the vibration motor 103 stops acting, the small material pump 209 is started, small particle activated carbon on the small hole screen 116 is pumped into the corresponding filling box 202 through the small material outlet hole 113 and the small material feeding pipe 206, falls into the corresponding packing box 205, the middle material pump 210 is started, the middle particle activated carbon on the middle hole screen 117 is pumped into the corresponding filling box 202 through the middle material outlet hole 114 and the middle material feeding pipe 207, and falls into the corresponding packing box 205, the large material pump 211 is started to pump the large granular activated carbon on the large screen 118 to the corresponding filling box 202 through the large discharging hole 115 and the large material feeding pipe 208, the large granular activated carbon falls into the corresponding packing box 205, the packing box 205 in the filling box 202 is placed on the lower pressing disc 218, the lower pressing column 219 and the lower pressing rack 221 are driven to descend along with the continuous increase of the weight of the packing box 205, the lower pressing spring 220 is compressed, the lower pressing rack 221 firstly drives the external gear 222 to rotate, the label rack 224 is driven to ascend, the lifting rod 225 and the ink pad 226 are driven to ascend, the ink pad 226 slowly lifts the packing box 205 on the driving belt 204, namely, the packing box 205 on the driving belt 204 is lifted up after the printing of labels, the lower pressing rack 221 descends to drive the internal gear 223 to rotate, the transverse rack 227 is driven to slide along the sliding groove 2121, whereby the push column 228 pushes the shrinkage triangular block 216 and the bottom push rod 215 toward the push-out frame 212 so that the push spring 214 is compressed, when the push column 228 brings the shrinkage triangular block 216 into contact with the stopper 213, the push column 228 continues to advance, the shrinkage triangular block 216 slides inward along the bottom push rod 215 under the action of the stopper 213, the shrinkage spring 217 is compressed, and finally the shrinkage triangular block 216 enters the bottom push rod 215, at this time, the bottom push rod 215 under the package 205 is completely separated, and the push column 228 cannot continue to push the shrinkage triangular block 216, will pass through the gap under the stopper 213, at this time, the push spring 214 begins to rebound to drive the bottom push rod 215 to pop forward, thereby pushing the package 205 just dropped from above the bottom push rod 215, pushing the package 205 above the lower platen 218, and pushing the package 205 under the seal plate 226, at this time, the packing box 205 originally located in the filling box 202 reaches above the lower platen 218, the packing box 205 originally located above the lower platen 218 and filled with activated carbon is located below the ink pad sheet 226, the packing box 205 originally located below the ink pad sheet 226 and filled with activated carbon is pushed out to move forward along the driving belt 204, the driving belt 204 is rotatable relative to the support 203, so that the pushing operation of the packing box 205 is facilitated, since the packing box 205 above the lower platen 218 and filled with activated carbon is pushed out to become an empty packing box 205, the lower pressing spring 220 rebounds to drive the lower pressing column 219, the lower platen 218 and the lower pressing rack 221 to rise, so that the external gear 222 and the internal gear 223 are reversed, thereby mobilizing the lifting rod 225 and the ink pad 226 to descend, and the packing box 205 just reaching below the ink pad sheet 226 is printed with labels, and simultaneously the pushing column 228 and the transverse tooth bar 227 return to the initial position, the contact with the shrinkage triangular block 216 will push the shrinkage triangular block 216 to slide into the bottom push rod 215, and squeeze the shrinkage spring 217, when the push column 228 passes through the shrinkage triangular block 216, the shrinkage spring 217 rebounds to drive the shrinkage triangular block 216 to pop up, and the initial state is returned to be ready for the next packaging and label printing operation. When the timing motor 302 continues to rotate, the moving column 306 is driven to continuously slide in the fixing frame 301, when the moving column 306 contacts with the right sensing piece 308, the moving frame 305 is driven to slide rightwards in the fixing frame 301, the right sensing piece 308 is pushed into a hole of the fixing frame 301, at the moment, the left sensing piece 307 slides out of the hole of the fixing frame 301, at the moment, the small material pump 209, the medium material pump 210 and the large material pump 211 stop acting, the vibration motor 103 starts to act, and the next active carbon screening action is continued, so that the active carbon particles are continuously screened, packaged and labeled.

Claims (8)

1. The utility model provides a label machine is categorized in screening of active carbon granule, includes the sieving mechanism of placing on ground, its characterized in that: the screening device comprises a fertilizer base (101) and a small discharging hole (113), wherein the fertilizer base (101) is placed on the ground, the screening device is used for screening activated carbon according to the size of particles, a packing device is arranged on the screening device, the packing device comprises a packing feeding box (201) and a small material feeding pipe (206), the packing feeding box (201) is placed on the ground, the small material feeding pipe (206) is fixedly arranged with the small discharging hole (113), the packing device is used for packing and labeling the screened activated carbon, a timing device is arranged on the packing device, the timing device comprises a fixing frame (301), the fixing frame (301) is fixedly arranged on the packing box (201), and the timing device is used for timing and switching the screening action and the packing action;

the screening device comprises a discharge hole (102) fixedly arranged on the side surface of a fertilizer base (101), a bottom hose (121) is fixedly arranged on the fertilizer base (101), a bottom barrel (124) is fixedly arranged at the other end of the bottom hose (121), a bottom sliding column (122) is fixedly arranged on the bottom barrel (124), a vibrating spring (123) is arranged between the bottom barrel (124) and the fertilizer base (101), a small screening barrel (109) is fixedly arranged on the bottom barrel (124), a middle screening barrel (110) is fixedly arranged on the small screening barrel (109), a large screening barrel (111) is fixedly arranged on the middle screening barrel (110), a feed hopper (112) is fixedly arranged on the large screening barrel (111), the small screening barrel (109), the middle screening barrel (110), the large screening barrel (111) and the feed hopper (112) are fixedly arranged together through long bolts (108) and nuts (107), a large pore screen (118) is fixedly arranged in the large screening barrel (111), a middle pore screen (117) is fixedly arranged in the middle screening barrel (109), a large screening barrel (111) is fixedly arranged in the middle screening barrel, a large screening barrel (116) is fixedly arranged in the middle screening barrel (116), a discharge hole (116) is fixedly arranged on the side surface of the large screening barrel (111), the outside of the bottom cylinder (124) is provided with a shaking mechanism, and unidirectional mechanisms are arranged in the large discharge hole (115), the middle discharge hole (114) and the small discharge hole (113);

the shaking mechanism comprises a shaking frame (106) which is slidably arranged outside a bottom cylinder (124), a shaking motor (103) is arranged on the ground, an eccentric disc (104) is fixedly arranged on a motor shaft of the shaking motor (103), a rotating connecting rod (105) is rotatably arranged on the eccentric disc (104), and the rotating connecting rod (105) and the shaking frame (106) are rotatably arranged.

2. The activated carbon particle screening and classifying labeler according to claim 1, wherein: the one-way mechanism comprises a sliding plug (119) which is slidably arranged in a large discharging hole (115), a middle discharging hole (114) and a small discharging hole (113), a certain gap is formed between the outer wall of the sliding plug (119) and the inner walls of the large discharging hole (115), the middle discharging hole (114) and the small discharging hole (113), a compression spring (120) is arranged between the sliding plug (119) and the large discharging hole (115), the middle discharging hole (114) and the small discharging hole (113), and an outlet plate (125) is arranged on the large discharging hole (115), the middle discharging hole (114) and the small discharging hole (113).

3. The activated carbon particle screening and classifying labeler according to claim 1, wherein: the diameters of the holes on the large-hole screen (118), the medium-hole screen (117) and the small-hole screen (116) are from large to small.

4. The activated carbon particle screening and classifying labeler according to claim 1, wherein: the packing device comprises a packing box (202) fixedly mounted on a packing feeding box (201), a small material pump (209), a middle material pump (210) and a large material pump (211) are fixedly mounted on the packing box (202), a small material feeding pipe (206) is fixedly mounted on the small material pump (209), a middle material feeding pipe (207) is fixedly mounted on the middle material pump (210), a large material feeding pipe (208) is fixedly mounted on the large material pump (211), the middle material feeding pipe (207) and the middle discharging hole (114) are fixedly mounted, a support (203) is arranged beside the packing box (202), a transmission belt (204) is rotatably mounted on the support (203), a pushing frame (212) is fixedly mounted on the packing box (201), a sliding groove (2121) is formed in the pushing frame (212), a packing box (205) is arranged in the packing feeding box (201), a weighing mechanism and a label mechanism are arranged on the packing box (202), and a pushing mechanism is arranged on the packing box (201).

5. The activated carbon particle screening and classifying labeler according to claim 4, wherein: the weighing mechanism comprises a pressing column (219) which is slidably arranged at the bottom of the filling box (202), a pressing disc (218) is fixedly arranged on the pressing column (219), a packing box (205) is arranged on the pressing disc (218), a pressing spring (220) is arranged between the pressing disc (218) and the bottom of the filling box (202), a pressing rack (221) is fixedly arranged below the pressing column (219), a bottom gear frame (229) is fixedly arranged at the bottom of the filling box (202), an external gear (222) is rotatably arranged on the bottom gear frame (229), an internal gear (223) is fixedly arranged on the external gear (222), and the external gear (222) is meshed with the pressing rack (221).

6. The activated carbon particle screening and classifying labeler according to claim 5, wherein: the label mechanism comprises a lifting rod (225) which is slidably arranged on the filling box (202), an ink pad piece (226) is fixedly arranged on the lifting rod (225), a label rack (224) is fixedly arranged at the bottom of the lifting rod (225), and the label rack (224) is meshed with the external gear (222).

7. The activated carbon particle screening and classifying labeler according to claim 5, wherein: the pushing mechanism comprises a transverse rack (227) which is slidably arranged at the bottom of the packaging feeding box (201), the transverse rack (227) is meshed with an inner gear (223), a pushing column (228) is fixedly arranged on the transverse rack (227), the pushing column (228) slides in a sliding groove (2121), a blocking block (213) is fixedly arranged on a pushing frame (212), a bottom push rod (215) is slidably arranged in the packaging feeding box (201), a pushing spring (214) is arranged between the bottom push rod (215) and the pushing frame (212), a shrinkage triangular block (216) is slidably arranged in the bottom push rod (215), and a shrinkage spring (217) is arranged between the shrinkage triangular block (216) and the bottom push rod (215).

8. The activated carbon particle screening and classifying labeler according to claim 1, wherein: the timing device comprises a timing motor (302) fixedly arranged on a packaging feeding box (201), a main connecting rod (303) is rotatably arranged on the timing motor (302), an auxiliary connecting rod (304) is rotatably arranged on the main connecting rod (303), a movable column (306) is rotatably arranged on the auxiliary connecting rod (304), a movable frame (305) is slidably arranged on a fixed frame (301), a left sensing piece (307) and a right sensing piece (308) are fixedly arranged on the movable frame (305), and the movable column (306) slides in the fixed frame (301).