阅读说明：本技术 一种活性炭颗粒打包装袋设备 (Activated carbon particle packing and bagging equipment ) 是由 段洋洋 于 2021-07-06 设计创作，主要内容包括：本发明涉及一种打包装袋设备,尤其涉及一种活性炭颗粒打包装袋设备。本发明的目的是提供一种工作效率较高且能够进行定量包装的活性炭颗粒打包装袋设备。本发明提供了这样一种活性炭颗粒打包装袋设备,包括有底座和壳体,壳体两侧下部均对称设有底座；导料口,壳体内顶部一侧设有导料口；上料机构,壳体上部设有上料机构；支撑机构,壳体内侧设有支撑机构；热接机构,壳体内侧设有热接机构,热接机构位于支撑机构下侧；裁剪机构,壳体内侧设有裁剪机构。本发明通过上料机构、支撑机构、热接机构、裁剪机构和驱动机构的配合,能够对活性炭颗粒进行定量上料包装,并对无纺布进行封边、封底和切割下料,工作效率较高。(The invention relates to packaging and bagging equipment, in particular to active carbon particle packaging and bagging equipment. The invention aims to provide activated carbon particle packaging and bagging equipment which is high in working efficiency and capable of quantitatively packaging. The invention provides active carbon particle packaging and bagging equipment which comprises a base and a shell, wherein the bases are symmetrically arranged at the lower parts of two sides of the shell; a material guide port is arranged on one side of the top in the shell; the upper part of the shell is provided with a feeding mechanism; the supporting mechanism is arranged on the inner side of the shell; the thermal connection mechanism is arranged on the inner side of the shell and is positioned on the lower side of the supporting mechanism; the cutting mechanism is arranged on the inner side of the shell. According to the invention, through the matching of the feeding mechanism, the supporting mechanism, the hot connection mechanism, the cutting mechanism and the driving mechanism, the quantitative feeding and packaging of the activated carbon particles can be carried out, and the edge sealing, bottom sealing, cutting and blanking of the non-woven fabric can be carried out, so that the working efficiency is higher.)

1. The utility model provides an active carbon granule baling bagging-off equipment, characterized by, including:

the device comprises a base (1) and a shell (2), wherein the bases (1) are symmetrically arranged at the lower parts of two sides of the shell (2);

a material guide port (3), wherein the material guide port (3) is arranged on one side of the inner top of the shell (2);

the feeding mechanism (4) is arranged at the upper part of the shell (2);

the supporting mechanism (5) is arranged on the inner side of the shell (2);

the heat connection mechanism (6) is arranged on the inner side of the shell (2), and the heat connection mechanism (6) is positioned on the lower side of the supporting mechanism (5);

the cutting mechanism (7) is arranged on the inner side of the shell (2);

the driving mechanism (8) is arranged on the inner side of the shell (2), and the driving mechanism (8) is positioned on the outer side of the cutting mechanism (7).

2. The activated carbon particle packing and bagging device as claimed in claim 1, wherein the feeding mechanism (4) comprises:

the upper parts of the two sides of the shell (2) are provided with electric push rods (41);

a first push rod (42) is arranged between one sides of the telescopic rods of the electric push rods (41);

the feeding rack (43) is arranged at the upper part of the left side of the first push rod (42);

the feeding device comprises a feeding groove (44), wherein the feeding groove (44) is formed in one side of the top of the shell (2), the feeding groove (44) is communicated with a material guide opening (3), and a feeding frame (43) slides in the feeding groove (44).

3. The activated carbon particle bagging apparatus as claimed in claim 2, wherein the supporting mechanism (5) comprises:

the first mounting rack (51) is symmetrically arranged on one side inside the shell (2);

the upper part of the first mounting frame (51) is provided with the rotating frame (52) in a rotating mode;

the middle of the upper part of the inner side of the shell (2) is symmetrically provided with a second mounting rack (53);

the clamping rods (54) are arranged in the second mounting rack (53);

the return springs (56) are connected between the clamping rod (54) and the second mounting rack (53);

the upper parts of the second push rods (55) and the rotating frame (52) are both provided with the second push rods (55) in a sliding mode, and one sides of the second push rods (55) are symmetrically connected with limiting blocks.

4. The activated carbon particle bagging apparatus as claimed in claim 3, wherein the thermal bonding mechanism (6) comprises:

the guide rails (61) are symmetrically arranged on the inner side of the shell (2);

the top of each guide rail (61) is provided with a first guide rod (62);

the tops of the guide rails (61) are symmetrically and slidably provided with third mounting frames (64), and the third mounting frames (64) are slidably connected with the first guide rods (62);

the first springs (63) are symmetrically wound on the first guide rods (62), and two ends of each first spring (63) are respectively connected with the third mounting frame (64) and the first guide rods (62);

the upper parts of the extrusion rollers (65) and the third mounting rack (64) are respectively provided with the extrusion rollers (65) in a rotating mode.

5. The activated carbon particle packing and bagging device as claimed in claim 4, wherein the cutting mechanism (7) comprises:

the inner side of the shell (2) is symmetrically provided with second guide rods (71), and the second guide rods (71) are positioned on the lower side of the guide rail (61);

the first sliding frame (72) is symmetrically and slidably arranged on the first sliding frame (72) and the second guide rod (71);

the clamping rods (73) are arranged between the inner sides of the two first sliding frames (72) which are transversely arranged on the same side;

and the second spring (74) is wound on the second guide rod (71), and two ends of the second spring (74) are respectively connected with the two first sliding frames (72) on the same side.

6. The activated carbon particle bagging apparatus as claimed in claim 5, wherein the driving mechanism (8) comprises:

the lower part of the inner side of the shell (2) is symmetrically provided with a fourth mounting rack (81);

the inner sides of the second sliding frames (82) and the fourth mounting frames (81) are both provided with the second sliding frames (82) in a sliding manner;

the third springs (83) are symmetrically wound on the second sliding frame (82), and two ends of each third spring (83) are respectively connected with the second sliding frame (82) and the fourth mounting frame (81);

the upper parts of the second sliding frames (82) are provided with motors (84);

the output shafts of the motors (84) are provided with driving wheels (85), and the driving wheels (85) are matched with the extrusion rollers (65);

the lower parts of the first limiting rod (86) and the second sliding frame (82) are respectively provided with a first limiting rod (86);

limiting plates (87), the bottoms of the two first sliding frames (72) are provided with the limiting plates (87), and the limiting plates (87) are matched with the first limiting rods (86).

7. The activated carbon particle packing and bagging device as claimed in claim 6, further comprising a folding mechanism (9), wherein the folding mechanism (9) comprises:

the middle of the bottom in the shell (2) is provided with a slide rail (91);

the middle part of the outer side of each clamping rod (73) is provided with a first connecting rod (92);

the upper part of one side of the first connecting rod (92) is rotatably provided with a first pull rod (93);

the second connecting rod (94) is arranged on one side of the sliding rail (91) in a sliding mode, and the first pull rods (93) are rotatably connected with the second connecting rod (94);

a second pull rod (95), wherein one side of the second connecting rod (94) is provided with the second pull rod (95), and the second pull rod (95) is connected with the shell (2) in a sliding manner;

the middle of the bottom of the first push rod (42) is provided with a push rod (96), and the push rod (96) is matched with the second pull rod (95).

8. The activated carbon particle packing and bagging device as claimed in claim 7, further comprising an opening mechanism (10), wherein the opening mechanism (10) comprises:

the upper parts of the inner sides of the rotating frames (52) are respectively provided with a connecting block (1001);

a third sliding frame (1002), wherein the inner side of the shell (2) is provided with the third sliding frame (1002) in a sliding manner;

the middle parts of the sliding blocks (1003) and the third sliding frame (1002) are symmetrically and slidably provided with the sliding blocks (1003);

the third connecting rod (1004) is rotatably arranged between the sliding block (1003) and the connecting block (1001) on the same side;

a fourth spring (1005), wherein the fourth spring (1005) is arranged between the inner sides of the sliding blocks (1003);

a third push rod (1006), the middle of the top of the third sliding frame (1002) is provided with the third push rod (1006), and the third push rod (1006) is connected with the shell (2) in a sliding way;

second gag lever post (1007), third mounting bracket (64) top of one side all is equipped with second gag lever post (1007), and second gag lever post (1007) cooperates with slider (1003).

Technical Field

The invention relates to packaging and bagging equipment, in particular to active carbon particle packaging and bagging equipment.

Background

The activated carbon particles have the characteristics of developed pore structure, good adsorption performance, high mechanical strength, easy repeated regeneration, low cost and the like, and are widely used for the purification of toxic gases, the treatment of waste gases, the purification treatment of industrial and domestic water and the like.

Activated carbon particle is after producing, need artifically encapsulate it respectively in the non-woven fabrics, generally it is artifical carries out back cover and closure with heating utensil to the non-woven fabrics, then pack activated carbon particle into the non-woven fabrics, carry out the capping operation to the non-woven fabrics again, the operation process is comparatively loaded down with trivial details, need consume more time and physical power, lead to efficiency not high, and the security is not high, be injured easily when the heat-seal to the non-woven fabrics, in addition, the unable ration packing that accomplishes of packing activated carbon particle, therefore, the activated carbon particle packing sack filling plant that has designed a work efficiency is higher and can carry out the ration packing.

Disclosure of Invention

In order to overcome the defects that the manual packing efficiency of the activated carbon particles is low and the quantitative packing cannot be realized, the invention aims to provide the activated carbon particle packing and bagging equipment which has higher working efficiency and can carry out the quantitative packing.

The technical scheme is as follows: the utility model provides an active carbon granule packing sack filling plant, including:

the device comprises a base and a shell, wherein the bases are symmetrically arranged at the lower parts of two sides of the shell;

a material guide port is arranged on one side of the top in the shell;

the upper part of the shell is provided with a feeding mechanism;

the supporting mechanism is arranged on the inner side of the shell;

the thermal connection mechanism is arranged on the inner side of the shell and is positioned on the lower side of the supporting mechanism;

the cutting mechanism is arranged on the inner side of the shell;

and the driving mechanism is arranged on the inner side of the shell and is positioned on the outer side of the cutting mechanism.

As the improvement of above-mentioned scheme, feed mechanism includes:

the upper parts of the two sides of the shell are provided with electric push rods;

the first push rod is arranged between one sides of the telescopic rods of the electric push rods;

the upper part of the left side of the first push rod is provided with a feeding frame;

the silo, casing top one side is equipped with the silo, and the silo communicates with the guide opening, and the pay-off frame slides in the silo.

As an improvement of the above aspect, the support mechanism includes:

the first mounting rack is symmetrically arranged on one side inside the shell;

the upper part of the first mounting frame is rotatably provided with a rotating frame;

the middle of the upper part of the inner side of the shell is symmetrically provided with a second mounting rack;

the clamping rods are arranged in the second mounting rack;

the return springs are connected between the clamping rod and the second mounting frame;

the upper parts of the second push rods and the rotating frame are all provided with second push rods in a sliding mode, and one sides of the second push rods are symmetrically connected with limiting blocks.

As an improvement of the above aspect, the thermal connection mechanism includes:

the guide rails are symmetrically arranged on the inner side of the shell;

the top of each guide rail is provided with a first guide rod;

the top of each guide rail is symmetrically and slidably provided with a third mounting frame, and the third mounting frames are slidably connected with the first guide rods;

the first springs are symmetrically wound on the first guide rods, and two ends of each first spring are connected with the third mounting frame and the first guide rod respectively;

and the extrusion rollers are arranged on the upper parts of the third mounting frames in a rotating mode.

As an improvement of the scheme, the cutting mechanism comprises:

the inner side of the shell is symmetrically provided with second guide rods which are positioned at the lower sides of the guide rails;

the first sliding frames are symmetrically and slidably arranged on the second guide rods;

the clamping rods are arranged between the inner sides of the two first sliding frames on the same transverse side;

and the second spring is wound on the second guide rod, and two ends of the second spring are respectively connected with the two first sliding frames at the same side.

As an improvement of the above aspect, the drive mechanism includes:

the lower part of the inner side of the shell is symmetrically provided with a fourth mounting rack;

the inner sides of the fourth mounting frames are both provided with a second sliding frame in a sliding manner;

the second sliding frame is symmetrically wound with a second spring, and two ends of the second spring are connected with the second sliding frame and the fourth mounting frame respectively;

the upper parts of the second sliding frames are provided with motors;

the output shafts of the motors are provided with driving wheels which are matched with the extrusion rollers;

the lower parts of the first limiting rod and the second sliding frame are provided with first limiting rods;

limiting plates are arranged at the bottoms of the two first sliding frames and are matched with the first limiting rods.

As an improvement of the scheme, the folding device further comprises a folding mechanism, and the folding mechanism comprises:

the middle of the bottom in the shell is provided with a slide rail;

the middle parts of the outer sides of the clamping rods are provided with first connecting rods;

the upper part of one side of the first connecting rod is rotatably provided with a first pull rod;

the second connecting rod is arranged on one side of the sliding rail in a sliding mode, and the first pull rods are rotatably connected with the second connecting rod;

a second pull rod is arranged on one side of the second connecting rod and is connected with the shell in a sliding manner;

the middle of the bottom of the first push rod is provided with a push rod, and the push rod is matched with the second pull rod.

As the improvement of the proposal, the utility model also comprises an opening mechanism, and the opening mechanism comprises:

the upper part of the inner side of the rotating frame is provided with a connecting block;

the third sliding frame is arranged in the shell in a sliding mode;

the middle part of the third sliding frame is symmetrically and slidably provided with a sliding block;

the third connecting rods are rotatably arranged between the sliding blocks and the connecting blocks on the same side;

a fourth spring is arranged between the inner sides of the sliding blocks;

a third push rod is arranged in the middle of the top of the third sliding frame and is connected with the shell in a sliding manner;

and the top of the third mounting frame on one side of the second limiting rod is provided with the second limiting rod, and the second limiting rod is matched with the sliding block.

The invention has the following advantages: 1. according to the invention, through the matching of the feeding mechanism, the supporting mechanism, the hot connection mechanism, the cutting mechanism and the driving mechanism, the quantitative feeding and packaging of the activated carbon particles can be carried out, and the edge sealing, bottom sealing, cutting and blanking of the non-woven fabric can be carried out, so that the working efficiency is higher.

2. According to the invention, the closing mechanism can automatically and intermittently push the pressure rod inwards, so that the packaging and blanking functions of the activated carbon particles are completed, manual operation is not required, and time and labor are saved.

3. According to the invention, through the opening mechanism, people can be assisted to sleeve the non-woven fabric on the rotating frame more quickly, and the position of the non-woven fabric is adjusted.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a partial perspective view of the present invention.

Fig. 3 is a schematic perspective view of the feeding mechanism and the supporting mechanism of the present invention.

Fig. 4 is a schematic partial perspective view of the supporting mechanism of the present invention.

Fig. 5 is a schematic perspective view of the thermal connection mechanism of the present invention.

Fig. 6 is a schematic perspective view of a portion of the thermal interface of the present invention.

Fig. 7 is a schematic perspective view of the cutting mechanism of the present invention.

Fig. 8 is a schematic perspective view of the driving mechanism of the present invention.

Fig. 9 is a schematic view of a first partial body structure of the driving mechanism of the present invention.

Fig. 10 is a schematic view of a second partial body structure of the driving mechanism of the present invention.

Fig. 11 is a schematic perspective view of the folding mechanism of the present invention.

Fig. 12 is a perspective view of the opening mechanism of the present invention.

Fig. 13 is a partial perspective view of the deployment mechanism of the present invention.

Number designation in the figures: 1: base, 2: a housing, 3: material guiding opening, 4: feed mechanism, 41: electric putter, 42: first push rod, 43: a feeding rack, 44: a trough, 5: support mechanism, 51: first mounting bracket, 52: rotating frame, 53: second mount, 54: jamming rod, 55: second push rod, 56: return spring, 6: thermal bonding mechanism, 61: guide rail, 62: first guide bar, 63: first spring, 64: third mounting bracket, 65: squeeze roller, 7: cutting mechanism, 71: second guide bar, 72: first carriage, 73: clamping rod, 74: second spring, 8: drive mechanism, 81: fourth mount, 82: second carriage, 83: third spring, 84: motor, 85: drive wheel, 86: first stopper rod, 87: limiting plate, 9: a folding mechanism, 91: slide rail, 92: first connecting rod, 93: first tie rod, 94: second connecting rod, 95: second tie rod, 96: ejector rod, 10: opening mechanism, 1001: connecting block, 1002: third carriage, 1003: slider, 1004: third connecting rod, 1005: fourth spring, 1006: third push rod, 1007: a second limiting rod.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings. It is only noted that the invention is intended to be limited to the specific forms set forth herein, including any reference to the drawings, as well as any other specific forms of embodiments of the invention.

Example 1

The utility model provides an active carbon granule packing sack filling plant, as shown in fig. 1-10, including base 1, casing 2, guide port 3, feed mechanism 4, supporting mechanism 5, hot joint mechanism 6, cutting mechanism 7 and actuating mechanism 8, the equal bilateral symmetry in both sides lower part is equipped with base 1 around casing 2, top left side is equipped with guide port 3 in casing 2, 2 upper portions of casing are equipped with feed mechanism 4, 2 inboard left parts of casing are equipped with supporting mechanism 5, 2 inboard left parts of casing are equipped with hot joint mechanism 6, hot joint mechanism 6 is located the 5 downside of supporting mechanism, 2 inboard left lower parts of casing are equipped with cutting mechanism 7, 2 inboard left lower parts of casing are equipped with actuating mechanism 8, actuating mechanism 8 is located the cutting mechanism 7 outside.

Feed mechanism 4 all is equipped with electric putter 41 around casing 2 on the left of both sides upper portion including electric putter 41, first push rod 42, pay-off frame 43 and silo 44, be equipped with first push rod 42 between electric putter 41's the telescopic link right side, first push rod 42 left side upper portion is equipped with pay-off frame 43, and 2 top left sides of casing are equipped with silo 44, and silo 44 and 3 intercommunications of guide mouth, pay-off frame 43 slide in silo 44.

Supporting mechanism 5 is including first mounting bracket 51, swivel mount 52, second mounting bracket 53, kelly 54, second push rod 55 and reset spring 56, the inside upper left side front and back symmetry of casing 2 is equipped with first mounting bracket 51, the equal rotary type in first mounting bracket 51 upper portion is equipped with swivel mount 52, the symmetry is equipped with second mounting bracket 53 around in the middle of the inboard upper portion of casing 2, all be equipped with kelly 54 in the second mounting bracket 53, all be connected with reset spring 56 between kelly 54 and the second mounting bracket 53, the equal slidingtype in swivel mount 52 upper portion is equipped with second push rod 55, second push rod 55 left side symmetric connection has the stopper, swivel mount 52 is located between two stoppers.

Hot mechanism 6 is including guide rail 61, first guide bar 62, first spring 63, third mounting bracket 64 and squeeze roller 65, 2 inboard left part bilateral symmetry of casing is equipped with guide rail 61, guide rail 61 top all is equipped with first guide bar 62, the equal fore-and-aft symmetry sliding type in guide rail 61 top is equipped with third mounting bracket 64, third mounting bracket 64 all with first guide bar 62 sliding type connection, the equal fore-and-aft symmetry is around having first spring 63 on first guide bar 62, the both ends of first spring 63 are connected with third mounting bracket 64 and first guide bar 62 respectively, the equal rotary type in third mounting bracket 64 upper portion is equipped with squeeze roller 65.

The cutting mechanism 7 comprises a second guide rod 71, a first sliding frame 72, a clamping rod 73 and a second spring 74, the left part of the inner side of the shell 2 is bilaterally symmetrical to the second guide rod 71, the second guide rod 71 is located on the lower side of the guide rail 61, the second guide rod 71 is provided with the first sliding frame 72 in a front-back symmetrical sliding mode, the clamping rod 73 is arranged between the inner sides of the two first sliding frames 72 on the same side transversely, the second guide rod 71 is wound with the second spring 74, and two ends of the second spring 74 are connected with the two first sliding frames 72 on the same side respectively.

Actuating mechanism 8 is including fourth mounting bracket 81, second carriage 82, third spring 83, motor 84, drive wheel 85, first gag lever post 86 and limiting plate 87, the preceding left side bilateral symmetry of casing 2 inboard lower part is equipped with fourth mounting bracket 81, the equal slidingtype of fourth mounting bracket 81 inboard is equipped with second carriage 82, the symmetry is around having third spring 83 around all on second carriage 82, the both ends of third spring 83 are connected with second carriage 82 and fourth mounting bracket 81 respectively, second carriage 82 upper portion all is equipped with motor 84, all be equipped with drive wheel 85 on the output shaft of motor 84, drive wheel 85 and extrusion roller 65 cooperation, second carriage 82 lower part all is equipped with first gag lever post 86, the first carriage 72 bottom of left front side and right rear side all is equipped with limiting plate 87, limiting plate 87 and the cooperation of first gag lever post 86.

When people need to pack and bag the activated carbon particles, the second push rod 55 is pushed rightwards, the second push rod 55 extrudes the clamping rod 54 to move rightwards, the reset spring 56 is compressed, then the rotating frame 52 can be rotated outwards to drive the second push rod 55 to rotate outwards, the second push rod 55 is separated from the clamping rod 54, the clamping rod 54 moves leftwards to reset under the action of the reset spring 56, then the people sleeve two rolls of non-woven fabrics on the second push rod 55, then the rotating frame 52 and the second push rod 55 rotate inwards to reset, so that the clamping rod 54 is contacted with the second push rod 55 and pushes the clamping rod to reset leftwards, at the moment, the non-woven fabrics are positioned between the rotating frame 52 and the second mounting frame 53, the clamping rod 54 clamps out the non-woven fabrics, when people need to replace the non-woven fabrics, the second push rod 55 is pushed rightwards again, two limit blocks on the left side of the second push rod 55 can prevent the non-woven fabrics from being separated from the rotating frame 52, then the third mounting frame 64 is pulled outwards, the first spring 63 is compressed to drive the squeezing rollers 65 to move outwards, then one end of the two rolls of non-woven fabric is pulled out, so that one end of the two rolls of non-woven fabric is attached to and penetrates between the four squeezing rollers 65, then the third mounting frame 64 is loosened, the first spring 63 is restored to the original state to drive the third mounting frame 64 and the squeezing rollers 65 to move inwards and reset, so that the squeezing rollers 65 clamp the left side and the right side of the two rolls of non-woven fabric, then one end of the two rolls of non-woven fabric is pulled downwards to drive the squeezing rollers 65 to rotate, the squeezing rollers 65 have a certain heating function and can seal the space between the left side and the right side of the two rolls of non-woven fabric, then one end of the two rolls of non-woven fabric penetrates between the clamping rods 73 and then pushes the clamping rods 73 inwards to drive the first sliding frame 72 to move inwards, the second spring 74 is compressed, and the clamping rods 73 also have a certain heating function, can carry out bottom sealing to one end of two rolls of non-woven fabrics, then loosen clamping bar 73, second spring 74 recovers the original state, drive clamping bar 73 and first carriage 72 to move and reset towards the outside, then butt joint the discharge port of the active carbon particle production equipment with silo 44, then start electric putter 41 and motor 84, the active carbon particle produced can drop into silo 44, motor 84 output shaft drives drive wheel 85 to rotate, control the telescopic link of electric putter 41 to shorten first, the telescopic link of electric putter 41 drives first push rod 42 and feeding rack 43 to move to the left, feeding rack 43 pushes the active carbon particle in silo 44 to the left, and block silo 44, make the active carbon particle produced no longer drop into silo 44, make the active carbon particle in silo 44 drop down to the non-woven fabrics through guide opening 3, carry out quantitative charging, then the non-woven fabric bag filled with the active carbon particle is pulled down, then the clamping rod 73 is pushed inwards, the second spring 74 is compressed, so that the non-woven fabric is capped, the non-woven fabric packaged next time is capped, the non-woven fabric bag packaged with the activated carbon particles is cut, meanwhile, the clamping rod 73 drives the first sliding frame 72 and the limiting plate 87 to move inwards, when the limiting plate 87 is in contact with the first limiting rod 86, the second sliding frame 82, the motor 84 and the driving wheel 85 are driven to move downwards, the third spring 83 is compressed, when the limiting plate 87 is separated from the first limiting rod 86, the third spring 83 is restored to the original state, the first limiting rod 86, the second sliding frame 82, the motor 84 and the driving wheel 85 are driven to move upwards to be restored, then the clamping rod 73 is released, the second spring 74 is restored to the original state, the clamping rod 73 is driven to move outwards to be restored, the clamping rod 73 drives the first sliding frame 72 and the limiting plate 87 to move outwards to be restored, when the limiting plate 87 is in contact with the first limiting rod 86, the first limiting rod 86, the second sliding frame 82, the motor 84 and the driving wheel 85 are driven to move upwards, the third spring 83 is stretched, the driving wheel 85 is in contact with the extrusion roller 65 to drive the extrusion roller 65 to rotate, the extrusion roller 65 transmits the non-woven fabric downwards and seals edges, when the limiting plate 87 is separated from the first limiting rod 86, the third spring 83 restores to the original state to drive the first limiting rod 86, the second sliding frame 82, the motor 84 and the driving wheel 85 to move downwards and reset, at the moment, the extension rod of the electric push rod 41 is controlled to extend, the extension rod of the electric push rod 41 drives the first push rod 42 and the feeding frame 43 to move rightwards and reset, so that the feeding frame 43 does not block the trough 44 any more, the produced activated carbon particles fall into the trough 44 again, the device operates repeatedly, and when people push the clamping rod 73 once inwards, the packaged activated carbon particles can be capped, and the non-woven fabric packaged next time is capped, and cutting and blanking the non-woven cloth bag packaged with the activated carbon particles, manually collecting the non-woven cloth bag packaged with the activated carbon particles, and closing the electric push rod 41 and the motor 84 after all the activated carbon particles are packaged.

Example 2

Based on embodiment 1, as shown in fig. 2, 11, 12 and 13, the folding device 9 further includes a folding mechanism 9, the folding mechanism 9 includes a sliding rail 91, a first connecting rod 92, a first pulling rod 93, a second connecting rod 94, a second pulling rod 95 and a top rod 96, the sliding rail 91 is disposed in the middle of the right side of the bottom in the housing 2, the first connecting rod 92 is disposed in the middle of the outer side of the clamping rod 73, the first pulling rod 93 is rotatably disposed on the upper portion of the right side of the first connecting rod 92, the second connecting rod 94 is slidably disposed on the left side of the sliding rail 91, the first pulling rod 93 is rotatably connected to the second connecting rod 94, the second pulling rod 95 is disposed on the right side of the second connecting rod 94, the second pulling rod 95 is slidably connected to the housing 2, the top rod 96 is disposed in the middle of the bottom of the first pushing rod 42, and the top rod 96 is matched with the second pulling rod 95.

When the first push rod 42 moves rightwards, the push rod 96 is driven to move rightwards, when the push rod 96 contacts with the second pull rod 95, the second pull rod 95 and the second connecting rod 94 are driven to move rightwards, the second connecting rod 94 drives the first connecting rod 92 and the clamping rod 73 to move inwards through the first pull rod 93, the second spring 74 is compressed, when the first push rod 42 moves leftwards, the push rod 96 is driven to move leftwards, the push rod 96 is separated from the second pull rod 95, the second spring 74 recovers the original state, the first connecting rod 92 and the clamping rod 73 are driven to move outwards to reset, the first connecting rod 92 drives the second pull rod 95 and the second connecting rod 94 to move leftwards to reset through the first pull rod 93, so that the packaging function of the activated carbon particles can be automatically completed, and the time and labor are saved.

Still including opening mechanism 10, opening mechanism 10 is including connecting block 1001, third carriage 1002, slider 1003, third connecting rod 1004, fourth spring 1005, third push rod 1006 and second gag lever post 1007, revolving rack 52 inboard upper portion all is equipped with connecting block 1001, 2 inboard upper left portion slidingtypes of casing are equipped with third carriage 1002, third carriage 1002 middle part front and back symmetry slidingtype is equipped with slider 1003, equal rotary type is equipped with third connecting rod 1004 between slider 1003 and the connecting block 1001 of homonymy, be equipped with fourth spring 1005 between the slider 1003 inboard, be equipped with third push rod 1006 in the middle of third carriage 1002 top, third push rod 1006 and casing 2 slidingtype are connected, left third mounting bracket 64 top all is equipped with second gag lever post 1007, second gag lever post 1007 and slider 1003 cooperation.

When people need to feed the non-woven fabric, the second push rod 55 is pushed rightwards, the second push rod 55 extrudes the clamping rod 54 to move rightwards, so that the clamping rod 54 loosens the rotating frame 52, then the third push rod 1006 is pulled downwards to drive the third sliding frame 1002 and the sliding block 1003 to move downwards, the sliding block 1003 drives the rotating frame 52 to rotate a little outwards through the third connecting rod 1004, then people manually continue to rotate the rotating frame 52 outwards to drive the sliding block 1003 to move outwards, the fourth spring 1005 is stretched to play a role in buffering, the sliding block 1003 drives the second limiting rod 1007, the left third mounting frame 64 and the left extrusion roller 65 to move outwards, therefore, the non-woven fabric is more convenient for people to sleeve on the rotating frame 52, one end of the non-woven fabric is pulled to pass between the extrusion rollers 65, then the rotating frame 52 is loosened, the fourth spring 1005 is recovered to be original, the sliding block 1003 is driven to move inwards to be restored, and the rotating frame 52 is driven to rotate inwards, and then the third push rod 1006 is pulled upwards to drive the third sliding frame 1002 and the sliding block 1003 to move upwards for resetting, the sliding block 1003 drives the rotating frame 52 to rotate inwards through the third connecting rod 1004 for completely resetting, so that the rotating frame 52 is clamped by the clamping rod 54 again, and the clamping rod 54 can push the second push rod 55 to move leftwards for resetting.

The above-mentioned embodiments are merely preferred embodiments of the present invention, which are not intended to limit the scope of the present invention, and therefore, all equivalent changes made by the contents of the claims of the present invention should be included in the claims of the present invention.