CN112794260A - Full-automatic sealing machine and method for carbon powder bottle - Google Patents

Abstract

The invention discloses a full-automatic sealing machine and a method for a carbon powder bottle, and the full-automatic sealing machine structurally comprises a bottom transmission box, a control box and a sealing box, wherein the bottom transmission box is provided with a limiting rod fixer, a conveying belt and a limiting rod; the sealing box is provided with a height adjuster, an induction area, a sealing groove, an aluminum foil tightener, an aluminum foil conveying pipe, a forward rotator and a reverse rotator, and the sealing box has the beneficial effects that: can aim at the carbon powder bottle bottleneck through aluminium foil alignment head with aluminium foil, the effect of rethread forward direction circulator and reverse direction circulator drives the carbon powder bottle and rotates, drives forward briquetting and reverse briquetting at the pivoted in-process and closely presses aluminium foil and paste on the bottleneck, and rethread high temperature seals rapidly, has guaranteed the gas tightness that seals, can not make the carbon dust leak from the bottleneck.

Description

Full-automatic sealing machine and method for carbon powder bottle

The invention relates to a divisional application of a full-automatic carbon powder bottle sealing machine, which has an application date of 2018, 11 and 27 and an application number of CN 201811423401.2.

Technical Field

The invention relates to the field of ink boxes, in particular to a full-automatic sealing machine and method for a carbon powder bottle.

Background

With the development of printer technology, the production quality and design technology of related accessories are improved, wherein the ink box has various requirements in the production process, for example, the height of the ink box, the sealing of the ink box and the size and specification of the ink box have different requirements, and the ink box has different sealing designs according to different bottle openings when being sealed.

Aiming at the existing carbon powder bottle sealing machine, a relative scheme is made aiming at the following problems:

the existing carbon powder bottle sealing technology is characterized in that a pure copper wire winding is electrified through high-frequency current, then a magnetic induction wire penetrates through a sealing aluminum foil material, and the sealing is performed rapidly at a high temperature state, but in the sealing process, the tightness of the aluminum foil to a carbon powder bottle opening is insufficient, so that the airtightness is reduced when the sealing is performed, and the leakage of carbon powder is caused.

Disclosure of Invention

The invention mainly aims to overcome the defects of the prior art and provides a full-automatic sealing machine and a method for a carbon powder bottle.

The invention is realized by adopting the following technical scheme: a full-automatic sealing machine and a method for a carbon powder bottle structurally comprise a bottom transmission box, a control box and a sealing box, wherein the bottom transmission box is connected below the sealing box through a bolt; the seal box is equipped with altitude controller, induction zone, seal groove, the inseparable ware of aluminium foil, aluminium foil conveyer pipe, forward direction rotator, reverse direction rotator, altitude controller passes through bolted connection in the bottom transmission case back, the induction zone passes through bolted connection in the seal box upper surface, the seal groove inlays locates the seal box bottom portion, the inseparable ware of aluminium foil inlays and locates inside the aluminium foil conveyer pipe, the aluminium foil conveyer pipe inlays and locates inside the seal groove, forward direction rotator and reverse direction rotator distribute respectively on the seal groove inner wall.

As an optimization, the aluminum foil tightener is provided with a pressing plate, two pressing rods, a return spring and two aluminum foil alignment heads, wherein the pressing plate is vertically welded between the pressing rods, the pressing rods are embedded on the inner wall of the aluminum foil conveying pipe, the return spring is vertically welded between the pressing rods and the sealing box, the aluminum foil alignment heads are vertically welded below the pressing plate, the pressing rods are made of metal materials, the two pressing rods are symmetrically distributed on two sides of the pressing plate, and the two return springs are arranged.

As optimization, the aluminum foil alignment head is provided with a movable groove, a rotating plate, steel balls, a steel ball magnetic seat, magnetic blocks, an avoiding groove and an aluminum foil, the movable groove is embedded inside the aluminum foil alignment head, the rotating plate is connected inside the movable groove through clearance fit, the steel balls are embedded inside the movable groove at equal intervals, the steel ball magnetic seat is uniformly distributed inside the movable groove, the magnetic blocks are embedded on the lower surface of the rotating plate, the avoiding groove is welded below the movable groove, the aluminum foil is connected below the magnetic blocks through magnetism, the movable groove is of a circular structure, the movable groove is used for assisting the rotating plate to rotate, the steel balls are a plurality of steel balls, the steel balls are connected on the steel ball magnetic seat through magnetism, the steel ball magnetic seat is of a groove shape, the magnetic blocks are of a fan-shaped structure, and the avoiding groove is made of plastics.

Preferably, the aluminum foil conveying pipe is provided with a sliding groove, the sliding groove is embedded in the inner wall of the aluminum foil conveying pipe, the aluminum foil conveying pipe is of a hollow circular tubular structure, and the number of the sliding grooves is two.

As the optimization, the forward direction circulator is equipped with forward direction pivot, forward direction connecting rod, forward direction briquetting, the forward direction pivot is connected on the enclosed slot inner wall through transition fit, the perpendicular welding of forward direction connecting rod is on the forward direction circulator, the perpendicular welding of forward direction briquetting is in forward direction connecting rod bottom, the forward direction connecting rod is the metal material, the forward direction connecting rod is U type structure, the forward direction briquetting is circular globular structure.

As optimization, the reverse rotator is equipped with reverse pivot, reverse connecting rod, reverse briquetting, reverse pivot is connected on the enclosed slot inner wall through transition fit, reverse connecting rod is vertical welded on the reverse rotator, reverse briquetting is vertical welded in reverse connecting rod bottom, reverse connecting rod is the metal material, reverse connecting rod is U type structure, reverse briquetting is circular globular structure.

Advantageous effects

The invention relates to a full-automatic sealing machine and a method for a carbon powder bottle, which are used for working and comprise the following steps:

the aluminum foil tightener is provided with the pressing plate, the pressing rod, the reset spring and the aluminum foil alignment head, when the carbon powder bottle enters the sealing groove, the pressing plate presses downwards, so that the pressing rod is driven to move downwards, the reset spring is elastically extruded, and the aluminum foil alignment head is driven to press downwards;

the positive rotator is provided with the positive rotating shaft, the positive connecting rod and the positive pressing block, the aluminum foil is adsorbed below the alignment head of the aluminum foil through magnetism, the positive rotator rotates anticlockwise when the aluminum foil is pressed downwards so as to drive the positive connecting rod and the positive pressing block to rotate anticlockwise, and when the positive pressing block passes through the aluminum foil and the upper part of the bottle opening, the aluminum foil is pressed and attached to the bottle opening through the positive pressing block and is driven to rotate anticlockwise on the bottle opening;

through being equipped with an aluminium foil alignment head, aluminium foil alignment head is equipped with movable groove, commentaries on classics board, steel ball magnetic base, magnetic path, dodge groove, aluminium foil, when aluminium foil rotated, because magnetic effect, and then drive the magnetic path and rotate, the magnetic path drives the commentaries on classics board under the magnetic coordination of steel ball and steel ball magnetic base when rotating to drive the magnetic path and change over to into dodge in the groove, through dodging the groove and keep apart the magnetism between aluminium foil and the magnetic path, paste through the pressure of forward briquetting and reverse briquetting this moment, make aluminium foil pressed down from aluminium foil alignment head, hug closely on the bottleneck, seal this moment again, then can guarantee the gas tightness that the carbon powder bottle sealed and excel in.

Compared with the prior art, the invention has the beneficial effects that: can aim at the carbon powder bottle bottleneck through aluminium foil alignment head with aluminium foil, the effect of rethread forward direction circulator and reverse direction circulator drives the carbon powder bottle and rotates, drives forward briquetting and reverse briquetting at the pivoted in-process and closely presses aluminium foil and paste on the bottleneck, and rethread high temperature seals rapidly, has guaranteed the gas tightness that seals, can not make the carbon dust leak from the bottleneck.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

fig. 1 is a schematic structural diagram of a full-automatic sealing machine and method for carbon powder bottles according to the present invention.

FIG. 2 is a schematic structural diagram of the aluminum foil conveying pipe of the present invention in a static state.

FIG. 3 is a schematic structural view of the aluminum foil conveying pipe of the present invention in a working state.

FIG. 4 is a schematic diagram of a vertical cross-sectional structure of an aluminum foil delivery tube according to the present invention.

FIG. 5 is an enlarged schematic view of the aluminum foil tightener of the present invention.

FIG. 6 is a schematic view of the internal structure of the aluminum foil alignment head of the present invention.

Fig. 7 is a schematic view of the internal structure of the evasion groove of the present invention.

Fig. 8 is a schematic cross-sectional view of an aluminum foil alignment head of the present invention.

Fig. 9 is a schematic structural view of the forward rotator of the present invention in a counterclockwise rotation state.

Fig. 10 is a schematic structural view of the counter rotator of the present invention in a clockwise rotation state.

In the figure: the device comprises a bottom transmission box 1, a control box 2, a sealing box 3, a position rod fixer 10, a conveying belt 11, a limiting rod 12, a height adjuster 30, a sensing area 31, a sealing groove 32, an aluminum foil tightener 33, an aluminum foil conveying pipe 34, a forward rotator 35, a reverse rotator 36, a pressing plate 330, a pressing rod 331, a return spring 332, an aluminum foil aligning head 333, a movable groove 3330, a rotating plate 3331, a steel ball 3332, a steel ball magnetic seat 3333, a magnetic block 3334, an avoiding groove 3335, an aluminum foil 3336, a sliding groove 340, a forward rotating shaft 350, a forward connecting rod 351, a forward pressing block 352, a reverse rotating shaft 360, a reverse connecting rod 361 and a reverse pressing block 362.

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. 1-10, the present invention provides a full-automatic sealing machine for carbon powder bottles and a method thereof: the structure of the device comprises a bottom transmission case 1, a control case 2 and a sealing case 3, wherein the bottom transmission case 1 is connected below the sealing case 3 through a bolt, the control case 2 is connected on the side surface of the bottom transmission case 1 through a bolt, the bottom transmission case 1 is provided with a limiting rod fixer 10, a conveying belt 11 and a limiting rod 12, the limiting rod fixer 10 is connected between the limiting rod 12 and the bottom transmission case 1 through a bolt, the conveying belt 11 is embedded on the upper surface of the bottom transmission case 1, and the limiting rod 12 is connected above the bottom transmission case 1 through a bolt; the sealing box 3 is provided with a height adjuster 30, a sensing area 31, a sealing groove 32, an aluminum foil tightener 33, an aluminum foil conveying pipe 34, a forward rotator 35 and a reverse rotator 36, the height adjuster 30 is connected to the back of the bottom transmission box 1 through bolts, the sensing area 31 is connected to the upper surface of the sealing box 3 through bolts, the sealing groove 32 is embedded at the bottom of the sealing box 3, the aluminum foil tightener 33 is embedded inside the aluminum foil conveying pipe 34, the aluminum foil conveying pipe 34 is embedded inside the sealing groove 32, the forward rotator 35 and the reverse rotator 36 are respectively distributed on the inner wall of the sealing groove 32, the aluminum foil tightener 33 is provided with a pressing plate 330, a pressing rod 331, a reset spring 332 and an aluminum foil aligning head 333, the pressing plate 330 is vertically welded between the pressing rods 331, the pressing rod 331 is embedded on the inner wall of the aluminum foil conveying pipe 34, the reset spring 332 is vertically welded between the pressing rod 331 and the sealing box 3, the aluminum foil aligning head 333 is vertically welded below the pressing plate 330, the return springs 332 are respectively connected to two ends of a pressing rod 331, the return springs 332 are used for driving the aluminum foil tightener 33 to move up and down, the aluminum foil aligning head 333 is provided with a movable groove 3330, a rotating plate 3331, steel balls 3332, a steel ball magnetic seat 3333, magnetic blocks 3334, an avoiding groove 3335 and an aluminum foil 3336, the movable groove 3330 is embedded inside the aluminum foil aligning head 333, the rotating plate 3331 is connected inside the movable groove 3330 through clearance fit, the steel balls 3332 are uniformly embedded inside the movable groove 3330 at equal intervals, the steel ball magnetic seats 3333 are uniformly distributed inside the movable groove 3330, the magnetic blocks 3334 are embedded on the lower surface of the rotating plate 3331, the avoiding groove 3335 is welded below the movable groove 3330, the aluminum foil 3336 is connected below the magnetic blocks 3334 through magnetism, the magnetic blocks 3334 are used for adsorbing the aluminum foil 3336, the avoiding groove 3335 is used for separating the magnetism between the aluminum foil 3334 and the magnetic blocks 3336, the aluminum foil conveying pipe 34 is provided with a sliding groove 340, the sliding groove 340 is embedded on the inner wall of the aluminum foil conveying pipe 34, the aluminum foil conveying pipe 34 is used for conveying aluminum foils 3336, the sliding groove 340 is used for assisting a pressing rod 331 to move up and down, the forward rotator 35 is provided with a forward rotating shaft 350, a forward connecting rod 351 and a forward pressing block 352, the forward rotating shaft 350 is connected to the inner wall of the sealing groove 32 in a transition fit manner, the forward connecting rod 351 is vertically welded on the forward rotator 35, the forward pressing block 352 is vertically welded at the bottom end of the forward connecting rod 351, the forward pressing block 352 is used for tightly pressing and pasting the aluminum foils 3336 and a bottle opening, the circular design of the forward pressing block 352 is used for preventing the aluminum foils 3336 from being scraped in the pressing and pasting process, the reverse rotator 36 is provided with a reverse rotating shaft 360, a reverse connecting rod 361 and a reverse pressing block 362, the reverse rotating shaft 360 is connected to the inner wall, the reverse connecting rod 361 is vertically welded on the reverse rotator 36, the reverse pressing block 362 is vertically welded at the bottom end of the reverse connecting rod 361, the reverse pressing block 362 is used for tightly pressing the aluminum foil 3336 against the bottle mouth, and the circular design of the reverse pressing block 362 is used for preventing the aluminum foil 3336 from being scraped in the pressing process.

When the carbon powder bottle is used, when the carbon powder bottle enters the sealing groove 32, the pressing plate 330 presses downwards to drive the pressing rod 331 to move downwards, so as to elastically extrude the return spring 332 and further drive the aluminum foil alignment head 333 to press downwards, the aluminum foil 3336 is adsorbed below the aluminum foil alignment head 333 through magnetism, when the aluminum foil 3336 presses downwards, the forward rotator 35 rotates anticlockwise to drive the forward connecting rod 351 and the forward pressing block 352 to rotate anticlockwise, when the forward pressing block 352 passes through the aluminum foil 3336 and the opening, the forward pressing block 352 presses the aluminum foil 3336 to be attached to the opening, and simultaneously drives the aluminum foil 3336 to rotate anticlockwise on the opening, and when the aluminum foil 3336 presses downwards, the reverse rotator 36 rotates clockwise to drive the reverse connecting rod 361 and the reverse pressing block 362 to rotate clockwise, when the reverse pressing block 362 passes through the aluminum foil 3336 and the opening, the aluminum foil 3336 is pressed and attached to the bottle opening through the reverse pressing block 362, the aluminum foil 3336 is driven to rotate clockwise on the bottle opening, when the aluminum foil 3336 rotates, the magnetic block 3334 is further driven to rotate due to the action of magnetism, the magnetic block 3334 drives the rotating plate 3331 to be matched with the magnetism of the steel ball 3332 and the steel ball magnetic seat 3333 when rotating, so that the magnetic block 3334 is driven to rotate into the avoiding groove 3335, the magnetism between the aluminum foil 3336 and the magnetic block 3334 is isolated through the avoiding groove 3335, at the moment, the aluminum foil 3336 is pressed down from the aluminum foil aligning head 333 through the pressing and attaching of the forward pressing block 352 and the reverse pressing block 362, the aluminum foil 3336 is attached to the bottle opening tightly, at the moment, the sealing is carried out, and the high-strength air tightness of the carbon powder bottle sealing can be.

Compared with the prior art, the invention has the technical progress that:

can aim at the carbon powder bottle bottleneck through aluminium foil alignment head with aluminium foil, the effect of rethread forward direction circulator and reverse direction circulator drives the carbon powder bottle and rotates, drives forward briquetting and reverse briquetting at the pivoted in-process and closely presses aluminium foil and paste on the bottleneck, and rethread high temperature seals rapidly, has guaranteed the gas tightness that seals, can not make the carbon dust leak from the bottleneck.

Although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that various changes in the embodiments and/or modifications of the invention can be made, and equivalents and modifications of some features of the invention can be made without departing from the spirit and scope of the invention.

Claims (3)

1. The utility model provides a full-automatic capper of carbon powder bottle which characterized in that: the structure of the device comprises a bottom transmission box (1), a control box (2) and a sealing box (3), wherein the bottom transmission box (1) is connected below the sealing box (3) through a bolt, and the control box (2) is connected on the side surface of the bottom transmission box (1) through a bolt;

bottom transmission case (1) is equipped with gag lever post fixer (10), conveyer belt (11), gag lever post (12), gag lever post fixer (10) pass through bolted connection between gag lever post (12) and bottom transmission case (1), conveyer belt (11) inlay and locate bottom transmission case (1) upper surface, gag lever post (12) pass through bolted connection in bottom transmission case (1) top.

2. The full-automatic capper of carbon powder bottle of claim 1 characterized in that: seal case (3) and be equipped with altitude controller (30), induction zone (31), seal groove (32), aluminium foil compacter (33), aluminium foil conveyer pipe (34), forward direction circulator (35), reverse rotator (36), altitude controller (30) are through bolted connection in bottom transmission case (1) the back, induction zone (31) are through bolted connection in seal case (3) upper surface, seal groove (32) inlay and are located seal case (3) bottom, aluminium foil compacter (33) are inlayed and are located inside aluminium foil conveyer pipe (34), aluminium foil conveyer pipe (34) are inlayed and are located seal groove (32) inside, forward direction circulator (35) and reverse rotator (36) distribute respectively on seal groove (32) inner wall, aluminium foil compacter (33) are equipped with clamp plate (330), depression bar (331), reset spring (332), The aluminum foil alignment head (333), the pressing plate (330) is vertically welded between the pressing rods (331), the pressing rods (331) are embedded on the inner wall of the aluminum foil conveying pipe (34), the return spring (332) is vertically welded between the pressing rods (331) and the sealing box (3), and the aluminum foil alignment head (333) is vertically welded below the pressing plate (330).

3. The full-automatic sealing machine and method for carbon powder bottles according to any one of claims 1-2, characterized in that:

when the carbon powder bottle is used, when the carbon powder bottle enters the sealing groove (32), the pressing plate (330) presses downwards to drive the pressing rod (331) to move downwards, so that the return spring (332) is elastically extruded, the aluminum foil alignment head (333) is driven to press downwards, and the aluminum foil (3336) is adsorbed below the aluminum foil alignment head (333) through magnetism;

when the aluminum foil (3336) is pressed downwards, the forward rotator (35) rotates anticlockwise to drive the forward connecting rod (351) and the forward pressing block (352) to rotate anticlockwise, and when the forward pressing block (352) passes through the aluminum foil (3336) and the upper part of the bottle opening, the aluminum foil (3336) is pressed on the bottle opening through the forward pressing block (352), and meanwhile, the aluminum foil (3336) is driven to rotate anticlockwise on the bottle opening;

meanwhile, when the aluminum foil (3336) is pressed downwards, the reverse rotator (36) rotates clockwise, so that the reverse connecting rod (361) and the reverse pressing block (362) are driven to rotate clockwise, when the reverse pressing block (362) passes through the aluminum foil (3336) and the upper part of the bottle opening, the aluminum foil (3336) is pressed on the bottle opening through the reverse pressing block (362), and meanwhile, the aluminum foil (3336) is driven to rotate clockwise on the bottle opening;

when the aluminum foil (3336) rotates, the magnetic block (3334) is further driven to rotate due to the action of magnetism, the magnetic block (3334) drives the rotating plate (3331) to rotate under the magnetic matching of the steel balls (3332) and the steel ball magnetic base (3333) when rotating, so that the magnetic block (3334) is driven to rotate into the avoiding groove (3335), the magnetism between the aluminum foil (3336) and the magnetic block (3334) is isolated through the avoiding groove (3334), and the aluminum foil (3336) is pressed down from the aluminum foil aligning head (333) and is tightly attached to the bottle opening through the pressing and attaching of the forward pressing block (352) and the reverse pressing block (362), so that the airtightness and high strength of the carbon powder bottle sealing can be ensured.

Images