CN210824280U - Shunting mechanism of glass bottle double-sided heat transfer printing production line - Google Patents

Abstract

The utility model discloses a reposition of redundant personnel mechanism of glass bottle two-sided heat-transfer seal production line, including setting up guiding mechanism and the supporting network of setting in the guiding mechanism below of total conveyer belt unloading end, the supporting network area is kept away from the one end of total conveyer belt is provided with the guide way, the glass bottle passes through and gets into in the guide way behind the guiding mechanism, the guide way is kept away from guiding mechanism's one end is provided with and is used for carrying out spacing stop gear to the glass bottle. The utility model has the advantages of can be better shunt the range to the glass bottle, simple structure, convenient to use, it is efficient.

Description

Shunting mechanism of glass bottle double-sided heat transfer printing production line

Technical Field

The utility model relates to a heat-transfer seal technical field especially relates to a reposition of redundant personnel mechanism of glass bottle double-sided heat-transfer seal production line.

Background

The heat transfer printing processing transfers the exquisite pattern on the transfer printing film on the surface of the product through one-step processing (heating and pressurizing) of a heat transfer printing machine, and the formed ink layer and the surface of the product are dissolved into a whole, so that the product is vivid and beautiful, and the grade of the product is greatly improved. The thermal transfer printing technology is a surface printing technology and is widely applied due to the characteristics of infinite creative design, simple printing requirement, rich colors of printed patterns, environment-friendly production environment, difficult removal and the like.

The existing heat transfer machine can only be used for flat ironing or rolling ironing, can only be used for plane products or cylindrical products, and cannot be used for irregular products. The specific process is that the heat transfer film is conveyed to the surface of a product to be transferred through the film guide device, the heating flat plate is pressed on the surface of the transfer film by utilizing the lifting power device, and after the transfer film is heated and pressed, the pattern is separated from the foil belt, so that the pattern can be transferred to the surface of the product.

However, for a square bottle 100, the bottle has a transition edge 101 on the side, which forms eight sides of the bottle, and the eight sides intersect to form an octagon, forming 8 corners. The transfer printing of the bottle body with the shape, such as the transfer printing of the classic bottle with the whitish color, requires the printing to the surface and the transition edge on the front surface, cannot be realized by the prior art, cannot be broken through by the technology, and becomes a first problem which troubles the technicians in the field.

The heat transfer printing processing transfers the exquisite pattern on the transfer printing film on the surface of the product through one-step processing (heating and pressurizing) of a heat transfer printing machine, and the formed ink layer and the surface of the product are dissolved into a whole, so that the product is vivid and beautiful, and the grade of the product is greatly improved. The thermal transfer printing technology is a surface printing technology and is widely applied due to the characteristics of infinite creative design, simple printing requirement, rich colors of printed patterns, environment-friendly production environment, difficult removal and the like.

The existing heat transfer machine can only be used for flat ironing or rolling ironing, can only be used for plane products or cylindrical products, and cannot be used for irregular products. The specific process is that the heat transfer film is conveyed to the surface of a product to be transferred through the film guide device, the heating flat plate is pressed on the surface of the transfer film by utilizing the lifting power device, and after the transfer film is heated and pressed, the pattern is separated from the foil belt, so that the pattern can be transferred to the surface of the product.

However, for the square glass bottle 100, the transition edge 101 is provided on the side of the glass bottle, the transfer printing of the bottle body with such a shape, i.e. the transfer printing of the classic bottle in white, is required to be printed on the surface and the transition edge on the front surface, and the prior art can not realize the transfer printing, and the transfer printing can not break through the prior art, which becomes a first problem troubling the technicians in the field.

Aiming at the existing problems, the applicant considers and designs a glass bottle double-sided heat transfer printing production line which comprises a heat transfer printing conveyor belt, wherein two heat transfer printing devices are arranged on one side of the heat transfer printing conveyor belt, the two heat transfer printing devices are respectively a front heat transfer printing device and a back heat transfer printing device, a turnover mechanism for turning over glass bottles is arranged between the two heat transfer printing devices, a locking mechanism is further arranged at the feeding end of the heat transfer printing conveyor belt, tools are arranged on the two sides of the heat transfer printing conveyor belt corresponding to the heat transfer printing devices, and a bottle body vertical mechanism for converting the glass bottles horizontally arranged on the heat transfer printing conveyor belt into glass bottles vertically arranged on the heat transfer printing conveyor belt and transferring the glass bottles to a discharging conveyor belt is arranged between the heat transfer printing conveyor belt and the discharging conveyor belt; the unloading end of unloading conveyer belt is provided with confluence mechanism, confluence mechanism is used for carrying out the confluence with the glass bottle on the unloading conveyer belt, the end of confluence mechanism is provided with reposition of redundant personnel mechanism, reposition of redundant personnel mechanism is used for arranging the glass bottle in a row, still includes bottle moving mechanism, bottle moving mechanism is used for pressing from both sides the glass bottle in a row and gets heating mesh belt, and stoving mechanism includes the oven, the oven is provided with import and export, heating mesh belt's material loading end and unloading end set up respectively the import and export the outside, heating mesh belt's unloading end outside is provided with the fan support, the fan support installs downwards and is used for carrying out the refrigerated fan to the glass bottle. Is used for carrying out double-sided heat transfer printing on the glass bottle. After the confluence of glass bottle, need the reposition of redundant personnel to arrange, then move and dry on the heating mesh belt, but how to design one kind and shunt the glass bottle on the total conveyer belt, form and arrange, arrange evenly, simple structure, convenient to use's reposition of redundant personnel mechanism becomes the technical problem that technical staff in the field solved first and foremost.

SUMMERY OF THE UTILITY MODEL

To the deficiency of the prior art, the technical problem to be solved by the present patent application is: how to provide the reposition of redundant personnel mechanism to glass bottle reposition of redundant personnel range that can be better, simple structure, convenient to use, the two-sided heat-transfer seal production line of efficient glass bottle.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a reposition of redundant personnel mechanism of glass bottle double-sided heat-transfer seal production line, is including setting up the guiding mechanism and the supporting mesh of setting in the guiding mechanism below of total conveyer belt unloading end, the supporting mesh area is kept away from the one end of total conveyer belt is provided with the guide way, the glass bottle passes through the guiding mechanism after and gets into in the guide way, the guide way is kept away from guiding mechanism's one end is provided with and is used for carrying out spacing stop gear to the glass bottle.

Like this, when the total conveyer belt transported the glass bottle to oven one side, oven one side was provided with the support guipure, utilizes guiding mechanism to lead the glass bottle to make the glass bottle get into every guide way in proper order respectively, then is provided with stop gear, carries out the position restriction to the glass bottle motion to the one end that is close to the heating guipure for the glass bottle is in bank to be set up, makes things convenient for the later stage to remove to the heating guipure and heats.

Further, guiding mechanism is including articulating the baffle at the limit guide's of total conveyer belt both sides tip, be provided with the guide shaft on the baffle, limit guide tip be provided with the guide pin bushing that the guide shaft matches, the guide shaft normal running fit is in the guide pin bushing, still including setting up the third brace table in support guipure one side, fixed mounting has two third driving motor on the third brace table, third driving motor's output shaft upwards set up and with guide shaft lower extreme fixed connection, the baffle with when limit guide is parallel, the baffle is in the intermediate position that supports the guipure.

Like this, the action of third driving motor drives the guide shaft and rotates, and the guide shaft drives the baffle and rotates, utilizes the interval between two baffles to carry on spacingly to the glass bottle for the glass bottle enters into every guide way in proper order, accomplishes the reposition of redundant personnel operation. When the guide plate is parallel to the limiting guide rail, the guide plate is located in the middle of the supporting net belt, when the guide plate rotates, the distance between the guide plate and each guide groove is smaller than the length size of one glass bottle, and the glass bottle can be prevented from flowing outwards.

Furthermore, the one end that the support guipure kept away from total conveyer belt is provided with the portal frame, portal frame lower extreme fixed mounting has the interval to be provided with the horizontal pole, and is adjacent interval between the horizontal pole constitutes the guide way, the circular arc that the one end place circle that the horizontal pole is close to total conveyer belt with the circular arc of place circle matches when the baffle rotates, the length direction of horizontal pole with the direction of delivery that supports the guipure is unanimous.

Therefore, the glass bottle is separated by the cross rod, the structure is simple, and the use is convenient. When the guide plate rotates, the circle where the guide plate is located is matched with the circle where the end part of the cross rod is located, so that the glass bottle can directly enter the guide groove, and the glass bottle guiding device is stable and reliable.

Further, stop gear includes the limiting plate, the limiting plate level sets up and sets up the horizontal pole is kept away from the one end of total conveyer belt, the limiting plate is located the horizontal pole with support between the guipure, the horizontal pole lower extreme with support the guipure interval and set up, the limiting plate pass through spacing cylinder with portal frame fixed connection.

Like this, after the glass bottle gets into the guide way, in order to make the glass bottle arrange neatly, increase the limiting plate, the time that the glass bottle got into every guide way is inconsistent, at this moment, spacing cylinder action, drive the limiting plate action, make the limiting plate be close to the motion of baffle direction, promote the motion of glass bottle to guide way opening direction, make the glass bottle be in the coplanar, later limiting plate resets, the support guipure drives the motion of glass bottle, the glass bottle moves to the tank bottom position of guide way, glass bottle lower extreme and limiting plate contact, make the glass bottle be in the coplanar all the time, make things convenient for later stage clamp to get synchronous motion. Specifically, the support guipure belongs to current product, and in the operation of heat-transfer seal production line in-process, the support guipure is in the action state all the time, rotates always.

Furthermore, a locking cylinder is fixedly mounted on the guide plate, a piston rod of the locking cylinder is arranged right opposite to the other side guide plate, and a clamp plate vertically arranged is fixedly mounted at the end part of the piston rod of the locking cylinder.

Like this, when glass brokenly gets into in the guide way two, the locking cylinder action utilizes overtime and baffle to press from both sides tightly the glass bottle, then the action of third driving motor, drives the baffle and rotates to just to next guide way, avoids glass bottle and guide arm collision, the better quality of guaranteeing the glass bottle.

Furthermore, a counter is fixedly arranged on the inner side of the guide plate. The number of the glass bottles entering each guide groove can be counted better, and then the locking cylinder can stretch and retract through counting.

In conclusion, the glass bottle shunting device can better shunt and arrange glass bottles, and is simple in structure, convenient to use and high in efficiency.

Drawings

Fig. 1 is a top view of a glass bottle double-sided heat transfer printing production line adopting the structure of the utility model.

Fig. 2 is a schematic structural view of the turnover mechanism.

Fig. 3 is a top view of fig. 2, wherein the clamping plate is rotated to a horizontal position.

Fig. 4 is a schematic view showing a state where the bottle body vertical mechanism sucks the glass bottles from the thermal transfer belt.

FIG. 5 is a schematic view showing a state where the bottle body erecting mechanism places the glass bottles on the discharging conveyor.

Fig. 6 is a schematic structural view of the thermal transfer device.

Fig. 7 is a schematic view of a-a of fig. 6.

Fig. 8 is a schematic structural view of the tool.

Fig. 9 is a top view of fig. 8.

Fig. 10 is a schematic view of another state of fig. 9.

Fig. 11 is a schematic structural view of the lock mechanism.

Fig. 12 is a schematic structural view of a top pallet.

Fig. 13 is a schematic configuration diagram of the merging mechanism.

Fig. 14 is a schematic structural view of the shunt mechanism.

Fig. 15 is a top view of fig. 14.

Fig. 16 is a schematic view of another state of fig. 15.

Fig. 17 is an enlarged schematic view of the structure of the guide shaft and the guide sleeve.

Fig. 18 is a side view of fig. 14.

Fig. 19 is an enlarged view of B in fig. 14.

Fig. 20 is an enlarged view of C in fig. 15.

FIG. 21 is a schematic view showing the structure of the bottle moving mechanism.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

In specific implementation, as shown in fig. 1 to 21, a double-sided thermal transfer printing production line for glass bottles includes a thermal transfer printing conveyor belt 12, two thermal transfer printing devices are arranged on one side of the thermal transfer printing conveyor belt 12, the two thermal transfer printing devices are a front thermal transfer printing device 121 and a back thermal transfer printing device 122 respectively, a turnover mechanism 13 for turning over glass bottles is arranged between the two thermal transfer printing devices, a locking mechanism is further arranged at a feeding end of the thermal transfer printing conveyor belt 12, tooling is arranged on two sides of the thermal transfer printing conveyor belt 12 corresponding to the thermal transfer printing devices, and a bottle vertical mechanism 14 for converting horizontally arranged glass bottles on the thermal transfer printing conveyor belt 12 into vertically arranged glass bottles and transferring the glass bottles onto a discharging conveyor belt 15 is arranged between the thermal transfer printing conveyor belt 12 and the discharging conveyor belt 15; the unloading end of unloading conveyer belt 15 is provided with the confluence mechanism, the confluence mechanism is used for converging the glass bottle on the unloading conveyer belt 15, the end of confluence mechanism is provided with reposition of redundant personnel mechanism, reposition of redundant personnel mechanism is used for arranging the glass bottle in a row, still includes bottle moving mechanism 17, bottle moving mechanism 17 is used for pressing from both sides the glass bottle in a row and gets heating guipure 19 on, and stoving mechanism includes oven 18, oven 18 is provided with import and export, heating guipure 19's material loading end and unloading end set up respectively the import and export the outside, heating guipure 19's unloading end outside is provided with fan support 191, fan support 191 installs downwards and is used for carrying out refrigerated fan 192 to the glass bottle.

Thus, the glass bottle is horizontally placed at the feeding end of the thermal transfer printing conveyor belt and then is transferred to the position of the tool, the glass bottle at the rear is locked by the locking mechanism, the tool is used for clamping the glass bottle, then the front thermal transfer printing device is used for performing thermal transfer printing on the front side of the glass bottle, the tool drives the glass bottle to rotate in the process of performing thermal transfer printing on the front side of the glass bottle, the side edge of the glass bottle 100 is provided with a transition edge 101, the tool drives the glass bottle to rotate, the front thermal transfer printing device can perform thermal transfer printing on the transition edge of the glass bottle, after the thermal transfer printing is finished, the tool places the glass bottle on the thermal transfer printing conveyor belt, the thermal transfer printing conveyor belt drives the glass bottle to continue to move, then the front side and the back side of the glass bottle are overturned by the overturning mechanism, the glass bottle is conveyed to the position of the back thermal transfer printing device by the thermal, the back side thermal transfer printing device carries out thermal transfer printing on the back side of the glass bottle, whether the tool device is needed to carry out thermal transfer printing on the transition edge is determined according to actual requirements, and after the thermal transfer printing of the previous glass bottle is finished, the locking mechanism is placed by the glass bottle to continue thermal transfer printing operation. After glass bottle heat-transfer seal ended, utilize the vertical mechanism of bottle to vertically place the glass bottle on the unloading conveyer belt, later utilize the confluence mechanism to carry out the confluence to the glass bottle on two at least unloading conveyer belts, after the confluence, utilize the reposition of redundant personnel mechanism to shunt the glass bottle in row, later utilize bottle moving mechanism to place the glass bottle after the reposition of redundant personnel on the heating mesh belt, utilize the heating mesh belt to drive the glass bottle and get into the oven, utilize the oven to toast the printing ink on glass bottle surface, utilize the fan to pack after cooling the glass bottle at last. This production line simple structure, production convenient operation, occupation space is little, and is efficient, better improvement heat-transfer seal quality, can realize the heat-transfer seal of the front and the reverse side of glass bottle by a production line to and the heat-transfer seal on transition limit, can solve the problem that exists at present.

Specifically, tilting mechanism is including just setting up the first supporting station 3 of heat-transfer seal conveyer belt 12 both sides, one of them fixed mounting has first driving motor 31 on the first supporting station 3, the output shaft level of first driving motor 31 sets up, equal fixed mounting has hinged-support 32 on the first supporting station 3, still including setting up the hinge 35 of heat-transfer seal conveyer belt 12 top, hinge 35 both ends are rotated and are installed on hinged-support 32, first driving motor 31's output shaft with hinge one end fixed connection, the both ends of hinge 35 are just to fixed mounting have grip block 33, and the inboard fixed surface that one of them grip block 33 corresponds another grip block 33 installs cylinder 34, the piston rod level of cylinder 34 sets up.

Specifically, the vertical mechanism of bottle is including setting up second mount table 116 between heat-transfer seal conveyer belt 12 and the unloading conveyer belt 15, it has second L shape rocking arm 117 to articulate on the second mount table 116, fixed mounting has second conversion motor 118 on the second mount table 116, second conversion motor 118 with second L shape rocking arm 117 one end fixed connection, second L shape rocking arm 117 other end fixed mounting has the second to inhale 119 dishes, second sucking disc 119 is connected with vacuum generator and is set up.

In this embodiment, the thermal transfer device includes a frame 35, the frame 35 is provided with a film releasing mechanism, a film receiving mechanism and a thermal transfer mechanism, the film releasing mechanism and the film receiving mechanism are respectively disposed on two opposite sides of the top of the thermal transfer mechanism, the thermal transfer mechanism includes a thermal transfer cylinder 36 fixedly mounted on the frame 35, a piston rod of the thermal transfer cylinder 36 is disposed downward and fixedly mounted with a housing 37, a vertical downward through cavity is disposed in the housing 37, a thermal roller 38 is rotatably connected in the cavity through a rotating shaft, a motor support is downwardly mounted at the lower end of the piston rod of the thermal transfer cylinder 36, a step motor 39 is fixedly mounted on the motor support, an output shaft of the step motor 39 and the rotating shaft are coaxially and fixedly connected through a coupler, and the lower end of the thermal roller 38 is located below the housing 37, the surface of the cavity of the shell 37 is provided with a heating furnace of an infrared heating tile, and a temperature controller connected with the heating furnace is also arranged in the shell 37 and is an existing product; it installs to put membrane mechanism and receipts membrane mechanism including rotating wind-up roll 4 and unreel roller 41 in the frame 35, correspond in the frame 35 wind-up roll 4 and unreel roller 41 fixed mounting have rolling motor 42 and unreel motor 43, rolling motor 42's output shaft with wind-up roll 4 passes through the coaxial fixed connection of shaft coupling, unreel motor 43's output shaft with it passes through the coaxial fixed connection of shaft coupling to unreel roller 41, rolling motor 42 and unreel motor 43 synchronization action, wind-up roll 4 is used for rolling the heat-transfer die, it is used for relaxing the heat-transfer die to unreel roller 41.

Like this, put membrane mechanism and receive membrane mechanism and be used for relaxing and the rolling to the heat-transfer seal film, when glass bottle moves to heat-transfer seal device below, the action of heat-transfer seal cylinder, the piston rod of heat-transfer seal cylinder drives shell and hot-rolling roller downstream, be provided with the heating furnace in the shell and heat the hot-rolling roller, the contact of hot-rolling roller and heat-transfer seal film, later through rolling motor and unreeling motor synchronization motion, combine the motion of frock, make heat-transfer seal film and glass bottle synchronization motion, better messenger's the printing ink on the heat-transfer seal film rendition to the glass bottle on.

In this embodiment, the tool includes mounting brackets 44 disposed at two sides of the thermal transfer belt 12, the mounting brackets 44 are connected with mounting plates 45 through horizontal moving mechanisms, vertically disposed supporting cylinders 46 are fixedly mounted on the mounting plates 45, a piston rod of one of the supporting cylinders 46 is upwardly disposed and fixedly mounted with a bottom supporting plate 47, a piston rod of the other supporting cylinder 46 is upwardly disposed and fixedly mounted with a top supporting plate 48, the mounting plates 45 are further fixedly mounted with supporting columns 49, one of the supporting columns 49 is directly opposite to the bottom supporting plate 47 and fixedly mounted with a clamping seat 5, the clamping seat 5 is rotatably connected with the supporting column 49 where the clamping seat is located through a connecting shaft, the connecting shaft is fixedly connected with an output shaft of a second driving motor 51, the second driving motor 51 is fixedly mounted on the supporting column 19, and the other supporting column 19 is directly opposite to the top supporting plate 48 and fixedly mounted with a horizontally disposed clamping cylinder 52, the piston rod of the clamping cylinder 52 is arranged opposite to the bottom supporting plate 47.

Thus, after the glass bottle is moved to the position corresponding to the tooling on the thermal transfer printing conveying belt, the bottom supporting plate and the top supporting plate on the supporting cylinder are respectively utilized to upwards support the bottle bottom and the bottle mouth of the glass bottle to the height of the piston rod of the clamping cylinder, then the clamping cylinder acts to push the glass bottle into the clamping seat, then the supporting cylinder connected with the bottom support plate falls and resets, then the second driving motor acts to drive the clamping seat to rotate, further drives the glass bottle to rotate, and simultaneously the horizontal moving mechanism drives the glass bottle to horizontally move, so that the thermal transfer printing device can carry out thermal transfer printing on the transition edge of the glass bottle, after the thermal transfer printing is finished, the clamping cylinder is retracted and reset, the supporting cylinder provided with the bottom support plate rises, then the two supporting cylinders synchronously carry out blanking, due to gravity, the glass bottles slide out of the clamping seats and then fall onto the thermal transfer printing conveyor belt, and the limiting guide rails arranged on two sides of the thermal transfer printing conveyor belt are used for correcting and limiting.

Specifically, the material loading end of the thermal transfer belt 12 is provided with a locking mechanism, one side of the locking mechanism close to the thermal transfer device is provided with a first photoelectric switch 53, the locking mechanism comprises locking baffles 54 arranged on the mounting bracket 44, a locking cylinder 55 horizontally arranged is fixedly mounted on one of the locking baffles 54, a locking plate 56 is fixedly mounted at the end part of the locking cylinder 55, and the locking cylinder 55 is opposite to the clamping cylinder 52. Can carry out spacingly to the glass bottle, guarantee to go on in order.

Specifically, the two sides of the thermal transfer printing conveyor belt 12 are provided with limiting guide rails 57, the limiting guide rails 57 are provided with openings corresponding to the tooling, and the openings are just opposite to the outer concave surfaces of the inner side surfaces of the end parts of the tooling to form guide arcs.

Specifically, the outer sides of the blanking conveyor belt 15, the thermal transfer conveyor belt 12 and the main conveyor belt 16 are provided with limit guide rails 57.

The horizontal movement mechanism comprises a horizontal movement cylinder 58 fixedly mounted on the mounting bracket 44, a piston rod of the horizontal movement cylinder 58 is horizontally arranged and is fixedly connected with one end of the mounting plate 45, a guide rail is arranged on the mounting bracket 44, and a sliding block matched with the guide rail is arranged at the lower end of the mounting plate 45.

A through groove is arranged above the bottom supporting plate 47 and opposite to the top supporting plate 48 in a penetrating manner.

The side of the top supporting plate 48, which faces the bottle mouth, is concave downwards to form a notch matched with the bottle mouth, and a ball 59 is embedded in the upper surface of the notch in a rolling fit mode.

The clamping seat 5 is just right one side indent of die clamping cylinder 52 forms the recess, be provided with the fixture that is used for carrying out the locking to the bottle bottom of glass bottle in the recess, fixture is including rotating to be installed grip block 6 in the recess, grip block 6 is L shape setting, the department of buckling of grip block 6 rotates to be installed the recess tank bottom, the recess tank bottom is just right the grip block is provided with reset support spring 61.

The bottom support plate 47 and the top support plate 48 are both made of plastic material.

And a clamping plug is fixedly mounted at the end part of a piston rod of the clamping cylinder and is made of a plastic material.

In this embodiment, the merging mechanism includes a first support 62 provided at the discharging end of the discharging conveyor 15, the first bracket 62 is provided with a confluence moving mechanism, the confluence moving mechanism is provided with a connecting plate 63 downwards, three vertically arranged moving cylinders 64 are fixedly arranged downwards on the connecting plate 63, piston rods of the three moving cylinders 64 are arranged downwards and correspond to the discharging ends of the three discharging conveyor belts 15, a rotating motor 65 is fixedly arranged downwards on the piston rod of the moving cylinder 64 positioned in the middle, two vertical plates 66 are fixedly arranged downwards at the lower ends of the output shaft of the rotating motor 65 and the piston rods of the moving cylinders 64 positioned at the two ends, first air bags 67 are respectively arranged on the opposite surfaces of the two vertical plates 66, the first air bag 67 is connected with a first air source, and the first air source is arranged on the first support 62; a main conveyor belt 16 is arranged on one side of the blanking end of the blanking conveyor belt 15, and the feeding end of the main conveyor belt 16 is arranged below the first support 62;

like this, confluence moving mechanism drives the connecting plate motion, the connecting plate drives three moving cylinder synchronous motion, among the three moving cylinder, the flexible length that is located the moving cylinder on both sides is unanimous and is greater than the flexible length that is located the moving cylinder in the middle of being, utilize first gasbag to inflate, carry out the centre gripping back to the bottleneck of glass bottle, drive glass bottle through confluence moving mechanism and move to total conveyer belt top, then utilize the rotation motor to rotate, the glass bottle in the middle of rotating to unanimous with the orientation of the glass bottle on both sides, later with first gasbag gassing, the glass bottle falls on total conveyer belt, accomplish the confluence. The unloading end of unloading conveyer belt is provided with the baffle, carries on spacingly to the glass bottle, avoids dropping.

Specifically, first support 62 upper end is rectangle frame structure, the confluence moving mechanism is including setting up the first forked tail guide rail 68 of the relative both sides in first support 62 upper end, connecting plate 63 lower extreme be provided with first forked tail guide rail 68 sliding fit's first dovetail, fixed mounting has the first moving cylinder 69 of level setting on first support 62, first moving cylinder 69 the piston rod with connecting plate 63 one end fixed connection sets up.

The shunting mechanism is including setting up the guiding mechanism and the support guipure 7 of setting in the guiding mechanism below at total conveyer belt 16 unloading end, support guipure 7 and keep away from the one end of total conveyer belt 16 is provided with guide way 71, the glass bottle gets into in the guide way 71 behind the guiding mechanism, guide way 71 is kept away from the one end of guiding mechanism is provided with and is used for carrying out spacing stop gear to the glass bottle.

Like this, when the total conveyer belt transported the glass bottle to oven one side, oven one side was provided with the support guipure, utilizes guiding mechanism to lead the glass bottle to make the glass bottle get into every guide way in proper order respectively, then is provided with stop gear, carries out the position restriction to the glass bottle motion to the one end that is close to the heating guipure for the glass bottle is in bank to be set up, makes things convenient for the later stage to remove to the heating guipure and heats.

Specifically, the guide mechanism comprises a guide plate 72 hinged at the end part of a limit guide rail 57 at both sides of the main conveyor belt 16, the guide plate 72 is provided with a guide shaft 73, the end part of the limit guide rail 57 is provided with a guide sleeve 74 matched with the guide shaft, the guide shaft 73 is rotatably matched in the guide sleeve 74, the guide mechanism further comprises a third support table 75 arranged at one side of the support mesh belt 7, two third driving motors 76 are fixedly installed on the third support table 75, the output shaft of the third driving motor 76 is upwards arranged and fixedly connected with the lower end of the guide shaft 73, when the guide plate 72 is parallel to the limit guide rail 57, the guide plate 72 is in the middle position of the support mesh belt 7, one end of the support mesh belt 7 far away from the main conveyor belt 16 is provided with a portal frame 77, the lower end of the portal frame 77 is fixedly installed with crossbars 78 at intervals, and the intervals between the adjacent crossbars, the arc of the circle where the end of the cross bar 78 close to the total conveyor belt 16 is located matches the arc of the circle where the guide plate 72 is located when rotating, and the length direction of the cross bar 78 coincides with the conveying direction of the support belt 7.

Specifically, the support mesh belt 7 rotates all the time, drives the glass bottle to move into the guide groove 71, and is limited by the limiting mechanism.

Specifically, stop gear includes limiting plate 79, limiting plate 79 level sets up and sets up the horizontal pole 78 is kept away from the one end of total conveyer belt 16, limiting plate 79 is located the horizontal pole 78 with support between the guipure 7, the horizontal pole 78 lower extreme with support guipure 7 interval and set up, limiting plate 79 through spacing cylinder 8 with portal frame 77 fixed connection.

A locking cylinder 81 is fixedly mounted on the guide plate 72, a piston rod of the locking cylinder 81 is arranged right opposite to the other side guide plate 72, and a clamp plate 82 vertically arranged is fixedly mounted at the end part of the piston rod of the locking cylinder 81.

A counter 80 is fixedly mounted on the inner side of the guide plate 72.

In this embodiment, the bottle moving mechanism is including setting up second support 83 between support guipure 7 and the heating guipure 19, be provided with reposition of redundant personnel moving mechanism on the second support 83, reposition of redundant personnel moving mechanism is provided with mounting panel 84 downwards, mounting panel 84 fixed mounting has the reposition of redundant personnel cylinder 85 of vertical setting downwards, reposition of redundant personnel cylinder 85 interval is provided with at least three, reposition of redundant personnel cylinder 85's piston rod sets up downwards and fixed mounting has diaphragm 86, diaphragm 86 fixed mounting has two vertical plates 87 downwards, and there is second gasbag 88 through relative surface difference fixed mounting between two vertical plates 87, second gasbag 88 is connected with the second air supply, the second air supply is installed on the second support 83.

Like this, reposition of redundant personnel moving mechanism drives the mounting panel motion, drives reposition of redundant personnel cylinder and diaphragm and vertical slat motion to the glass bottle top in bank through the mounting panel, and the piston rod of reposition of redundant personnel cylinder stretches out, and it is located the glass bottle bottleneck outside to drive the second cylinder, and later the second gasbag is aerifyd, carries out the centre gripping to the glass bottle, then the reposition of redundant personnel cylinder shrink, and reposition of redundant personnel moving mechanism drives the glass bottle to heating mesh belt after, and the reposition of redundant personnel cylinder extends, and the second gasbag is deflated, and the glass bottle is placed on heating mesh belt.

Specifically, the blanking conveyor belt 15 and the total conveyor belt 16 are both chain plate type heavy-duty turning conveyors.

Specifically, second support 83 upper end is rectangle frame structure, reposition of redundant personnel moving mechanism is including setting up the second forked tail guide rail 89 of the relative both sides in second support 83 upper end, mounting panel 84 lower extreme be provided with second forked tail guide rail 89 sliding fit's second dovetail, the second moving cylinder 9 that the fixed mounting has the level to set up on the second support 83, the second moving cylinder 9 the piston rod with mounting panel 83 one end fixed connection sets up.

The control cabinet is internally provided with a controller which is a PLC controller and is used for controlling the actions of the electrical elements, and the PLC controller is selected from S7-200. Specifically, the stretching speed of the unreeling motor, the reeling motor, the second driving motor and the horizontal moving cylinder can be adjusted according to actual needs.

Finally, it should be noted that: the above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those skilled in the art; the technical solutions described in the foregoing embodiments may still be modified, or some or all of the technical features may be equivalently replaced; such modifications and substitutions do not substantially depart from the scope of the embodiments of the present invention, and are intended to be covered by the claims and the specification.

Claims (6)

1. The utility model provides a reposition of redundant personnel mechanism of glass bottle two-sided heat-transfer seal production line which characterized in that, is including setting up the guiding mechanism and the support net of setting in the guiding mechanism below of total conveyer belt unloading end, the support net area is kept away from the one end of total conveyer belt is provided with the guide way, the glass bottle passes through behind the guiding mechanism and gets into in the guide way, the guide way is kept away from guiding mechanism's one end is provided with and is used for carrying out spacing stop gear to the glass bottle.

2. The flow dividing mechanism of a double-sided thermal transfer printing production line for glass bottles as claimed in claim 1, wherein the guiding mechanism comprises a guide plate hinged to the end of a limiting guide rail on both sides of the main conveyor belt, the guide plate is provided with a guide shaft, the end of the limiting guide rail is provided with a guide sleeve matching with the guide shaft, the guide shaft is rotatably fitted in the guide sleeve, the flow dividing mechanism further comprises a third support platform arranged on one side of the support net belt, two third driving motors are fixedly mounted on the third support platform, the output shaft of the third driving motor is arranged upwards and fixedly connected with the lower end of the guide shaft, and when the guide plate is parallel to the limiting guide rail, the guide plate is located in the middle of the support net belt.

3. The flow dividing mechanism of a glass bottle double-sided heat transfer printing production line according to claim 2, wherein a portal frame is arranged at one end of the support mesh belt far away from the main conveyor belt, cross bars are fixedly arranged at the lower end of the portal frame at intervals, guide grooves are formed at the intervals between the adjacent cross bars, the arc of the circle where one end of each cross bar close to the main conveyor belt is located is matched with the arc of the circle where the guide plate is located when the guide plate rotates, and the length direction of each cross bar is consistent with the conveying direction of the support mesh belt.

4. The flow dividing mechanism of the glass bottle double-sided heat transfer printing production line according to claim 3, wherein the limiting mechanism comprises a limiting plate, the limiting plate is horizontally arranged and disposed at one end of the cross rod away from the main conveyor belt, the limiting plate is located between the cross rod and the supporting mesh belt, the lower end of the cross rod is spaced from the supporting mesh belt, and the limiting plate is fixedly connected with the portal frame through a limiting cylinder.

5. The flow dividing mechanism for a double-sided thermal transfer printing production line of glass bottles as claimed in claim 4, wherein a locking cylinder is fixedly mounted on the guide plate, a piston rod of the locking cylinder is arranged right opposite to the other side guide plate, and a vertically arranged clamping plate is fixedly mounted at an end of the piston rod of the locking cylinder.

6. The flow dividing mechanism of a double-sided thermal transfer printing production line of glass bottles of claim 5, wherein a counter is fixedly arranged on the inner side of the guide plate.

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