CN216300142U - Thermoforming machine and one-mold three-action in-mold labeling, conveying and boxing production line - Google Patents

Abstract

The utility model relates to a thermoforming machine and an in-mold labeling, conveying and boxing production line with one mold and three actions, wherein a cup making machine is provided with two lower molds which are in left-right translation and alternate work, the movement mode that the lower molds of the traditional cup making machine can only lift up and down but can not translate left and right is overturned, and in addition, because the lower molds of the traditional cup making machine can not translate left and right, equipment used for in-mold labeling or stacking transmission equipment can only be arranged in front of the cup making machine, so that in-mold labeling production of one mold can be finished by eleven actions in the traditional technology. The two lower dies can alternately work in an up-and-down lifting mode and a left-and-right translation mode, when one lower die is used for producing products after receiving the label and located at the thermoforming station below the upper die, the other lower die is located at the outer side of the connecting support frame and used for receiving the label, each lower die can normally work when reaching the thermoforming station without waiting for multiple actions of an in-die labeling manipulator to enter the label placing mode like the traditional process, and the production time of each die is shortened.

Description

Thermoforming machine and one-mold three-action in-mold labeling, conveying and boxing production line

Technical Field

The utility model relates to a plastic container preparation device for catering, in particular to a thermoforming machine for preparing containers and covers of disposable plastic cups, bowls, plates and the like for catering and drinking by using plastic sheets and an in-mold labeling, conveying and boxing production line with one mold and three actions.

Background

The production method of the prior art for the daily used disposable plastic tableware, such as disposable cups, bowls, dishes, lids, boxes and other products, mainly adopts air-compression thermoforming, but has the defects of multiple actions and slow efficiency, and still has the defect that the multi-specification shapes produced by a multifunctional die-labeling and white cup cannot be conveyed to be boxed by one machine. Plastic suction molding and injection molding, and the products need label patterns, curved surface printing pictures and texts, or sticking adhesive labels or thermal shrinkage decoration, for example, the higher grade is in-mold labeling and injection molding production. Although the sheet material power consumption can be saved due to the fact that the raw materials of the injection molding are not provided with corners, the problems that the mold is high in price, the mold processing and debugging period is long, and the market first machine is easily lost are solved, and the quantity and the speed of each mold time can not be compared with those of a sheet material air-compression thermal forming cup making machine, so that the applicant of the utility model develops a multifunctional thermal forming mold cavity labeling production line to realize that labels with rich pictures and texts are attached while products are produced and prepared, the attractiveness of the products is greatly improved, and the additional value of mechanical and cup making products is increased. However, the utility model of the cup-making connecting and stacking manipulator disclosed by the applicant requires eleven actions per mold, a multifunctional in-mold labeling manipulator needs to be added to a production line when in-mold labeling is performed, the multifunctional in-mold labeling manipulator firstly needs to move horizontally into, move downwards to place a label, move upwards and move horizontally out of four actions after the multifunctional material-taking and conveying manipulator descends to empty a space, and the multifunctional in-mold labeling manipulator needs eleven actions to complete one mold action when being connected with an upper and lower pressing thermoforming cup-making machine (for example, the in-mold labeling container production line connected with a pressing and air-heating molding machine with the publication number of CN 106273375B), even the multifunctional in-mold labeling manipulator connected with an advanced turnover mold needs nine actions to complete one mold action, and the problem that the multiple effect rate of the action is relatively slow exists. Along with the improvement of social consumption level, the appearance and packaging requirements of consumers on products are gradually improved, the market share of the blank cup container formed by air-compression thermoforming in the existing production process is greatly reduced due to the low grade, and in order to solve the problem of reduction of the market share of cup products, the label production line in the air-compression thermoforming is already released in developed countries, but the market can not be opened due to the problems of high price, incapability of multi-function use and the like, so that the product labeling can meet the requirements of consumers on high-grade products and the market share, therefore, aiming at the problems that the existing equipment is high in investment cost, special equipment can not be used in multiple functions, the market can not be opened due to the technical subsidence, the problem of reduction of the market of the blank cup needs to develop a conveying production line which is low in investment cost and high in automation, and ensures that the in-mold labeling function and multiple specifications and shapes are added on the basis of unchanged mould of the original equipment to realize multiple purposes by one machine, greatly improves the added value of equipment and products, and meets the needs of the domestic and foreign mass market to save the market share of the downslide.

Disclosure of Invention

The utility model aims to avoid the defects in the prior art and provides the thermoforming machine which can be improved based on the traditional cup making machine, has low modification cost and high production efficiency and can realize the preparation of white cups and the in-mold labeling.

The purpose of the utility model is realized by the following technical scheme:

the upper die mechanism is provided with an upper die, the lower die mechanism is provided with two lower dies, a lower lifting die table, a lower lifting driving device and a translation driving device, the two lower dies can be arranged on the lower lifting die table in a sliding manner, and the lower lifting die table can be driven by the lower lifting driving device to ascend or descend so that the lower dies are matched with the upper die or separated from the upper die in a die opening manner;

each lower die is correspondingly provided with a balance weight box, and the balance weight box can slide on the placing seat and the lower lifting die table;

a bolt is arranged at one side of the bottom of the lower die, which is close to the balance weight box, a connecting plate is connected with one side of the balance weight box, which is close to the lower die, a bolt hole is formed in the front end of the connecting plate, and the bolt of the lower die can be inserted into the bolt hole;

when the lower lifting die platform descends to a proper position, the pins of the two lower dies are inserted into the pin holes of the connecting plates of the corresponding balance weight boxes to form a balance linkage structure capable of mutually pulling and alternately exchanging stations, the formed lower dies push the corresponding balance weight boxes out of the lower lifting die platform and enable the balance weight boxes to slide to the placing seat for standby, the balance weight boxes on the other sides are pulled to be pulled up and down from the placing seat by using the pins at the bottoms of the corresponding lower dies as force points, the lower dies positioned on the material receiving and discharging standby conveying stations are horizontally moved to the forming standby conveying stations, and the lower dies positioned on the forming standby conveying stations are changed to the material taking and discharging standby conveying stations.

Preferably, the bottom of each lower die is provided with a translational sliding base, the two translational sliding bases are connected through a traction bearing seat, a sliding block is fixed at the bottom of the translational sliding base and is slidably arranged on a track, the track is fixed on a lower lifting die table, and a clutch traction bolt is arranged at the bottom of the tail end of the translational sliding base.

Preferably, when the lower lifting die platform rises to a proper position, the upper die and the lower die are used for die assembly of a product for forming, the other lower die is used for synchronously finishing the label taking, in the process that the lower lifting die platform falls, a demoulding cylinder of the demoulding unit rises to enable the product to be separated from the die cavity and hung at the corner, and then the demoulding unit resets; when the lower lifting die platform descends to the right position, a traction clutch bolt under the translational sliding base of the lower die outside the forming station is inserted into a bolt hole of the balance weight box to form a translational linkage structure in which the two lower dies are respectively dragged with the balance weight box outside.

Preferably, the upper die mechanism is mounted on the connecting support frame, an upper support table is fixed at the upper end part of the connecting support frame, the tail part of the upper end of the upper lifting gantry column is fixed on the upper support table, the lower end of the upper lifting gantry column is fixed on cross beams positioned at two sides of the connecting support frame and positioned outside the sheet conveying chain, the upper lifting die table is slidably arranged on the upper lifting gantry column, and the upper die is mounted on the upper lifting die table; the lower lifting die table is fixedly connected with a lower lifting portal column, the lower lifting portal column is slidably arranged on a sliding sleeve seat, and the sliding sleeve seat is fixed on the supporting base; the bottom of the connecting support frame is fixed on the sliding sleeve seat and the support base to form an integral connection structure of an up-down lifting structure.

Preferably, the bottom of the lower die is fixedly connected with a attracted iron close to the balance weight box, and a connecting plate of the balance weight box is provided with an electromagnet.

Preferably, the placing seat is provided with a rotatable balance auxiliary wheel, and when the balance weight box descends to the right position, the connecting plate at the bottom of the balance weight box can be arranged on the balance auxiliary wheel in a sliding manner.

Preferably, every lower mould is including shaping die cavity and drawing of patterns unit, drawing of patterns unit is equipped with stripper plate and drawing of patterns lifter plate, and the stripper plate is provided with the knockout according to the die cavity of shaping die cavity, connects through the connecting rod between drawing of patterns lifter plate and the stripper plate, and during the drawing of patterns, the telescopic link of drawing of patterns cylinder upwards stretches out and pushes up the drawing of patterns lifter plate, and drawing of patterns lifter plate moves the stripper plate and up moves the drawing of patterns, and the knockout of stripper plate drives the product opening edge after the shaping up the removal drawing of patterns.

Preferably, the bottom of the demoulding lifting plate is provided with a demoulding clutch slide bar which passes through the bottom of the lower die and the translational sliding base; the telescopic link rigid coupling of drawing of patterns cylinder has the drawing of patterns kicking one, and the drawing of patterns kicking one is equipped with the ejector pin upwards, and during the drawing of patterns, the ejector pin is aimed at the drawing of patterns separation and reunion slide bar of lower mould drawing of patterns unit upwards.

Preferably, the translation driving device is composed of a motor, a driving wheel and a transmission belt, the driving wheel is rotatably arranged on the lower lifting die table, the transmission belt is arranged on the driving wheel and is connected with one of the lower dies, and the motor drives the driving wheel and the transmission belt to rotate; the driving belt directly or indirectly drives the two lower dies to simultaneously translate.

Preferably, the lower lifting driving device comprises an upper rotary supporting seat, a lower rotary supporting seat, an upper lifting motion crank, a lower lifting motion crank, a positioning lifting shaft, a vertical lifting limit slider, a lever pressing and pulling lifting crank, a positioning rotary sliding lever crank, a positioning lifting shaft and a push-pull driving mechanism,

the lower rotary supporting seat is fixed on a static base, the lower rotary supporting seat is connected with the lower end of the lower lifting motion crank in a relatively rotatable manner through a hinged shaft, the upper end of the lower lifting motion crank is connected with the positioning rotary sliding lever crank in a relatively rotatable manner through a hinged shaft, the upper end of the positioning rotary sliding lever crank is hinged with the lower end of the upper lifting motion crank through a hinged shaft, the upper end of the upper lifting motion crank is connected with the lower end of the upper rotary supporting seat in a relatively rotatable manner through a hinged shaft, the upper rotary supporting seat is fixed at the bottom of an object to be lifted, the positioning lifting shaft is arranged on the positioning rotary sliding lever crank, a vertical lifting limiting sliding piece is arranged on the positioning lifting shaft, the vertical lifting limiting sliding piece is arranged on the static supporting seat in a sliding manner, and the hinged shaft, the positioning lifting shaft and the lower lifting motion crank are connected with the lower rotary supporting seat are formed, A vertical lifting structure with a hinge shaft connected with the upper lifting motion and the upper rotary supporting seat always in a line of three points;

the lower tail end of the positioning rotary sliding lever crank is connected with one end of the lever pressing and pulling lifting crank in a relatively rotatable manner through a shaft; the other end of the lever pressing and pulling lifting crank is driven by a push-pull driving mechanism to move.

The utility model aims to avoid the defects in the prior art and provides an in-mold labeling and conveying and boxing production line which is improved based on a traditional cup making machine, has low modification cost and high production efficiency and can realize one-mold-time three-action of white cup preparation, in-mold labeling, product stacking and conveying and boxing.

Providing an in-mold labeling, conveying and boxing production line with one mold and three actions, wherein the production line comprises a thermoforming machine and two groups of label conveying groups, two lower molds of the thermoforming machine move left and right to work alternately, and each lower mold corresponds to one group of label conveying groups respectively;

each group of label conveying group comprises an in-mold labeling, taking and conveying mechanical arm, a label transfer conveying device, a label conveying mechanical arm and a label bin;

every mould time in the mould when labeling, the action of lower mould and in-mould labeling manipulator including:

a first action: when the lower die of the forming station completes the forming of the product, the other lower die of the material taking and discharging station synchronously completes the taking of the label and the descending; an in-mold labeling manipulator positioned on one side of the balance weight box translates to a label taking station while translating and replacing stations of the two lower molds, and finishes label receiving while a lower lifting mold table ascends; when the label transferring and conveying device synchronously ascends to finish label conveying, the lower lifting die platform is communicated with the lower die to descend together, and the label is synchronously conveyed to a label ascending and unloading station before the labeling manipulator in the next die reaches the material receiving station; after the label transferring and conveying device and the label transferring and conveying device reach respective material taking and discharging stations, the label conveying manipulator continuously finishes descending and conveying labels, ascending after discharging, translating to the position above a label bin, descending and taking labels, ascending and translating to the material taking station for standby before the label transferring and conveying device reaches the material taking station;

a second action; the two lower dies are translated and exchanged with stations at the same time; synchronously translating the in-mold labeling manipulator which is connected with the label to a label conveying station for standby; the other in-mold labeling manipulator which finishes label conveying synchronously translates to a label taking station, and the in-mold labeling manipulator and the label conveying unit cooperate according to programming presetting;

a third action: when one lower die rises and is matched with the upper die to prepare a product, the labeling manipulator in the die matched with the other lower die and positioned at a standby station sticks a label to the inner wall of the die cavity, and meanwhile, the two groups of label conveyor units work cooperatively according to preset programming.

Preferably, the automatic cup making machine is also connected with a plastic container stacking and conveying unit, after the sheet of the cup making machine is formed at a forming station, the sheet conveying chain rail carries corners and products to a punching and shearing station for punching and shearing and then conveys the punched edges and the cut edges to a finished product receiving and conveying device, the finished product receiving and conveying device is provided with a lifting and discharging device and a receiving and discharging conveying manipulator, the finished product receiving and conveying device conveys the finished products to a receiving and stacking and conveying device, a transfer conveying manipulator, a single-row whole-strip receiving and stacking lateral conveying device, a limiting receiving and overturning transverse quantitative conveying device, a receiving and quantitative conveying platform, a receiving and quantitative conveying device and a multi-specification conveying and boxing device to complete whole-course conveying and boxing;

the position and the operation characteristics of the plastic container stacking, conveying and boxing unit are as follows: the receiving tray is positioned outside the finished product receiving and conveying device, the finished product receiving and conveying device jacks and conveys the products to the receiving and discharging conveying manipulator from the ascending discharging device after completing receiving and stacking, the receiving and discharging conveying manipulator operates above the receiving tray positioned outside the finished product receiving and stacking and storing device to vertically discharge, the receiving tray translates to a sampling inspection station or a discharging station after completing receiving and then receives the materials and moves back and forth between the receiving station and the single-row whole receiving and stacking lateral conveying device to indirectly discharge, the single-row whole receiving and stacking lateral conveying device vertically receives and stacks the materials, the products are pushed to the limiting receiving and overturning lateral quantitative conveying device after completing receiving, the limiting receiving and overturning lateral quantitative conveying device conveys the products to the receiving and overturning lateral conveying platform, and the receiving quantitative conveying platform pushes the products to the receiving and discharging trays which are provided with limiting positions on two sides of the receiving and quantitative conveying device, the whole product tray which is connected with the material unloading tray is conveyed into the carton by the layer-material-connection quantitative conveying device, and the operation is repeated until the carton is full.

The utility model has the beneficial effects that:

(1) the thermoforming machine is provided with the two lower dies which can be horizontally moved to work alternately, the movement mode that the lower dies of the traditional cup making machine can only be lifted up and down but not be horizontally moved is overturned, and because the lower dies of the traditional cup making machine can not be horizontally moved, equipment used for in-mold labeling or stacking transmission equipment can only be arranged in front of the cup making machine, so that the in-mold labeling production of one die can be completed by eleven actions or six actions in the traditional technology. The two lower dies can alternately work in an up-and-down lifting mode and a left-and-right translation mode, when one lower die is in a label receiving station and receives and places labels, the other lower die completes forming in a forming station, the in-die labeling manipulator on the other side simultaneously takes the labels and translates the labels to the position above a label unloading station for standby, punching and shearing are completed simultaneously in a punching and shearing station in front of the forming station, a finished product receiving and stacking station is formed before the completion, and therefore the three actions of one die are completed together with the in-die labeling.

Meanwhile, the other lower die is positioned on the outer side of the connecting support frame to be connected with the label, and each lower die can normally work when reaching a forming station without waiting for a plurality of actions of an in-die labeling manipulator to enter the label placing process like the traditional process, so that the production time of each die is shortened, and the working efficiency is improved. When the white cup (product without labeling) is produced, the lower die mechanism can realize dual-die cup replacement and material conveying, so that the production rate is high.

(2) The two lower dies can be connected with the balance weight boxes on the left side or the right side as required to form a balance linkage group, so that the balance motion and the smooth lifting of the two lower dies are ensured, accessories such as weights and the like can be prevented in the balance weight boxes, and the weight of the balance weight boxes can be flexibly adjusted according to the weight of the lower dies.

(3) The traditional cup making machine utilizes a cup ejecting mechanism to slightly eject a product to realize demoulding when the die opening is lowered after the product is formed by thermoforming a sheet so as to facilitate subsequent material taking, but because the two lower dies are arranged and the moving mode of the two lower dies is different from that of the traditional lower dies, the cup ejecting mechanism of the traditional lower dies cannot be suitable for demoulding the product from the die cavity of the lower die, and how to improve the equipment structure is another technical problem in the field. The lower die is provided with a stripper, the stripper is provided with a stripper plate, the stripper plate is provided with stripping ribs according to the die cavity of the molding die cavity, and the stripping ribs are positioned outside the opening of the die cavity and can drive the molded product to rise so as to separate the product from the die cavity to achieve the purpose of stripping.

(4) The lower lifting driving device of the thermoforming machine has the advantages that the rotary lifting crank is arranged to be approximately L-shaped, the middle turning part of the rotary lifting crank is used as a fulcrum, two arms are used as force arms to form a lever, the length of an upper connecting end of the rotary lifting crank is longer than that of a lower connecting end, the large-amplitude lifting is realized by utilizing the lever principle, the load is heavy, and the large-tonnage heavy object can be easily and stably lifted or lowered.

(5) The upper die mechanism and the lower die mechanism are respectively provided with independent portal columns, the traditional whole portal column is replaced by the support column of the upper die mechanism and the support column of the lower die mechanism together, the weight of each section can be reduced due to the sectional arrangement of the portal columns, the flexibility is higher, the upper die table support frame and the lower die table support frame can be used for accurately butting the portal columns of the upper die mechanism and the lower die mechanism, and the accuracy of die assembly of the upper die and the lower die is ensured.

(6) The actions of the lower die and the in-die labeling manipulator in each die in-die labeling process comprise die separation descending, linkage translation and ascending die assembly, in the process, one lower die is normal, and a lower die product positioned on the outer side of the cup making machine receives a label conveyed by the in-die labeling manipulator after being unloaded. The utility model not only realizes the purpose of sticking labels with rich pictures and texts while producing and preparing products, greatly improves the aesthetic degree of the products, increases the added value of the mechanical and cup-making products, but also simplifies the action number of the in-mold sticking manipulator per mold, can finish in-mold sticking production by only 3 actions, and has extremely high production efficiency. Compared with an injection mold, the upper mold and the lower mold used by the cup making machine are low in investment cost and short in production period, so that the improvement cost of products is reduced, and the market is occupied quickly.

(7) The plastic container stacking and conveying unit comprises a single-row transfer conveying manipulator and a single-row whole-piece stacking lateral pushing device which are vertically stacked and are in limit conveying in the whole process, and the limit receiving turnover and horizontal conveying device is connected and pushed to the receiving quantitative conveying device and the quantitative whole-layer pushing boxing device and the multi-specification boxing device which are all in front-back link limit conveying, so that containers and covers in any specification and shape can be neatly and smoothly conveyed in the whole process. Particularly, the vertical material receiving and discharging of a plurality of groups of limiting skewers of the multifunctional material receiving and discharging device, the gear-shifting staggered pushing cylinder of the single-row transfer conveying manipulator and the double-single-row whole piece overlapping lateral material pushing and discharging device ensure the smooth conveying of staggered arrangement.

Drawings

The utility model is further illustrated by means of the attached drawings, the content of which is not in any way limitative of the utility model.

Fig. 1 is a schematic structural view of an embodiment of a one-time three-motion in-mold label transfer boxing production line of the present invention.

Fig. 2 is another angle structure diagram of an embodiment of the one-time three-motion in-mold label conveying and boxing production line of the present invention.

Fig. 3 is a schematic view of a thermoforming machine and two sets of label transfer sets of a one-die three-action in-mold label transfer boxing line of the present invention.

FIG. 4 is a schematic block diagram of one embodiment of the thermoforming machine of the present invention.

Fig. 5 is a schematic structural view of a lower die mechanism of the thermoforming machine according to an embodiment of the present invention.

Fig. 6 is a schematic structural view of one embodiment of two lower molds and an ejector of the thermoforming machine of the present invention.

Fig. 7 is a schematic structural view of one embodiment of two lower molds of the thermoforming machine of the present invention.

Fig. 8 is a schematic view of two lower die lifting drive mechanisms of the thermoforming machine of the present invention.

Fig. 9 is a schematic view of two lower mold lifting drive mechanisms and a counterweight box of the thermoforming machine of the present invention.

Fig. 10 is a schematic view showing a state in which the lower die mechanism is interlocked in one embodiment of the thermoforming machine of the present invention.

FIG. 11 is another angle schematic view of the lower die mechanism linkage of one embodiment of the thermoforming machine of the present invention.

Fig. 12 is a schematic view showing the lower lift driving device of the lower die mechanism of the thermoforming machine according to the embodiment of the present invention.

Fig. 13 is a schematic view of a lower lift driving means of a lower die mechanism in a folded state according to an embodiment of the thermoforming machine of the present invention.

Fig. 14 is a schematic view of a lower elevation driving device of a lower die mechanism of another embodiment of the thermoforming machine of the present invention.

Fig. 15 is a schematic view of a lower elevation driving device of a lower die mechanism of still another embodiment of the thermoforming machine of the present invention.

Fig. 16 is a schematic structural view of a finished product receiving and conveying device according to an embodiment of the present invention.

Fig. 17 is another state diagram of the finished product receiving and conveying device according to the embodiment of the present invention.

Fig. 18 is a schematic structural view of a multi-mode sub-receiving conveying robot of the finished product receiving conveying device according to an embodiment of the utility model.

Fig. 19 is a schematic structural view of a receiving storage channel and a limit card of the finished product receiving and conveying device according to an embodiment of the utility model.

Fig. 20 is a schematic structural view of a finished product receiving and conveying device according to an embodiment of the present invention.

Fig. 21 is a schematic structural view of a transfer robot and a single row of full-splices side-to-side transfer device according to an embodiment of the present invention.

Fig. 22 is another angle structure diagram of the transfer robot and the single row full splice side conveyor according to an embodiment of the present invention.

FIG. 23 is a schematic view of a clutched limit receiver of a single row full splice lateral transfer device according to one embodiment of the present invention.

Fig. 24 is a schematic structural view of a part of a limiting material receiving overturning transverse quantitative conveying device according to an embodiment of the utility model.

Fig. 25 is a schematic structural view of another angle part of the material-receiving-overturning transverse quantitative conveying device according to an embodiment of the utility model.

Fig. 26 is a schematic structural view of a receiving quantitative transfer platform according to an embodiment of the present invention.

Fig. 27 is a schematic structural view of a layer-by-layer material quantitative transfer apparatus according to an embodiment of the present invention.

Fig. 28 is a schematic view showing the butt-joint cooperation of the material-receiving-overturning limiting transverse quantitative conveying device, the material-receiving quantitative conveying platform and the layer-by-layer material-receiving quantitative conveying device according to one embodiment of the present invention.

Fig. 29 is another schematic view of the butt-joint cooperation of the material-receiving-overturning limiting transverse quantitative conveying device, the material-receiving quantitative conveying platform and the layer-by-layer material-receiving quantitative conveying device according to one embodiment of the present invention.

Fig. 30 is a schematic diagram of the mating of a layer-by-layer material quantitative transfer device and a multi-specification material-receiving container transfer device according to an embodiment of the present invention.

Fig. 31 is a schematic structural view of a multi-specification receiving-boxing conveying device according to an embodiment of the present invention.

Fig. 32 is a schematic structural diagram of a receiving material translation and rotation driving unit of the multi-specification receiving material conveying boxing apparatus according to an embodiment of the present invention.

Fig. 33 is a schematic structural view of a carton placing unit of the multi-specification material receiving conveying boxing apparatus according to the embodiment of the utility model.

Fig. 34 is a schematic structural diagram of a membrane ferrule removing unit of the multi-specification receiving material conveying boxing apparatus according to an embodiment of the present invention.

Fig. 1 to 34 include:

a thermoforming machine

A1 connecting support frame, A2 upper die mechanism, A3 lower die mechanism, A4 electric furnace, A4-1 sheet material conveying chain

An upper die mechanism: an A2-1 upper die, an A2-2 upper supporting table, an A2-3 ascending and descending driving device, an A2-4 ascending and descending die table and an A2-5 ascending and descending portal column;

a lower die mechanism:

a3-1 lower die, A3-11 molding die cavity, A3-12 demoulding unit, A3-13 demoulding cylinder, A3-14 demoulding device, A3-15 demoulding lifting plate, A3-16 connecting rod, A3-17 demoulding clutch sliding rod, A3-18 translation sliding base, A3-19 demoulding jacking piece, A3-20 ejector rod, A3-25 traction bearing seat, A,

A3-2 lower lifting die table, A3-21 slide block, A3-22 track, A3-23 bolt, A3-24 attracted iron,

A3-3 lower lifting driving device, A3-32 push-pull rod, A3-33 lower support rotating component, A3-31 push-pull driving mechanism, A3-331 lower connecting seat, A3-332 lower support rotating shaft, A3-333 lower lifting connecting piece, A3-34 rotating lifting crank, A3-35 upper rotating component,

A3-4 translation driving device, A3-41 motor, A3-42 transmission belt, A3-43 transmission wheel,

The device comprises an A3-5 balance weight box, an A3-51 connecting plate, an A3-6 placing seat, an A3-61 balance auxiliary wheel, an A3-7 supporting base and an A3-8 lower lifting portal column;

b intra-mould labeling manipulator, C label transfer conveyer, D label transfer manipulator and E label storehouse.

Detailed Description

The utility model is further illustrated by the following examples.

Example 1

Referring to fig. 1 to 13, the thermoforming machine a of this embodiment includes an upper die mechanism a2, a lower die mechanism A3, and an electric furnace a4, where the electric furnace a4 is located between the upper die mechanism a2 and the lower die mechanism A3, two sides of the circuit are installed to drive the sheet material to move, and the electric furnace a4 heats the sheet material to soften the sheet material. The upper die mechanism A2 is provided with an upper die A2-1, the lower die mechanism is provided with two lower dies, a lower lifting die platform A3-2, a lower lifting driving device A3-3 and a translation driving device A3-4, the two lower dies are slidably arranged on the lower lifting die platform A3-2, and the lower lifting die platform A3-2 can be driven by the lower lifting driving device A3-3 to ascend or descend so that the lower dies are matched with or separated from the upper dies. In the embodiment, an upper die mechanism is installed on a connecting support frame A1, an upper support table A2-2 is fixed at the upper end part of the connecting support frame A1, the tail part of the upper end of an upper lifting portal column A2-5 is fixed on the upper support table A2-2, the lower end of the upper lifting portal column A2-5 is fixed on cross beams positioned at two sides of the connecting support frame outside a sheet conveying chain, an upper lifting die table A2-4 is slidably arranged on the upper lifting portal column A2-5, and an upper die is installed on the upper lifting die table A2-4; the lower lifting die table A3-2 is fixedly connected with a lower lifting portal column, the lower lifting portal column is slidably arranged on a sliding sleeve seat, and the sliding sleeve seat is fixed on the supporting base; the bottom of the connecting support frame is fixed on the sliding sleeve seat and the support base to form an integral connection structure of an up-down lifting structure. Compare in the prior art about the pillar be a whole post, go up mold mechanism A2 and lower mold mechanism A3 and be provided with independent pillar respectively, the pillar of every mechanism is lighter, and the flexibility is stronger, is applicable to independent and the high-speed operation of mold mechanism A2 and lower mold mechanism A3.

Each lower die is correspondingly provided with a balance weight box which can slide on the placing seat and the lower lifting die table A3-2; a bolt A3-23 is arranged at one side of the bottom of the lower die, which is close to the balance weight box, a connecting plate is connected at one side of the balance weight box, which is close to the lower die, the front end of the connecting plate is provided with a bolt A3-23 hole, and the bolt A3-23 of the lower die can be inserted into the bolt A3-23 hole; when the lower lifting mould platform A3-2 descends to a proper position, the pin A3-23 of the two lower moulds are inserted into the pin A3-23 of the connecting plate of the corresponding balance weight box to form a balance linkage structure which can be mutually pulled to alternately exchange stations, the formed lower mould pushes the corresponding balance weight box out of the lower lifting mould platform A3-2 and enables the balance weight box to slide to a placing seat for standby, the balance weight box at the other side is pulled from the placing seat to the upper lifting mould platform A3-2 under the action of the bottom pin A3-23 of the corresponding lower mould with the jack as a force point, the lower mould at the material receiving and discharging standby conveying station is translated to the forming standby station and is transposed to the material taking and discharging standby conveying lower mould at the forming standby station, wherein the station is not a real object, the position for working is selected according to different spaces, sizes and internal layouts of a factory building according to actual conditions, the position of the station is not limited to the scope of the utility model, and the position of the lower die for receiving and discharging materials, waiting or conveying work is within the protection scope of the utility model.

In the embodiment, the bottom of each lower die is provided with the translational sliding bases A3-18, but it should be noted that the translational sliding bases A3-18 are not necessary, and only the translational sliding bases A3-18 are added, so that only the translational sliding bases A3-18 are modified without modifying all the lower dies, and the universality is higher. The lower dies are detachably mounted on the translational sliding seats, so that dies with different specifications can be conveniently replaced according to actual needs, the two translational sliding seats A3-18 are connected through traction bearing seats A3-25, sliders A3-21 are fixed at the bottoms of the translational sliding seats A3-18, the sliders A3-21 are slidably arranged on rails A3-22, the rails A3-22 are fixed on the lower lifting die table A3-2, clutch traction bolts A3-23 are arranged at the bottoms of the tail ends of the translational sliding seats A3-18, and when the translational sliding seats A3-18 are not used, the two lower dies are directly connected through connecting pieces and fixedly connected with the sliders at the bottoms. The translation driving device A3-4 of the lower die comprises a motor A3-41, a driving wheel A3-43 and a driving belt A3-42, wherein the driving wheel A3-43 is rotatably arranged on the lower lifting die table A3-2, the driving belt A3-42 is arranged on the driving wheel A3-43, the driving belt A3-42 is connected with one of the lower dies, and the motor A3-41 drives the driving wheel A3-43 and the driving belt A3-42 to rotate; the belts A3-42 directly or indirectly move the two lower molds in translation simultaneously, and the belts A3-42 may be connected to the lower molds in various ways, such as by special clamps, nails, screws, or other means.

Each lower die comprises a forming die cavity A3-11 and a demoulding unit A3-12, the demoulding unit A3-12 is provided with a demoulding plate A3-121 and a demoulding lifting plate A3-15, the demoulding plate A3-12 is provided with a demoulding device A3-14 according to the die cavity of the forming die cavity A3-11, the demoulding device A3-14 is composed of parting strips, and the shapes of the parting strips are set according to the shapes of the forming die cavities A3-11. The demoulding lifting plate A3-15 and the demoulding plate A3-12 are connected through a connecting rod A3-16, when demoulding, the telescopic rod of the demoulding cylinder A3-13 extends upwards to push the demoulding lifting plate upwards, the demoulding lifting plate drives the demoulding plate to move upwards, and the demoulding device of the demoulding plate drives the opening edge of the formed product to move upwards for demoulding. The bottom of the demoulding lifting plate A3-15 is provided with a demoulding clutch sliding rod A3-17 which passes through the bottom of the lower die and the translational sliding base A3-18; the telescopic rod of the demoulding cylinder A3-13 is fixedly connected with a demoulding top piece A3-19, the demoulding top piece A3-19 is provided with a mandril A3-20 upwards, and the mandril A3-20 upwards aligns to a demoulding clutch slide bar A3-17 of a lower mould demoulding unit during demoulding. Therefore, the demolding cylinder A3-13 can jack up the demolding lifting plate A3-15 in a limited space, the structure is compact, and the occupied space is small. In the prior art, a finished product is jacked up by a cup bottom rod assembly to separate the finished product from a lower die, but the finished product which is not fully cooled by jacking of the cup bottom rod assembly is easy to generate a concave point at the cup bottom or deform the cup bottom of the finished product.

When the lower lifting die table A3-2 is lifted to a proper position, when an upper die A2-1 and a lower die are closed, a cup-making sheet is clamped in a forming cavity of the upper die A2-1 and the lower die and is subjected to hot press forming, the other lower die synchronously finishes label taking, when the lower lifting die table A3-2 is lowered, a demoulding cylinder A3-13 of a demoulding unit A3-12 is lifted to enable a product to be separated from the forming cavity A3-11 and hung at a corner, and then the demoulding unit A3-12 is reset; when the lower lifting die platform A3-2 descends to a proper position, the traction clutch bolt A3-23 under the translational sliding base A3-18 of the lower die on the outer side of the forming station is inserted into the bolt A3-23 hole of the balance weight box A3-5 to form a translational linkage structure that the two lower dies are respectively dragged with the balance weight box A3-5 on the outer side. The bottom of the lower die close to the balancing weight box is fixedly connected with a attracted iron A3-24, and a connecting plate A3-51 of the balancing weight box A3-5 is provided with an electromagnet. The placing seat A3-6 is provided with a rotatable balance auxiliary wheel A3-61, and when the balance weight box A3-5 descends to a proper position, a connecting plate A3-51 at the bottom of the balance weight box A3-5 can be placed on the balance auxiliary wheel A3-61 in a sliding mode. In order to obtain better connecting and separating effects, after the bolt A3-23 is inserted into the bolt A3-23 hole, the electromagnet is simultaneously electrified to be connected with the attracted iron A3-24 in an adsorption mode, so that the connection between the lower die and the balance weight box A3-5 is strengthened, and the connection is firmer. When the lower die needs to be separated from the balance weight box A3-5, the electromagnet is powered off to remove the attraction force on the attracted iron A3-24, the lower lifting platform is lifted at the same time, and the bolt A3-23 leaves the bolt hole. In order to enable the balance weight box A3-5 to be more smoothly butted with a lower die, the placing seat A3-6 is provided with a balance auxiliary wheel A3-61, and when the balance weight box A3-5 is butted with the lower die, the balance auxiliary wheel A3-61 can support and cushion the attracted iron A3-24 of the balance weight box A3-5 to ensure that the balance weight box A3-5 is stably transited on a knife lifting platform.

The upper mold a2-1 and the lower mold A3-3 of the present embodiment are any devices that can lift the lower lifting platform, and may be hydraulic cylinders, air cylinders, or screw lifters, and the structure and operation principle of the conventional lifting driving device should be clearly understood by those skilled in the art.

It should be noted that the components of the motor A3-41, the cylinder, the electric furnace a4, the electromagnet, the driving wheel A3-43, the driving belt A3-42, the auxiliary wheel, etc. used in the present embodiment belong to the prior art, and the structure principle of the present invention should be clear in the art, but the thermoforming machine of the present invention formed by combining several components is an inventive invention, and the present invention has been described in detail by combining the embodiments and the drawings, but the detailed description of the embodiments does not limit the protection of the claims.

The in-mold labeling, conveying and boxing production line with one mold and three actions comprises the thermoforming machine A and two groups of label conveying groups, wherein the two lower molds of the thermoforming machine A move left and right to work alternately, each lower mold corresponds to one group of label conveying group respectively, and each group of label conveying group comprises an in-mold labeling manipulator B, a label transfer conveying device C, a label conveying manipulator D and a label bin EE. One of the key difference points of this production line and prior art lies in, when a lower mould is located the thermoforming station, another lower mould is located the subsides mark station, and labeling manipulator B in the mould puts into the lower mould of subsides mark station with label transfer conveyer C's label, realizes that every mould time three actions accomplish the interior subsides mark of mould, and is specific, and every mould time in the mould is labeled the time, and lower mould and mould in the action of labeling manipulator B including:

a three-action one-time in-mold labeling conveying and boxing production line, which comprises a thermoforming machine A and two groups of label conveying groups, wherein two lower molds of the thermoforming machine A move left and right to work alternately, and each lower mold corresponds to one group of label conveying groups;

each label conveying group comprises an in-mold labeling, taking and conveying manipulator, a label transfer and conveying device C, a label conveying manipulator D and a label bin E;

every mould time in the mould when labeling, the action of lower mould and in-mould labeling manipulator B including:

a first action: when the lower die of the forming station completes the forming of the product, the other lower die of the material taking and discharging station synchronously completes the taking of the label and the descending; an in-mold labeling manipulator B positioned on one side of the balance weight box translates to a label taking station while translating and replacing stations of the two lower molds, and finishes label receiving while a lower lifting mold platform A3-2 rises; when the label transferring and conveying device C synchronously ascends to finish label conveying, the lower lifting die platform A3-2 is communicated with the lower die to descend together, and the labeling manipulator B in the next die synchronously arrives at the label ascending and unloading station before arriving at the material receiving station; after the label transferring and conveying device and the label transferring and conveying device C reach respective material taking and discharging stations, the label conveying manipulator D continuously finishes descending and conveying labels, ascending after discharging, translating to the position above the label bin E, descending and taking labels, ascending and translating to the material taking station for standby before the label transferring and conveying device C reaches the material taking station;

a second action; the two lower dies are translated and exchanged with stations at the same time; synchronously translating the in-mold labeling manipulator B which finishes the label connection to a label conveying station for standby; the other in-mold labeling manipulator B which finishes label conveying synchronously translates to a label taking station, and the in-mold labeling manipulator B and the label conveying unit cooperatively operate according to programming presetting;

a third action: when one lower die rises and is matched with the upper die to prepare a product, the labeling manipulator B in the die, which is matched with the other lower die and is positioned at a standby station, sticks a label to the inner wall of the die cavity, and meanwhile, the two groups of label conveyor units are cooperatively operated according to preset programming.

And repeating the actions of the cup making machine and the in-mold label taking and conveying manipulator for the next mold, wherein the actions are operated by the PLC control system.

Example 2

The main technical solution of this embodiment is substantially the same as that of embodiment 1, and the features that are not explained in this embodiment adopt the explanations in embodiment 1, and are not described herein again. In the embodiment, the device is also connected with a plastic container stacking and conveying unit, a sheet of the cup making machine is formed at a forming station, and then the sheet is carried to a punching and shearing station by a sheet conveying chain rail, is punched and sheared by a punching and shearing machine F, and then is conveyed to a finished product receiving and conveying device G, and the rest edge is conveyed to a rolling station;

the position and the operation characteristics of the plastic container stacking, conveying and boxing unit are as follows: the receiving tray of the receiving stacking and conveying device H is positioned outside the finished product receiving and conveying device G, the finished product receiving and conveying device G lifts and conveys products to a receiving and discharging conveying manipulator G2 from a lifting and discharging device G1 after receiving and stacking, the receiving and discharging conveying manipulator G2 runs to the position above the receiving tray positioned outside the finished product receiving and stacking and storing device G to vertically discharge, the receiving tray is translated to a drawing inspection station or a discharging station after receiving and conveying, the transferring and conveying manipulator I receives the materials in rows and moves back and forth to the receiving station and indirectly discharges the materials by the single-row whole-strip receiving and stacking lateral conveying device J to vertically receive and stack the materials, the products are pushed to a limiting receiving and overturning transverse quantitative conveying device K after receiving the materials, the limiting receiving and overturning transverse quantitative conveying device K then conveys the products to a receiving and quantitative conveying platform L, the receiving and quantitative conveying platform L pushes the products to the receiving and discharging trays which are provided with limiting positions on two sides of the receiving and stacking and quantitative conveying device M, the layer-by-layer material-receiving quantitative conveying device M conveys the whole product tray with the material-receiving tray into the paper box placed in the multi-specification conveying boxing device N, and the operation is repeated until the box is filled.

The punching and shearing machine F, the finished product receiving and conveying device G, the receiving and stacking and conveying device H, the transfer conveying manipulator I, the single-row whole receiving and stacking lateral conveying device J, the limiting receiving and overturning transverse quantitative conveying device K, the receiving quantitative conveying platform L, the receiving material quantitative conveying device M and the multi-specification conveying and boxing device N can adopt the equipment in the prior art. However, in the present embodiment, the structure of each of the aforementioned apparatuses adopts the most preferable embodiment of the present invention.

In the embodiment, the finished product receiving and conveying device G comprises a discharging mechanism, a finished product collecting device G2 and a multi-mode secondary receiving and conveying manipulator, wherein the discharging mechanism is provided with a plurality of discharging ejector rods G1 and a discharging lifting driving device G3-7, and the discharging lifting driving device G3-7 drives the discharging ejector rods G1 to ascend or descend; the finished product collecting device G2 is located above the discharging mechanism, the finished product collecting device G2 is provided with a limiting support plate G2-1, the limiting support plate G2-1 is provided with a through hole G2-2 corresponding to each discharging ejector rod G1, a plurality of limiting rods G2-3 are arranged around the through hole G2-2, a material receiving storage channel G2-4 is formed among the plurality of limiting rods G2-3, and each limiting rod G2-3 is provided with a limiting card G2-5; the multi-mode secondary material receiving conveying manipulator comprises a plurality of groups of storage conveying assemblies G3-1, a conveying support plate G3-5, a translation driving device G3-5, a lifting driving device G3-7 and a discharging assembly, wherein the conveying support plate G3-5 is positioned above a finished product collecting device G2, the plurality of groups of storage conveying assemblies G3-1 are all installed on the conveying support plate G3-5 and are driven by the translation driving device G3-5 to translate, each group of storage conveying assemblies G3-1 is composed of a plurality of storage limiting rods G3-2 with protruding points G3-3 at the lower ends, and a storage conveying cavity G3-4 is formed among a plurality of storage limiting plates; the unloading assembly is arranged on the part below the non-collision storage conveying assembly G3-1 and above the storage conveying cavity G3-4, and the lifting driving device G3-7 can enable the storage conveying cavity G3-4 and the unloading assembly to move relatively. The discharging assembly consists of a plurality of parallel plate pieces G3-8, and the plate pieces G3-8 can be inserted between conveying limiting rods G2-3 of each group of material taking and conveying assemblies; during discharging, the translation driving device G3-5 drives the storage conveying assembly G3-1 to translate to a preset station, at the moment, the plate G3-8 is inserted into the storage conveying cavity G3-4, the lifting driving device G3-7 drives the storage conveying assembly to ascend, and the plate G3-8 presses the products in the storage conveying cavity G3-4 to enable the stacked products to be placed in the receiving placement position and enable the stacked products to fall down. After the finished product is molded by a cup making machine of a cup making machine, the finished product is formed and half-hung on the sheet, the finished product is unloaded, collected and stacked to be conveyed to next equipment by the finished product receiving and conveying device G of the embodiment, when the finished product is taken from the sheet, the unloading lifting driving device drives the unloading ejector rod G1 to ascend to push the finished product half-hung on the sheet upwards and separate the finished product from the corner of the sheet, the lifted product is conveyed into the material receiving and storing channel G2-4 of the finished product collecting device G2 and clamped on the limiting card G2-5, after repeated operation is carried out until the stacking is completed in the material receiving and storing channel, the unloading lifting driving device drives the unloading ejector rod G1 to push the whole stacked product into a material storing and conveying cavity G3-4 formed by the material storing and conveying component G3-1, the translation driving device G3-5 drives the material storing and conveying component G3-1 to translate to a preset station, at the moment, the plate G3-8 is inserted into the storage conveying cavity G3-4, the lifting driving device G3-7 drives the storage conveying assembly to ascend, and the plate G3-8 presses the products in the storage conveying cavity G3-4 so that the stacked products are placed in the receiving placement positions and fall down. It should be noted that, the lifting driving device G3-7 can drive the storage conveying assembly to ascend or descend as required to match the height of the receiving conveying device H, and when the lifting driving device G3-7 drives the storage conveying assembly to descend and discharge to the receiving conveying device H, the embodiment is further provided with a panel lifting driving device G3-9, at this time, the panel lifting driving device G3-9 drives the panel G3-8 to descend to push the product down to the receiving tray H1 of the receiving conveying device H.

The receiving material conveying device H of the present embodiment is provided with a translation supporting framework H2, a translation driving device (not shown in the figure) and a receiving tray H1, wherein the receiving tray H1 is slidably disposed on the translation supporting framework H2 through a rail and a slider, and the translation driving device drives the receiving tray H1 to move. The receiving tray H1 is provided with a tray body and a receiving plate, the receiving tray H1 is provided with a plurality of receiving holes, and cup molds are placed in the receiving holes; or the receiving disc H1 is provided with a plurality of rows of receiving frames, and other receiving frames except the last row of receiving frames can independently lift and unload materials in a single row; or the material receiving disc H1 is provided with a plurality of material receiving grooves which are parallel to each other, and a limiting division bar is arranged between every two adjacent material receiving grooves. Different receiving trays H1 can be selected according to different cup types. The translation driving device may be composed of a motor and a transmission assembly, and the specific installation manner is conventional means, which should be clearly understood by those skilled in the art. It should be noted that the translation driving device may also be an electric push rod, an electric lead screw, or other driving devices, as long as it can drive the take-up pan H1 to move.

The number of the receiving trays H1 can be two, and the two receiving trays H1 operate alternately.

The transfer conveying manipulator is provided with a support fork I1, a material pressing limiting plate I2, a material pressing cylinder I3, a dislocation driving cylinder I4, a connecting seat I5, a translation lifting supporting seat I6, a lifting driving device and a translation driving device I8, and the front end of the support fork is provided with a plurality of material taking forks I1-1; the material pressing cylinder I3 drives the material pressing limit plate I2 to ascend or descend, and the material pressing cylinder I3 drives the material pressing limit plate I2 to descend to press the product to clamp the product up and down, so that the transfer conveying manipulator I can meet the conveying requirements of various cup-shaped products and products with different sizes without worrying about the phenomenon that the stacked products are unstable and fall or are scattered; the supporting fork I1 and the material pressing cylinder I3 are arranged on the connecting seat I5, and the dislocation driving cylinder I4 can drive the supporting fork to move leftwards or rightwards, so that the smooth conveying of cup pieces in dislocation and non-dislocation arrangement is met. The lifting driving device is arranged on the translation lifting supporting seat I6 and drives the connecting seat I5 to ascend or descend, the translation lifting supporting seat I6 is driven to translate by the translation driving device I8, and the translation driving device I8 is composed of a motor, a driving wheel and a driving belt. Compared with the prior art, the transfer conveying manipulator is simpler and more reasonable in structure, convenient to operate and lower in manufacturing cost. In the embodiment, the lifting driving device comprises a rack I7-1, a gear I7-2, a transmission shaft I7-3 and a motor I7-4, wherein the lower end of the rack is fixedly connected with the connecting seat, teeth of the rack are meshed with the gear, the gear is fixedly connected with the transmission shaft, and the transmission shaft is rotatably arranged on the translation lifting supporting seat and is driven by the motor to rotate.

The single-row whole piece stacking lateral conveying device J comprises a clutch limiting material receiver J1, a frame J2, a lifting material receiving platform J3, a lifting driving device J4, a pushing material discharging plate J5 and a lateral pushing device J6, wherein the lifting material receiving platform J3 is located in the frame J2, the lifting driving device J4 drives the lifting material receiving platform J3 to lift, and the clutch limiting material receiver J1 is located on the upper portion of the frame J2 and above the lifting material receiving platform J3 to conveniently receive products transferred by a transfer conveying manipulator. The clutch limiting material receiver J1 comprises two forward and reverse screw rods J1-1, two clutch limiting rod supporting seats J1-3, a plurality of material receiving limiting rods J1-5 and a forward driving device, wherein the two forward and reverse screw rods J1-1 are respectively and rotatably arranged on clutch transmission supporting seats J1-10, the clutch transmission supporting seats J1-10 are fixed on the upper part of a frame J2, and two ends of each screw rod are arranged on the clutch transmission supporting seats J1-10 on two sides through bearings. The end parts of the same sides of the two screw rods are provided with driving wheels J1-11, the driving wheels J1-11 are connected through a driving belt J1-12, a positive and negative driving device can drive the two screw rods to synchronously rotate in a positive direction or a negative direction, the two positive and negative screw rods J1-1 are respectively provided with two screw rod nuts J1-2 which can move in opposite directions or in opposite directions, the two screw rod nuts J1-2 of each screw rod are respectively fixedly connected with the two ends of a clutch limiting rod supporting seat J1-3, in the embodiment, each clutch limiting rod supporting seat J1-3 is provided with an aluminum profile and two aluminum profile connecting pieces, the two ends of the aluminum profile are respectively fixedly connected with the two aluminum profile connecting pieces, each aluminum profile connecting piece is correspondingly connected with one screw rod nut J1-2, and the material receiving limiting rod J1-5 can be locked at any position of the aluminum profile due to the special structure of the aluminum profile, the installation is convenient, the position adjustment is convenient, and the requirements of products with different specifications can be met. When the forward and reverse driving device can drive the two screw rods to synchronously rotate forward or reversely, the two clutch limiting rod supporting seats J1-3 can relatively approach or move away from each other. The forward and reverse driving device comprises an air cylinder, a rack J1-8 and a gear J1-9, wherein the air cylinder drives the rack J1-8 to ascend or descend, the rack J1-8 is in meshing transmission with the gear J1-9, the gear J1-9 is fixedly connected with a screw rod to drive the screw rod to rotate so as to enable two screw rod nuts J1-2 on the screw rod to move in an opposite direction or in a reverse direction, and the screw rod nut J1-2 drives a clutch limiting rod supporting seat J1-3 to move.

The clutch limiting rod supporting seat J1-3 of this embodiment is all installed with many and connects material limiting rod J1-5, and clutch limiting rod supporting seat J1-3 installs gag lever post mounting J1-4 through welding or bolt, gag lever post mounting J1-4 and connect material gag lever post J1-5 rigid coupling, and every connects material gag lever post J1-5 to be equipped with spacing rand J1-6 and is used for bearing cushion goods, and this spacing rand J1-6 directly embolias connects material gag lever post J1-5 and blocks in gag lever post mounting J1-4's top.

The lifting driving device J4 comprises a lifting driving wheel J4-11, a lifting transmission belt J4-12 and a lifting driving motor 4-3, wherein a lifting material receiving platform J3 is connected with the lifting transmission belt J4-12 through a connecting assembly, guide rails are respectively arranged on two sides of the lifting transmission belt J4-12, and the lifting material receiving platform J3 is connected with slide blocks of the guide rails through the connecting assembly.

The pushing discharging plate J5 is located in the frame J2 and perpendicular to the lifting material receiving platform J3, the lateral pushing device J6 drives the pushing discharging plate J5 to laterally translate, the lateral pushing device J6 comprises a lateral pushing driving device and a pushing connecting seat, the pushing discharging plate J5 is installed on the pushing connecting seat, and the pushing connecting seat is driven by the lateral pushing driving device to laterally translate so as to push the material out of the frame J2. The lateral pushing driving device consists of a lateral pushing motor, a lateral pushing driving wheel, a lateral pushing transmission shaft and a lateral pushing transmission belt, and the lateral pushing transmission belt drives the sliding seat to laterally translate; the lateral pushing driving device is also an air cylinder or other devices capable of driving the sliding seat to move laterally.

Spacing material horizontal ration conveyer that connects upset includes conveying platform K1, discharge drive arrangement K2, connect material translation unloading connecting seat K3, the push plate K4 of unloading, telescopic cylinder K5 and flexible material unloading board K6 that connects, conveying platform K1's the back is equipped with upset supporting seat K7 and upset location connecting seat K8, upset location connecting seat K8 rotationally installs in upset supporting seat K7 through the round pin axle, upset location connecting seat K8 drives actuating cylinder K9's telescopic link with the upset and articulates. The lifting gate K10 device is installed to spacing material receiving upset horizontal quantitative conveyer's feed inlet, and lifting gate K10 device is including lifting gate K10 and lift cylinder K11, and lift cylinder K11 drive lifting gate K10 rises or descends. Still be provided with lift drive and upset conveying limit brake K16, lift drive is including elevator motor K12, lifting gear K13, lifting rack K14, lift limit guide rail K15, lifting gear K13 install in elevator motor K12's output shaft and with lifting rack K14 meshing transmission, lifting rack K14's back rigid coupling lift limit guide rail K15, lifting rack K14 and lift limit guide rail K15's lower extreme is connected with the upset limit brake. In the embodiment, the unloading driving device K2 is installed above the conveying platform K1 and drives the material receiving translational unloading connecting seat K3 to translate, the unloading push plate K4 is fixed in front of the material receiving translational unloading connecting seat K3, the telescopic cylinder K5 is installed on the translational unloading connecting seat, the telescopic material receiving unloading plate K6 is installed on the telescopic rod of the telescopic cylinder K5, the material receiving limit gate L7 which can be matched with the material receiving quantitative conveying platform L is arranged to convey, when the unloading push plate K4 pushes the product to the limit, the tail end of the product is still left on the conveying platform K1, at the moment, the telescopic cylinder K5 is needed to push the product forward to enable the product to enter the conveying platform L1 from the conveying platform K1, but the telescopic material receiving unloading plate K6 cannot return immediately after pushing is finished, otherwise the product is scattered, especially, for the cover, dish and other low-body-shaped products, the front and back ends of the product cannot be scattered all by constantly limiting, after the telescopic material receiving and discharging plate K6 is pushed, the material receiving limit brake L7 of the material receiving quantitative conveying platform L is returned and reset after the material receiving limit lifting driving device descends to a proper position and is blocked at the tail end of a product. When the limiting material receiving overturning transverse quantitative conveying device K finishes discharging and pushing in place and the telescopic discharging plate retracts, the material receiving limiting brake L7 of the material receiving quantitative conveying platform L is descended by the material receiving limiting lifting driving device; when the limiting material receiving overturning transverse quantitative conveying device resets, the material receiving limiting gate descends again, so that the limiting material receiving overturning transverse quantitative conveying device K and the material receiving quantitative conveying platform L are matched to convey products, after conveying is completed, the products are all limited in the material receiving quantitative conveying platform L and cannot collapse, and meanwhile, the limiting material receiving overturning transverse quantitative conveying device K can reset to start next action.

The material receiving quantitative conveying platform L comprises a conveying platform L1, a limiting plate L4, an attaching plate L5, an attaching driving device L6, a material receiving limiting brake L7, a material receiving limiting lifting driving device and a discharging pushing device L13, the material receiving limiting brake L7 is positioned at a feed inlet on one side of the conveying platform L1 and is driven to lift by the material receiving limiting lifting driving device, the limiting plate L4 is arranged on the other side of the feed inlet of the conveying platform L1, the discharging pushing device L13 is arranged above the conveying platform L1 to push out a product to be conveyed to the material receiving quantitative conveying device, the conveying platform L1 is provided with a sliding groove L2, a fixed connecting piece of the attaching plate L5 penetrates through the sliding groove L2 to be fixed on a sliding block and slides on a track L11 through the sliding block, the track L11 is fixed on a support frame L3 below the conveying platform L1, the attaching driving device L6 comprises a motor L8, a driving wheel and a driving belt, the driving wheel are arranged at the front end and the back end of the conveying platform L1, the conveyer belt is installed in transfer wheel and is driven the motion by motor L8, the drive belt is connected with the shift fork, after unloading is accomplished to the pusher L13 of unloading, shift fork propelling movement backup plate L5 to spacing connecing the standby of the horizontal quantitative transfer device discharge gate of material upset, the spacing unloading push plate L14 who connects the horizontal quantitative transfer device of material upset of deuterogamying connects the material, when spacing unloading drive arrangement who connects the horizontal quantitative transfer device of material upset and unloading the propelling movement goods, article promote backup plate L5 and slide and return the below of limiting plate L4.

The receiving limiting lifting driving device of the receiving quantitative conveying platform L comprises a motor L8, a gear L9, a rack L10, a rail L11, a sliding block and a sliding block supporting seat L12, wherein the sliding block is fixed on the sliding block supporting seat L12, the rail L11 is in sliding connection with the sliding block, the back of the rack L10 is fixedly connected with the rail L11, the lower ends of a rack L10 and the rail L11 are both connected with a receiving limiting brake L7, the rack L10 is in meshing transmission with the gear L9, the gear L9 is installed on an output shaft of the motor L8, the gear and rack are matched for transmission, so that the receiving limiting brake L7 can realize multiple lifting of the receiving limiting brake L7 at any distance, and the lifting effect is good.

The material receiving quantitative conveying platform L is used for pushing a feeding hole of the layer-by-layer ascending boxing device through the discharging pushing device L13, and the discharging pushing device drives the descending product to be pushed to the layer-by-layer ascending boxing device.

The quantitative conveying device for material pressing and layer bonding is arranged on a quantitative conveying support M1 and drives a conveying table M7 to lift, the quantitative conveying device for material pressing and layer bonding comprises a motor M2, a lifting support seat M3, a sliding block, a gear, a rack M4, a guide rail M5 and a lifting connecting plate M6, the motor M2 is arranged on the outer side of the lifting support seat M3, the sliding block is fixedly connected to the side face of the lifting support seat M3, the guide rail M5 is slidably arranged on the sliding block, the guide rail M5 is fixedly connected with the rack M4, the rack M4 is meshed with the gear arranged on a rotating shaft of the motor M2 for conveying, the lifting support seat M3 is provided with a sliding sleeve, the sliding sleeve is slidably provided with a sliding rod, the upper end portion of the rack M4 and the upper end portion of the guide rail are fixedly connected with the bottom of a translation pushing framework, and the lower end portion of the sliding rod, the rack M4 and the lower end portion of the guide rail are fixedly connected with the lifting connecting plate M6. The lifting can be realized by utilizing the meshing transmission of the rack M4 and the gear to lift for a plurality of times and at any distance, and the meshing transmission effect of the teeth is more stable and the loading performance is stronger.

Wherein, the pushing device comprises a translational pushing supporting framework M11, a translational pushing driving device M5, a translational lifting support platform M13, a lifting driving source M14, a lifting connecting framework M15, a material pushing plate M16, a cylinder fixing seat M17, a bolt lifting cylinder M18, a bolt connecting plate M19 and a bolt M20, the translational lifting support platform M20 is slidably arranged on the upper part of the translational pushing supporting framework M20 through a guide rail and a slide block and is driven to translate by the translational pushing driving device M20, the lifting driving source M20 is arranged on the translational lifting support platform M20 and drives the lifting connecting framework M20 to lift, the front lower part of the lifting connecting framework M20 is fixedly connected with the material pushing plate M20, the back of the lifting connecting framework M20 is fixed with the cylinder fixing seat M20, the bolt lifting cylinder M20 is arranged on the cylinder fixing seat M20 and independently drives the bolt M20 to lift the bolt M20, the bolt M20 is fixed at the bottom of the bolt M20, the bolt M20 can be inserted into a bolt hole M20-1 of the material bearing plate M20 to enable the material pushing plate to move along with the material pushing plate M20, the material bearing disk M8 is slidably arranged on the conveying platform M7. Meanwhile, the material pushing plate M16 of the embodiment can be moved to the rear of the material bearing plate by the translation pushing support framework M11 to push the product of the material bearing plate M8 forward for a certain distance so that the product of the material bearing plate M8 leaves the position of the pin hole M8-1 on the material bearing plate M8, and by adopting the structure, the pin M20 can be smoothly inserted into the pin hole M8-1, and a lifting material pushing device which is specially used for pushing the product for a small distance and cannot influence normal material pushing is not required to be added, so that the structure is reasonable, the operation is simple and rapid, and the working efficiency is effectively improved. In this embodiment, the discharging gate lifting driving device M3 is located on the upper portion of the front end of the lifting pushing support framework, the discharging gate lifting driving device M3 drives the discharging gate M2 to ascend or descend, and the lifting of the gate plate is used to limit the movement of the product during the non-pushing process to avoid the falling or scattering of the product.

The multi-specification material receiving, conveying and boxing device can be a simple shelf capable of placing cartons, and can also adopt boxing equipment in the prior art, but in order to realize full automation of a unit, the multi-specification material receiving, conveying and boxing device of the embodiment is set as a multi-specification material receiving, boxing and conveying device independently developed by the applicant. Specifically, the multi-specification material receiving box conveying device of the embodiment is provided with a diaphragm ferrule N1-3, a material receiving translation and rotation driving unit N3, a lifting driving device N4, a carton placing unit N1 and a diaphragm ferrule removing unit N2, a magnetic attraction part N1-31 capable of being attracted by magnetic substances is arranged on the upper frame of the diaphragm ferrule N1-3, and the material of the ferrule N1-3 of the embodiment can be iron. Initially, the film bag is sleeved into the carton N5, the carton N5 is placed in the carton placing unit N1, the lifting driving device N4 drives the carton placing unit N1 to drive the carton N5 and the diaphragm ferrule N1-3 to ascend and be aligned with the diaphragm ferrule removing unit N2 for detection, and the two groups of telescopic driving devices of the diaphragm ferrule removing unit N2 enable the removing electromagnet N2-1 and the magnetic suction part N1-31 of the diaphragm ferrule N1-3 to be accurately aligned. After the alignment verification is finished, the lifting driving device N4 drives the paper box N5 and the diaphragm ferrule N1-3 to descend and translate to the position below a box opening limiting mechanism N3-1 of the material receiving translation and rotation driving unit N3, the lifting driving device N4 enables the paper box N5 and the diaphragm ferrule N1-3 to ascend, the paper box N5 is clamped to the box opening limiting mechanism N3-1, and the material receiving translation and rotation driving unit N3 enables an overturning opening of the paper box N5 to face a material receiving and boxing device M for receiving materials. The problem that the prior art is very difficult to solve in bagging and boxing is that after a film bag is sleeved in a carton, if a machine device is used for automatically loading products, the film bag is easy to deviate, shift, fall or slide into a box bottom, so that the prior art often has two difficulties in selecting, or automatically boxing without sleeving the product with a large film bag as a whole, and the mode only can disperse and take the materials when taking the materials from the carton, easily pollutes and stains the products and does not meet the sanitary requirements; or the film bags are sleeved firstly and then the products are put one by one manually, but the working efficiency is low and the products are not placed orderly (influenced by various unstable factors of workers), and the film bags are fixed by the diaphragm ferrule N1-3 in the utility model, so that the problems of buckling, shifting, slipping and the like of the film bags can be effectively prevented, and meanwhile, the functions of automatically boxing and pulling out the diaphragm ferrule N1-3 after the film bags are sleeved are realized by matching with other equipment, so that the product sanitation, the orderly boxing of the products and the high working efficiency are ensured. The carton placing unit is provided with a carton limiting frame N1-1 and a clutch supporting side plate N1-14 which can bear the carton, the side surface of the clutch supporting side plate N1-14 is provided with a guide rail N1-17, the guide rail N1-17 is slidably provided with a sliding block N1-18, the sliding block N1-18 is fixedly connected with a bolt connecting seat N1-19, the bolt connecting seat N1-19 is provided with a bolt N1-20, the bolt connecting seat N1-19 can be fixedly connected with the aluminum profile through screws, the bolt connecting seat N1-19 can be locked at different positions of the aluminum profile according to actual needs, and in actual application, the positions and the number of the bolt N1-20 and the bolt connecting seat N1-19 can be adjusted according to specific conditions, but the technical scheme of adjusting the positions and the number is within the protection scope of the utility model. And a bolt hole seat N3-2 is fixed on a back plate of a rotating seat N3-5 of the material receiving translation and rotation driving unit N3 corresponding to a bolt N1-20, a bolt hole is formed in the bolt hole seat N3-2, the bolt N1-20 and a bolt hole of a bolt hole seat N3-2 are correspondingly assembled and spliced, and when the lifting driving device N4 drives the carton placing unit N1 to ascend towards the box opening limiting mechanism N3-1, the bolt N1-20 can be inserted into the bolt hole seat N3-2 corresponding to the back plate of the rotating seat N3-5 to play a role in reinforcing connection. In order to further enhance the firmness of connection, the back plate of the rotating seat N3-5 in this embodiment may further be provided with an electromagnet for adsorbing the clutch support side plate N1-14 to adsorb the column diaphragm ferrule N1-3 and the carton N5, and the diaphragm ferrule N1-3 is provided with a portion that can be adsorbed by the electromagnet, or may be made of iron entirely, or may be made of iron as the main body of the portion that needs to be adsorbed by stainless steel.

In order to realize the turning of the carton, a rotating shaft N3-8 is fixedly connected to the lower portion of a rotating seat N3-5 of the material receiving translational and rotational driving unit N3 of the embodiment, the rotating shaft N3-8 is rotatably mounted on a bearing seat N3-9, the bearing seat N3-9 is fixed to a translational and rotational connecting seat N3-10, the upper portion of the rotating seat N3-5 is hinged to one end of a rotating connecting rod N3-11, and the other end of the rotating connecting rod N3-11 is pushed and pulled by an air cylinder N3-12. The box opening limiting mechanism N3-1 comprises a box opening gate supporting frame N3-2, a gate N3-3 and a gate driving device N3-4, the box opening gate supporting frame N3-1 is installed on a rotating seat N3-5 of the material receiving translation and rotation driving unit N3, and taper limiting blocks N3-6 are arranged on the inner sides of four corners of the box opening gate supporting frame N3-1; the gate driving device N3-4 is arranged at the side edge of the box port gate support frame N3-1 and drives the gate N3-3 to move through a connecting plate N3-13. The box opening of the carton N5 is clamped in the box opening limiting mechanism N3-1 and rotates together with the box opening limiting mechanism N3-1 along with rotation, the rotating box opening is butted with a discharge opening of the layer-by-layer material conveying device, and the gate N3-3 ascends gradually under the action of the gate driving device N3-4 so as to prevent products conveyed into the carton N5 in the layer-by-layer material conveying device from falling out.

In this embodiment, the lifting driving device N4 comprises a motor, a transmission assembly, a gear and a mechanism consisting of racks 4-12, wherein the rack is connected with the clutch lifting seat, the gear is meshed with the rack, and the gear is driven by the motor to rotate through the transmission assembly.

In this embodiment, the diaphragm ferrule removing unit includes a removing support frame N2-4, an adjustable stroke cylinder N2-3, a removing lifting structure N2-2 and an electromagnet N2-1, the adjustable stroke cylinder N2-3 is mounted on the removing support frame N2-4 and drives the removing lifting structure N2-2 to lift, the removing lifting structure N2-2 is provided with an electromagnet N2-1 capable of adsorbing the diaphragm ferrule, wherein a frame of the removing lifting structure N2-2 is formed by an aluminum profile, the electromagnet N2-1 is mounted at any position of the aluminum profile through a connecting piece, and the position of the electromagnet N2-1 on the aluminum profile can be adjusted at any time as required. When the specification of the carton needs to be changed, the clutch carton placing unit automatically operates to adjust the limiting block according to the size and the specification corresponding to the carton opening limiting mechanism, and then operates to the diaphragm ferrule removing unit to adjust the electromagnet, so that the operation can be performed according to the action after the verification is completed.

Example 3

The main technical solution of this embodiment is substantially the same as that of embodiment 1, and the features that are not explained in this embodiment adopt the explanations in embodiment 1, and are not described herein again. The difference between the embodiment and the embodiment 1 is that the lower lifting driving device comprises an upper rotary supporting seat 125-3, a lower rotary supporting seat 3-1, an upper lifting motion crank 5-1, a lower lifting motion crank 3-3, a positioning lifting shaft, a vertical lifting limit slider 10, a lever pressing and pulling lifting crank 2, a forward and reverse rotation driving crank 1-4, a positioning rotation sliding lever crank 4, a positioning lifting shaft 9 and a push and pull driving mechanism, wherein the push and pull driving mechanism is a servo motor 1-1, the servo motor 1-1 is provided with a speed reducer 1-2, and the forward and reverse rotation driving crank 1-4 is fastened on a driving shaft 1-3 of the speed reducer 1-2.

In this embodiment, the lower end of the lower lifting exercise crank 3-3 is connected to the lower rotary support base 3-1 through a hinge shaft in a relatively rotatable manner, the upper end of the lower lifting exercise crank 3-3 is connected to the positioning rotary slide lever crank 4 through a hinge shaft in a relatively rotatable manner, and the upper end of the positioning rotary slide lever crank 4 is connected to the lower end of the upper rotary support base 125-3 through a hinge shaft in a relatively rotatable manner. The lower tail end part of the positioning rotary sliding lever crank 4 is connected with one end of the lever pressing and pulling lifting crank 2 in a way of relative rotation through a shaft; the other end of the lever pressing and pulling lifting crank 2 is connected with a forward and reverse rotation driving crank 1-4 in a way of being opposite to a rotating shaft, and the forward and reverse rotation driving crank 1-4 is driven to rotate by a push-pull driving mechanism. The articulated shaft 8 between the upper lifting motion crank 5-1 and the positioning rotation sliding lever crank 4 simultaneously passes through the upper connecting end of the positioning rotation sliding lever crank 4 and the upper lifting motion crank 5-1, so that the upper connecting end of the lifting arm 4-1 of the positioning rotation sliding lever crank 4 is relatively rotatably connected with the upper lifting motion crank 5-1, one end of the upper lifting motion crank 5-1 is relatively rotatably connected with the articulated shaft 5-2, the upper connecting end of the lifting arm 4-1 of the positioning rotation sliding lever crank 4 is relatively rotatably connected with the other end of the upper lifting motion crank 5-1, and by utilizing the lever motion principle similar to a human body skeleton system, in the swinging process of the positioning rotation sliding lever crank 4, the upper lifting motion crank 5-1 rotates along with the articulated shaft to vertically lift or horizontally turns to fold and descend, and linkage is realized.

The articulated shaft 7 between the upper end of the lower lifting motion crank and the positioning rotary sliding lever crank simultaneously penetrates through the middle turning part 4-2 of the positioning rotary sliding lever crank 4 and the lower support connecting rod, so that the middle turning part 4-2 of the positioning rotary sliding lever crank 4 is rotatably arranged at the other end of the lower lifting motion crank 3-3 to be used as a lever fulcrum, an object is driven to lift by utilizing the lever principle, and the device is labor-saving and convenient. In order to obtain the best lifting driving effect, the positioning rotating sliding lever crank 4 of the embodiment is divided into two parts, specifically, a lifting arm 4-1 and a power arm 4-3, an included angle between the lifting arm 4-1 and the power arm 4-3 is an obtuse angle, the power arm 4-3 is connected with a lever to press and pull the lifting crank 2, wherein the middle turning part 4-2 of the positioning rotating sliding lever crank 4 is used as a fulcrum of the power arm 4-3 and the lifting arm 4-1, and in order to realize large-amplitude lifting, the length of the lifting arm 4-1 is greater than that of the power arm 4-3. The positioning rotating sliding lever crank 4 is set to be similar to an L shape, the middle turning part 4-2 is used as a fulcrum to support the upper rotating component to lift by utilizing a lever principle, the lifting amplitude is mainly influenced by the length of the lifting arm 4-1, the lifting arm 4-1 can rotate to be vertical or rotate to be folded by utilizing the middle turning part 4-2 as the fulcrum with a small rotating angle, the influence of the bending degree of the lifting crank 2 pressed and pulled by the lever is small because the required rotating angle is small, and the lifting arm 4-1 can realize large-amplitude lifting. In addition, the prior art drives the lifting by using torque, the bearing of the mechanism is limited due to limited torque, and the mechanism cannot drive heavy articles or equipment to lift, but the utility model adopts a lever principle, the mechanism can be easily lifted or lowered even if the bearing of the mechanism is heavy, the bearing effect is better, and the utility model is also provided with a vertical lifting limit slider, so that a positioning lifting shaft moves along the vertical direction to realize lever linkage lifting, and through mechanical tests, if the positioning lifting shaft does not move in a fixed lifting chute by the limit of the vertical lifting limit slider, the effect of rapid lifting of large tonnage can not be achieved. The present embodiment further includes a vertical lifting limiting sliding member 10 and a vertical lifting limiting fixing member 11 cooperating with the positioning rotating sliding lever crank 4, specifically, the positioning lifting shaft 9 passes through the positioning rotating sliding lever crank 4, and a bearing is installed between the connecting portion of the positioning lifting shaft 9 and the positioning rotating sliding lever crank 4. Two ends of the positioning lifting shaft 9 are fixedly connected with vertical lifting limiting sliding pieces, and each vertical lifting limiting sliding piece is slidably arranged on a vertical lifting limiting fixing piece 11 of a supporting seat 12 on one side; the vertical lifting limiting sliding part 10 and the vertical lifting limiting fixing part 11 can limit the positioning lifting shaft 9 to move in the vertical direction all the time, so that enough support can be provided for the positioning rotating sliding lever crank 4 during rotation so as to tilt an object (such as a lower die of a cup making machine), and if the assistance combined action of the vertical lifting limiting sliding part 10 and the vertical lifting limiting fixing part 11 is not provided, the positioning rotating sliding lever crank 4 cannot realize the lifting driving of a large-tonnage object in practice. When the lifting device ascends, the vertical lifting positioning sliding piece and the vertical lifting sliding piece 11, the link shaft between the upper rotary supporting base and the lower rotary supporting base and the positioning lifting shaft 9 can form a limiting vertical lifting structure with three points in a line. It should be noted that the vertical lift limiting sliding element 11 may also be an integrated structure, in this case, the stationary supporting seat 12 is mounted with a stationary sliding sleeve 12-1, and the vertical lift limiting sliding element 10 is slidably disposed on the sliding sleeve 12-1.

The positions of the stations described in all the above embodiments are only the positions where the specific equipment implements a certain function, and the positions of the stations can be determined according to the actual plant space, layout and volume of the equipment, and the actual positions of the stations do not form a limitation to the scope of protection of this patent, and it is clear and clear for a person skilled in the art to arrange the stations of the equipment according to the actual situation.

Finally, it should be noted that the above embodiments are only used for illustrating the technical solutions of the present invention and do not limit the protection scope of the claims. It will be understood by those skilled in the art that various modifications and equivalents may be made to the embodiments of the present invention without departing from the spirit and scope of the utility model.

Claims (11)

1. Thermoforming machine, including last mold mechanism, lower mold mechanism and electric stove, last mold mechanism is provided with mould, its characterized in that: the lower die mechanism is provided with two lower dies, a lower lifting die table, a lower lifting driving device and a translation driving device, the two lower dies are slidably arranged on the lower lifting die table, and the lower lifting die table can be driven by the lower lifting driving device to ascend or descend so as to enable the lower dies to be matched with the upper die or to be separated from the upper die in a die opening mode;

each lower die is correspondingly provided with a balance weight box, and the balance weight box can slide on the placing seat and the lower lifting die table;

a bolt is arranged at one side of the bottom of the lower die, which is close to the balance weight box, a connecting plate is connected at one side of the balance weight box, which is close to the lower die, a bolt hole is formed in the front end of the connecting plate, and the bolt of the lower die can be inserted into the bolt hole;

when the lower lifting die platform descends to a proper position, the pins of the two lower dies are inserted into the pin holes of the connecting plates of the corresponding balance weight boxes to form a balance linkage structure capable of mutually pulling and alternately exchanging stations, the formed lower dies push the corresponding balance weight boxes out of the lower lifting die platform and enable the balance weight boxes to slide to the placing seat for standby, the balance weight boxes on the other sides are pulled to be pulled up and down from the placing seat by using the pins at the bottoms of the corresponding lower dies as force points, the lower dies positioned on the material receiving and discharging standby conveying stations are horizontally moved to the forming standby conveying stations, and the lower dies positioned on the forming standby conveying stations are changed to the material taking and discharging standby conveying stations.

2. The thermoforming machine as recited in claim 1, wherein: the bottom of each lower die is provided with a translational sliding base, the two translational sliding bases are connected through a traction bearing seat, a sliding block is fixed at the bottom of the translational sliding base and is slidably arranged on a track, the track is fixed on a lower lifting die table, and a clutch traction bolt is arranged at the bottom of the tail end of the translational sliding base.

3. The thermoforming machine as recited in claim 1, wherein: when the lower lifting die platform rises to a proper position, the upper die and the lower die are matched to form a product, the other lower die synchronously finishes taking a label, in the process of descending the lower lifting die platform, a demoulding cylinder of the demoulding unit rises to enable the product to be separated from a die cavity and hung at a corner, and then the demoulding unit resets; when the lower lifting die platform descends to the right position, a traction clutch bolt under the translational sliding base of the lower die outside the forming station is inserted into a bolt hole of the balance weight box to form a translational linkage structure in which the two lower dies are respectively dragged with the balance weight box outside.

4. The thermoforming machine as recited in claim 1, wherein: the upper die mechanism is arranged on the connecting support frame, an upper support table is fixed at the upper end part of the connecting support frame, the tail part of the upper end of the upper lifting portal column is fixed on the upper support table, the lower end of the upper lifting portal column is fixed on cross beams positioned at two sides of the connecting support frame and positioned outside the sheet conveying chain, the upper lifting portal column is slidably arranged on the upper lifting portal column, and the upper die is arranged on the upper lifting portal table;

the lower lifting die table is fixedly connected with a lower lifting portal column, the lower lifting portal column is slidably arranged on a sliding sleeve seat, and the sliding sleeve seat is fixed on the supporting base;

the bottom of the connecting support frame is fixed on the sliding sleeve seat and the support base to form an integral connection structure of an up-down lifting structure.

5. The thermoforming machine as recited in claim 1, wherein: the bottom of lower mould is close to the rigid coupling of balanced weight box and is had the attracted-iron, the connecting plate of balanced weight box is equipped with the electro-magnet.

6. The thermoforming machine as recited in claim 1, wherein: the placing seat is provided with a rotatable balance auxiliary wheel, and when the balance weight box descends to the right position, the connecting plate at the bottom of the balance weight box can be arranged on the balance auxiliary wheel in a sliding manner.

7. The thermoforming machine as recited in claim 1, wherein: every lower mould is including shaping die cavity and drawing of patterns unit, the drawing of patterns unit is equipped with stripper plate and drawing of patterns lifter plate, the stripper plate is provided with the knockout according to the die cavity of shaping die cavity, connects through the connecting rod between drawing of patterns lifter plate and the stripper plate, and during the drawing of patterns, the telescopic link of drawing of patterns cylinder upwards stretches out and pushes up the drawing of patterns lifter plate, and drawing of patterns lifter plate moves the stripper plate and up moves the drawing of patterns, and the product opening edge after the knockout of stripper plate drives the shaping up moves the drawing of patterns.

8. The thermoforming machine of claim 7, wherein: the bottom of the demoulding lifting plate is provided with a demoulding clutch sliding rod which penetrates through the bottom of the lower die and the translational sliding base;

the telescopic link rigid coupling of drawing of patterns cylinder has the drawing of patterns kicking piece, drawing of patterns kicking piece is equipped with the ejector pin up, and during the drawing of patterns, the ejector pin is aimed at the drawing of patterns separation and reunion slide bar of lower mould drawing of patterns unit up.

9. The thermoforming machine as recited in claim 1, wherein: the translation driving device is composed of a motor, a driving wheel and a transmission belt, the driving wheel is rotatably arranged on the lower lifting die table, the transmission belt is arranged on the driving wheel and is connected with one lower die, and the motor drives the driving wheel and the transmission belt to rotate; the transmission belt directly or indirectly drives the two lower dies to simultaneously translate.

10. The thermoforming machine as recited in claim 1, wherein: comprises an upper rotary supporting seat, a lower rotary supporting seat, an upper lifting motion crank, a lower lifting motion crank, a positioning lifting shaft, a vertical lifting limit slider, a lever pressing and pulling lifting crank, a positioning rotary sliding lever crank, a positioning lifting shaft and a push-pull driving mechanism,

the lower rotary supporting seat is fixed on a static base, the lower rotary supporting seat is connected with the lower end of the lower lifting motion crank in a relatively rotatable manner through a hinged shaft, the upper end of the lower lifting motion crank is connected with the positioning rotary sliding lever crank in a relatively rotatable manner through a hinged shaft, the upper end of the positioning rotary sliding lever crank is hinged with the lower end of the upper lifting motion crank through a hinged shaft, the upper end of the upper lifting motion crank is connected with the lower end of the upper rotary supporting seat in a relatively rotatable manner through a hinged shaft, the upper rotary supporting seat is fixed at the bottom of an object to be lifted, the positioning lifting shaft is arranged on the positioning rotary sliding lever crank, a vertical lifting limiting sliding piece is arranged on the positioning lifting shaft, the vertical lifting limiting sliding piece is arranged on the static supporting seat in a sliding manner, and the hinged shaft, the positioning lifting shaft and the lower lifting motion crank are connected with the lower rotary supporting seat are formed, A vertical lifting structure with a hinge shaft connected with the upper lifting motion and the upper rotary supporting seat always in a line of three points;

the lower tail end of the positioning rotary sliding lever crank is connected with one end of the lever pressing and pulling lifting crank in a relatively rotatable manner through a shaft; the other end of the lever pressing and pulling lifting crank is driven by a push-pull driving mechanism to move.

11. The production line for conveying and boxing the in-mold labels in one-time and three-action mode is characterized by comprising a thermoforming machine as claimed in any one of claims 1 to 10 and two groups of label conveying groups, wherein two lower dies of the thermoforming machine move left and right to work alternately, and each lower die corresponds to one group of label conveying groups; each label conveying group comprises an in-mold labeling, taking and conveying mechanical arm, a label transferring and conveying device, a label conveying mechanical arm and a label bin.

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