CN105150595A

CN105150595A - Cavity mechanism

Info

Publication number: CN105150595A
Application number: CN201510565518.4A
Authority: CN
Inventors: 张勋
Original assignee: Wenzhou Gaosheng Machinery Co Ltd
Current assignee: Wenzhou Gaosheng Machinery Co Ltd
Priority date: 2015-07-21
Filing date: 2015-09-08
Publication date: 2015-12-16
Anticipated expiration: 2035-09-08
Also published as: CN105150595B

Abstract

The invention discloses a cavity mechanism. The cavity mechanism comprises a paper box mold and a paper box, wherein the paper box comprises a main plate and a side plate; the main plate comprises a baseplate (28) and a bent plate; and the bent plate comprises a front bent plate (29) and a back bent plate (30). The cavity mechanism further comprises four sets of belt transmission components and four sets of synchronous belt transmission components; the four sets of belt transmission components respectively perform the bending formation for the front bent plate (29) and the back bent plate (30); each set of synchronous belt transmission components and each set of belt transmission components are connected through a main transmission shaft (26); and the synchronous belt transmission components comprise synchronous belts (10) and side plate support moving components. Compared with the prior art, the cavity mechanism has the following beneficial effects: the application range is wide; the work of forming various equilateral paper boxes, unequilateral paper boxes and special-shaped paper boxes can be finished; and the optimal glue spraying bonding effect of the formed paper boxes can be obtained.

Description

Die cavity mechanism

Technical field

The present invention relates to full-automatic box machine technical field, particularly relate to the die cavity mechanism in full-automatic box machine.

Background technology

At present in cartridge device field processed, existing full-automatic box machine can only machine-shaping equilateral carton, such as square paper box or rectangular paper box, thus make the box kind processed of existing full-automatic box machine single, enterprise or the client user demand for the various inequilateral shape carton of processing or special-shaped carton cannot be met at all.

The die cavity mechanism of existing full-automatic box machine is the shaping mechanism of carton, and described die cavity mechanism is formed primarily of four clamp bars, two guiding movement clamping plate.Wherein, the left side plate for carton positioned opposite is shaping between two for four clamp bars, and two guiding movement clamping plate mainboards for carton positioned opposite are shaping.The technological process of existing die cavity mechanism is: when mould promote first shaping carton move from top to bottom time, because four limit lateral surfaces of first shaping carton are tightly clamped by described clamp bar and guiding movement clamping plate respectively, therefore, once namely the extreme position that mould moves to setting stroke starts counter motion and depart from after first carton reset, the frictional force effect by described clamp bar and guiding movement clamping plate is continued maintenance clamp position by four sides of first shaping carton; When mould promote second shaping carton move from top to bottom time, the bottom surface of second shaping carton contacts with the end face of first shaping carton and promotes first shaping carton until complete box action downwards, second shaping carton arrives the clip position of first carton immediately, and the action of the above-mentioned superposition of repetitive cycling successively of and then follow-up shaping carton, propelling movement shaping carton is above until complete box.The major technique defect of prior art is: due to the forming process of carton be rely on before and after superposition successively between carton, promote.Therefore, this technical scheme is when two box superpositions, promote a rear shaping carton downwards by mould, and make the bottom surface of a rear shaping carton be fitted in the end face of previous shaping carton completely, the active force that previous shaping carton promotes a rear shaping carton is downwards formed with this, due to processing is equilateral carton, therefore, it is possible to ensure that described impetus power is in poised state.But, if when needing the shaping carton of processing to belong to inequilateral or special-shaped carton, the such as end face of shaping carton is an inclined-plane, now when carrying out two box superpositions, can only fit completely with a side in previous forming paper box top in the bottom surface of a rear shaping carton, this will break the effect equilibrant force that previous shaping carton promotes a rear shaping carton downwards at one stroke, very easily cause a rear shaping carton to the monolateral crimp of previous shaping carton, the quality having a strong impact on shaping carton even causes scrapping of shaping carton.Obviously, prior art cannot complete the work of machine-shaping various inequilateral shape carton or special-shaped carton, urgently improves.

The patent No. is the processing method that the Chinese invention patent of ZL201310256960.X discloses a kind of Full-automatic board splicing formula box machine and packing box, Full-automatic board splicing formula box machine comprises base plate conveying glue spraying station and formed product station, described formed product station is connected with left and right side plate vertical conveying plate station respectively, wherein, described biside plate vertical conveying plate station is respectively arranged with left riser mechanism and right riser mechanism.The processing method of packing box be the plate conveying of packing box and automatic glue-spraying and after the technical process of reinforcing through mould molding.Technological process involved by this invention is simple, achieve the effect of saving material and reducing costs, the effect that automatic glue-spraying technique is firmly attractive in appearance after achieving formed product, the full-automation of packing box process also helps tissue and produces and significantly raise labour productivity.Because the Cavity 4 in this invention is formed primarily of four clamp bars, two guiding movement clamping plate, this carton forming technique is superposing successively before and after relying between carton, has promoted carton forming until the box that falls, obviously, the technical scheme of this invention can only machine-shaping straight flange carton, can not machine-shaping inequilateral carton or special-shaped carton, the user demand of client for machine-shaping various inequilateral shape carton or special-shaped carton cannot be met.

The patent No. is that the Chinese utility model patent of ZL201320862896.5 discloses a kind of Full-automatic board splicing formula box machine, it comprises base plate conveying glue spraying station and formed product station, described formed product station is connected with left and right side plate vertical conveying plate station respectively, wherein, described biside plate vertical conveying plate station is respectively arranged with left riser mechanism and right riser mechanism, left riser mechanism is configured with left riser assembly and left holder bar assembly, and right riser mechanism is configured with right riser assembly and right holder bar assembly.Technological process involved by this utility model is simple, achieve the effect of saving material and reducing costs, the effect that automatic glue-spraying technique is firmly attractive in appearance after achieving formed product, the full-automation of packing box process also helps tissue and produces and significantly raise labour productivity.Because the Cavity 4 in this utility model is formed primarily of four clamp bars, two guiding movement clamping plate, this carton forming technique is superposing successively before and after relying between carton, has promoted carton forming until the box that falls, obviously, the technical scheme of this utility model can only machine-shaping straight flange carton, can not machine-shaping inequilateral carton or special-shaped carton, the user demand of client for machine-shaping various inequilateral shape carton or special-shaped carton cannot be met.

Summary of the invention

In order to solve the technological deficiency that in above-mentioned existing full-automatic box machine, die cavity mechanism exists, the technical solution used in the present invention is as follows:

Die cavity mechanism, comprise carton forming mould and carton, described carton comprises mainboard and side plate, described mainboard comprises base plate and bending plate, described bending plate comprises front bending plate and rear bending plate, described side plate comprises left plate and right plate, also comprise four groups of V belt translation assemblies and four groups of toothed belt transmission assemblies, described four groups of V belt translation assemblies carry out bending and molding to described front bending plate and described rear bending plate respectively, each is organized described toothed belt transmission assembly and organizes between described V belt translation assembly with each and be all connected by final drive shaft, described toothed belt transmission assembly comprises Timing Belt and side plate supports moving assembly, described side plate supports moving assembly and comprises two groups of left plates support moving assemblies and two groups of right plates support moving assemblies.

Preferably, described side plate supports moving assembly and comprises cantilever connecting plate, draw runner, box holder bar, cantilever block, cam, guide rail, slide block and cam bawl, cantilever connecting plate is threaded connection part and is fixedly connected with described Timing Belt, described cantilever connecting plate has draw runner slotted eye, described draw runner slotted eye is built with draw runner, described box holder bar has installation slotted eye, the front end of described draw runner is fixedly connected with described box holder bar through described installation slotted eye, described draw runner has through hole, described through hole is built with described cam bawl, described cantilever connecting plate has bearing slotted eye, described cam bawl is contained in described bearing slotted eye, described box holder bar is provided with the right angle supporting surface supporting described base plate and described side plate, described cantilever connecting plate has cantilever block mounting groove, one end of described cantilever block is fixedly mounted in described cantilever block mounting groove, the other end of described cantilever block is installed with slide block, described slide block set is contained on described guide rail and forms guideway, at right angles arrange between described cantilever connecting plate and described cantilever block, cam is provided with in space inside described right angle.

In above-mentioned either a program preferably, described cam is provided with bearing slideway.

In above-mentioned either a program preferably, paste edge at the described side plate of described carton and the glue spraying of described bending plate and be provided with block.

In above-mentioned either a program preferably, described toothed belt transmission assembly comprises Timing Belt driving wheel and Timing Belt driven pulley, and described Timing Belt driving wheel and described Timing Belt driven pulley are equipped with Timing Belt.

In above-mentioned either a program preferably, described V belt translation assembly comprises band driving wheel and band driven pulley, described band driving wheel and described band driven pulley is equipped with and send box belt.

In above-mentioned either a program preferably, in the endoporus of described band driving wheel, freewheel clutch is housed, in the endoporus of described freewheel clutch, final drive shaft is housed.

In above-mentioned either a program preferably, described V belt translation assembly the inner side of the inner side of described band driving wheel, described band driven pulley and described in send the inner side of box belt jointly to surround space in band gripper shoe is installed.

In above-mentioned either a program preferably, in the endoporus of described band driven pulley, belt wheel mandrel is housed.

In above-mentioned either a program preferably, described guideway adopts line slideway.

In above-mentioned either a program preferably, described line slideway adopts open type line slideway.

In above-mentioned either a program preferably, described line slideway adopts enclosed line slideway.

In above-mentioned either a program preferably, described line slideway adopts sliding friction guide rail.

In above-mentioned either a program preferably, described line slideway adopts rolling guide.

In above-mentioned either a program preferably, described sliding friction guide rail adopts face of cylinder guide rail.

In above-mentioned either a program preferably, described sliding friction guide rail adopts prismatic surface guide rail.

In above-mentioned either a program preferably, described face of cylinder guide rail adopts convex guide rail.

In above-mentioned either a program preferably, described face of cylinder guide rail adopts spill guide rail.

In above-mentioned either a program preferably, described prismatic surface guide rail adopts triangular guide.

In above-mentioned either a program preferably, described triangular guide adopts convex guide rail.

In above-mentioned either a program preferably, described triangular guide adopts spill guide rail.

In above-mentioned either a program preferably, described triangular guide adopts symmetrical triangle guide rail.

In above-mentioned either a program preferably, described triangular guide adopts asymmetric triangular guide.

In above-mentioned either a program preferably, described prismatic surface guide rail adopts rectangular guideway.

In above-mentioned either a program preferably, described rectangular guideway adopts convex guide rail.

In above-mentioned either a program preferably, described rectangular guideway is spill guide rail.

In above-mentioned either a program preferably, described prismatic surface guide rail adopts dovetail slideway.

In above-mentioned either a program preferably, described dovetail slideway adopts convex guide rail.

In above-mentioned either a program preferably, described dovetail slideway adopts spill guide rail.

In above-mentioned either a program preferably, described prismatic surface guide rail adopts assemblied guide rail.

In above-mentioned either a program preferably, described assemblied guide rail adopts double triangle guide rail.

In above-mentioned either a program preferably, described assemblied guide rail adopts double square guide rail.

In above-mentioned either a program preferably, described assemblied guide rail adopts triangle and rectangle composite guideway.

In above-mentioned either a program preferably, described assemblied guide rail adopts swallow-tail form and triangle composite guideway.

In above-mentioned either a program preferably, described assemblied guide rail adopts swallow-tail form and rectangle composite guideway.

In above-mentioned either a program preferably, described rolling guide adopts spherical guide.

In above-mentioned either a program preferably, described rolling guide adopts roller guide.

In above-mentioned either a program preferably, described guideway adopts magnetic pad suspension guide.

In above-mentioned either a program preferably, described magnetic pad suspension guide bottom is configured with linear electric motors.

In above-mentioned either a program preferably, described Timing Belt adopts one side cingulum.

In above-mentioned either a program preferably, described Timing Belt adopts two-sided cingulum.

In above-mentioned either a program preferably, the power source of described V belt translation assembly adopts and controls motor.

In above-mentioned either a program preferably, described control motor adopts servomotor.

In above-mentioned either a program preferably, described control motor adopts stepper motor.

In above-mentioned either a program preferably, described freewheel clutch adopts Wedge type over running clutch.

In above-mentioned either a program preferably, described freewheel clutch adopts roller-type overrunning clutch.

In above-mentioned either a program preferably, described freewheel clutch adopts ratchet type overrunning clutch.

In above-mentioned either a program preferably, described Wedge type over running clutch adopts basic model Wedge type over running clutch.

In above-mentioned either a program preferably, described Wedge type over running clutch adopts without inner ring type Wedge type over running clutch.

In above-mentioned either a program preferably, described Wedge type over running clutch adopts band bearing type Wedge type over running clutch.

In above-mentioned either a program preferably, described carton forming mould is straight flange carton forming mould, and described carton is straight flange carton.

In above-mentioned either a program preferably, described carton forming mould is special-shaped carton mould, and described carton is special-shaped carton.

In above-mentioned either a program preferably, described special-shaped carton mould is hypotenuse carton forming mould, and described special-shaped carton is hypotenuse carton.

In above-mentioned either a program preferably, described hypotenuse carton comprises mainboard and side plate, described side plate comprises three straight flanges and a hypotenuse, the end face of described three straight flanges is side plate glue spraying sticking veneer, described mainboard is mainboard glue spraying sticking veneer at the medial surface near left and right edges at two ends, described side plate glue spraying sticking veneer and described mainboard glue spraying sticking veneer are pasted together mutually the bottom surface and four sides that form spatial accommodation, described hypotenuse carton is provided with an opening, and four limits of described opening comprise two straight flanges of described mainboard and two hypotenuses of described side plate.

The present invention's beneficial effect is compared with prior art: applied widely, can not only manufacture the shaping work of various equilateral carton, inequilateral shape carton and special-shaped carton, can also obtain the best glue spraying sticking effect of described carton simultaneously; The present invention passes through the shaping conveyer of four groups of V belt translation assemblies and four groups of toothed belt transmission assembly formation cartons, when carton arrives described die cavity mechanism, while carton forming mould pushes carton downwards, carton base plate is supported by described box holder bar, the described forward and backward bending plate sending box belt to support mainboard, under the interaction of carton forming mould and box holder bar, realize better glue spraying adhering effect between the base plate of carton and described forward and backward bending plate, thoroughly solve base plate viscose glue technological deficiency loosely in prior art; Undertaken spacing by arranging block at the left and right side plate of carton near the outer fix of pasting faying face, thus ensure that the best sticking effect between left and right side plate and mainboard; By arranging cam, make carton forming mould promote downwards carton to described in send the bottom of box belt time, can ensure that the box holder bar supporting left and right side plate departs from carton in good time; Described in supporting, send box belt by arranging band gripper shoe, thus effectively ensure the optimum adhesion effect of glue spraying sticking veneer between left and right side plate and forward and backward bending plate; Owing to adopting V belt translation, thoroughly solve the cut problem produced because die cavity mechanism supports inwall extrudes for shaping carton surface in prior art; By arranging freewheel clutch in the endoporus of band driving wheel, ensureing to be supported on when Timing Belt upwards reverses and resets and sending the carton on box belt keep transfixion and can complete box action smoothly.

Accompanying drawing explanation

Fig. 1 is the general structure axonometric drawing according to die cavity mechanism one of the present invention preferred embodiment;

Fig. 2 is according to die cavity mechanism of the present invention front view embodiment illustrated in fig. 1;

Fig. 3 is according to die cavity mechanism of the present invention right view embodiment illustrated in fig. 1;

Fig. 4 is according to die cavity mechanism of the present invention top view embodiment illustrated in fig. 1;

Fig. 5 is according to die cavity mechanism of the present invention upward view embodiment illustrated in fig. 1;

Fig. 6 is the axonometric drawing according to die cavity mechanism of the present invention middle hypotenuse carton forming mould embodiment illustrated in fig. 1;

Fig. 7 is the front view according to die cavity mechanism of the present invention middle hypotenuse carton forming mould embodiment illustrated in fig. 1;

Fig. 8 is the right view according to die cavity mechanism of the present invention middle hypotenuse carton forming mould embodiment illustrated in fig. 1;

Fig. 9 is the top view according to die cavity mechanism of the present invention middle hypotenuse carton forming mould embodiment illustrated in fig. 1;

Figure 10 is the upward view according to die cavity mechanism of the present invention middle hypotenuse carton forming mould embodiment illustrated in fig. 1;

Figure 11 is the axonometric drawing according to die cavity mechanism of the present invention middle hypotenuse carton embodiment illustrated in fig. 1;

Figure 12 is the front view according to die cavity mechanism of the present invention middle hypotenuse carton embodiment illustrated in fig. 1;

Figure 13 is the left view according to die cavity mechanism of the present invention middle hypotenuse carton embodiment illustrated in fig. 1;

Figure 14 is the right view according to die cavity mechanism of the present invention middle hypotenuse carton embodiment illustrated in fig. 1;

Figure 15 is the rearview according to die cavity mechanism of the present invention middle hypotenuse carton embodiment illustrated in fig. 1;

Figure 16 is the top view according to die cavity mechanism of the present invention middle hypotenuse carton embodiment illustrated in fig. 1;

Figure 17 is the upward view according to die cavity mechanism of the present invention middle hypotenuse carton embodiment illustrated in fig. 1;

Figure 18 is the axonometric drawing according to die cavity mechanism of the present invention middle V belt translation assembly embodiment illustrated in fig. 1;

Figure 19 is the front view according to die cavity mechanism of the present invention middle V belt translation assembly embodiment illustrated in fig. 1;

Figure 20 is the right view according to die cavity mechanism of the present invention middle V belt translation assembly embodiment illustrated in fig. 1;

Figure 21 is the axonometric drawing according to die cavity mechanism of the present invention middle toothed belt transmission assembly embodiment illustrated in fig. 1;

Figure 22 is the syndeton schematic diagram according to die cavity mechanism of the present invention middle Timing Belt embodiment illustrated in fig. 1 and cantilever connecting plate;

Figure 23 is the axonometric drawing according to die cavity mechanism of the present invention middle band driving wheel embodiment illustrated in fig. 1;

Figure 24 is the axonometric drawing according to die cavity mechanism of the present invention middle freewheel clutch embodiment illustrated in fig. 1;

Figure 25 is the axonometric drawing according to die cavity mechanism of the present invention middle band gripper shoe embodiment illustrated in fig. 1;

Figure 26 be embodiment illustrated in fig. 1 according to die cavity mechanism of the present invention in send the axonometric drawing of box belt;

Figure 27 is the axonometric drawing according to die cavity mechanism of the present invention middle band driven pulley embodiment illustrated in fig. 1;

Figure 28 is the axonometric drawing according to die cavity mechanism of the present invention middle belt wheel mandrel embodiment illustrated in fig. 1;

Figure 29 is the axonometric drawing according to die cavity mechanism of the present invention middle box holder bar embodiment illustrated in fig. 1;

Figure 30 is the axonometric drawing according to die cavity mechanism of the present invention middle draw runner embodiment illustrated in fig. 1;

Figure 31 is the axonometric drawing according to die cavity mechanism of the present invention cam roller embodiment illustrated in fig. 1;

Figure 32 is the axonometric drawing according to die cavity mechanism of the present invention middle cantilever connecting plate embodiment illustrated in fig. 1;

Figure 33 is the axonometric drawing according to die cavity mechanism of the present invention cam embodiment illustrated in fig. 1;

Figure 34 is the axonometric drawing according to die cavity mechanism of the present invention middle guide embodiment illustrated in fig. 1;

Figure 35 is the axonometric drawing according to die cavity mechanism of the present invention middle cantilever block embodiment illustrated in fig. 1;

Figure 36 is the axonometric drawing according to die cavity mechanism of the present invention middle slide block embodiment illustrated in fig. 1;

Figure 37 is the axonometric drawing according to die cavity mechanism of the present invention middle final drive shaft embodiment illustrated in fig. 1;

Figure 38 is the axonometric drawing according to die cavity mechanism of the present invention middle block embodiment illustrated in fig. 1;

The structural representation of straight flange carton die cavity mechanism in the existing full-automatic box machine of Figure 39;

In the existing full-automatic box machine of Figure 40, straight flange carton superposes shaping structural representation;

Figure 41 to adopt in existing full-automatic box machine straight flange carton die cavity mechanism to superpose the structural representation of shaping hypotenuse carton.

Description of reference numerals:

1 hypotenuse carton forming mould; 2 hypotenuse cartons; 3 Timing Belt driving wheels; 4 band driving wheels; 5 freewheel clutches; 6 band gripper shoes; 7 send box belt; 8 band driven pulleys; 9 belt wheel mandrels; 10 Timing Belts; 11 Timing Belt driven pulleys; 12 blocks; 13 box holder bars; 14 draw runners; 15 cam bawls; 16 cantilever connecting plates; 17 cams; 18 guide rails; 19 clamp bars; 20 guide plates; 21 move clamping plate; 22 clamping plate; 23 straight flange cartons; 24 cantilever blocks; 25 slide blocks; 26 final drive shafts; 27 straight flange carton forming moulds; 28 base plates; Bending plate before 29; Bending plate after 30; 31 left plates; 32 right plates.

Detailed description of the invention

In order to understand the present invention better, below in conjunction with specific embodiment, the present invention is explained in detail, but, obviously can carry out different modification and remodeling to the present invention and not exceed the wider spirit and scope of the present invention of appended claims.Therefore, following examples have exemplary and hard-core implication.

Embodiment 1:

As shown in Fig. 1-38, die cavity mechanism, comprise carton forming mould and carton, described carton comprises mainboard and side plate, described mainboard comprises base plate 28 and bending plate, described bending plate comprises front bending plate 29 and rear bending plate 30, described side plate comprises left plate 31 and right plate 32, also comprise four groups of V belt translation assemblies and four groups of toothed belt transmission assemblies, described four groups of V belt translation assemblies carry out bending and molding to described front bending plate 29 and described rear bending plate 30 respectively, each is organized described toothed belt transmission assembly and organizes between described V belt translation assembly with each and be all connected by final drive shaft 26, described toothed belt transmission assembly comprises Timing Belt 10 and side plate supports moving assembly, described side plate supports moving assembly and comprises two groups of left plates support moving assemblies and two groups of right plates support moving assemblies, described side plate supports moving assembly and comprises cantilever connecting plate 16, draw runner 14, box holder bar 13, cantilever block 24, cam 17, guide rail 18, slide block 25 and cam bawl 15, cantilever connecting plate 16 is threaded connection part and is fixedly connected with Timing Belt 10, cantilever connecting plate 16 has draw runner slotted eye, described draw runner slotted eye is built with draw runner 14, box holder bar 13 has installation slotted eye, the front end of draw runner 14 is fixedly connected with box holder bar 13 through described installation slotted eye, draw runner 14 has through hole, described through hole is built with cam bawl 15, cantilever connecting plate 16 has bearing slotted eye, cam bawl 15 is contained in described bearing slotted eye, box holder bar 13 is provided with the right angle supporting surface of support baseboard 28 and described side plate, cantilever connecting plate 16 has cantilever block mounting groove, one end of cantilever block 24 is fixedly mounted in described cantilever block mounting groove, the other end of cantilever block 24 is installed with slide block 25, slide block 25 is set with and forms guideway on the track 18, at right angles arrange between cantilever connecting plate 16 and cantilever block 24, cam 17 is provided with in space inside described right angle, cam 17 is provided with bearing slideway, paste edge at the described side plate of described carton and the glue spraying of described bending plate and be provided with block 12, described toothed belt transmission assembly comprises Timing Belt driving wheel 3 and Timing Belt driven pulley 11, Timing Belt driving wheel 3 and Timing Belt driven pulley 11 are equipped with Timing Belt 10, described V belt translation assembly comprises band driving wheel 4 and band driven pulley 8, band driving wheel 4 and band driven pulley 8 are equipped with and send box belt 7, freewheel clutch 5 is housed in the endoporus with driving wheel 4, final drive shaft 26 is housed in the endoporus of freewheel clutch 5, described V belt translation assembly is in the inner side of band driving wheel 4, inner side with driven pulley 8 and send the inner side of box belt 7 jointly to surround space in be provided with band gripper shoe 6, belt wheel mandrel 9 is housed in the endoporus with driven pulley 8, described guideway adopts line slideway, described line slideway adopts open type line slideway, described line slideway adopts sliding friction guide rail, described sliding friction guide rail adopts face of cylinder guide rail, described face of cylinder guide rail adopts convex guide rail, Timing Belt 10 adopts one side cingulum, the power source of described V belt translation assembly adopts and controls motor, described control motor adopts servomotor, freewheel clutch 5 adopts Wedge type over running clutch, described Wedge type over running clutch adopts basic model Wedge type over running clutch, described carton forming mould is special-shaped carton mould, described carton is special-shaped carton, described special-shaped carton mould is hypotenuse carton forming mould 1, described special-shaped carton is hypotenuse carton 2, hypotenuse carton 2 comprises mainboard and side plate, the described side plate of hypotenuse carton 2 comprises three straight flanges and a hypotenuse, the end face of described three straight flanges is side plate glue spraying sticking veneer, described mainboard is mainboard glue spraying sticking veneer at the medial surface near left and right edges at two ends, described side plate glue spraying sticking veneer and described mainboard glue spraying sticking veneer are pasted together mutually the bottom surface and four sides that form spatial accommodation, hypotenuse carton 2 is provided with an opening, four limits of described opening comprise two straight flanges of described mainboard and two hypotenuses of described side plate.

The present invention forms primarily of four groups of V belt translation assemblies and four groups of toothed belt transmission assemblies the base plate 28 that relative combinations structure between two supports hypotenuse carton 2 respectively, front bending plate 29, rear bending plate 30, left plate 31 and right plate 32, when arriving the described die cavity mechanism in carton forming station when hypotenuse carton 2, when hypotenuse carton forming mould 1 pushes hypotenuse carton 2 downwards, hypotenuse carton 2 is held by box holder bar 13, right angle supporting surface on box holder bar 13 supports the base plate 28 of hypotenuse carton 2, box belt 7 is sent to support front bending plate 29 and rear bending plate 30, under the interaction of hypotenuse carton forming mould 1 and box holder bar 13, realize glue spraying adhering effect best between the base plate 28 of hypotenuse carton 2 and front bending plate 29 and rear bending plate 30, thoroughly solve base plate 28 viscose glue technological deficiency loosely in prior art, undertaken spacing by arranging block 12 respectively at the left plate 31 of hypotenuse carton 2 and right plate 32, thus ensure that left plate 31 and the best sticking effect between right plate 32 and described mainboard, by arranging cam 17, making hypotenuse carton forming mould 1 downwards promoting hypotenuse carton 2 to when sending the bottom of box belt 7, ensureing that the box holder bar 13 supporting left plate 31 and right plate 32 departs from hypotenuse carton 2 in good time, by arranging band gripper shoe 6 for a support sending box belt 7, thus effectively ensure left plate 31 and right plate 32 and the optimum adhesion effect of glue spraying sticking veneer between front bending plate 29 and rear bending plate 30, owing to adopting V belt translation, thoroughly solve the cut problem produced because die cavity mechanism supports inwall extrudes for shaping carton surface in prior art, by installing freewheel clutch 5 in the endoporus of band driving wheel 4, ensure to be supported on when upwards reversing and resetting at Timing Belt 10 to send the hypotenuse carton 2 on box belt 7 keep transfixion and can complete box action smoothly.

As shown in Figure 39-41, the die cavity mechanism of existing full-automatic box machine is formed primarily of four clamp bars, 19, two guiding movement plates 20 and two clamping plate 21, wherein, four clamp bar 19 is positioned opposite between two and left side plate for carton is shaping, and clamping plate 21 are positioned opposite and mainboard for carton is shaping for two guiding movement plates 20 and two.The major technique defect of prior art is: due to the forming process of carton be rely on before and after superposition successively between carton, promote, therefore this technical scheme is only applicable to the shaping of straight flange carton 23, is not suitable for shaping as hypotenuse carton 2 of special-shaped carton.

From the contrast of the invention described above technical scheme and prior art, the present invention completely eliminates existing full-automatic box machine must rely on the technological deficiency superposing successively, promoted between the straight flange carton of front and back in shaping straight flange carton process, thus breach prior art can only shaping straight flange carton kind limitation, the present invention can the work of shaping various equilateral carton, inequilateral shape carton and special-shaped carton, can also obtain the best glue spraying sticking effect of described carton simultaneously.

Embodiment 2:

Die cavity mechanism, similar to embodiment 1, difference is, described face of cylinder guide rail adopts spill guide rail.

Embodiment 3:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts triangular guide, and described triangular guide adopts convex guide rail.

Embodiment 4:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts triangular guide, and described triangular guide adopts spill guide rail.

Embodiment 5:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts triangular guide, and described triangular guide adopts symmetrical triangle guide rail.

Embodiment 6:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts triangular guide, and described triangular guide adopts asymmetric triangular guide.

Embodiment 7:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts rectangular guideway, and described rectangular guideway adopts convex guide rail.

Embodiment 8:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts rectangular guideway, and described rectangular guideway is spill guide rail.

Embodiment 9:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts dovetail slideway, and described dovetail slideway adopts convex guide rail.

Embodiment 10:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts dovetail slideway, and described dovetail slideway adopts spill guide rail.

Embodiment 11:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts assemblied guide rail, and described assemblied guide rail adopts double triangle guide rail.

Embodiment 12:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts assemblied guide rail, and described assemblied guide rail adopts double square guide rail.

Embodiment 13:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts assemblied guide rail, and described assemblied guide rail adopts triangle and rectangle composite guideway.

Embodiment 14:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts assemblied guide rail, and described assemblied guide rail adopts swallow-tail form and triangle composite guideway.

Embodiment 15:

Die cavity mechanism, similar to embodiment 1, difference is, described sliding friction guide rail adopts prismatic surface guide rail, and described prismatic surface guide rail adopts assemblied guide rail, and described assemblied guide rail adopts swallow-tail form and rectangle composite guideway.

Embodiment 16:

Die cavity mechanism, similar to embodiment 1, difference is, described line slideway adopts rolling guide, and described rolling guide adopts spherical guide.

Embodiment 17:

Die cavity mechanism, similar to embodiment 1, difference is, described line slideway adopts rolling guide, and described rolling guide adopts roller guide.

Embodiment 18:

Embodiment 19:

Die cavity mechanism, similar to embodiment 1, difference is, described guideway adopts magnetic pad suspension guide, and described magnetic pad suspension guide bottom is configured with linear electric motors.

Embodiment 20:

Die cavity mechanism, similar to embodiment 1, difference is, described line slideway adopts enclosed line slideway.

Embodiment 21:

Die cavity mechanism, similar to embodiment 1, difference is, Timing Belt 10 adopts two-sided cingulum.

Embodiment 22:

Die cavity mechanism, similar to embodiment 1, difference is, described control motor adopts stepper motor.

Embodiment 23:

Die cavity mechanism, similar to embodiment 1, difference is, freewheel clutch 5 adopts Wedge type over running clutch, and described Wedge type over running clutch adopts without inner ring type Wedge type over running clutch.

Embodiment 24:

Die cavity mechanism, similar to embodiment 1, difference is, freewheel clutch 5 adopts Wedge type over running clutch, and described Wedge type over running clutch adopts band bearing type Wedge type over running clutch.

Embodiment 25:

Die cavity mechanism, similar to embodiment 1, difference is, freewheel clutch 5 adopts roller-type overrunning clutch.

Embodiment 26:

Die cavity mechanism, similar to embodiment 1, difference is, freewheel clutch 5 adopts ratchet type overrunning clutch.

Embodiment 27:

Die cavity mechanism, similar to embodiment 1, difference is, described carton forming mould is straight flange carton forming mould 27, and described carton is straight flange carton 23.

Claims

1. die cavity mechanism, comprise carton forming mould and carton, described carton comprises mainboard and side plate, described mainboard comprises base plate (28) and bending plate, described bending plate comprises front bending plate (29) and rear bending plate (30), described side plate comprises left plate (31) and right plate (32), it is characterized in that, also comprise four groups of V belt translation assemblies and four groups of toothed belt transmission assemblies, described four groups of V belt translation assemblies carry out bending and molding to described front bending plate (29) and described rear bending plate (30) respectively, each is organized described toothed belt transmission assembly and organizes between described V belt translation assembly with each and be all connected by final drive shaft (26), described toothed belt transmission assembly comprises Timing Belt (10) and side plate supports moving assembly, described side plate supports moving assembly and comprises two groups of left plates support moving assemblies and two groups of right plates support moving assemblies.

2. die cavity mechanism as claimed in claim 1, it is characterized in that, described side plate supports moving assembly and comprises cantilever connecting plate (16), draw runner (14), box holder bar (13), cantilever block (24), cam (17), guide rail (18), slide block (25) and cam bawl (15), cantilever connecting plate (16) is threaded connection part and is fixedly connected with Timing Belt (10), (16) have draw runner slotted eye to cantilever connecting plate, described draw runner slotted eye is built with draw runner (14), box holder bar (13) has installation slotted eye, the front end of draw runner (14) is fixedly connected with box holder bar (13) through described installation slotted eye, draw runner (14) has through hole, described through hole is built with cam bawl (15), (16) have bearing slotted eye to cantilever connecting plate, cam bawl (15) is contained in described bearing slotted eye, box holder bar (13) is provided with the right angle supporting surface of support baseboard (28) and described side plate, cantilever connecting plate (16) has cantilever block mounting groove, one end of cantilever block (24) is fixedly mounted in described cantilever block mounting groove, the other end of cantilever block (24) is installed with slide block (25), slide block (25) is sleeved on guide rail (18) and forms guideway, at right angles arrange between cantilever connecting plate (16) and cantilever block (24), cam (17) is provided with in space inside described right angle.

3. die cavity mechanism as claimed in claim 2, it is characterized in that, cam (17) is provided with roller slideway.

4. die cavity mechanism as claimed in claim 1, is characterized in that, paste edge be provided with block (12) at the described side plate of described carton and the glue spraying of described bending plate.

5. die cavity mechanism as claimed in claim 1, it is characterized in that, described toothed belt transmission assembly comprises Timing Belt driving wheel (3) and Timing Belt driven pulley (11), and Timing Belt driving wheel (3) and Timing Belt driven pulley (11) are equipped with Timing Belt (10).

6. die cavity mechanism as claimed in claim 1, is characterized in that, described V belt translation assembly comprises band driving wheel (4) and band driven pulley (8), band driving wheel (4) and be with driven pulley (8) is equipped with and send box belt (7).

7. die cavity mechanism as claimed in claim 6, is characterized in that, in the endoporus of band driving wheel (4), freewheel clutch (5) is housed, final drive shaft (26) is housed in the endoporus of freewheel clutch (5).

8. die cavity mechanism as claimed in claim 6, is characterized in that, described V belt translation assembly is provided with band gripper shoe (6) in the inner side of band driving wheel (4), the inner side of being with driven pulley (8) and the space sending the inner side of box belt (7) jointly to surround.

9. die cavity mechanism as claimed in claim 6, is characterized in that, in the endoporus of band driven pulley (8), belt wheel mandrel (9) is housed.

10. die cavity mechanism as claimed in claim 2, is characterized in that, described guideway adopts line slideway.