CN213128201U - Automatic production and manufacturing device for artificial flowers - Google Patents

Abstract

The utility model discloses an artificial flower automatic production manufacturing installation, comprises a control console, the setting is provided with the pre-compaction forming module on the control cabinet and from a left side to the right side, the hot briquetting module, transfer the subassembly, series connection shaping module and transport subassembly, the pre-compaction forming module includes first heating injection barrel, go up pre-compaction mould and preforming mould down, the discharge gate of first heating injection barrel and the top intercommunication of last pre-compaction mould, set up preforming mould under last pre-compaction mould, the hot briquetting module includes hot forming mould and thermoforming mould down, the thermoforming mould slides and sets up on the control cabinet down, this time the thermoforming mould comes and goes to slide under last hot forming mould between under and the series connection shaping module, it transfers the subassembly to set up between the below rear side of last pre-compaction mould and last hot forming mould, set up the transport subassembly on the control cabinet of series connection shaping module right side below. The utility model discloses can accomplish a series of process flows of artificial flower production automatically, improve the efficiency of artificial flower production, the cost is reduced.

Description

Automatic production and manufacturing device for artificial flowers

Technical Field

The utility model belongs to the technical field of artificial flower preparation equipment, especially, relate to an artificial flower automatic production manufacturing installation.

Background

The artificial flower refers to a false flower made of silk, crepe paper, polyester, plastic, crystal and other materials, and a dried flower baked from fresh flowers, and is generally called as an artificial flower in the industry. The artificial flower is made up by using fresh flower as blue book and using cloth, yarn, silk and plastics as raw material through the processes of imitation, and said artificial flower is formed from petal, flower leaf and flower stem, and different artificial flowers must be matched with different petals and flower leaves. The artificial flower with flower-like grains and three-dimensional structure can be produced through a plurality of processing steps such as flower making, gluing, coloring, die forming, flower gathering, flower carrying and forming. The existing processes of feeding, discharging, gluing, coloring, flower discharging, flower gathering, carrying and the like generally adopt manual modes, petals are manually taken down from a hot die after die pressing and shaping are completed, then flower pieces of various specifications are sent to a flower gathering station, and the processes of flower gathering and assembling and the like are completed manually.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an artificial flower automatic production manufacturing installation, the utility model discloses an automatic production device can quick hot melt shaping, transport, hot pressing design, take and pass on and place to can full-automatic a series of process flow of accomplishing the production of integrated artificial flower, improved the work efficiency of artificial flower production greatly, reduced the cost of labor by a wide margin. In order to achieve the above purpose, the utility model adopts the following technical scheme:

according to one aspect of the utility model, an automatic production and manufacturing device for artificial flowers is provided, which comprises a control console, a pre-pressing forming module, a hot-pressing forming module, a transfer component, a series forming module and a carrying component, wherein the pre-pressing forming module, the hot-pressing forming module, the transfer component, the series forming module and the carrying component are arranged on the control console from left to right in sequence, the pre-pressing forming module comprises a first heating injection barrel, an upper pre-pressing die and a lower pre-pressing die, a discharge port of the first heating injection barrel is communicated with the top end of the upper pre-pressing die, the lower pre-pressing die is arranged under the upper pre-pressing die, the lower pre-pressing die is fixed on the surface of the control console through a first lifting cylinder, the hot-pressing forming module comprises an upper hot-pressing die and a lower hot-pressing die, the upper hot-pressing die is fixed on the top end of the control console through a second lifting cylinder, the lower hot forming die is arranged on the surface of the console in a sliding mode, the lower hot forming die slides back and forth between the position right below the upper hot forming die and the position right below the serial forming module, the transfer assembly is arranged between the upper prepressing die and the lower rear side of the upper hot forming die, and the carrying assembly is arranged on the console below the right side of the serial forming module.

In a further preferred embodiment of the above scheme, the transfer assembly includes a rotating arm, a transfer support arm support and a suction cup, one end of the rotating arm is fixed to the top end of the pre-pressing forming module through a rotating motor, the other end of the rotating arm vertically extends downwards and is in transmission connection with the transfer support arm support horizontally arranged, a suction cup support plate is arranged below the support arm support, the suction cup is arranged on the suction cup support plate, and the suction cup support plate is fixed below the support arm support through a third telescopic cylinder.

In a further preferred embodiment of the above-mentioned solution, the tandem molding module comprises a second heating injection molding barrel, an upper pre-tandem molding press die and a lower pre-tandem molding support template, the second heating injection molding gun barrel and the upper pre-series molding pressing die are arranged on the top end of the console from top to bottom, the discharge hole of the second heating injection molding gun barrel is communicated with the top end of the upper pre-series molding pressing die, the lower pre-series molding supporting template is arranged right below the upper pre-series molding pressing die, the lower pre-tandem forming support template is fixed on the surface of the control console through a fourth lifting cylinder, the bottom end of the lower hot forming die is provided with a forming die supporting template, the lower hot forming die is arranged on the surface of the console through the forming die supporting template, and the lower thermoforming mold is slidable back and forth between the surface of the forming mold support platen and the surface of the lower pre-tandem forming support platen.

In a further preferred embodiment of the above-mentioned solution, petal-shaped molding press grooves are formed in the surface of the lower thermal forming die, and a flower bone molding groove is formed between the adjacent petal-shaped molding press grooves and communicated with the adjacent petal-shaped molding press grooves; and an upper molding fixed die head and a flower bone injection head are arranged on the lower surface of the upper pre-serial molding pressing die.

In a further preferred aspect of the above aspect, the carrying assembly includes a material conveying console fixed to a side of the console, a gripping device is arranged on the material conveying control platform, the gripping device comprises a fixed ring and a rotating shaft arranged in the fixed ring, the rotating shaft vertically extends upwards from the material conveying control platform to the outside of the material conveying control platform, a plurality of shaking blocks are fixedly connected on the fixed ring in an annular manner, the top end side wall of the rotating shaft is symmetrically and fixedly connected with top grinding rods, the top grinding rods are in relative rotating contact with the shaking blocks, a supporting rod is fixedly connected with the top end side wall of the rotating shaft and positioned between the two top grinding rods, the supporting rod is vertically fixed on the side wall of the top end of the rotating shaft, a hydraulic rod is arranged on the upper surface of the supporting rod, a grabbing claw is arranged at the free end part of the supporting rod, the output shaft of the hydraulic rod is in transmission connection with the grabbing claws, and the grabbing claws slide back and forth at the free end parts of the supporting rods.

The above scheme is further preferred, it includes snatchs the claw head, snatchs the claw tail and promotes the piece to snatch the claw, should promote the piece and slide and set up on the bracing piece, the output shaft of hydraulic stem with the stiff end transmission that promotes the piece is connected, the free end both sides that promote the piece are leaned forward and are stretched out and be provided with the catch bar, and the one end of this catch bar is articulated with the free end both sides that promote the piece, the other end of catch bar with the head of snatching the claw tail is connected.

The above scheme is further preferred, the free end of the supporting rod is fixedly connected with a T-shaped fixed connection lug, two sides of the T-shaped fixed connection lug are respectively hinged with the tail part of the grabbing claw tail, and the fixed part of the T-shaped fixed connection lug is connected with the free end of the pushing block.

In a further preferred mode of the above aspect, the side wall of the lower surface of the T-shaped fixed engaging lug is relatively slidably disposed on the free end of the supporting rod.

Above-mentioned scheme is further preferred, the lower extreme fixedly connected with of rotation axis keeps off the dish, keep off and be equipped with the spring on the rotation axis between dish and the solid fixed ring.

In a further preferred embodiment of the above aspect, the lower end of the rotating shaft passes through the blocking disk, and a driving shaft is fixedly connected to an end portion of the rotating shaft below the blocking disk.

To sum up, because the utility model adopts the above technical scheme, the utility model discloses following technological effect has:

the utility model discloses an automatic production device can quick hot melt shaping, transport, hot pressing design, take and place, can accomplish a series of process flows of artificial flower integration production automatically, improves the degree of automation of artificial flower production technology greatly, practices thrift the cost, raises the efficiency.

Drawings

FIG. 1 is a schematic structural diagram of an automatic artificial flower manufacturing device according to the present invention;

FIG. 2 is a schematic structural view of a handling assembly of the present invention;

fig. 3 is a schematic structural view of the gripping device of the present invention;

fig. 4 is a schematic structural view of the gripping claw of the present invention;

in the drawing, a console 10, a pre-pressing molding module 1, a hot press molding module 2, a transfer module 3, a series molding module 4, a carrying module 5, a placing frame 6, a first heating injection molding barrel 100, an upper pre-pressing mold 101, a lower pre-pressing mold 102, a first lifting cylinder 103, a pre-pressing die head 104, a raw material placing groove 105, an upper hot molding mold 200, a lower hot molding mold 201, a second lifting cylinder 202, a molding mold supporting template 203, a petal molding press film groove 204, a flower bone molding groove 205, a rotating arm 300, a transfer supporting arm frame 301, a suction cup 302, a rotating motor 303, a suction cup supporting plate 304, a third telescopic cylinder 305, a second heating injection molding barrel 400, an upper pre-series molding press mold 401, a lower pre-series molding supporting template 402, an upper molding fixing die head 403, a flower bone injection head 404, a material conveying console 500, a gripping device 501, a fixing ring 502, a rotating shaft 503, a shaking block 504, a, the support rod 506, the hydraulic rod 507, the grabbing claw 508, the blocking disc 509, the spring 510, the driving shaft 511, the grabbing claw head 5080, the grabbing claw tail 5081, the pushing block 5082, the pushing rod 5083 and the T-shaped fixed connecting lug 5084.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail below with reference to the accompanying drawings and by referring to preferred embodiments. It should be understood, however, that the numerous specific details set forth in the specification are merely set forth to provide a thorough understanding of one or more aspects of the present invention, which may be practiced without these specific details.

As shown in fig. 1 and 2, the automatic artificial flower production and manufacturing device according to the present invention comprises a console 10, and a pre-pressing molding module 1, a hot-pressing molding module 2, a transfer module 3, a series molding module 4 and a carrying module 5 which are sequentially disposed on the console 10 from left to right, wherein the pre-pressing molding module 1 comprises a first heating injection barrel 100, an upper pre-pressing mold 101 and a lower pre-pressing mold 102, a discharge port of the first heating injection barrel 100 is communicated with a top end of the upper pre-pressing mold 101, the lower pre-pressing mold 101 is disposed under the upper pre-pressing mold 101, the lower pre-pressing mold 101 is fixed on a surface of the console 10 by a first lifting cylinder 103, the hot-pressing molding module 2 comprises an upper hot-pressing mold 200 and a lower hot-pressing mold 201, a plurality of raw material placing grooves 105 are disposed on a surface of the lower pre-pressing mold 102, the upper hot-pressing mold 200 is fixed on the top end of the console 10 by a second lifting cylinder 202, the hot forming die 200 and the series forming module 4 are fixed on the top of the console 10 in the same straight line, the lower hot forming die 201 is arranged on the surface of the console 10 in a sliding manner, the lower hot forming die 201 slides back and forth between the position under the upper hot forming die 200 and the position under the series forming module 4, the transfer component 3 is arranged between the lower rear sides of the upper prepressing die 101 and the upper hot forming die 200, the carrying component 5 is arranged on the console 10 under the right side of the series forming module 4, in the utility model, the petal raw materials are added into the first heating injection barrel 100 for heating through transfer, then the first heating injection barrel 100 extrudes the plastic raw materials with high temperature melting into the upper prepressing die 101, the first lifting cylinder 103 pushes the lower prepressing die 102 upwards into the upper prepressing die 101, so that the upper prepressing die 101 and the lower prepressing die 102 are pressed, the surface of the upper prepressing die 101 extends downwards and is provided with a plurality of prepressing die heads 104, the prepressing die heads 104 are provided with injection holes, molten plastic raw materials which are hot-melted on the upper prepressing die 101 and are extruded from the injection holes enter the raw material placing groove 105 of the lower prepressing die 102, the molten plastic raw materials in the lower prepressing die 102 form a simulated blade prototype (a simulated petal prototype), so that a simulated petal injection process is realized, the transferring component 3 transfers the simulated blade prototype (the simulated petal prototype) pre-pressed and formed in the raw material placing groove 105 into the lower hot forming die 201, a plurality of petal hot pressing forming grooves 204 are arranged in the lower hot forming die 201, the inner wall of each petal hot pressing forming groove 204 is provided with a petal shape, the transferring component 3 places the simulated blade prototype (the simulated petal prototype) pre-pressed and formed in the raw material placing groove 105 into the petal hot pressing forming groove 204, at this time, the simulated blade prototype (simulated petal prototype) is placed at the embossing station (hot press forming station), then the second lifting cylinder 202 is started to extend downwards and drive the upper hot press forming die 200 to move downwards, and the film pressing head of the upper hot press forming die 200 extends into the petal hot press forming groove 204 of the lower hot press forming die 201 to perform matching hot press forming and pressing, the simulated blade prototype is hot press formed again to form a simulated blade (simulated petal), after the simulated blade (simulated petal) is hot press formed, the second lifting cylinder 202 contracts upwards to move the upper hot press forming die 200 upwards, the upper hot press forming die 200 is separated from the lower hot press forming die 201, the sliding driving device (not shown) of the lower hot press forming die 201 is started to slide the lower hot press forming die 201 to the lower part of the series forming die set 4, the series forming die set 4 extrudes and injects high-temperature molten flower bone raw material (plastic) into the series forming die set 4, the simulation leaves (simulation petals) placed in the adjacent serial forming modules 4 are connected in series through hot-melt plastic raw materials, the adjacent simulation leaves (simulation petals) are connected in series through the flower bones, so that the simulation petal bone injection operation is completed, then the simulation leaf (simulation petal) group formed in the serial forming modules 4 is conveyed and transferred to the petal collection frame 6 through the conveying assembly 5, so that the automatic generation process of the simulation leaves (simulation petals) is completed, the sliding driving device (not shown) drives the lower hot forming die 201 to return to slide to the position below the upper hot forming die 200 again, and the next hot forming and simulation petal bone injection operation is waited.

In the present invention, as shown in fig. 1, the transferring assembly 3 includes a rotating arm 300, a transferring support arm frame 301 and a suction cup 302, one end of the rotating arm 300 is fixed on the top end of the pre-pressing forming module 1 through a rotating motor 303, the other end of the rotating arm 300 vertically extends downward to be in transmission connection with the transferring support arm frame 301 horizontally disposed, a suction cup support plate 304 is disposed below the support arm frame 301, the suction cup 302 is disposed on the suction cup support plate 304, and the suction cup support plate 304 is fixed below the support arm frame 301 through a third telescopic cylinder 305; after the lower prepressing die 102 forms a simulated blade prototype (simulated petal prototype) from the molten plastic raw material, the first lifting cylinder 103 contracts downwards to drive the lower prepressing die 102 to move downwards and separate from the upper prepressing die 101, the lower prepressing die 102 moves downwards to the original position, the rotating motor 303 drives the rotating arm 300 to rotate, the transfer support arm frame 301 rotates to the upper part of the lower prepressing die 102, the sucking disc 302 is communicated with the suction pump through an air pipe, after the suction pump is opened, when the third telescopic cylinder 305 moves downwards to drive the sucking disc 302 to the upper part of the petal hot-pressing molding groove 204, the sucking disc 302 sucks the simulated blade prototype (simulated petal prototype) in each corresponding raw material placing groove 105 on the sucking disc 302 due to the negative pressure suction effect, the third telescopic cylinder 305 contracts upwards, the rotating motor 303 reversely drives the rotating arm 300 to rotate, and the transfer support arm frame 301 is rotated back to the upper part of the lower hot forming die 201, the third telescopic cylinder 305 moves downwards in an extending way, the sucker 302 releases a simulated blade prototype (a simulated petal prototype) and falls into the petal hot forming groove 204, the rotating motor 303 drives the rotating arm 300, the transfer support arm frame 301 and the sucker 302 to rotate to the original position, the second lifting cylinder 202 extends downwards and drives the upper hot forming die 200 to move downwards, the film pressing head of the upper hot forming die 200 extends into the petal hot forming groove 204 of the lower hot forming die 201 to be matched with hot forming and pressed to form the simulated blade (a simulated petal) hot forming, and the transfer assembly 3 realizes that the simulated blade prototype (the simulated petal prototype) is rapidly transferred to the hot forming die set 2 to be further hot formed.

The utility model discloses in, as shown in fig. 1 and 2, series forming module 4 includes that the second heats the barrel 400 of moulding plastics, goes up pre-series connection shaping moulding-die 401 and pre-series connection shaping supporting template 402 down, the second heats the barrel 400 of moulding plastics and goes up the console 10 top that pre-series connection shaping moulding-die 401 set up from top to bottom on, the discharge gate of the barrel 400 of moulding plastics of second heating with go up pre-series connection shaping moulding-die 401's top intercommunication, set up under last pre-series connection shaping moulding-die 401 pre-series connection shaping supporting template 402 down, this is fixed through fourth lift cylinder 403 to pre-series connection shaping supporting template 402 down on the surface of console 10, the bottom of thermoforming mould 201 is provided with moulded die supporting template 203 down, thermoforming mould supporting template 201 sets up on the surface of console 10 through moulded die 203 down to thermoforming mould 201 can be between the surface of moulded die supporting template 203 and the surface of pre-series connection shaping supporting template 402 down between the surface Sliding back and forth; petal forming film pressing grooves 204 are formed in the surface of the lower hot forming die 201, flower bone forming grooves 205 are formed between the adjacent petal forming film pressing grooves 204, and the flower bone forming grooves 205 are communicated into the adjacent petal forming film pressing grooves 204; an upper molding fixing die 403 and a flower bone injection head 404 are provided on the lower surface of the upper pre-tandem molding press die 401.

As shown in fig. 1 and 2, after the film pressing head of the upper thermoforming mold 200 extends into the petal thermoforming groove 204 of the lower thermoforming mold 201 to perform matching thermoforming to form simulated blades (simulated petals), a sliding driving device (not shown) of the lower thermoforming mold 201 is started, and the lower thermoforming mold 201 is driven to slide into the sliding rail of the lower pre-tandem forming supporting mold 402 from the sliding rail of the forming mold supporting mold 203, one or more infrared sensors are respectively arranged at the left end of the forming mold supporting mold 203 and the right end of the lower pre-tandem forming supporting mold 402, and are used for detecting the sliding stroke of the lower thermoforming mold 201 between the left end of the forming mold supporting mold 203 and the right end of the lower pre-tandem forming supporting mold 402, when sliding leftwards, the sliding of the left end of the lower thermoforming mold 201 is aligned with the lower right of the upper thermoforming mold 200, and when sliding rightwards, when the right end of the lower hot forming die 201 is aligned with the lower part of the right end of the upper pre-tandem forming pressing die 401, the sliding is stopped, the lower hot forming die 201 carries simulation blades (simulation petals) formed by hot pressing to slide rightwards to match and correspond to the lower pre-tandem forming supporting template 402 under the upper pre-tandem forming pressing die 401, the fourth lifting cylinder 403 pushes the lower pre-tandem forming supporting template 402 upwards and drives the lower hot forming die 201 to move upwards, so that the simulation blades (simulation petals) placed in the petal hot pressing forming groove 204 are in positioning contact with the upper forming fixing die head 403 arranged in the upper pre-tandem forming pressing die 401, the second heating injection molding gun barrel 400 heats the stored bone raw materials (plastics) at high temperature, the second heating injection molding gun barrel 400 extrudes and injects the bone raw materials (plastics) melted at high temperature into the bone injection head 404, the second heating injection molding gun barrel 400 is used for pouring high-temperature molten flower skeleton raw materials (plastics) into the flower skeleton forming groove 205 under the pressure effect to form flower skeletons (branches) of simulation leaves (simulation petals), the flower skeletons (branches) are connected among corresponding simulation leaves (simulation petals) in the flower skeleton forming groove 205 in the pouring process, so that simulation petal bone shooting operation is completed to form a string of simulation flowers, after the simulation petals are connected in series, the fourth lifting cylinder 403 contracts downwards, the lower thermal forming die 201 is separated from the upper pre-series forming pressing die 401, then the lower pre-series forming supporting die plate 402 drives the lower thermal forming die 201 to descend to the table top of the control console 10, the simulation flower string formed in series in the lower thermal forming die 201 is conveyed and transferred to the petal collecting frame 6 through the conveying assembly 5, and after the conveying is completed, the sliding driving device (not shown in the figure) drives the lower thermal forming die 201 to slide back to the position below the upper thermal forming die 200 again, thereby completing the automatic generation process of the simulated leaves (simulated petals) and waiting for the next hot-press molding and simulated petal bone shooting operation.

In the utility model, as shown in fig. 1, fig. 2 and fig. 3, the carrying assembly 5 includes a material transporting console 500 fixed on the side of the console 10, a gripping device 501 is arranged on the material transporting console 500, the gripping device 501 includes a fixing ring 502 and a rotating shaft 503 arranged inside the fixing ring 502, the rotating shaft 503 vertically extends upwards from the material transporting console 500 to the outside of the material transporting console 500, a plurality of shaking blocks 504 are fixedly connected to the fixing ring 503 in an annular manner, top grinding rods 505 are fixedly connected to the top side wall of the rotating shaft 503 symmetrically, the top grinding rods 505 are in relative rotational contact with the shaking blocks 504, a supporting rod 506 is fixedly connected to the top side wall of the rotating shaft 503 and positioned between the two top grinding rods 505, the supporting rod 506 is vertically fixed on the top side wall of the rotating shaft 503, a hydraulic rod 507 is arranged on the upper surface of the supporting rod 506, a gripping claw 508 is arranged at the free end of the supporting rod 506, the output shaft of the hydraulic rod 507 is in transmission connection with the grabbing claws 508, and the grabbing claws 508 slide back and forth at the free end of the support rod 506; the grabbing claw 508 comprises a grabbing claw head 5080, a grabbing claw tail 5081 and a pushing block 5082, the pushing block 5082 is arranged on the supporting rod 506 in a sliding mode, an output shaft of the hydraulic rod 507 is in transmission connection with a fixed end of the pushing block 5082, two sides of a free end of the pushing block 5082 are provided with pushing rods 5083 in a forward inclining and extending mode, one end of each pushing rod 5083 is hinged with two sides of a free end of the pushing block 5082, and the other end of each pushing rod 5083 is connected with the head of the grabbing claw tail 5081; the rotation process of the rotating shaft 503 drives the hydraulic rod 507 and the grabbing claw 508 on the supporting rod 506 to rotate simultaneously, when the grabbing claw 508 on the supporting rod 506 rotates to the lower hot forming die 201 below the upper pre-serial forming pressing die 401, the hydraulic rod 507 is started to control the grabbing claw 508 to grab the serially-formed simulated flower bunch in the lower hot forming die 201.

In the present invention, as shown in fig. 2, 3 and 4, a T-shaped fixing lug 5084 is fixedly connected to a free end of the support rod 506, two sides of the T-shaped fixing lug 5084 are respectively hinged to a tail of the grabbing claw tail 5081, and a fixing portion of the T-shaped fixing lug 5084 is connected to a free end of the pushing block 5082; the side wall of the lower surface of the T-shaped fixed connecting ear 5084 is relatively arranged on the free end of the supporting rod 506 in a sliding way; the T-shaped fixing lugs 5084 are adapted to better secure the position of the gripper jaw 508 by pushing the gripper jaw head 5080 and the gripper jaw tail 5081 to move caudally when the pushing rod 5083 is moved in the retracting direction of the hydraulic rod 507, and the gripper jaw tail 5081 is rotated about the position where it is hinged to the T-shaped fixing lugs 5084 to bring the gripper jaw heads 5080 closer to each other; the grabbing of the simulated leaves (simulated petals) or the flower bones (branches) can be accelerated, so that the simulated leaves can be grabbed better; a grabbing claw 508 is arranged at the free end part of the supporting rod 506, the output shaft of the hydraulic rod 507 is in transmission connection with the grabbing claw 508, and the grabbing claw 508 slides back and forth at the free end part of the supporting rod 506; a blocking disc 509 is fixedly connected to the lower end of the rotating shaft 503, and a spring 510 is arranged on the rotating shaft 503 between the blocking disc 509 and the fixing ring 502; the lower end of the rotating shaft 503 passes through the blocking disc 509, and a driving shaft 511 is fixedly connected to the end of the rotating shaft 503 below the blocking disc 509, wherein the driving shaft 511 is a screw rod or a long gear, preferably a screw rod; the driving motor is engaged and driven when the driving shaft 511 (lead screw) rotates in the lead screw nut through driving to realize the lifting action, when the driving shaft 511 (lead screw) rotates, the driving shaft 511 (lead screw) drives the rotating shaft 503 to lift and rotate, and when the driving shaft 511 (lead screw) drives the rotating shaft 503 to descend and rotate, the spring 510 is extruded to shrink, so that the rotating shaft 503 is gradually limited from moving downwards; the rotating shaft 503 drives the top grinding rod 505 and the supporting rod 506 to rotate, the fixing ring 503 is fixed at the top end of the rotating shaft 32, and the top grinding rod 33 slides along a track formed by an elastic film on the surface of the concave-convex shaking block 35, so that the friction between the shaking block 35 and the top grinding rod 33 is reduced, and the top grinding rod 33 can be prevented from rotating excessively; the lower hot forming die 201 slides to the lower part of the upper pre-tandem forming die 401, and after the support rod 506 moves to the designated position of the lower hot forming die 201, the driving shaft 511 (screw rod) stops rotating; opening the hydraulic rod 507 to make the output shaft of the hydraulic rod 507 extend out of the hydraulic rod 507, thereby pushing the push block 5082 to move, making the push block 5082 hinged with the push rod 5083 to make the push rod 5083 rotate around the position hinged with the push block 5082, making the push rod 5083 hinged with the tail of the grabbing claw tail 5081 through the push rod 5083 through the push block 5082 and making the grab claw tail 5081 to move, making the grabbing claw tail 5081 rotate around the position hinged with the T-shaped fixed connecting ear 5084 through the T-shaped fixed connecting ear 5084 and making the grabbing claw head 5080 approach each other to grab the artificial flower string, after the grabbing of the artificial flower string is completed, the driving shaft 511 (lead screw) rotates to drive the rotating shaft 503 to rotate, and the artificial flower string is moved to the top position on the petal collecting frame 6, opening the hydraulic rod 507 to make the output shaft drive the grabbing claw heads 5080 on the grabbing claws 508 to separate from each other, the artificial flower bunch is unloaded, when the artificial flower bunch is unloaded, the artificial flower bunch falls onto the petal collection frame 6, so that the artificial flower bunch slides onto a collection table on the ground along the petal collection frame 6, and the transmission and collection of the artificial flower bunch are finished, therefore, the utility model can quickly grab the artificial flower and improve the speed of picking the artificial flower; for this reason, the utility model discloses can pour into the pre-compaction forming die set fast to the plastics raw materials to and can transport emulation blade rudiment (emulation petal rudiment) fast, and can establish ties emulation petal fast, thereby accomplish the emulation petal and penetrate the bone operation in order to form the emulation flower cluster, and can be fast with snatching the emulation flower cluster and transmit on to petal collection frame 6, for this, the utility model discloses a full automated production technology of whole emulation flower arranges compactly, and every process can effectively link up, can be fast, accomplish the raw materials injection high-speed and full-automatic, the petal shaping concatenates and forwards a series of process flows to the petal, and the big way has improved the work efficiency of emulation flower production, has reduced the cost of labor by a wide margin.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications and decorations can be made without departing from the principle of the present invention, and these modifications and decorations should also be regarded as the protection scope of the present invention.

Claims (10)

1. The utility model provides an artificial flower automatic production manufacturing installation which characterized in that: the hot-press forming die set comprises an upper hot-press forming die and a lower hot-press forming die, wherein the upper hot-press forming die and the lower hot-press forming die are fixed on the top end of the console in the same straight line, and the lower hot-press forming die is arranged on the surface of the console in a sliding manner, the lower hot forming die slides back and forth between the position under the upper hot forming die and the position under the serial forming module, the transfer assembly is arranged between the lower back sides of the upper prepressing die and the upper hot forming die, and the carrying assembly is arranged on a control console below the right side of the serial forming module.

2. The automatic production and manufacturing device of the simulated flower according to claim 1, wherein: the transfer assembly comprises a rotating arm, a transfer support arm frame and a sucker, one end of the rotating arm is fixed to the top end of the pre-pressing forming module through a rotating motor, the other end of the rotating arm vertically extends downwards to be in transmission connection with the transfer support arm frame horizontally arranged, a sucker support plate is arranged below the support arm frame, the sucker is arranged on the sucker support plate, and the sucker support plate is fixed below the support arm frame through a third telescopic cylinder.

3. The automatic production and manufacturing device of the simulated flower according to claim 1, wherein: the series molding module comprises a second heating injection molding barrel, an upper pre-series molding pressing die and a lower pre-series molding supporting template, the second heating injection molding barrel and the upper pre-series molding pressing die are arranged on the top end of a console from top to bottom, a discharge port of the second heating injection molding barrel is communicated with the top end of the upper pre-series molding pressing die, the lower pre-series molding supporting template is arranged right below the upper pre-series molding pressing die and fixed on the surface of the console through a fourth lifting cylinder, a molding die supporting template is arranged at the bottom end of a lower hot molding die, the lower hot molding die is arranged on the surface of the console through the molding die supporting template, and the lower hot molding die can slide back and forth between the surface of the molding die supporting template and the surface of the lower pre-series molding supporting template.

4. An automatic production and manufacturing device of a simulated flower according to claim 3, wherein: petal forming film pressing grooves are formed in the surface of the lower hot forming die, and flower bone forming grooves are formed between the adjacent petal forming film pressing grooves and communicated to the adjacent petal forming film pressing grooves; and an upper molding fixed die head and a flower bone injection head are arranged on the lower surface of the upper pre-serial molding pressing die.

5. The automatic production and manufacturing device of the simulated flower according to claim 1, wherein: the carrying assembly comprises a material conveying control platform fixed on the side of the control platform, a gripping device is arranged on the material conveying control platform, the gripping device comprises a fixing ring and a rotating shaft arranged in the fixing ring, the rotating shaft vertically extends upwards from the material conveying control platform to the outside of the material conveying control platform, a plurality of shaking blocks are fixedly connected on the fixed ring in an annular manner, the top end side wall of the rotating shaft is symmetrically and fixedly connected with top grinding rods, the top grinding rods are in relative rotating contact with the shaking blocks, a supporting rod is fixedly connected with the top end side wall of the rotating shaft and positioned between the two top grinding rods, the supporting rod is vertically fixed on the side wall of the top end of the rotating shaft, a hydraulic rod is arranged on the upper surface of the supporting rod, a grabbing claw is arranged at the free end part of the supporting rod, the output shaft of the hydraulic rod is in transmission connection with the grabbing claws, and the grabbing claws slide back and forth at the free end parts of the supporting rods.

6. An automatic production manufacturing device of a simulated flower according to claim 5, characterized in that: snatch the claw including snatching the claw head, snatch the claw tail and promote the piece, should promote the piece and slide and set up on the bracing piece, the output shaft of hydraulic stem with the stiff end transmission that promotes the piece is connected, the free end both sides that promote the piece are leaned forward and are stretched out and be provided with the catch bar, and the one end of this catch bar is articulated with the free end both sides that promote the piece, the other end of catch bar with the head of snatching the claw tail is connected.

7. The automatic production and manufacturing device of the simulated flower according to claim 6, wherein: the fixed connection of the free end of the bracing piece has T-shaped fixed connection lugs, the two sides of the T-shaped fixed connection lugs are respectively hinged with the tail of the grabbing claw tail, and the fixed part of the T-shaped fixed connection lugs is connected with the free end of the pushing block.

8. The automatic production and manufacturing device of the simulated flower according to claim 7, wherein: the side wall of the lower surface of the T-shaped fixed connection lug is arranged on the free end part of the supporting rod in a relatively sliding manner.

9. An automatic production manufacturing device of a simulated flower according to claim 5, characterized in that: the lower extreme fixedly connected with of rotation axis keeps off the dish, keep off and be equipped with the spring on the rotation axis between dish and the solid fixed ring.

10. The automatic production and manufacturing device of the simulated flower according to claim 9, wherein: the lower end of the rotating shaft penetrates through the blocking disc, and a driving shaft is fixedly connected to the end portion of the rotating shaft below the blocking disc.

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