CN110172790B

CN110172790B - Method for slicing multiple gold sheets

Info

Publication number: CN110172790B
Application number: CN201910415464.1A
Authority: CN
Inventors: 鲁友强; 胡聪伟; 张伟; 张彬; 张�杰; 周亦君; 吴虹波
Original assignee: Huzhou Guanjiong Mechanical And Electrical Technology Co ltd
Current assignee: Huzhou Guanjiong Mechanical And Electrical Technology Co ltd
Priority date: 2019-05-17
Filing date: 2019-05-17
Publication date: 2022-06-14
Anticipated expiration: 2039-05-17
Also published as: CN110172790A

Abstract

The invention discloses a method for slicing multiple gold sheets, which is characterized in that a cutter is arranged to be matched with a sheet feeding mechanism of a multiple gold sheet feeder, the cutter is arranged at a sheet feeding station to be matched with the sheet feeder at the station for slicing, and a slicing driver drives the cutter to slice. The cutter of the method of the invention only needs to rotate for slicing, has high transmission efficiency, simple transmission structure and low manufacturing cost, and has extremely high manufacturing and practical values.

Description

Method for slicing multiple gold sheets

Technical Field

The invention relates to a method for slicing multiple gold sheets.

Background

The gold sheet device is used for embroidering gold sheets on a fabric, the gold sheets which are continuously conveyed need to be cut off one by one through a cutter, and multiple gold sheets can be output in multiple specifications and multiple gold sheets and have higher output efficiency. The current multi-sequin slicing generally comprises a cutting blade matched with a corresponding sequin conveying groove of the multi-sequin and a cutter bar connected with the corresponding blade, wherein the sequin conveying groove drives the corresponding sequin conveying groove to be matched with a needle bar through a sequin conveying groove driving mechanism according to needs, and the cutter bar is driven by the driving mechanism to move to cut the corresponding sequin. In order to ensure that each blade can cut off gold flakes and ensure the precision, the blades are usually arranged to be thin and easy to break, and the whole cutter bar is required to act to slice any gold flakes so as to drive all the blades to slice. The structure is complex, and the installation and debugging difficulty of a plurality of blades is high.

Disclosure of Invention

The invention provides a multi-sequin slicing method which reduces the structure of a device and is convenient for slicing, aiming at solving the problems that a multi-sequin cutter is complex in structure, slicing is inconvenient to use and the like in the prior art.

The technical scheme for solving the existing problems is as follows: a method for slicing multiple gold sheets includes setting sheet-changing driver on sheet-feeding mechanism composed of at least two sheet-feeding units arranged side by side, selecting sheet-changing driver or driving corresponding sheet-feeding unit on sheet-feeding mechanism to move to sheet-feeding position to feed sheet and match with embroidery needle, setting a cutter at sheet-feeding position to match with corresponding sheet-feeding unit at sheet-feeding position, and driving the cutter to cut sheet by sheet-cutting driver.

As a further improvement, the cutter can be rotatably arranged on a cutter frame.

As a further improvement, the cutter shaft of the cutter can be axially and elastically moved and is arranged on the cutter rest to be matched with the corresponding sheet feeder positioned at the sheet feeding station, and the elastic pretightening force is arranged on the cutter shaft or the cutter to ensure that the cutter is matched with the corresponding sheet feeder positioned at the sheet feeding station.

As a further improvement, an end plate is arranged at one end or two ends of the slice conveying mechanism, and the slice driver or/and the knife rest are/is fixedly arranged at the corresponding position of the corresponding end plate.

As a further improvement, a controller is arranged to coordinate and drive the film changing driver, the film slicing driver and the film feeding mechanism to be matched.

As a further improvement, the slicing driver of the cutting knife comprises a power transmission structure which is connected with a slicing power input device and used for transmitting power, and the knife rest is relatively and fixedly arranged at the corresponding position of the slice feeding mechanism.

As a further improvement, the cutter comprises a cutting edge and a driving arm, the cutter is rotatably arranged on the cutter frame, and the corresponding part of the power transmission structure is movably connected with the corresponding part of the driving arm.

As a further improvement, the power input device is a slicing motor, air pressure, hydraulic pressure or an electromagnetic push rod.

As a further improvement, the power transmission structure comprises a swing rod arranged on a motor shaft of the slicing machine and a connecting rod with one end movably connected with the swing rod, and the other end of the connecting rod can drive the corresponding part of the slicing cutter to be movably connected with the corresponding part of the cutting cutter driving arm.

As a further improvement, the piece feeding mechanism is provided with a feeding mechanism which drives the piece feeding mechanism to feed or retreat towards the embroidery needle to a proper position according to the specification size of the gold pieces, the feeding mechanism advances or retreats to compensate the difference of the gold pieces with different specifications, the pieces are fed to the position right below the embroidery needle, and the proper position is the position where the upper piece feeder and the lower piece feeder can feed the gold pieces to the normal embroidery pieces below the embroidery needle.

As a further improvement, the feeding mechanism comprises a connecting sheet feeding mechanism and a supporting body, a power-driven screw rod or screw rod structure, a driving connecting rod structure, a matched gear rack structure or a matched belt wheel and synchronous belt structure, or a linear motor, an air pressure or a hydraulic rod.

As a further improvement, the at least one group of film feeders comprises an upper film feeder and a lower film feeder of the laminated film.

As a further improvement, the upper and lower sheet feeders respectively include corresponding upper and lower plectrum rods, upper and lower sheet grooves and plectrum rod drivers, the upper plectrum rod of the upper sheet feeder of each group of sheet feeders is sleeved on an upper shaft, the lower plectrum rod of the lower sheet feeder of each group of sheet feeders is sleeved on the lower shaft, the plectrum rod driver includes upper and lower plectrum motors, the upper and lower plectrum motors are respectively and correspondingly connected with upper and lower connecting rod assemblies, one end of the upper and lower shafts is fixed on the mounting plate of the multi-gold sheet slicing device, the upper and lower plectrum motors are fixed on the mounting plate, the upper and lower connecting rod assemblies selectively drive the upper and lower plectrum rods of any group of sheet feeders, and the upper and lower connecting rod assemblies selectively drive the corresponding group of sheet feeders along with the drive of the sheet feeder of the corresponding group of sheet feeders.

As a further improvement, the cutting knife is an upper lamination cutting knife and a lower lamination cutting knife which correspond to the upper and lower sheet feeders.

As a further improvement, a lifting mechanism is arranged to drive the sheet feeding mechanism to be matched with the machine head or to be away from the machine head.

As a further improvement, the lifting mechanism comprises an upper section fixedly arranged on the machine head, a lower section formed by a multi-sequin slicing device and a support body, and a lifter connected with the upper section and the lower section, wherein the lifter drives the lower section to move downwards at the matching part of the embroidery needle and drives the lower section to lift and separate from the matching part of the embroidery needle.

Compared with the prior art, the method for slicing the gold sheets has the advantages that the method is simple in slicing, a cutter is convenient to install, debug and maintain, the cutter can be relatively thick and firm, the service life of the cutter can be prolonged, the gold sheets of the multiple gold sheet feeders can be cut by the same cutter, and the slicing effect is neat and tidy. The cutter of the method of the invention only needs to rotate for slicing, has high transmission efficiency, simple transmission structure and low manufacturing cost, and has extremely high manufacturing and practical values.

The method can be widely applied to the existing embroidery machines and can be matched with other functional devices such as a bead embroidery device and the like to be arranged on the machine head of the embroidery machine. The device has high efficiency of slice of the embroidered piece, and the cutter is convenient to maintain and tidy.

Drawings

Fig. 1 is a schematic view showing a structure in which the apparatus of the present invention is installed at one side of an embroidery head.

Fig. 2 is a side view of the apparatus of the present invention installed at one side of the embroidery head.

Fig. 3 is a schematic structural diagram of the multi-gold-piece slicing device of the present invention.

Fig. 4 is a partial schematic view of the multiple gold plate slicing apparatus of the present invention.

Fig. 5 is a schematic structural diagram of another view angle of the multi-sequin slicing device of the present invention.

Fig. 6 is a schematic view of another view of a portion of the multi-sequin slicing apparatus method of the present invention.

Fig. 7 is another perspective view illustrating the method of cutting a gold multi-sheet according to the present invention installed at one side of an embroidery machine head.

Detailed Description

Referring to fig. 1-7, a method for slicing multiple gold sheets, a sheet changing driver 103 is arranged on a sheet feeding mechanism 100 formed by at least two sheet feeders 101 arranged side by side, the sheet changing driver 103 selects or drives the corresponding sheet feeder 101 on the sheet feeding mechanism 100 to move to a sheet feeding station to feed sheets to be matched with embroidery needles, a cutter 201 is arranged at the sheet feeding station to be matched with the corresponding sheet feeder 101 at the sheet feeding station, and a sheet driver 203 drives the cutter 201 to slice. The cutter 201 may be rotatably disposed on a tool holder 202.

Further, the cutter 201 is arranged on the cutter frame 202 and can axially and elastically move to be matched with the corresponding sheet feeder 101 located at the sheet feeding station, and the elastic pretightening force is arranged on the cutter shaft or the cutter 201 to enable the cutter to be matched with the corresponding sheet feeder 101 located at the sheet feeding station.

Further, an end plate 104 may be provided at one or both ends of the sheet feeding mechanism 100, and the slice driver 203 or/and the tool holder 202 may be fixed to the corresponding portion of the corresponding end plate 104.

Further, the controller may be configured to coordinate and drive the slide replacing driver 103, the slide driver 203, and the slide feeding mechanism 100. Further, a lifting mechanism 300 may be provided to drive the sheet feeding mechanism 100 into engagement with the head 9 or away from the head 9.

Furthermore, the feeding mechanism 100 is provided with a feeding mechanism 57 for driving the feeding mechanism 100 to feed or retreat toward the embroidery needle to a proper position according to the standard size of the tinsels, the feeding mechanism 57 compensates the difference of the tinsels with different standards by advancing or retreating, and the tinsels are fed to the position right below the embroidery needle, and the proper position is the position where the upper and lower tinsels can feed the tinsels to the normal tinsels below the embroidery needle. The feed mechanism 57 can be adapted to different sizes of multiple gold pieces and also to different sizes of upper and lower laminations.

In order to facilitate understanding of the method for cutting the multiple sequins, the invention also provides a multiple sequins slicing device and an embroidery machine.

Referring to fig. 1-7, the device comprises a sheet feeding mechanism 100 provided with at least two sets of sheet feeders 101 side by side, a cutter assembly 200 matched with the sheet feeding mechanism 100, a sheet feeding driver 102 for driving the corresponding sheet feeder 101 to feed sheets, a sheet feeding station arranged on the sheet feeding mechanism 101, and a sheet changing driver 103 for switching the corresponding or any set of sheet feeders 101 to the sheet feeding station to feed sheets to be matched with an embroidery needle, wherein the cutter assembly 200 comprises a cutter 201 arranged at the sheet feeding station and matched with the sheet feeder 101 at the station to cut sheets, and the cutter 201 is provided with a cutter frame 202 for installing and positioning the cutter 201 and a sheet driver 203 for driving the cutter 201 to cut sheets. The controller can be independently arranged and used for controlling the corresponding driver of the multi-sequin slicing device or/and the corresponding motor to act, or the controller on the embroidery machine can be used for integrally controlling the multi-sequin slicing device to work.

Each group of film feeders 101 can be independently arranged vertically, and film feeding mechanisms 100 comprising independent groups of film feeders are combined, or the film feeding mechanisms 100 can be formed by uniformly and integrally arranging a plurality of groups of film feeders 101.

The sheet feeding mechanism 100 is provided with end plates 104 at one or both ends, and the slicing driver 203 and/or the tool holder 202 are fixed to the corresponding positions of the corresponding end plates 104 for the sake of simplicity of construction. Of course, the slicing driver 203 or/and the knife rest 202 can be separately provided with corresponding fixing seats or plates, so that the slicing driver 203 or/and the knife rest 202 can be installed at corresponding positions, and even the knife rest 201 can be omitted, the cutting knife 201 is installed in a positioning way relative to the sheet feeding mechanism 100, and the slicing driver 203 can be directly installed on the fixing seats.

The slicing driver 203 of the cutting knife 201 comprises a power transmission structure connected with a slicing power input device for transmitting power, and the knife rest 202 is relatively and fixedly arranged at the corresponding position of the slice feeding mechanism 100.

The cutter 201 comprises a cutting edge 204 and a driving arm 205, the cutter 201 is rotatably arranged on the cutter frame 202, and the corresponding part of the power transmission structure is movably connected with the corresponding part of the driving arm 205.

The power input device is a slicing motor 206, a pneumatic, hydraulic or electromagnetic push rod, and in the embodiment, the slicing motor 206 is adopted for the convenience of control.

The power transmission structure comprises a swing rod 207 arranged on a motor shaft of the slicing motor 206 and a connecting rod 208 with one end movably connected with the swing rod 207, and the other end of the connecting rod 208 can drive the corresponding part of the slicing position of the cutter 201 to be movably connected with the corresponding part of the cutter driving arm 205.

The cutter 201 is provided with an elastic pretightening force matched with the corresponding sheet feeder 101 positioned at the sheet feeding station, and a cutter shaft of the cutter 201 can be axially and elastically moved and is arranged on the cutter rest 202 to be matched with the corresponding sheet feeder 101 positioned at the sheet feeding station, so that the cutter 201 can be elastically buffered when the cutter is cut or touches a hard object, and the cutter 201 is prevented from being damaged.

In the drawings of the present embodiment, each group of film feeders 101 is a single gold sheet feeding. Each sheet feeder 100 can be provided with a corresponding sheet shifting rod 5, a sheet groove 59 and a sheet shifting rod 51 driver, the sheet shifting rod 51 of each group of sheet feeders 101 is sleeved on a shaft 52, and the shaft 52 can be fixed on an end plate 104 of the sheet feeder. The driver of the piece shifting rod 51 is a piece shifting motor 105, the piece shifting motor 105 is connected with a connecting rod assembly 106, the piece shifting motor 105 is fixed on the mounting plate, the connecting rod assembly 4 selectively drives the piece shifting rods 51 of any group of piece feeders 100, the connecting rod assembly 4 switches the corresponding group of piece feeders 101 to the piece feeding station along with the driving of the piece changing driver 103, and selectively drives the piece shifting rods 51 of the piece feeders 101 to feed pieces at the piece feeding station.

Referring to fig. 7, the link assembly 4 includes a swing link 53 connected to the paddle motor 51, and a transmission link 56 engaged with the paddle lever 51, wherein the transmission link 56 is rotatably disposed on a rotating shaft, and a universal link 54 is directly disposed between the transmission link 56 and the swing link 53. A paddle switch 55 may be provided, the paddle switch 55 being relatively fixedly disposed on the mounting plate, and the shaft of the transfer link 56 may be disposed on the paddle switch 55.

Of course, at least one set of sheet feeders 101 may be provided including upper and lower sheet feeders for the stacked sheets, or all of the sheet feeders 101 may be upper and lower sheet feeders for the stacked sheets.

The upper and lower sheet feeders respectively comprise corresponding upper and lower sheet shifting rods, upper and lower sheet grooves and sheet shifting rod drivers, the upper sheet shifting rod of the upper sheet feeder of each group of sheet feeders is sleeved on an upper shaft, the lower sheet shifting rod of the lower sheet feeder of each group of sheet feeders is sleeved on a lower shaft, each sheet shifting rod driver comprises an upper sheet shifting motor and a lower sheet shifting motor, the upper sheet shifting motor and the lower sheet shifting motor are respectively and correspondingly connected with an upper connecting rod assembly and a lower connecting rod assembly, one end of the upper shaft and one end of the lower shaft are fixed on a mounting plate of the multi-gold sheet slicing device, the upper sheet shifting motor and the lower sheet shifting motor are fixed on the mounting plate, the upper connecting rod assembly and the lower connecting rod assembly selectively drive the upper sheet shifting rod and the lower sheet shifting rod of any group of sheet feeders, and the upper connecting rod assembly and the lower connecting rod assembly selectively drive the upper sheet shifting rod and the lower sheet shifting rod of the corresponding group along with the sheet feeder of the corresponding group driven by the sheet changing driver.

In order to facilitate rapid slicing and stacking, the cutter 201 is an upper and a lower stacking cutter corresponding to the upper and the lower sheet feeder. Both the lamination structure and the lamination cutter can completely adopt the prior art.

The sheet feeding mechanism 100 is further provided with a feeding mechanism 57 for driving the sheet feeding mechanism to feed or retreat toward the embroidery needle to a proper position where the upper and lower sheet feeders can feed the gold sheet to a normal embroidery sheet below the embroidery needle according to the specifications of the gold sheets of the single gold sheet and the upper and/or lower gold sheets.

The feeding mechanism 57 includes a screw rod or screw rod structure connected with the sheet feeding mechanism 100 and the support body, a power-driven screw rod or screw rod structure, a driving link structure, a matched gear rack structure or a matched belt wheel and synchronous belt structure, or a linear motor, an air pressure or a hydraulic rod. The changer driver 103 may also be constructed like a feed mechanism. If the film-changing driver 103 can comprise a film-changing motor 7, and a corresponding screw rod and a sliding sleeve 8, the film-changing motor 7 is connected with the screw rod and drives it to rotate to drive the sliding sleeve 8 to move, the sliding sleeve 8 can be connected with the film-feeding mechanism 100 through an end plate 104 or a connecting plate, and drives the film-feeding mechanism 100 to move so as to drive and switch the corresponding film feeder 101 to move to the film-feeding station for feeding the film.

The lifting mechanism 300 is further included, so that the embroidery machine can achieve multiple purposes, and the embroidered piece can be embroidered flatly or matched with other embroidery machines such as bead embroidery and the like. The lifting mechanism 300 comprises an upper section fixedly mounted on the machine head 9, a lower section formed by a multi-sequin slicing device and a support body 58, and a lifter 301 connected with the upper section and the lower section, wherein the lifter 301 drives the lower section to move downwards at the position matched with the embroidery needle and drives the lower section to lift and separate from the position matched with the embroidery needle. The lifter 301 may be implemented using a cylinder and corresponding rail assembly, or other known prior art.

The invention also provides an embroidery machine provided with the multi-sequin slicing method in any one scheme or any combination of schemes, wherein the embroidery machine is provided with at least one machine head 9, and a multi-sequin slicing device is arranged on one side, the front side or/and two sides of the at least one machine head 9.

In the embroidery machine, one side of at least one machine head is provided with the multi-sequin slicing device, and the other side is provided with the bead embroidery device. The mounting structure can also adopt the existing mounting mode and the existing bead embroidery device (the bead embroidery device is not shown in the figure).

The description of the embodiments and the drawings are only for illustrating the inventive concept, and the specific components or structures are not to be considered as limiting the scope of the inventive concept, and all modifications or changes made to the corresponding components or structures within the inventive concept shall fall within the scope of the invention.

Claims

1. A method for slicing multiple gold sheets is characterized in that: the embroidery needle embroidery machine is characterized in that a piece-changing driver is arranged on a piece-feeding mechanism formed by at least two piece-feeding devices arranged side by side, the piece-changing driver selects or drives the corresponding piece-feeding devices on the piece-feeding mechanism to move to a piece-feeding station to feed pieces to be matched with an embroidery needle as required, a cutter is arranged at the piece-feeding station to be matched with the corresponding piece-feeding devices positioned at the piece-feeding station, the cutter driver drives the cutter to cut the pieces, the piece-cutting driver of the cutter comprises a power transmission structure connected with a piece-cutting power input device and used for transmitting power, and a cutter rest is relatively and fixedly arranged at the corresponding position of the piece-feeding mechanism; the cutter comprises a cutting edge and a driving arm, the cutter is rotatably arranged on the cutter frame, and the corresponding part of the power transmission structure is movably connected with the corresponding part of the driving arm; the power transmission structure comprises a swing rod arranged on a slicing motor shaft and a connecting rod, one end of the connecting rod is movably connected with the swing rod, the other end of the connecting rod can drive the corresponding part of the slicing cutter to be movably connected with the corresponding part of a cutter driving arm, a cutter shaft of the cutter can be arranged on a cutter frame in an axially elastic movable mode to be matched with a corresponding sheet feeder positioned at a sheet feeding station, and elastic pretightening force is arranged on the cutter shaft or the cutter to enable the cutter to be matched with the corresponding sheet feeder positioned at the sheet feeding station.

2. The method of multi-gold slicing as defined in claim 1 wherein: and end plates are arranged at one end or two ends of the slice conveying mechanism, and the slice driver or/and the tool rest are fixedly arranged at corresponding positions of the corresponding end plates.

3. The method of multi-gold slicing as defined in claim 1 wherein: the controller is arranged to coordinate and drive the film changing driver, the film slicing driver and the film feeding mechanism to be matched.

4. The method of multi-gold slicing as defined in claim 1 wherein: the power input device is a slicing motor, a pneumatic, hydraulic and electromagnetic push rod.

5. The method of multi-gold slicing as defined in claim 1 wherein: the feeding mechanism is provided with a feeding mechanism which drives the feeding mechanism to feed or retreat to a proper position towards the embroidery needle according to the specification size of the sequins, the feeding mechanism advances or retreats to compensate the difference of the sequins with different specifications, the sequins are fed to the position under the embroidery needle, and the proper position is the position where the upper and lower sequin feeders can feed the sequins to the normal embroidery sheet under the embroidery needle.

6. The method of multi-gold slicing as defined in claim 5 wherein: the feeding mechanism comprises a connecting piece feeding mechanism and a supporting body, a screw rod or a screw rod structure driven by power, a driving connecting rod structure, a matched gear rack structure or a matched belt wheel and synchronous belt structure, or a linear motor, an air pressure or a hydraulic rod.

7. The method of multi-gold slicing as defined in claim 1 wherein: at least one set of sheet feeders includes upper and lower sheet feeders for the stacked sheets.

8. The method of multi-gold slicing as defined in claim 7 wherein: the upper and lower sheet feeders respectively comprise corresponding upper and lower sheet shifting rods, upper and lower sheet grooves and sheet shifting rod drivers, the upper sheet shifting rod of the upper sheet feeder of each group of sheet feeders is sleeved on an upper shaft, the lower sheet shifting rod of the lower sheet feeder of each group of sheet feeders is sleeved on a lower shaft, each sheet shifting rod driver comprises an upper sheet shifting motor and a lower sheet shifting motor, the upper sheet shifting motor and the lower sheet shifting motor are respectively and correspondingly connected with an upper connecting rod assembly and a lower connecting rod assembly, one end of each upper shaft and one end of each lower shaft are fixed on a mounting plate of the multi-sequin slicing device, the upper sheet shifting motor and the lower sheet shifting motor are fixed on the mounting plate, the upper connecting rod assembly and the lower connecting rod assembly selectively drive the upper sheet shifting rod and the lower sheet shifting rod of any group of sheet feeders, and the upper connecting rod assembly and the lower connecting rod assembly selectively drive the upper sheet shifting rod and the lower sheet shifting rod of the corresponding group along with the sheet feeder of the corresponding group.

9. The method of multi-sequin slicing as recited in claim 8, wherein: the cutter is an upper lamination cutter and a lower lamination cutter which correspond to the upper and lower sheet feeders.

10. The method of multi-gold slicing as defined in claim 1 wherein: and a lifting mechanism is arranged to drive the sheet feeding mechanism to be matched with the machine head or to be far away from the machine head.

11. The method of multi-sequin slicing as recited in claim 10, wherein: the lifting mechanism comprises an upper section fixedly arranged on the machine head, a lower section formed by a multi-sequin slicing device and a support body, and a lifter connected with the upper section and the lower section, wherein the lifter drives the lower section to move downwards at the embroidery needle matching position and drives the lower section to lift and separate from the embroidery needle matching position.