CN216969113U - Opposite-penetrating device for thread assembling machine - Google Patents

Abstract

The utility model discloses a penetration device for a thread binding machine, which comprises a penetration fixing component, a left penetration component, a right penetration component, a penetration power component and a penetration positioning component, wherein the left penetration component and the right penetration component are respectively arranged at the left end and the right end of the penetration fixing component and are driven to move left and right by the penetration power component fixed on one side of the penetration fixing component, and the penetration positioning component is arranged on the penetration fixing component and is used for positioning the left penetration component and the right penetration component. According to the binding machine, the left threading assembly and the right threading assembly are fixed on the opposite threading fixing assembly, and the opposite threading power assembly drives the left threading assembly and the right threading assembly to carry out opposite threading on the binding wire, so that the aim of knotting after the binding wire is directly opposite threaded is fulfilled, the problem of binding by means of a tool is avoided, and the labor cost is reduced.

Description

Opposite-penetrating device for thread assembling machine

Technical Field

The utility model relates to the technical field of thread binding machines, in particular to a penetrating device for a thread binding machine.

Background

A thread binding machine is a machine that fixes paper, plastic, leather, and the like with staples, hot melt adhesives, and the like. The product types of the thread binding machine are generally a hot melting thread binding machine, a voucher thread binding machine, a financial thread binding machine, a punching thread binding machine, an accounting voucher thread binding machine, a comb type rubber ring thread binding machine, an iron ring thread binding machine, a thread binding machine and the like on the market according to the adopted binding mode.

The initial manual binding method is to use a thread awl to prick small holes, then hook the binding threads one by a crochet hook, and finally bind by knotting manually. In the binding process, a large amount of manpower is needed to operate threading, and knotting is manually carried out, so that the operation is inconvenient, a large amount of labor cost is needed, and great inconvenience is brought to production.

SUMMERY OF THE UTILITY MODEL

The present invention provides a threading device for a thread forming machine.

In order to achieve the purpose, the technical scheme of the utility model is realized as follows:

the embodiment of the utility model provides a threading device for a thread binding machine, which comprises a threading fixing component, a left threading component, a right threading component, a threading power component and a threading positioning component, wherein the left threading component and the right threading component are respectively arranged at the left end and the right end of the threading fixing component and are driven to move left and right by the threading power component fixed on one side of the threading fixing component, and the threading positioning component is arranged on the threading fixing component and is used for positioning the left threading component and the right threading component.

Preferably, the pair-through fixing component comprises a machine bedplate, a first abdicating groove and a second abdicating groove, the left-through component and the right-through component are respectively arranged at the left end and the right end of the machine bedplate, and are driven by the pair-through power component to respectively move left and right in the first abdicating groove and the second abdicating groove.

Preferably, the left penetrating component comprises a first electric push rod, a first fixed block, a first connecting block, a first moving block, a first fixed block, a first wire pulling hook, a first V-shaped wire pushing sheet and a first clamping jaw, one end of the first moving block is fixed with a first fixed block, a telescopic shaft of the first electric push rod passes through the first fixed block and then is connected with the first connecting block, the other end of the first connecting block is provided with a first V-shaped wire pushing sheet and a first clamping jaw, the first V-shaped wire pushing sheet and the first clamping jaw push the first connecting block to act by a first electric push rod, the first fixing piece is fixed on the machine bedplate, a first wire poking hook is rotatably arranged between the first fixing piece and the machine bedplate, one end of the first wire pulling hook is connected with the first fixing part through a first tension spring, a first sliding column is arranged on the first moving block, and the first wire pulling hook is pulled by the first sliding column to rotate when moving along with the first moving block.

Preferably, the right penetrating component comprises a second electric push rod, a second fixed block, a second connecting block, a second moving block, a second fixed block, a second wire pulling hook, a second V-shaped wire pushing sheet and a second clamping jaw, one end of the second moving block is fixed with a second fixed block, a telescopic shaft of a second electric push rod passes through the second fixed block and then is connected with a second connecting block, the other end of the second connecting block is provided with a second V-shaped wire pushing sheet and a second clamping jaw, the second V-shaped wire pushing sheet and the second clamping jaw push the second connecting block to act by a second electric push rod, the second fixed part is fixed on the machine bedplate, a second wire poking hook is rotationally arranged between the second fixed part and the machine bedplate, one end of the second wire pulling hook is connected with the second fixing part through a tension spring, a sliding column is arranged on the second moving block, and the second wire pulling hook is pulled by the sliding column to rotate when moving along with the second moving block.

Preferably, one side of the second moving block is provided with an open-loop piece, and the open-loop piece is provided with an open-loop auxiliary hook for opening a binding line pulled back by the lifting line hooking mechanism.

Preferably, the through power assembly comprises a first forward and reverse screw rod, a first screw rod nut mounting seat, a first supporting seat, a second screw rod nut mounting seat, a second supporting seat, a first stepping motor, a first synchronous belt and a first synchronous wheel, one end of the first forward and reverse screw rod is sequentially connected with the first screw rod nut, the first screw rod nut mounting seat and the first supporting seat, the first screw rod nut mounting seat is of an L-shaped structure and is connected with a first moving block after penetrating through a first abdicating groove, the other end of the first forward and reverse screw rod is sequentially connected with the second screw rod nut, the second screw rod nut mounting seat and the second supporting seat, the second screw rod nut mounting seat is of an L-shaped structure and is connected with a second moving block after penetrating through a second abdicating groove, one end of the first forward and reverse screw rod and a rotating shaft of the first stepping motor are respectively provided with the first synchronous wheel, the two first synchronous wheels are connected through a first synchronous belt.

Preferably, the through positioning assembly comprises a first limit sensor, a second limit sensor, a limit device sliding groove, a support column and a second guide rail, one end of the machine platen, which is positioned at the left penetration mechanism, is provided with a stopper sliding groove, the first limit sensor and the second limit sensor are arranged on the stopper sliding groove in a sliding manner, the first limit sensor is arranged in the middle of the machine bedplate, the second limit sensor is arranged on one side of the outer end of the first abdicating groove, the first limit sensor and the second limit sensor are used for detecting the moving position of the first moving block, the spreading column is arranged in the middle of the bedplate, the lifting wire hooking mechanism is used for unfolding the open-loop auxiliary hook and the open-loop piece and unfolding the binding wire ring pulled down by the lifting wire hooking mechanism, a second guide rail is arranged on one side of the machine bedplate, and the second guide rail is used for sliding the first moving block and the second moving block.

Compared with the prior art, the left threading assembly and the right threading assembly are fixed on the opposite threading fixing assembly, and the opposite threading power assembly drives the left threading assembly and the right threading assembly to carry out opposite threading on the binding wire, so that the aim of directly tying a knot after opposite threading on the binding wire is fulfilled, the problem of binding by means of a tool is avoided, and the labor cost is reduced.

Drawings

FIG. 1 is a first schematic view of a piercing mechanism provided in an embodiment of the present invention;

FIG. 2 is a second schematic structural view of a piercing mechanism provided in the embodiment of the present invention;

FIG. 3 is a schematic diagram of a left-handed assembly according to an embodiment of the present invention;

fig. 4 is a first schematic structural diagram of a right penetration assembly according to an embodiment of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the utility model and do not limit the utility model.

The same or similar reference numerals in the drawings of the present embodiment correspond to the same or similar components; in the description of the present invention, it should be understood that the terms "upper", "lower", "left", "right", "inner", "outer", etc. indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, which are only for convenience of description and simplification of description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed in a specific orientation, and operate, and therefore, the terms describing the positional relationships in the drawings are only used for illustrative purposes and are not to be construed as limitations of the present patent, and specific meanings of the terms may be understood according to specific situations by those of ordinary skill in the art.

It should be noted that, in this document, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, article, or apparatus that comprises a list of elements does not include only those elements but also other elements not expressly listed or inherent to such process, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in the process, article, or apparatus that comprises the element.

As shown in fig. 1, an embodiment of the present invention provides an opposite-through device for a thread-threading machine, including an opposite-through fixing component, a left-through component, a right-through component, an opposite-through power component, and an opposite-through positioning component, where the left-through component and the right-through component are respectively disposed at left and right ends of the opposite-through fixing component, and are driven to move left and right by the opposite-through power component fixed on one side of the opposite-through fixing component, and the opposite-through positioning component is mounted on the opposite-through fixing component and is used for positioning the left-through component and the right-through component.

As shown in fig. 1 to 4, the pair-through fixing component includes a machine platen 101, a first abdicating groove 118 and a second abdicating groove 119, the left-side through component and the right-side through component are respectively disposed at the left end and the right end of the machine platen 101, and are driven by the pair-through power component to respectively move left and right in the first abdicating groove 118 and the second abdicating groove 119.

As shown in fig. 1 to 4, the left-hand penetrating component includes a first electric push rod 110, a first fixed block 111, a first connecting block 112, a first moving block 113, a first fixed block 114, a first wire-pulling hook 115, a first "V" shaped wire-pushing piece 116, and a first clamping jaw 117, one end of the first moving block 113 fixes the first fixed block 111, a telescopic shaft of the first electric push rod 110 passes through the first fixed block 111 and then is connected with the first connecting block 112, the other end of the first connecting block 112 is provided with the first "V" shaped wire-pushing piece 116 and the first clamping jaw 117, the first "V" shaped wire-pushing piece 116 and the first clamping jaw 117 are pushed by the first electric push rod 110 to move, the first fixed block 114 is fixed on the bedplate 101, the first wire-pulling hook 115 is rotatably arranged between the first fixed block 114 and the bedplate 101, one end of the first wire-pulling hook 115 is connected with the first fixed block 114 through a first tension spring 136, the first moving block 113 is provided with a first sliding column 137, and the first wire pulling hook 115 is pulled by the first sliding column 137 to rotate when moving along with the first moving block 113.

As shown in fig. 1 to 4, the right-hand penetrating component includes a second electric push rod 102, a second fixed block 103, a second connecting block 104, a second moving block 105, a second fixed block 106, a second wire-pulling hook 107, a second "V" shaped wire-pushing piece 108, and a second clamping jaw 109, one end of the second moving block 105 fixes the second fixed block 103, a telescopic shaft of the second electric push rod 102 passes through the second fixed block 103 and then is connected to the second connecting block 104, the other end of the second connecting block 104 is provided with the second "V" shaped wire-pushing piece 108 and the second clamping jaw 109, the second electric push rod 102 pushes the second connecting block 104 to move the second V "shaped wire-pushing piece 108 and the second clamping jaw 109, the second fixed block 106 is fixed to the bedplate 101, the second wire-pulling hook 107 is rotatably arranged between the second fixed block 106 and the bedplate 101, one end of the second wire-pulling hook 107 is connected to the second fixed block through a tension spring 136, a sliding column 137 is arranged on the second moving block 105, and the second wire pulling hook 107 is pulled by the sliding column 137 to rotate when moving along with the second moving block 105.

As shown in fig. 1 to 4, an open loop piece 130 is disposed at one side of the second moving block 105, and an open loop auxiliary hook 135 is disposed on the open loop piece 130, and is used for opening a binding thread open loop pulled back by the lifting thread hooking mechanism 3.

As shown in fig. 1 to 4, the through power assembly includes a first forward and reverse lead screw 120, a first lead screw nut 121, a first lead screw nut mounting seat 122, a first supporting seat 123, a second lead screw nut 124, a second lead screw nut mounting seat 125, a second supporting seat 126, a first stepping motor 127, a first synchronous belt 128, and a first synchronous wheel 129, one end of the first forward and reverse lead screw 120 is connected with the first lead screw nut 121, the first lead screw nut mounting seat 122, and the first supporting seat 123 in sequence, the first lead screw nut mounting seat 122 is an "L" type structure, and is connected with the first moving block 113 after passing through the first abdicating groove 118, the other end of the first forward and reverse lead screw 120 is connected with the second lead screw nut 124, the second lead screw nut mounting seat 125, and the second supporting seat 126 in sequence, the second lead screw nut mounting seat 125 is an "L" type structure, and is connected with the second moving block 105 after passing through the second abdicating groove 119, one end of the first forward and reverse screw rod 120 and the rotating shaft of the first stepping motor 127 are both provided with a first synchronous wheel 129, and the two first synchronous wheels 129 are connected through a first synchronous belt 128.

As shown in fig. 1 to 4, the pair-penetrating positioning assembly includes a first limit sensor 131, a second limit sensor 132, a limit stop chute 133, a spreading column 134 and a second guide rail 135, the machine deck 101 is provided with the limit stop chute 133 at one end of the left pair-penetrating mechanism, the first limit sensor 131 and the second limit sensor 132 are slidably disposed on the limit stop chute 133, the first limit sensor 131 is disposed in the middle of the machine deck 101, the second limit sensor 132 is disposed at one side of the outer end of the first abdicating groove, the first limit sensor 131 and the second limit sensor 132 are configured to detect the moving position of the first moving block 113, the spreading column 134 is mounted in the middle of the machine deck 101 and is configured to spread the open-loop auxiliary hook 135 and the open-loop piece 130, spread the binder loop pulled by the lifting wire-hooking mechanism 3, one side of the machine deck 101 is provided with the second guide rail 135, the second guide rail 135 is used for sliding the first moving block 113 and the second moving block 105.

The working principle of the utility model is as follows:

as shown in fig. 1-4, a control system is provided inside the wire loading machine, under the action of a first stepping motor 127, a first wire-pulling hook 115, a first "V" shaped wire-pushing piece 116 and a first clamping jaw 117 act on a first electric push rod 110 of the threading mechanism 1, the left wire loop is pushed by the first "V" shaped wire-pushing piece 116, the right wire loop is pushed by a second "V" shaped wire-pushing piece 108, the middle wire loop is stretched by the first wire-pulling hook 115 and the second wire-pulling hook 107, the left and right wire loops are pushed by the first "V" shaped wire-pushing piece 116 and the second "V" shaped wire-pushing piece 108 through the middle wire loop, the second "V" shaped wire-pushing piece 108 and the first "V" shaped wire-pushing piece 116 are respectively clamped by the first clamping jaw 117 and the second clamping jaw 109, the first stepping motor 127 is driven by the post-control system to pull back, and the purpose of threading of the binding wire is achieved.

In conclusion, the left threading assembly and the right threading assembly are fixed on the opposite threading fixing assembly, and the opposite threading power assembly drives the left threading assembly and the right threading assembly to carry out opposite threading on the binding wire, so that the aim of directly tying a knot after opposite threading on the binding wire is fulfilled, the problem of binding by means of a tool is avoided, and the labor cost is reduced.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention.

Claims (7)

1. The utility model provides a to wearing device for line installation, its characterized in that includes to wearing fixed subassembly, a left side and wears the subassembly, the right side and wears the subassembly, to wearing power component and to wearing locating component, the subassembly is worn on a left side and the right side is worn the subassembly and is set up respectively in the both ends about wearing fixed subassembly, and controls the removal through being fixed in to wearing power component to wearing of fixed subassembly one side, to wearing locating component to install on wearing fixed subassembly for wear the subassembly for a left side and wear the subassembly location on the right side.

2. The pair-through device for the thread binding machine according to claim 1, wherein the pair-through fixing component comprises a machine bedplate, a first abdicating groove and a second abdicating groove, the left-side through component and the right-side through component are respectively arranged at the left end and the right end of the machine bedplate, and are driven by the pair-through power component to respectively move left and right in the first abdicating groove and the second abdicating groove.

3. The opposite-penetrating device for the thread assembling machine according to claim 1 or 2, wherein the left penetrating component comprises a first electric push rod, a first fixed block, a first connecting block, a first moving block, a first fixed block, a first thread-pulling hook, a first V-shaped thread-pushing piece and a first clamping jaw, one end of the first moving block is fixed with the first fixed block, a telescopic shaft of the first electric push rod penetrates through the first fixed block and then is connected with the first connecting block, the other end of the first connecting block is provided with the first V-shaped thread-pushing piece and the first clamping jaw, the first V-shaped thread-pushing piece and the first clamping jaw push the first connecting block by the first electric push rod to act, the first fixed block is fixed on the machine bedplate, the first thread-pulling hook is rotatably arranged between the first fixed block and the machine bedplate, one end of the first thread-pulling hook is connected with the first fixed block through a first tension spring, the first moving block is provided with a first sliding column, and the first wire pulling hook is pulled by the first sliding column to rotate when moving along with the first moving block.

4. The opposite-through device for the wire inserting machine according to claim 3, wherein the right-through component comprises a second electric push rod, a second fixed block, a second connecting block, a second moving block, a second fixed block, a second wire pulling hook, a second V-shaped wire pushing sheet and a second clamping jaw, one end of the second moving block is fixed on the second fixed block, a telescopic shaft of the second electric push rod penetrates through the second fixed block and then is connected with the second connecting block, the other end of the second connecting block is provided with the second V-shaped wire pushing sheet and the second clamping jaw, the second V-shaped wire pushing sheet and the second clamping jaw push the second connecting block through the second electric push rod to move, the second fixed block is fixed on the machine platen, the second wire pulling hook is rotatably arranged between the second fixed block and the machine platen, one end of the second wire pulling hook is connected with the second fixed block through a tension spring, and a sliding column is arranged on the second moving block, and the second wire pulling hook is pulled by the sliding column to rotate when moving along with the second moving block.

5. The opposite-penetrating device for the thread binding machine according to claim 4, wherein a ring opening piece is arranged on one side of the second moving block, and a ring opening auxiliary hook is arranged on the ring opening piece and used for opening a binding thread ring pulled back by the lifting thread hooking mechanism.

6. The opposite-penetrating device for the thread binding machine according to claim 5, wherein the opposite-penetrating power assembly comprises a first forward and reverse lead screw, a first lead screw nut mounting seat, a first supporting seat, a second lead screw nut mounting seat, a second supporting seat, a first stepping motor, a first synchronous belt and a first synchronous wheel, one end of the first forward and reverse lead screw is connected with the first lead screw nut, the first lead screw nut mounting seat and the first supporting seat in sequence, the first lead screw nut mounting seat is of an L-shaped structure and is connected with the first moving block after penetrating through the first abdicating groove, the other end of the first forward and reverse lead screw is connected with the second lead screw nut, the second lead screw nut mounting seat and the second supporting seat in sequence, the second lead screw nut mounting seat is of an L-shaped structure and is connected with the second moving block after penetrating through the second abdicating groove, one end of the first forward and reverse screw rod and a rotating shaft of the first stepping motor are respectively provided with a first synchronous wheel, and the two first synchronous wheels are connected through a first synchronous belt.

7. The opposite-penetrating device for the wire-loading machine according to claim 6, wherein the opposite-penetrating positioning assembly comprises a first limit sensor, a second limit sensor, a limit device chute, a spreading column and a second guide rail, the left opposite-penetrating mechanism is provided with the limit device chute at one end of the machine platen, the first limit sensor and the second limit sensor are slidably arranged on the limit device chute, the first limit sensor is arranged in the middle of the machine platen, the second limit sensor is arranged at one side of the outer end of the first abdicating groove, the first limit sensor and the second limit sensor are used for detecting the moving position of the first moving block, the spreading column is arranged in the middle of the machine platen and is used for spreading the open-loop auxiliary hook and the open-loop piece and spreading the binding wire loop pulled down by the lifting wire-hooking mechanism, and the second guide rail is arranged at one side of the machine platen, the second guide rail is used for sliding the first moving block and the second moving block.

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