KR100994163B1 - take-up machine - Google Patents

Abstract

The present invention relates to a winding machine, the winding machine according to the present invention includes a drive shaft that rotates by the rotational force of the drive source; A first driving part formed at one side of the driving shaft to transmit a rotational force of the driving shaft; A second driving part formed on the other side of the driving shaft and transmitting a rotational force corresponding to the rotational force of the first driving part; A first fixed chuck reciprocating in parallel with the drive shaft and connected to the first driving part to rotate; And a second fixed chuck reciprocating in parallel with the drive shaft and connected to the second driving part to rotate.

By this, by transmitting the rotational force of the motor to the first fixed chuck and the second fixed chuck at the same time, it is possible to prevent the difference in the rotational force between the two fixed chuck, to prevent the twisting of the core, and to prevent the phenomenon that occurs in the film Wrinkles or wrinkles of the film can be prevented, by adjusting the rotational force of the motor to rotate the two fixed chuck at the same time, there is provided a winding machine that can be stably wound the film.

Winder, fixed chuck, reducer, pulley, belt, sprocket, chain,

Description

Take-up machine

The present invention relates to a winding machine, and more particularly, a pair of fixing chucks fixing the both ends of the core corresponding to the width of the film to wind the film to the core, a pair of fixing to fix both ends of the core The present invention relates to a winding machine capable of winding a film in a well-opened state by preventing driving, wrinkles, or wrinkles of the film wound on the core by simultaneously driving the chuck.

Generally, a winding machine is an apparatus which winds a film etc. continuously.

1 is a front view showing a winder according to the prior art, and FIG. 2 is a side view showing part "A" of FIG.

1 and 2, the conventional winder is a motor 100 generates a rotational force by the applied power, the reducer 200 is connected to the motor 100 by the rotary shaft 110 to the motor 100 Adjust the rotational force of

A connection pulley 211 is formed at an end of the connection shaft 210 extending from the reducer 200, and a transmission pulley 231 is formed at one end of the transmission shaft 230 installed in parallel with the connection shaft 210. do. Then, the connection pulley 211 and the transmission pulley 231 is connected by the belt 220, the rotational force of the connection shaft 210 is transmitted to the transmission shaft 230, the other end of the transmission shaft 230 transmission sprocket 233 is formed.

The core C on which the film F is wound is disposed in parallel with the delivery shaft 230, and both ends of the core C are fixed by the first fixing chuck 250 and the second fixing chuck 260. The fixed sprocket 251 is formed on the first fixed chuck 250. Then, the transmission sprocket 233 and the fixed sprocket 251 are connected by the transmission chain 240 so that the rotational force of the transmission shaft 230 is transmitted to the first fixed chuck 250.

Finally, the rotational force of the motor 100 is transmitted to the first fixed chuck 250 and the core fixed by the first fixed chuck 250 and the second fixed chuck 260 as the first fixed chuck 250 rotates. Will rotate (C). At this time, the second fixed chuck 260 is formed to be free to rotate. In addition, the first fixing chuck 250 and the second fixing chuck 260 is preferably to be able to reciprocate in the longitudinal direction of the core (C) to facilitate the removal of the core (C), the first fixed chuck The reciprocating movement of the 250 and the second fixed chuck 260 may be operated in a cylindrical manner by the pressure pump 253 or by a rotation of the handle 263.

However, in the case of the winder according to the prior art, a difference occurs in the rotational force of the first fixed chuck to which the rotational force of the motor is transmitted and the second fixed chuck to freely rotate. Accordingly, the core has a problem in that a torsion occurs.

In addition, as a difference occurs in the rotational force between the first fixing chuck and the second fixing chuck, there is a problem in that the film is wound around the core or the wrinkles or wrinkles occur in the film being wound.

Accordingly, an object of the present invention is to solve such a conventional problem, by simultaneously transmitting the rotational force of the motor to the first and second fixed chuck, to prevent the difference in the rotational force between the two fixed chuck, It is to provide a winding machine that can prevent the twisting phenomenon.

In addition, the present invention provides a winding machine that can prevent the phenomena of the film or wrinkles or wrinkles generated in the film.

The above object, according to the present invention, a drive shaft for rotating by the rotational force of the drive source; A first driving part formed at one side of the driving shaft to transmit a rotational force of the driving shaft; A second driving part formed on the other side of the driving shaft and transmitting a rotational force corresponding to the rotational force of the first driving part; A first fixed chuck reciprocating in parallel with the drive shaft and connected to the first driving part to rotate; A second fixed chuck reciprocating in parallel with the drive shaft and connected to the second driving part to rotate; A reducer for adjusting the rotational force of the drive source in response to the rotational force of the first fixed chuck and the second fixed chuck, a connecting shaft rotated by the reducer, and a first end member for transmitting the rotating force of the connecting shaft to the drive shaft. It is achieved by a winder comprising a; power transmission unit.

The power transmission unit may further include a transmission shaft connected to the drive shaft, and the rotational force of the connection shaft is transmitted to the transmission shaft by the first end member.

The above object, according to the present invention, a drive shaft for rotating by the rotational force of the drive source; A first driving part formed at one side of the driving shaft to transmit a rotational force of the driving shaft; A second driving part formed on the other side of the driving shaft and transmitting a rotational force corresponding to the rotational force of the first driving part; A first fixed chuck reciprocating in parallel with the drive shaft and connected to the first driving part to rotate; A second fixed chuck reciprocating in parallel with the drive shaft and connected to the second driving part to rotate; A plurality of transmission gear assemblies configured to transmit the rotational force of the drive source to the drive shaft with a rotational shaft rotated by the drive source and a gear ratio meshed with the drive shaft and corresponding to the rotational force of the first fixed chuck and the second fixed chuck; And a power transmission unit including a transmission shaft through which the rotational force of the rotation shaft is transmitted by the transmission gear assembly.

Here, it is preferable to further include a second end member for transmitting the rotational force of the transmission shaft to the drive shaft between the transmission shaft and the drive shaft.

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According to the present invention, by simultaneously transmitting the rotational force of the drive source to the first fixed chuck and the second fixed chuck, there is provided a winding machine which can prevent the rotational force difference between the two fixed chuck to occur, and to prevent the twisting of the core.

In addition, a winding machine is provided that can prevent the pulling phenomenon or wrinkle or wrinkle of the film to occur in the film.

Further, by winding the two fixed chucks simultaneously by adjusting the rotational force of the drive source, there is provided a winding machine in which the film can be stably wound.

In addition, a winding machine capable of simultaneously winding a film on a plurality of cores with a rotational force of a single drive source, and having an effect of improving productivity and improving work efficiency, is provided.

In addition, a winding machine capable of stably transmitting the rotational force of the driving source is provided even if the distance between the connecting shaft and the transmission shaft.

In addition, a winding machine capable of accurately transmitting the rotational force of the drive source between the connecting shaft and the transmission shaft is provided.

In addition, a winder is provided in which two fixing chucks fixing both ends of the core can be accurately rotated by the rotational force of the driving source.

Prior to the description, in the various embodiments, components having the same configuration will be representatively described in the first embodiment using the same reference numerals, and in other embodiments, different configurations from the first embodiment will be described. do.

Hereinafter, a winder according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

Figure 3 is a front view showing a winding machine according to a first embodiment of the present invention, Figure 4 is a side view showing the "B" portion of Figure 3, Figure 5 shows a "C" portion of FIG. 6 is a side view, and FIG. 6 is a plan view showing a winder according to the first embodiment of the present invention.

3 to 6, the winding machine according to the first embodiment of the present invention drive shaft 40, the first driving unit 50, the second driving unit 60, the first fixing chuck 70 and the second fixing It can be divided into chuck (80).

As power is applied to the drive source 10 such as a motor, the drive source 10 rotates the rotary shaft 11.

The drive shaft 40 is connected to the rotary shaft 11 of the drive source 10 to rotate by the rotational force of the drive source 10. In this case, a power transmission unit 20 may be formed between the driving source 10 and the driving shaft 40 to be connected to the rotating shaft 11 of the driving source 10 to transmit the rotational force of the driving source 10.

The power transmission unit 20 is connected to the rotary shaft 11 of the drive source 10 as shown in the drawing to reduce the speed of the rotational force 21 and the rotational force adjusted by the reducer 21 to the drive shaft 40 It can be divided into a transmission unit 22 for transmitting.

The reducer 21 adjusts the rotational force of the driving source 10 in response to the rotational force of the first fixed chuck 70 and the second fixed chuck 80.

As shown in the drawing, the transmission part 22 transmits the rotational force of the connection shaft 31 connected to the reduction gear 21, the transmission shaft 32 connected to the drive shaft 40, and the connection shaft 31. It may be configured to include a first end member 33 for transmitting to (32).

Here, the first end member 33 is a belt for connecting the pulley 33a and the pulley 33a which are respectively installed at one end of the connecting shaft 31 and one end of the transmission shaft 32 as shown in the drawing. It may be composed of a (33b), the belt (b) so that the rotational force of the connecting shaft 31 is easily transmitted to the transmission shaft 32 by adjusting the tension of the belt 33b between the pair of pulleys (33a) described above. An auxiliary pulley 33c for pressing 33b) may be further formed.

Although not shown, the pulley 33a and the auxiliary pulley 33c in the first end member 33 may be composed of a sprocket and an auxiliary sprocket, respectively, and the belt 33b may be configured in a chain corresponding to the sprocket.

The second end member 34 may further be provided between the transmission shaft 32 and the driving shaft 40 to transmit the rotational force of the transmission shaft 32 to the driving shaft 40.

Like the first end member 33 described above, the second end member 34 has a transmission sprocket 34a and a transmission sprocket 34a installed on the drive shaft 40 and the transmission shaft 32, respectively. It may be composed of a chain (34b), between the pair of the transmission sprocket (34a) described above by adjusting the tension of the transmission chain (34b) so that the rotational force of the transmission shaft 32 is easily transmitted to the drive shaft (40) The adjusting sprocket 34c for pressing the chain 34b may be further formed.

Although not shown, the second end member 34 may be composed of the combination 33a, 33b, 33c of the pulley and the belt described above.

As more than one second end member 34 is installed, a plurality of drive shafts 40 can be formed in one winding machine as shown in the drawing, and thus, a plurality of cores can be formed as one drive source 10. By simultaneously rotating (C), productivity and work efficiency can be improved.

Here, the first driving unit 50 and the second driving unit 60 are formed at both ends of the driving shaft 40, respectively.

The first driving unit 50 is formed at one end of the driving shaft 40 to transmit the rotational force of the driving shaft 40, and the first driving unit is installed at one end of the driving shaft 40 and the first fixed chuck 70, respectively. It can be divided into a sprocket 51 and a first chain 52 connecting the pair of first drive sprockets 51, a first auxiliary sprocket 53 between the pair of first drive sprockets 51 Further installation to adjust the tension of the first chain (52).

In particular, the first driving unit 50 is composed of a combination of the sprocket and the chain can accurately transmit the rotational force of the drive shaft 40 to the first fixed chuck (70).

The second drive unit 60 is formed at the other end of the drive shaft 40 to transmit the rotational force of the drive shaft 40, the second drive is installed on the other end of the drive shaft 40 and the second fixed chuck 80, respectively It can be divided into a sprocket 61 and a second chain 62 connecting the pair of second drive sprockets 61, and between the pair of second drive sprockets 61 a second auxiliary sprocket 63 Further installation to adjust the tension of the second chain (62).

Like the first driving unit 50, the second driving unit 60 may be configured by a combination of the sprocket and the chain so as to accurately transmit the rotational force of the driving shaft 40 to the first fixed chuck 70.

Here, the first driving part 50 and the second driving part 60 are symmetrical with each other so that the first fixing chuck 70 and the second fixing chuck 80 have the same rotational force in the same direction according to the rotation of the driving shaft 40. It is desirable to deliver.

The first fixed chuck 70 is fixed to the first driving sprocket 51 and rotates according to the rotation of the first driving sprocket 51, and is mounted by the first moving part 71 to attach or detach the core C. It can be reciprocated parallel to the drive shaft (40). The first moving part 71 may be configured as a handle to reciprocate the first fixing chuck 70 according to the rotation of the first moving part 71. Although not shown, the first moving part 71 may be configured as a pressure pump of a cylinder type to reciprocate the first fixed chuck 70 according to the piston movement of the first moving part 71.

The second fixing chuck 80 is fixed to the second driving sprocket 61 and rotates according to the rotation of the second driving sprocket 61. The second fixing part 80 is attached to and detached from the core C by the second moving part 81. It can be reciprocated parallel to the drive shaft (40). The second moving part 81 may be configured as a handle to reciprocate the second fixing chuck 80 according to the rotation of the second moving part 81. Although not shown, the second moving part 81 may be configured as a cylinder type pressure pump to reciprocate the second fixed chuck 80 according to the piston movement of the second moving part 81.

Here, the guide roller 90 may be further installed in parallel with the longitudinal direction of the core C, and the film F may be stably guided to the core C by the guide roller 90.

The operation of the winder according to the first embodiment of the present invention will now be described.

7 is a configuration diagram illustrating an operating state of a winding machine according to a first embodiment of the present invention, wherein the winding machine according to the first embodiment of the present invention simultaneously holds the film F on two cores C. I can wind it up.

Referring to FIG. 7, the driving shaft 10 is operated by the applied power to rotate the rotary shaft 11. Since the reducer 21 is connected to the rotary shaft 11, the reducer 21 adjusts the rotational force of the driving source 10 to correspond to the rotational force of the first fixed chuck 70 and the second fixed chuck 80.

The rotational force of the drive source 10 adjusted by the reducer 21 is transmitted to the drive shaft 40 via the connecting shaft 31, the first end member (), and the transmission shaft 32.

Here, the second end member () may be installed between the transmission shaft 32 and the drive shaft 40 to form two drive shafts 40.

The first driving part 50 and the second driving part 60 are formed to be symmetrical with each other at both ends of the drive shaft 40, and the first fixed chuck is provided at the first driving part 50 and the second driving part 60, respectively. Since the 70 and the second fixed chuck 80 are connected, the rotational force of the drive shaft 40 is simultaneously transmitted to the first driver 50 and the second driver 60.

Then, the first fixing chuck 70 and the second fixing chuck 80 may be simultaneously rotated through the first driving unit 50 and the second driving unit 60.

Here, the core C is disposed between the first fixed chuck 70 and the second fixed chuck 80, and the first fixed chuck 70 is operated by operating the first moving part 71 and the second moving part 81. ) And the core C is fixed between the second fixing chuck 80.

Then, the first fixed chuck 70 and the second fixed chuck 80 are simultaneously rotated in the same direction according to the rotational force of the drive shaft 40, and correspond to the rotational force of the drive shaft 40 with the first fixed chuck 70. The second fixed chuck 80 has the same rotational force.

Therefore, it is possible to prevent the twisting of the core C fixed between the first fixing chuck 70 and the second fixing chuck 80, and the bending or wrinkles or wrinkles of the film F wound around the core C. Can be prevented.

The winding machine according to the second embodiment of the present invention will now be described.

FIG. 8 is a configuration diagram illustrating an operating state of a winder according to a second embodiment of the present invention. Referring to FIG. 8, the winder according to the second embodiment of the present invention is described in the first embodiment of the present invention. Similar to the winding machine according to the embodiment, as power is applied to the drive source 10 such as a motor, the drive source 10 rotates the rotary shaft 11. The rotational force of the driving source 10 is transmitted to the driving shaft 40 through the power transmission unit 20 connected to the rotating shaft 11, and the rotational force of the driving shaft 40 is provided on the first driving unit 50 provided at both ends of the driving shaft 40. ) And the second driving part 60 are transferred to the first fixing chuck 70 and the second fixing chuck 80, respectively.

Here, the core C is disposed between the first fixed chuck 70 and the second fixed chuck 80, and the first fixed chuck 70 is operated by operating the first moving part 71 and the second moving part 81. And the core C between the second fixing chuck 80.

Then, the first fixed chuck 70 and the second fixed chuck 80 are simultaneously rotated in the same direction according to the rotational force of the drive shaft 40, and correspond to the rotational force of the drive shaft 40 with the first fixed chuck 70. The second fixed chuck 80 has the same rotational force.

Therefore, it is possible to prevent the twisting of the core C fixed between the first fixing chuck 70 and the second fixing chuck 80, and the bending or wrinkles or wrinkles of the film F wound around the core C. Can be prevented.

Herein, the power transmission unit 20 according to the second embodiment of the present invention may be divided into a transmission shaft 32 and a transmission gear assembly 24.

The transmission shaft 32 is connected to the drive shaft 40 as described above, the transmission gear assembly 24 and the first fixed chuck 70 between the rotation shaft 11 and the transmission shaft 32 of the drive source 10 The gear ratio corresponding to the rotational force of the second fixing chuck 80 is engaged to transmit the rotational force of the driving source 10 to the transmission shaft 32. In this case, the rotational force of the driving source 10 may be adjusted by the gear ratio of the transmission gear assembly 24.

In addition, in the second embodiment of the present invention, two or more gears are engaged between the transmission shaft 32 and the drive shaft 40 so as to have a gear ratio corresponding to the rotational force of the first fixed chuck 70 and the second fixed chuck 80. The second end member 34 may be further configured.

In addition, the first driving unit 50 according to the second embodiment of the present invention is engaged at a gear ratio corresponding to the rotational force of the first fixed chuck 70 between one end of the drive shaft 40 and the first fixed chuck 70. Composed of the first drive gear assembly 55 is to transmit the rotational force of the drive shaft 40 to the first fixed chuck 70, the second drive portion 60 is the other end and the second fixed chuck of the drive shaft 40 The second driving gear assembly 65 is engaged with the gear ratio corresponding to the rotational force of the second fixed chuck 80 between the 80 to transmit the rotational force of the drive shaft 40 to the second fixed chuck 80. .

In this case, in order to prevent the twisting of the core C, the rotational force of the first fixing chuck 70 and the rotational force of the second fixing chuck 80 are preferably the same, and thus the first driving gear assembly 55 and the second driving are the same. The gear assemblies 65 are symmetrically installed with the same gear ratio to each other so that the first fixed chuck 70 and the second fixed chuck 80 have the same rotational force in the same direction.

The scope of the present invention is not limited to the above-described embodiments but may be implemented in various forms of embodiments within the scope of the appended claims. Without departing from the gist of the invention claimed in the claims, it is intended that any person skilled in the art to which the present invention pertains falls within the scope of the claims described herein to various extents that can be modified.

1 is a front view showing a winder according to the prior art,

FIG. 2 is a side view showing part “A” of FIG. 1;

3 is a front view showing a winder according to the first embodiment of the present invention;

4 is a side view showing a portion “B” of FIG. 3;

FIG. 5 is a side view showing part “C” of FIG. 3;

6 is a plan view showing a winder according to a first embodiment of the present invention;

7 is a configuration diagram showing an operating state of the winder according to the first embodiment of the present invention;

8 is a configuration diagram showing an operating state of the winder according to the second embodiment of the present invention.

<Explanation of symbols for main parts of the drawings>

10: drive source 11: rotation shaft 20: power transmission unit

21: reducer 22: transmission portion 24: transmission gear assembly

31: connecting shaft 32: transmission shaft 33: first end member

33a: pulley 33b: belt 33c: auxiliary pulley

34: second end member 34a: transfer sprocket 34b: transfer chain

34c: adjusting sprocket 40: drive shaft 50: first driving part

51: first driving sprocket 52: first chain 53: first auxiliary sprocket

55: first drive gear assembly 60: second drive portion 61: second drive sprocket

62: second chain 63: second auxiliary sprocket 65: second drive gear assembly

70: first fixed chuck 71: first moving part 80: second fixed chuck

81: second moving part 90: guide roller

C: Core F: Film

Claims (7)

A drive shaft rotating by the rotational force of the drive source; A first driving part formed at one side of the driving shaft to transmit a rotational force of the driving shaft; A second driving part formed on the other side of the driving shaft and transmitting a rotational force corresponding to the rotational force of the first driving part; A first fixed chuck reciprocating in parallel with the drive shaft and connected to the first driving part to rotate; A second fixed chuck reciprocating in parallel with the drive shaft and connected to the second driving part to rotate; A reducer for adjusting the rotational force of the drive source in response to the rotational force of the first fixed chuck and the second fixed chuck, a connecting shaft rotated by the reducer, and a first end member for transmitting the rotating force of the connecting shaft to the drive shaft. Winding machine comprising a; power transmission unit. The method of claim 1, The power transmission unit Further comprising a transmission shaft connected to the drive shaft, And a rotational force of the connection shaft is transmitted to the transmission shaft by the first end member. A drive shaft rotating by the rotational force of the drive source; A first driving part formed at one side of the driving shaft to transmit a rotational force of the driving shaft; A second driving part formed on the other side of the driving shaft and transmitting a rotational force corresponding to the rotational force of the first driving part; A first fixed chuck reciprocating in parallel with the drive shaft and connected to the first driving part to rotate; A second fixed chuck reciprocating in parallel with the drive shaft and connected to the second driving part to rotate; A plurality of transmission gear assemblies configured to transmit the rotational force of the drive source to the drive shaft with a rotational shaft rotated by the drive source and a gear ratio meshed with the drive shaft and corresponding to the rotational force of the first fixed chuck and the second fixed chuck; And a power transmission unit including a transmission shaft through which the rotational force of the rotation shaft is transmitted by the transmission gear assembly. The method according to claim 2 or 3, And a second end member for transmitting a rotational force of the transmission shaft to the drive shaft between the transmission shaft and the drive shaft. delete delete delete

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