KR101637116B1 - Gear box for winder - Google Patents

Abstract

The present invention relates to a gear box for a winder. The gear box for a winder comprises: a housing (110) having a drive gear (111) installed on one side of a winder (200); a traverse cam (120) having a cam groove (122) of a circulation spiral shape along the outer circumference of a cam shaft (121) mounted on the drive gear (111); a pair of block guides (130) arranged on an upper portion of the traverse cam (120) in parallel, wherein both ends thereof are mounted on the housing; a guide rail (140) comprising a linear rail (141) disposed on both sides of the block guides (130) and a first reciprocating guide (143) having a first mounting unit (142); a second reciprocating guide (150) comprising a cam insertion unit (151) which is mounted in the cam groove (122) to protrude downwards, a block unit (152) mounted on the block guides (130), and a second mounting unit (153) formed on both sides of the block unit (152) and integrated into the block unit (152) to reciprocate along the block guides (130); and a traverse bar drive unit (160) comprising a third mounting unit (163) and a fourth mounting unit (164) formed in an L shape and hinge and mounted onto the first mounting unit (142) and the second mounting unit (153), into which hinge shafts (161, 162) are inserted, and a friction reduction means (165, 166) disposed on the inner circumference thereof. A frictional force created between devices during reciprocation can be efficiently reduced. A winding width of a yarn wound on a bobbin can be easily changed and adjusted.

Description

Gear box for winder {GEAR BOX FOR WINDER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gear box for a winder, and more particularly, to a winder device for winding a yarn on a bobbin or a cylinder, and a device for efficiently driving the traverse guide to uniformly wind the winding width of the yarn in the longitudinal direction of the bobbin To a provision of a gear box for a winder to be mounted.

Generally, a winder is a device for winding a yarn on a bobbin or a cylinder (hereinafter referred to as a bobbin) by a necessary amount in advance before a fabric is woven using a yarn. A traverse guide is provided on one side of the bobbin in order to prevent the yarn from being rolled up at one point in the winding process so that the winding width of the yarn fed to the bobbin is uniformly wound while being linearly reciprocated in the longitudinal direction of the bobbin. In order to drive the above-described traverse guide, there is conventionally employed a method of linearly reciprocating the traverse guide by separately providing a traverse cam, which is an apparatus that is easy to convert rotational motion of the driving gear into reciprocating motion.

For example, since a traverse drive device for a twisted yarn machine is known from Registration Utility Model No. 20-0219390, the detailed construction will be described below.

A rotary shaft 15 connected to the front side of the cradle 3 on which the bobbin 2 is to be installed is formed and the operation cam 12 is inserted in the vicinity of the rotary shaft 15 to continuously reciprocate on the outer surface of the operation cam 12 After the cam groove 13 is formed, the thread guide 20 is brought into contact with the thread guide 20 so that the thread guide 20 reciprocates when the operation cam 12 rotates. A motor 5 is connected to one end of a rotary shaft 15 on which the operation cam 12 is installed to rotate the rotary shaft 15. The operation cam 12 has two helical cam grooves 13, And the rollers 21 and the guide holes 22 of the seal guide 20 reciprocate along the cam groove 13 when the operation cam 12 rotates . Therefore, the yarn guide 20 is linearly reciprocated in the longitudinal direction of the bobbin 2 in accordance with the rotation drive of the operation cam 12, so that the yarn is wound with an equal width.

The apparatus for driving and winding the operating cam as described above has an advantage that the thread guide can be made to reciprocate more easily by only the operation of the driving gear necessary for the rotational motion. However, in a general winder for performing winding work using tens to hundreds of bobbins, since the number of operating cams for linearly reciprocating the yarn guides provided for each bobbin is set and driven by the number of bobbins, energy consumption is excessively generated, There is a problem that the cost and the manufacturing cost are increased.

In view of the above-mentioned problem, recently, various configuration devices for linear reciprocation of the thread guide, including an operation cam, are mounted on one gear box and installed on one side of the winder, A traverse driving device capable of linear reciprocating motion of a sphere has been developed and provided. A typical example will be described with reference to FIG.

Since the traverse cam 20 which is rotated by the driving gear 10 is mounted and the reciprocating means 30 which reciprocates linearly is provided, the traverse bar connecting the traverse guides provided for the individual bobbins is connected to the reciprocating means 30, And the traverse guides are reciprocated linearly at the same time. Particularly, the oil pump 40, which lubricates the oil by using the power of the drive gear 10, is incorporated to supply oil to the oil storage portion 31 coupled to the reciprocating means 30 through the discharge port 41 So that oil is supplied to the frictional portions 50, 60, which have a large frictional force during high-speed linear reciprocation. Thereby inducing a lubricating action by the oil on the frictional portions 50, 60 to minimize the wear phenomenon.

Registration Utility Model No. 20 - 0219390 - 0000 Registration Utility Model No. 20 - 0318818 - 0000 Published Patent No. 10-2006- 0013930

The above-described conventional gear box eliminates the problem that an individual operation cam is provided for each yarn guiding hole in the above-described conventional winder device, which causes an increase in the maintenance cost and the like. Thus, by driving only one traverse cam, The guide can be reciprocated in a straight line.

However, the gear box to which the prior art is applied is provided with an oil pump as means for minimizing the wear phenomenon necessarily occurring when reciprocating between the devices, so that various oils and greases are supplied to the oil storage portion and supplied to the friction portion Resulting in the problem that the pumped oil is scattered out or drained out of the oil reservoir while the traverse cam or reciprocating means is rotating at a high speed and reciprocating linearly. The spilled oil flows into various parts of the gear box and is mixed with various impurities to prevent the maintenance of the cleanliness inside the gear box, and also causes another problem such as malfunction of the constitution device and shortening the life span.

The gear box to which the conventional technique is applied is not easily variable in the reciprocating range of the traverse guide as in a conventional traverse drive device, and thus can be wound only at a constant width in the longitudinal direction of the bobbin, It is difficult to cope with the length.

Accordingly, the present invention has been made to solve the above-mentioned problems,

A housing 110 provided at one side of the winder 200 and provided with a driving gear 111 that receives power and rotates;

A traverse cam 120 having a circular spiral cam groove 122 formed along the outer diameter of the cam shaft 121 coupled to the driving gear 111;

A pair of block guides 130 having both ends connected to the housing 110 and parallel to the upper portion of the traverse cam 120;

A guide rail 140 is formed of a straight rail 141 provided on both sides of the block guide 130 and a first reciprocating guide 143 linearly reciprocating along the rail 141 and having a first engaging portion 142 formed thereon. and;

A pair of block portions 152 projecting downward from the cam insertion groove 151 to be engaged with the cam groove 122 and engaged with the block guide 130 and a second coupling portion 152 formed on both sides of the block portion 152, A second reciprocating guide 150 integrally formed with the traverse cam 120 and linearly reciprocating along the block guide 130 by rotation of the traverse cam 120;

A third engaging portion 163 and a fourth engaging portion 164 which are formed in a letter shape and into which the hinge shafts 161 and 162 are inserted are formed so that the first engaging portion 142 and the second engaging portion 153 The traverse bar driving unit 160 having the friction reducing means 165 and 166 is hinge-coupled to the inner circumferential portion thereof. Thus, the frictional force generated in the reciprocating motion can be efficiently reduced and the winding width of the yarn wound on the bobbin can be easily varied and adjusted It is possible to achieve the purpose.

The present invention relates to a gear box for a winder which is installed in a winder for winding a yarn on a bobbin and winds the yarn in a uniform width in the longitudinal direction of the bobbin, And has a structure for reducing friction efficiently, thereby remarkably improving wear resistance.

Accordingly, it is possible to prevent the occurrence of problems such as the scattering or leakage of oil and the malfunction of the apparatus due to the deposition of foreign matters mixed in the oil, and to improve the cleanliness inside the gear box The life of the gearbox mounted devices can be prolonged, and ultimately, productivity can be improved.

In addition, since the moving range of the traverse bar in the straight reciprocating motion of the traverse bar can be changed quickly and easily by the operator, the width of the yarn wound on the bobbin can be variously formed, Bobbin, cone type bobbin and the like can be further expanded.

1 is a perspective view of an embodiment of a gearbox for a winder according to the present invention.
2 is an exploded view according to an embodiment of a gearbox for a winder according to the present invention;
3 is a plan view of an embodiment of a gearbox for a winder according to the present invention.
4 to 5 are sectional views of the main part according to the embodiment of the gearbox for a winder according to the present invention.
6 is a view illustrating an example of the use state of the gear box for a winder according to the embodiment of the present invention.
7 is a configuration diagram of a conventional gear box.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the structure and operation of a gearbox for a winder according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a perspective view of an embodiment of a gear box for a winder according to the present invention, FIG. 2 is an exploded view of an embodiment of a gear box for a winder according to the present invention, And FIG. 4 is a cross-sectional view of a main part of a gear box for a winder according to the present invention. FIG. 6 is an explanatory view of a gear box for a winder according to an embodiment of the present invention. Together with a block diagram thereof.

The gear box 100 for a winder to which the technique of the present invention is applied comprises a housing 110 provided at one side of the winder 200 and provided with a driving gear 111 that receives power and rotates, A traverse cam 120 having a circular spiral cam groove 122 formed along an outer diameter portion of the cam shaft 121 coupled to the upper portion of the housing 110, And a first reciprocating guide 130 formed on both sides of the block guide 130 and linearly reciprocating along a rail 141 and formed with a first engaging portion 142, A pair of block portions 152 projecting downward from the cam insertion portion 151 to be engaged with the cam groove 122 and engaged with the block guide 130, And a second engaging portion 153 formed on both sides of the block guide 130. The second engaging portion 153 is integrally formed on both sides of the block guide 130, And a third engaging portion 163 and a fourth engaging portion 164 for receiving the hinge shafts 161 and 162. The second engaging portion 164 and the second engaging portion 163 are formed to have a substantially U- And a traverse bar driving unit 160 hinged to the first engaging part 142 and the second engaging part 153 and provided with friction reducing means 165 and 166 on the inner diameter part.

The housing 110 installed at one side of the winder 200 is provided with a traverse cam 120 for driving the traverse guide 220 to reciprocate linearly, a block guide 130, a guide rail 140, (150), and a traverse bar guide (160).

The traverse cam 120 is a device derived from a conventional well known technique of converting a rotational motion into a reciprocating motion. The traverse cam 120 is provided with a cam groove 122 circulating spirally in the axial direction in the outer diameter portion, The cam insertion portion 151 of the guide 150 is engaged. When the cam shaft 121 receives power from the start gear 111 and the traverse cam 120 rotates, the cam insertion portion 151 moves along the cam groove 122 to rotate the second reciprocating guide 150 Direction.

A considerable frictional force is generated in the frictional portion between the cam groove 122 and the cam insertion portion 151 due to the movement direction of the cam insertion portion 151 which resists the rotation direction of the traverse cam 120. [ Therefore, it is preferable that the cam groove 122 or the cam insertion portion 151 is provided with a roller or a bearing to increase abrasion resistance.

The block guide 130 is a pawl-shaped guide means for guiding the second reciprocating guide 150 in the horizontal direction. So that the second reciprocating guide 150 reciprocates stably and linearly.

The guide rail 140 includes a straight rail 141 having a rail groove and a first reciprocating guide 143 coupled to the rail 141 and reciprocating linearly. The first coupling portion 142 formed on the first reciprocating guide 143 hinges on the third coupling portion 163 of the traverse bar driving portion 160 and reciprocates along the rail 141. The frictional force between the rail 141 and the first reciprocating guide 143 due to the reciprocating motion is generated as in the case of the cam groove 122 and the cam inserting portion 151. Therefore, It is preferable to derive the rail information, which can be referred to a well-known rail technology, so that a detailed description will be omitted.

The guide rail 140 may be configured to vary the movement range of the traverse bar driving unit 160 hinged to the first reciprocating guide 143 according to the arrangement angle so as to vary the winding width of the yarn, It is a means to implement the function of A guide slot 144 is formed on one side of the guide rail 140 and is coupled to the housing 110 by a fastening member 145 so as to easily change the arrangement angle of the guide rail 140, The angle of the guide rail 140 can be varied by the displacement of the guide rail 140. [ Since the angle of arrangement of the guide rail 140 can be varied by the displacement of the guide slot 144 based on the hinge point where the engaging member 145 is engaged, the moving range of the traverse bar driving unit 160 can be varied And the traverse bar 230 coupled to the traverse bar guide section 160 linearly reciprocates in the moving range and winds the yarn passing through the traverse guide 220 at a uniform width.

The second reciprocating guide 150 is coupled to the block guide 130 which is reciprocated in the axial direction by moving the cam protruding portion 151 protruding downward along the cam groove 122, A linear reciprocation in the horizontal direction is induced. The inner diameter portion of the block portion 152 is tightly engaged with the block guide 130 so as to prevent the second reciprocating guide 150 from being separated from the block guide 130 when reciprocating at a high speed, . 4, a bushing 155 with an inlaid solid lubricant 154 is provided on the inner diameter portion of the block portion 152 so that the frictional force with the block guide 130 when the second reciprocating guide 150 reciprocates linearly .

The solid lubricant (154) is a thin film or a solid powder in the form of a wear resistant material. The solid lubricant (154) reduces the frictional force of the portion that moves with the friction portion to prevent surface wear. The material of the solid lubricant 154 is typically two molybdenum molybdenum or graphite graphite, and other oxides, titanium sulfide, tungsten sulfide, and talc powder can be used. It is effective to use the solid lubricant 154 in an environment where it is not possible to use an oil type lubricant mainly in a vacuum, a high temperature and a high pressure environment, and it has an advantage that a lubricating effect is remarkably high without causing pollution or bad smell due to oil deposition. Therefore, the solid lubricant 154 is inlaid or coated on the bushing 155 to provide a lubrication effect when rubbing against the block guide 130, thereby remarkably improving the wear resistance without supplying any additional oil or grease, The operation of the guide 150 can be smoothly performed.

The traverse bar guide unit 160 is provided for each bobbin or cylinder 210 of the winder 200 and includes one end of a traverse bar 230 for connecting several traverse guides 220 for guiding the yarn, And are linearly reciprocated in the lateral direction.

The third engaging portion 163 formed at one end of the 'A' -shaped bent portion is hinged by the first engaging portion 142 of the first reciprocating guide 143 and the hinge shaft 161, Is guided by the reciprocating motion of one reciprocating guide (143). The fourth engaging portion 164 formed on the bent portion is hinged to the second engaging portion 153 of the second reciprocating guide 150 by the hinge shaft 162 so that the linear reciprocating force of the second reciprocating guide 150 ≪ / RTI >

The transverse movement displacement of the second reciprocating guide 150 is changed according to the arrangement angle of the guide rail 140 and the moving range of the traverse bar driving unit 160 is also variable, The frictional force due to the hinge movement necessarily occurs in the portions 142, 153, 163 and 164. 5 (a) and 5 (b), friction reducing means 165 and 166 are provided on inner diameter portions of the third engaging portion 163 and the fourth engaging portion 164 to improve abrasion resistance .

The frictional reducing means 165 and 166 preferably use conventional bearings which are excellent in reducing frictional force due to hinge movement. However, the frictional reducing means 165 and 166 are not limited to the second engaging portion 153 and the frictional reducing means 165 and 166, 4 coupling portion 164, or may be coupled to the outer diameter portion of the hinge shafts 161, 162, the same effect can be achieved.

Operation of the gear box for a winder to which the technique of the present invention having the above-described configuration is applied will be described below.

One end of a traverse bar 230 connecting a traverse guide 220 provided for each of the individual bobbins 210 installed in the winder 200 is disposed at one side of the winder 200, To the traverse bar guide (160). When the power is transmitted to the winder 200, the bobbin 210 coupled to the driving shaft rotates and the yarn passes through the traverse guide 220 and is transferred to the bobbin 210 and wound.

At the same time, when the start gear 111 installed in the housing 110 of the gear box 100 of the present invention operates to rotate the traverse cam 120 coupled to the cam shaft 121, The second reciprocating guide 150 to which the insertion portion 151 is coupled is reciprocated linearly along the block guide 130 coupled to the block portion 152 in the transverse direction. The second reciprocating guide 150 also linearly reciprocates at a high speed in proportion to the rotational speed of the traverse cam 120, so that frictional force is generated between the block portion 152 and the block guide 130. Accordingly, the solid lubricant 154 is provided on the inner diameter portion of the block portion 152 to provide a bushing 155 inlaid or coated to significantly reduce the frictional force.

Meanwhile, the traverse bar guide unit 160 hinges on the fourth engaging portion 164 formed on the bent portion of the 'A' character formation and the second engaging portion 153 of the second reciprocating guide 150, The third engaging portion 163 formed at one end and the first engaging portion 142 of the first reciprocating guide 143 are hinged to each other to reciprocate in the direction of arrangement of the guide rail 140, do.

The guide rail 140 has a hinge point of a fastening member 145 coupled to the guide slot 144 so that the displacement of the traverse bar driving unit 160 is adjusted to be equal to the length of the wound wire wound on the bobbin 210. [ So that they are arranged at an angle. For example, if the guide rail 140 is disposed in a straight line in the same horizontal direction as the transverse axis direction, the first to fourth engaging portions 142, 153, 163 and 164 are maintained in a state of not performing hinge movement, 150). In this state, since the traversing bar driving unit 160 has the shortest moving displacement, the moving range of the traverse guide 220 is also shortened so that the winding width of the yarn wound on the bobbin 210 is short.

When the guide rail 140 is obliquely arranged at a maximum angle in the transverse direction, hinge movement occurs in the first to fourth engaging portions 142, 153, 163, 164 and the traverse bar driving portion 160 and the traverse bar 230 Is reciprocated in an arcuate shape. In this state, since the traverse bar driving unit 160 has the longest moving displacement in the transverse direction, the moving range of the traverse guide 220 is also long, and the winding width of the yarn wound on the bobbin 210 is long.

As described above, since the hinge range becomes larger as the inclination angle of the guide rail 140 is larger, the frictional force between the first to fourth engaging portions 142, 153, 163, 164 and the hinge shafts 161, 162 is increased. Therefore, the frictional force can be minimized through the friction reducing means 165, 166 coupled to the inner diameter portion of the third engaging portion 163 and the fourth engaging portion 164 or the outer diameter portion of the hinge shafts 161, 162.

The gear box for a winder according to the present invention is configured such that the traverse cam driving unit 120 starts to rotate and the traverse bar driving unit 160 coupled to the first and second reciprocating guides 143 and 150 The traverse bar 230 is linearly reciprocated at a high speed by the operation, and the winding operation is performed smoothly.

Particularly, a solid lubricant 154 having an excellent lubrication effect is provided in a region where a frictional force due to the hinge movement of the linear reciprocating motion and the first to fourth engaging portions 142, 153, 163, The bushing 155 or the friction reducing means 165 and 166 significantly improves the abrasion resistance compared to the conventional oil lubrication system and causes problems such as contamination problems and malfunctions of the gearbox internal apparatus caused by oil scattering and deposition It is possible to expect an effect of ultimately improving the productivity.

In addition, since the angle of arrangement of the guide rails 140 can be varied by a simple operation, the width of the yarn wound on the bobbin 210 can be easily varied, and the advantage of further expanding the use range of the winder have.

100: gear box for winder 110: housing
111: driving gear 120: traverse cam
121: camshaft 122: cam groove
130: block guide 140: guide rail
141: rail 142: first coupling portion
143: first reciprocating guide 144: guide slot
145: fastening member 150: second reciprocating guide
151: cam insertion portion 152:
153: second engaging portion 154: solid lubricant
155: Bushing 160: Traverse Bar East
161, 162: Hinge shaft 163:
164: fourth coupling portion 165,166: friction reducing means
200: Winder 210: Bobbin or cylinder
220: Traverse guide 230: Traverse bar

Claims (3)

A housing 110 provided at one side of the winder 200 and provided with a driving gear 111 that receives power and rotates;
A traverse cam 120 having a circular spiral cam groove 122 formed along the outer diameter of the cam shaft 121 coupled to the driving gear 111;
A pair of block guides 130 having both ends connected to the housing 110 and parallel to the upper portion of the traverse cam 120;
A guide rail 140 is formed of a straight rail 141 provided on both sides of the block guide 130 and a first reciprocating guide 143 linearly reciprocating along the rail 141 and having a first engaging portion 142 formed thereon. and;
A pair of block portions 152 projecting downward from the cam insertion groove 151 to be engaged with the cam groove 122 and engaged with the block guide 130 and a second coupling portion 152 formed on both sides of the block portion 152, A second reciprocating guide 150 integrally formed with the traverse cam 120 and linearly reciprocating along the block guide 130 by rotation of the traverse cam 120;
A third engaging portion 163 and a fourth engaging portion 164 which are formed in a letter shape and into which the hinge shafts 161 and 162 are inserted are formed so that the first engaging portion 142 and the second engaging portion 153 And a traverse bar driving part (160) hinged to the inside diameter part and having friction reducing means (165, 166). The method according to claim 1,
A bushing 155 with an inlaid solid lubricant 154 is provided on the inner diameter portion of the block portion 152 to reduce frictional force with the block guide 130 when the second reciprocating guide 150 reciprocates linearly. Gearbox for the winder. The method according to claim 1,
An arcuate guide slot 144 is formed at one side of the guide rail 140 and is coupled to the housing 110 by a fastening member 145 to vary the angle of arrangement of the guide rail 140 by the displacement of the guide slot 144. [ Wherein the gear box is configured so as to be able to rotate the gear box.

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