KR20170063329A - Ring-shaped Core Winding Machine - Google Patents

Abstract

The present invention relates to a ring-shaped core winding machine (1), comprising a coiled body (C) wound in an inner circle (I) A coil winding section (3); And a core rotating part (5) for placing the wound core (C) at a loading position (L) and rotating the wound core (C) one time when the coil winding part (3) makes one rotation Wherein the coil winding portion 3 is formed by winding the wound core C in a twisted relationship with the inner circle I or by winding the wound core I in a twisted relationship with the inner circle I, And the opening of the inner circle I for withdrawing the coil from the upper half and the lower half of the coil winding bundle is performed by a one-touch operation of the user. It is possible to more conveniently and quickly perform the core winding operation in which the plurality of wound core cores are continuously wound, and thus the working efficiency of the core winding can be greatly improved.

Description

Ring-shaped Core Winding Machine [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ring-type core winding, and more particularly, to a ring-type core winding, such as a toroidal core used for a transformer or the like, Core winding.

Generally, the toroidal core, which is widely used as an inductor, is an annular core. Since a magnetic flux is formed in a closed loop and leakage magnetic flux is small, it is widely used in a high frequency circuit. In order to solve such inconvenience, a core winding machine has been proposed.

Examples of the annular core winder used to wind the coil on the annular core include an elliptical and polygonal toroidal coil winder (Patent No. 10-0639706 and No. 10-1362333) A coil winding portion for winding a coil of a wire rod on a coil core to be wound, that is, a core rotating portion for rotating and transferring the wound core in a certain step while supporting the coil core while winding the coil.

However, such a conventional coil winding machine includes a coil winding bundle 123 that is rotatably mounted on a supporting base 111, as shown by reference numeral 103 in Fig. 1, This coil winding bundle 123 is again constituted by an annular housing (not shown), a rotating ring 132 and an annular shuttle 133, as shown in Fig.

Here, although the annular housing is not shown, the coil winding bundle 123 serves as an outer body and is fixed to the opening of the support base 111 to rotatably support the rotary ring 132 As shown in Fig. 1, one side is opened so that the core C can be placed on the inner circle I of the coil winding bundle 123 of the bar. The rotating ring 132 is a kind of ring gear, which is engaged with the driving gear 128 connected to the driving motor and rotates by the rotational driving force transmitted from the driving motor, thereby winding the coil substantially. Finally, the annular shuttle 133 is a portion where the coil is wound, coaxially fitted in the inside of the rotation ring 132, and rotates together along the rotation ring 132, but the wound coil is smoothly discharged at the time of winding So as to rotate relative to the rotary ring 132. Therefore, the coil winding bundle 123 rotates the rotating ring 132 by the rotational driving force of the driving gear 128 transmitted from the driving motor to loosen the coil wound around the shuttle 133 and rotate the core C ), Thereby completing one winding core.

In order to arrange the wound core C for the winding in the inner circle I of the annular coil winding bundle 123 as described above, one side of the rotating ring 132 and the annular shuttle 133 is formed as shown in FIGS. 2, in order to allow the rotary ring 132 and the shuttle 133 to operate normally, in the case of the rotary ring 132, as shown in FIG. 2, The opening and closing pieces 110 need to be attached to and detached from the opening portion O and the opening and closing door 120 is required for the shuttle 133. [ 2, when the core C is inserted into the coil winding bundle 123, the opening and closing pieces 110 are separated from the rotary ring 132 and the opening and closing door 120 of the shuttle 133 is closed (O) by pushing it inward so as to overlap with the opening 133 of the opening. After the core C is disposed in the inner circle I, the opening / closing piece 110 and the opening / closing door 120 are closed so that the coil winding bundle 123 can perform a normal winding operation . When the winding is finished, the opening / closing piece 110 and the opening / closing door 120 are opened again to pull out the core C disposed in the inner circle I outward.

However, as described above, in order to wind one core 123 by the conventional core winding machine 101, there is a problem that when the wound core C is placed in the inner circle I of the coil winding bundle 123, It is necessary to attach and detach the opening and closing piece 110 to the rotary ring 132 and the opening and closing door 120 to and from the shuttle 133 twice when the core is collected from the inner circle I, In addition, since it takes a lot of time, the working efficiency of the coil winding is greatly reduced. Also, when the opening / closing piece 110 or the opening / closing door 120 is not tightened in order to make up for the reduced working efficiency, a large failure may occur in the entire device.

KR 10-0639706 KR 10-1362333

SUMMARY OF THE INVENTION The present invention has been proposed in order to overcome the problems of the conventional core winding machine as described above, and it is an object of the present invention to provide a core winding assembly, in which a core for winding a coil is disposed in a coil winding bundle, The present invention aims at improving the efficiency of the core winding operation by simplifying the opening and closing mechanism of the coil winding bundle opened for entry and exit by one-touch method, such as making the core winding operation easier and shortening the winding time.

Another object of the present invention is to improve the safety of the winding work by allowing the coil winding bundle to be stably opened and closed while making the winding operation convenient and quick as described above.

In order to achieve the above object, the present invention provides a coil winding device comprising: a coil winding part which is loosely wound on an outer circumference and rotatably installed on a support so as to be repeatedly wound on an annular body of a to-be-wound core which is wound around an inner circle; And a core rotating part provided adjacent to the support for seating the wound core in a loading position in the coil winding part and rotating the wound core one rotation when the coil winding part makes one rotation, The coil winding unit includes: an annular housing formed as an outer body and fixed to the support base; A rotating ring rotatably fitted on the housing and rotating along the housing (31) by a driving force supplied from a driving source; And an annular shuttle fitted in the outer periphery of the rotating ring to rotate along the housing together with the rotating ring and being rotatable relative to the rotating ring so that a coil wound around the outer periphery before unwinding of the winding can be unwound during the winding operation; Wherein the coil winding bundle is divided radially into respective portions of the housing, the rotary ring, and a portion of each of the shuttles in the same section, When the winding core is to be fitted in a twisted relationship or the winding core inserted in a twisted relationship in the inner circle is to be taken out, the part is separated from the other part by the user's operation, And the opening / closing of the annular core winding is performed.

The housing, the rotary ring, and the shuttle are each divided into upper and lower halves to form a lower half of the housing, a lower half of the upper ring, and a lower half of the shuttle, wherein the lower half of the housing, The upper half of the housing, the upper half of the rotating ring, and the upper half of the shuttle are mounted on the upper part of the support so as to be movable up and down.

The lower half of the support is fixed on the base while supporting the lower half of the housing, the lower half of the rotation ring, and the lower half of the shuttle, and the upper half of the support is supported on the upper half of the housing, The upper half of the rotation ring, and the upper half of the shuttle while supporting the upper half of the rotation ring, and the upper half of the rotation ring, and the upper half of the shuttle.

The coil winding portion may include a lift-up bundle installed at one side of the coil winding bundle to allow the inner circle to be opened and closed by a user's operation, and the lift-up bundle may guide the lifting operation of the coil winding bundle An elevating guide means; And elevating operation means for elevating and lowering the coil winding bundle along the elevating guide means.

According to the annular core winder of the present invention, when the core to be wound, that is, the core to be wound, is placed at a loaded position in the coil winding bundle of the coil winding portion or the winding core in which the winding is completed at the loading position of the coil winding bundle, For example, the upper half of the coil winding bundle can be separated by one-touch operation of an opening / closing mechanism such as depressing the pedal of the lifting bundle, so that the opening for opening and closing the core can be easily ensured, It is possible to more conveniently and quickly carry out the core winding operation to be performed so that the working efficiency of the core winding can be remarkably improved.

In addition, while the convenience and efficiency of the core winding operation can be improved as described above, the housing, the rotating ring, the annular shuttle, and the support, if necessary, of the coil bundle can be maintained in a stable state without passing through separate fastening means Not only the stability of the winding operation can be ensured, but also the durability life of the device can be greatly increased.

1 is a perspective view showing a coil winding portion of a conventional core winding machine.
FIG. 2 is a perspective view explaining the rotating ring and the annular shutter of the coil winding portion shown in FIG. 1; FIG.
3 is a perspective view of a annular core winder in accordance with an embodiment of the present invention.
Figure 4 is a front view of Figure 3;
Figure 5 is a plan view of Figure 3;
Fig. 6 is a perspective view showing the coil winding portion shown in Fig. 3 in detail in an open state; Fig.
Fig. 7 is a perspective view of the coil winding bundle shown in Fig. 6 in a partially exploded state; Fig.
8 is a rear perspective view of the core rotating portion shown in Fig.
Fig. 9 is a bottom perspective view of Fig. 8; Fig.
Fig. 10 is a rear perspective view showing the coil winding portion shown in Fig. 3 in an open state. Fig.
Fig. 11 is a perspective view showing the annular core winder shown in Fig. 3 with the core winding bundle opened. Fig.
FIG. 12 is a view for explaining a process in which a coil is preliminarily wound on the coil winding portion of FIG. 6; FIG.
Fig. 13 is a view for explaining a process in which a coil pre-wound on the coil winding portion of Fig. 6 is wound by a core. Fig.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, an annular core winder according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

The annular core winder of the present invention comprises mainly a coil winding portion 3 and a core rotating portion 5, as indicated by reference numeral 1 in Figs. 3 to 5.

Here, the coil winding portion 3 is a coil winding portion directly to the annular core C, and as shown in Figs. 3 to 5, the coil winding portion 3 is wound in a twisted relationship with the inner circle I, , And the coil W is wound in a radial direction on an annular coiled core (C) body to be wound so as to be interwoven with each other at an angle of 90 degrees. To this end, the coil winding part 3 is mounted on the support 11 standing vertically on the base 7 so that a part of the inner circumferential part is rotatable. The coil winding part 21, the coil winding bundle 23, A drive bundle 25, and a lift bundle 27. [

The coil input bundle 21 is a portion into which the coil W is inserted into the coil winding bundle 23 before the winding operation is started and is extended from the one side to the coil winding bundle 23, And a coil cutter 221 mounted adjacent to the innermost putting roll 72. The feed roll 72 includes a plurality of rollers 71, . At this time, the coil cutter 221 is wound around the outer periphery of the coil winding bundle 23 so as to cut the charged end of the coil W. The coil winding bundle 23 is rotated without being constrained by the coil W So that the coil W wound on the outer periphery can be wound around the core C.

The coil winding bundle 23 is a portion which substantially coils the coil W on the core C. The coil winding bundle 23 is partly rotatably mounted on the support base 11 to release the coil W wound on the outer circumference, The winding of the coil W is repeatedly wound in accordance with the rotation of the coil winding bundle 23 so that the winding of the coil W is tightly wound on the body of the core C loaded in the winding coil I in the radial direction. To this end, the coil winding bundle 23 is formed so that the core C to be wound around the inner circle I is twisted or twisted or the core C in which the winding is completed is drawn out from the inner circle I fitted in a twisted relationship , The inner circle I is opened by one-touch operation of the user.

Thus, the coil winding bundle 23 again includes an annular housing 31, a rotating ring 32, and an annular shuttle 33, as shown in detail in Figures 3-5 and 6- do. In addition, each of the housing 31, the rotary ring 32, and the shuttle 33 is divided radially with each other portion in the same section. Therefore, when the user moves the portion of the same section by one-touch operation, the housing 31, the rotary ring 32, and the shuttle 33, that is, the coil winding bundle 23, Thereby opening the inner circle I so that the core C can be loaded or recovered.

More specifically, the coil winding bundle 23 according to the present embodiment is vertically split at an angle of 180 degrees to form a coil winding bundle upper half portion 23-1 and a coil winding bundle lower half portion 23-2 of a return type. The coil winding bundle upper half portion 23-1 is composed of a housing upper half portion 31-1, a rotary ring upper half portion 32-1 and a shuttle upper half portion 33-1, A lower half 31-2, a lower half 32-2 of the rotary ring, and a lower half 33-2 of the shuttle.

In particular, the coil winding bundle 23 is formed so that the lower half 23-2 of the coil winding bundle, that is, the lower half 31-2 of the housing, the lower half 32-2 of the rotating ring and the lower half 33-2, And the upper half of the coil winding bundle 23-1, that is, the upper half 31-1 of the housing, the upper half 32-1 of the rotating ring, and the upper half 33-1 of the shuttle are vertically moved The opening of the support 11 for fitting the coil winding bundle 23 is formed higher than that of the coil winding bundle 23 so that the coil bundle 23 is divided into two halves as shown in FIG. The upper half 23-1 of the coil winding bundle can be lifted up from the lower half 23-2 of the coil winding bundle.

6, the support base 11 is divided into upper and lower halves like the coil winding bundle 23 to be formed as the lower half halves 11-1 and 11-2 of the support base. Thus, the support base 11 is coupled with the coil winding bundle 23 It is preferable to transmit an external force for lifting the coil winding bundle upper half 23-1 while moving. The lower half half 11-2 of the bracket is fixed on the base 7 while supporting the lower half 31-2 of the housing, the lower half 32-2 of the rotary ring and the lower half 33-2 of the shuttle, -1 is supported by the upper half 31-1 of the housing, the upper half 32-1 of the rotating ring, and the upper half 31-1 of the housing while supporting the upper half 31-1, the upper half 32-1, And is aligned with the shuttle upper half portion 33-1 on the lower half portion 11-2 of the support base so as to be movable up and down.

3 to 7, the annular housing 31 is formed in a circular opening of the support 11 so as to form an inner circle I, as shown in FIGS. 3 to 7, As shown in enlarged view in Fig. 6 so as to form a guide groove for rotatably fitting the rotary ring 32 and the annular shuttle 33, as shown in detail in Figs. 6 and 7, (35), a partition plate (36), and a finishing plate (37). At this time, the board 35 has a U-shaped cross-sectional shape so that the inner surface thereof is attached to the support base 11, and the outer tooth gear 39 of the rotary ring 32 is received in the concave groove of the outer surface. The partition plate 36 is attached to the outer surface of the substrate 35 so as to cover the recessed grooves of the substrate 35 as much as possible and serves to support the external gear 39. The finishing plate 37 supports the partition plate 36 on the substrate 35 attached to the support 11 and supports the annular shuttle 33 fitted to the rotary ring 32, And is fastened with bolts 38 onto the substrate 35 through the plate 36.

As described above, the rotary ring 32 is a portion that rotatably fits on the housing 31 and winds the coil W on the core C by rotating the rotary ring 32. As shown in Figs. 6 and 7 Similarly, the outer sheath gear 39 is formed on the inner side so as to be inserted into the concave groove of the substrate 35, and the outer sheath 41 is joined to the outer side so as to hold the shuttle 33 between the partition plate 36 and the partition plate. Therefore, the rotary ring 32 is engaged with the drive gear 28 mounted on the lower end of the support base 11 by the external gear 39, and is rotated by the rotational drive force transmitted from the drive source 29 to the drive gear 28, ).

Finally, the annular shuttle 33 is fitted in the outer periphery of the rotary ring 32 and guides the discharge of the coil W wound on the outer periphery. As shown in FIGS. 6 and 7, And is rotatable relative to the rotary ring 32 in the circumferential direction, that is, relatively rotatably mounted on the rotary ring 32. The rotary ring 32 is rotatably mounted on the housing 31, do. Further, since the coil groove 43 is formed along the outer circumferential surface, the coil W to be used for winding before the start of winding on the core C is preliminarily wound on the coil groove 43, . Therefore, the annular shuttle 33 is designed to unwind the coil W wound on the coil groove 43 during the winding operation. As the coil rotates relative to the rotation ring 32, the annular shuttle 33 gradually becomes shorter The coil W is pulled by the core C so that it can be loosened smoothly without being tense.

3 to 7, as described above, the drive ring 25 is a means for supplying a rotational driving force to the coil winding bundle 23, particularly, the rotary ring 32. As described above, A drive source 29 such as a drive motor for generating a rotational force of the drive gear 28 and a drive source 29 for driving the drive source 29 such that the rotational drive force of the drive source 29 is transmitted to the drive gear 28, And a belt pulley assembly 30 for transmitting the rotational drive force of the drive source 29 mounted in the middle of the base 7 to the drive gear 28 through the belt pulley assembly 30, (32) meshing with the drive gear (28) by means of the drive shaft (39). In this case, the drive gear 28 may further include a rotary knob 13 on the opposite side to the belt pulley assembly 30 of the gear center axis. In this case, before the drive source 29 is driven, It is possible to wind the coil W around the outer periphery of the shuttle 33 more easily.

3 to 5, Fig. 10 and Fig. 11, the lifting bundle 27 is a means for lifting the coil winding bundle 23 by one-touch operation of the user and opening and closing the inner circle I The coil winding bundle 23 extends from the side of the coil winding bundle 23 to the position adjacent to the bottom surface through the base 7 and is again divided into the elevating guide means 57 and the elevating operation means 59.

Here, the elevation guiding means 57 is constituted by a guide rail 61 and a conveying block 62 as means for guiding the elevating operation of the coil winding bundle 23, as shown in FIG. 10, And guides the lifting and lowering of the coil winding bundle upper half 23-1 to the lower half 23-2 of the coil winding bundle 23-2. That is, it guides the movement of the support base upper half 11-1 that vertically moves up and down at the support base lower half 11-2. To this end, the guide rail 61 is installed adjacent to one side of the coil winding bundle 23 through a rail frame 63 provided on the base 7, as shown in Figs. 5 and 10. Therefore, the guide rails 61 are elongated vertically to guide the upper and lower portions of the coil winding bundle upper half 23-1, that is, the upper half of the support base 11-1, up and down. The conveying block 62 is a means for mediating between the guide rail 61 and the upper half portion 23-1 or the upper half portion 11-1 of the coil winding bundle, Or may be indirectly attached to the support upper half 11-1 via an extension plate 64 as shown in Figures 5 and 10 and the rear face can be attached to the guide rail 61 vertically So that the guide block 61 and the conveying block 62 are engaged with each other by the dovetail-like concavo-convex shape, thereby making it possible to guide the coil winding bundle upper half portion 23-1 more stably.

The elevating operation means 59 is means for moving the coil winding bundle 23, that is, the coil winding bundle upper half portion 23-1 along the elevating guide means 57, A link 47, and a pivot rod 49. 3, 4, 10 and 11, the pedal 45 is installed below the base 7 so as to be pressed or released by a user. As shown in FIG. 10, The support link 46 pivots in the clockwise direction in the drawing so that the push link 47 is lifted up and the coil winding bundle upper half portion 23-1 and the support base upper half portion 11- 1), thus opening the inner circle I. On the contrary, when the pressing force P by the user is removed, the pedal 45 returns to the original standby position by the reaction force of the return spring 65, and thus the coil winding bundle upper half portion 23-1 and the support upper half portion 11 -1) falls to its original closed position. The push link 47 is a rod that transmits the pushing force P applied to the pedal 45 to the pivot rod 49. The lower end of the push link 47 is connected to the support link 46) action end, and the upper end is pinned to the force end of the pivot rod (49). Therefore, the push link 47 moves up and down in accordance with the pivotal rotation of the pedal 45 to transmit the pressing force P applied to the pedal 45 to the coil winding bundle 23. Finally, the pivot rod 49 directly lifts the coil winding bundle upper half 23-1 by the urging force P transmitted from the pedal 45 through the push link 47, The coil winding bundle upper half portion 23-1 can be connected to the coil winding bundle upper half portion 23-1 in a variety of ways, for example, as shown in Fig. 10, (23-1). Therefore, the pivot rod 49 becomes a force point at the left end in the drawing, which is pin-coupled to the upper end of the push link 47, and the upper end of the coil winding bundle 23-1, that is, 11-1 is a point of action and the inner end on the right side in the drawing pin-coupled to the lower half 23-2 of the coil winding bundle through the lower half 11-2 of the supporter serves as a fulcrum. The pin 66 connected to the extension plate 64 is then coupled to the pivot rod 49 through the pin slot 68 so as not to constrain the pivoting movement of the pivot rod 49.

The lift unit 27 may further include a lift locking unit 201 as a safety device for preventing the coil winding bundle 23 from being opened during the winding operation. But it is preferable that it is composed of the lock hole 203, the fitting hole 205, and the catch 207 as shown in Figs. 3 to 5, 10 and 11. Here, the lock hole 203 is a pivot rod 49, as shown in Figs. 5 and 10, as a means for blocking the movement itself as well as pivoting the pivot rod 49 with the catch 207 inserted therebetween. More specifically, in a direction perpendicular to the pivot rotation direction between the point of action of the pivot rod 49 and the point of action. The fitting hole 205 is an entrance for aligning the locking hole 203 with the locking hole 203 when the upper and lower operation means 59 is in the standby position so that the locking hole 203 can be inserted into the locking hole 203, On the lower side of the lower half 11-2 of the support frame or on a separate lock frame 208 mounted on the side of the lower frame half 11-2 as shown in Fig. 3 to 5, 10, and 20, as the means for preventing the movement of the pivot rod 49, and furthermore the coil winding bundle upper half 23-1, As shown in Fig. 4, when the lifting operation means 59 is in the standby position, the lifting operation means 59 is in the form of a cylinder so that it can be simultaneously fitted in the fitting hole 205 and the lock hole 203, The pivot rod 49 is prevented from rotating so as to prevent the pivotal movement of the inner circle (not shown) due to inadvertent operation of the pedal 45 or the like during the winding operation, I) is not attempted. Conversely, when the lifting operation means 59 is to be operated, the pawl 207 is retracted into the housing 211 as shown enlarged in FIG. 5 to be pulled out of the lock hole 203, And is retained on the upper surface 211 until the lifting operation is completed.

The coil winding unit 3 may further include a coil cutter 221 for cutting the coil W connected to the coil winding bundle 23 after the preliminary winding is completed in the coil input bundle 21, 3 to 5 and Figs. 10 to 13, the coil cutter 221 is disposed on the innermost rollers 72 of the plurality of rollers 72 of the coil input roll 21, And is mounted on the top of the support 11 so as to be adjacent thereto. 12, when the coil W to be pre-wound on the shuttle 33 of the coil winding bundle 23 is supplied from the outside along a plurality of the input rolls 72, By allowing the coil cutter 221 to pass through before the winding, the coil W having finished the preliminary winding can be cut between the innermost closing roll 72 and the shuttle 33 as shown in Fig.

To this end, the coil cutter 221 comprises a casing 223, a cutting knife 225, and a cutter knob 227 as shown in Figs. 3-6 and Figs. 10-13. 12 and 13, the casing 223 has a cylindrical shape. The casing 223 is formed below the innermost insertion roll 72 of the support 11, A through hole 228 penetrates the outer circumferential surface of the coil 22 in a radial direction so that the coil W can straightly pass through the through hole 228. In order to cut the coil W at the coil entrance edge of the through hole 228, A receiving blade 229 is formed. The cutting knife 225 is a portion that cuts the coil W substantially in response to the upper receiving bladder 229 and is a portion of the casing 223 as shown in FIGS. 3 to 6 and 10 to 13, One end is mounted in the casing 223 so as to rotate coaxially along the inner peripheral surface of the support base 11 while the other end protrudes in the opposite direction through the support base 11 as shown in Fig. At this time, one end on the front side of the cutting knife 225 opens the through hole 228 of the casing 223 at the stand-by position shown in Fig. 12, and in response to the receiving blade 229, A cutting edge 231 is formed at one end edge corresponding to the receiving edge 229 to cut the coil W passing through the cutting edge 228. Finally, as shown in FIG. 10, the cutter knob 227 is mounted on the other end of the cutting knife 225 so that the user can easily grasp the cut knife 225 when the cutting knife 225 is rotated.

The core rotating portion 5 is a means for holding the core C when the coil C is wound around the core C by the coil winding portion 3 as described above, And also serves to rotate the core C that is seated in the loading position L at a predetermined angle in cooperation with the rotation of the coil winding part 3, particularly, the rotating ring 32. [ That is, when the rotary ring 32 makes one revolution and the coil W is wound around the core C, the coil W is rotated by one rotation so that the coil W can be wound the next time. For example, in Fig. 13, while the rotary ring 32 makes one rotation in the direction of the arrow B, the core C is rotated in the direction of the arrow C by one rotation so that the coil W can be wound with the next wheel.

3 to 5, 8, and 9, the core rotating portion 5 includes a roller bundle 75 for supporting the core C in the loading position L, 75) up and down and back and forth.

The roller bundle 75 further includes a drive roll 79 for directly rotating and rotating the core C and a plurality of support rolls 81 for supporting the core C on the front and rear sides of the drive roll 79, 9, the drive roll 79 rotates by the step motor 82 connected to the lower end to rotate the core C, and each of the support rolls 81 Is brought into contact with or spaced from the core C by the rotation of the opening / closing handle 83 linked through the worm 84 and the worm gear 85. 8, the driving roll 79 is pressed against the core C through the pressing assembly 86 assembled at the lower end, and the position where the pressing rod 87 is engaged by the pin 89 Or by changing the engagement position of the pin 90 of the spring latch 88 with respect to the pressing rod 87. [ Each of the support rolls 81 is rotated synchronously with the drive roll 79 by a rotational force transmitted through the gear train 93 connected before and after the drive roll 79. [

The movable bed 77 can change the position of the roller bundle 75 as desired by adjusting the height of the bed surface or the separation distance from the core C by the vertical adjustment unit 91 and the horizontal adjustment unit 92, 8, the upper and lower adjustment unit 91 is composed of the adjustment knob 93, the bevel gear train 95, and the feed screw 97 (see FIG. 8) And the left and right adjusting unit 92 is composed of the adjusting knob 94 and the feed screw 96.

Now, the operation of the annular core winder 1 according to the preferred embodiment of the present invention will be described as follows.

6, in order to wind the coil W on the core C by the core winding machine 1 of the present invention, the pedal 45 is stepped on to operate the lifting sheave 27, The upper half portion 23-1 of the coil winding bundle of the portion 3 is lifted up together with the upper half portion 11-1 of the support base. When the inner circle I of the coil winding bundle 23 is opened, the core C to be wound is inserted into the inner circle I through the opening as shown in FIG. 6, So that the core C is arranged in a twisted relationship with the coil winding bundle 23 when the inner circle I is closed as shown in FIG.

Then, the coil W wound through the coil input bundle 21 is wound around the outer periphery of the coil winding bundle 23 from an external winding coil. To this end, after the coil W received from the outside through the input roll 72 is fixed to the shuttle 33 of the coil winding bundle 23 through the coil cutter 221 as shown in FIG. 12, 29 to rotate the rotary ring 32 in the direction of arrow A in Fig. The coil W supplied from the outside along the winding roll 72 is wound around the coil groove 43 of the shuttle 33. The amount of winding of the core C is 200 times The shuttle 33 is wound around. At this time, the rotation number of the rotation ring 32 is counted by the rotation detection sensor 51 and controlled by the control unit. When the coil W is wound by the predetermined length in this way, the operator turns the cutting knife 225 of the coil cutter 221 to cut the coil W, and cuts the cut end to the coil cutter 225, The coil spring 53 at the upper end of the housing 31 adjacent to the coil spring 221 is engaged with the guide roll 55 to complete the reception of the coil W. [

3 to 5, Fig. 8, and Fig. 8, the core C sandwiching the inner circle I is seated in the loading position L before or after the preparation of the coil W as described above. The core C is seated on the core rotating portion 5, as shown in Fig. To this end, the operator first operates the open / close knob 83 to open the front and rear support rolls 81 back and forth, and pulls the pin 90 of the spring latch 88 to release the pressing assembly 86. The core C is then placed on the triangular fulcrum formed by the two support rolls 81 and drive rolls 79. 8 and 9, the support roll 81 is brought into close contact with the core C, and then the spring latch 88 is again hooked onto the pressure bar 87 so that the drive roll 79 is also engaged with the core C). At this time, the position of the drive roll 79 can be changed by changing the engagement position of the pin 89 according to the diameter of the core C, so that it is possible to appropriately cope with the change in the diameter of the core C. After the core C is seated between the three rolls 79 and 81, the grips 93 and 94 of the vertical adjustment part 91 and the horizontal adjustment part 92 are manipulated to move up and down the transporting bed 77, The position of the core C is adjusted by adjusting the position. In order to align the height of the conveying bed 77 with the height of the conveying bed 77 in order to match the winding height to the center of the coil winding bundle 23, that is, the inner circle I, at the loading position L where the thickness varies with the thickness of the core C. Right and left positions of the conveying bed 77 are adjusted so that the position at which the winding is performed at the loading position L is the center of the coil winding bundle 23 or the inner circle I even when the diameter of the core C changes significantly To come.

When the loading of the core C and the winding of the coil W are completed in this manner, the coil W hanged on the guide roll 55 is dragged and wound around the core C once, The rotation of the rotary ring 32 in the direction of the arrow B causes the coil W wound on the shuttle 33 to be wound on the core C. Thereafter, At this time, as mentioned above, when the rotary ring 32 makes one rotation, the core C rotates in the direction of the arrow C by one rotation so that when the rotary ring 32 rotates next time, Let it wind on the pitch. When the rotating ring 32 rotates by the predetermined number of times and the coils W wound on the shuttle 33 are wound around the core C for about 1000 times on the core C after all the coils W are wound on the core C Winding of the core (C) is completed.

Finally, the winding core C of the loading position L is separated from the core rotating portion 5, the pedal 45 is depressed to lift the upper portion 23-1 of the coil winding bundle 23-1 to open the inner circle I again The winding core C separated from the loading position L is collected from the coil winding portion 3, and the core winding operation is completed.

1: Winding machine 3: Coil winding part
5: core rotating part 7: expectation
11: support member 13: rotation handle
21: coil input bundle 23: coil winding bundle
23-1: Upper half of the coil winding bundle 23-2: Lower half of the coil winding bundle
25: a drive bundle 27: a lift bundle
28: driving gear 29: driving source
30: Belt pulley assembly 31: Housing
32: rotating ring 33: shuttle
39: shout gear 43: coil groove
45: Pedal 46: Clamp
51: rotation detecting sensor 53: coil hook
55: guide roll 57: elevating guide means
59: lift-up operation means 72:
75: roller bundle 79: driving roll
81: Support roll 86: Pressurization assembly
91: upper and lower adjustment part 92:
201: lift-and-lock means 221: coil cutter
C: Core I: inner circle
L: Loading position W: Coil

Claims (4)

A coil winding portion 3 rotatably provided on a support base 11 so as to be repeatedly wound on an annular body of a to-be-wound core C loaded in a twisted manner with respect to the inner circle I by unwinding the coil W wound on the outer periphery, ; And
Is provided adjacent to the support base (11) so as to seat the wound core (C) at a loading position (L) in the coil winding part (3), and when the coil winding part (3) And a core rotating part (5) for rotating the core (C) by one rotation,
The coil winding section (3)
An annular housing (31) forming an outer body and fixed to the support base (11);
A rotating ring (32) rotatably fitted on the housing (31) and rotating along the housing (31) by a driving force supplied from a driving source (29); And
The winding ring 30 is fitted on the outer periphery of the rotary ring 32 so as to rotate along the housing 31 together with the rotary ring 32 so that the coil W wound along the outer circumference before the winding is started can be released during the winding operation, And an annular shuttle (33) adapted to be rotatable relative to the coil winding bundle (32), wherein the coil winding bundle (23)
The coil winding bundle 23 is formed such that a portion of each of the housing 31, the rotary ring 32 and the shuttle 33 is radially divided with respect to each other portion in the same section, When the winding core (C) is to be fitted in a twisted relationship with the inner core (I) or when the winding core (C) inserted in a twisted relationship in the inner circle (I) And the inner circle (I) is opened and closed by separating the part from the other part by the inner ring (I). The method according to claim 1,
The housing 31, the rotary ring 32 and the shuttle 33 are vertically divided into upper and lower halves 31-1 and 31-2 of the housing and upper and lower halves 32-1 and 32-2 of the rotary ring, 2) and the shuttle upper and lower halves 33-1, 33-2,
The lower half 31-2 of the housing, the lower half 32-2 of the rotating ring and the lower half 33-2 of the shuttle are mounted on the lower part of the support 11,
Characterized in that the upper half (31-1) of the housing, the upper half (32-1) of rotation, and the upper half (33-1) of the shuttle are mounted movably up and down on the support base (11) . The method of claim 2,
The support base 11 is divided into upper and lower halves to form the lower half halves 11-1 and 11-2 on the support base,
The lower half 11-2 of the support is fixed on the base 7 while supporting the lower half 31-2 of the housing, the lower half 32-2 of the rotary ring and the lower half 33-2 of the shuttle,
The upper half 11-1 of the support frame supports the upper half 31-1 of the housing, the upper half 32-1 of the rotation ring and the upper half 33-1 of the shuttle while supporting the upper half 31-1, Is rotatably mounted on the lower half (11-2) of the support together with the rotary ring upper half (32-1) and the shuttle upper half (33-1). The method of claim 2,
The coil winding section 3 includes a lift bundle 27 installed at one side of the coil winding bundle 23 to open and close the inner circle I by the user's operation,
The ascending / descending bundle (27)
An elevating guide means (57) for guiding the elevating operation of the coil winding bundle (23); And
And an elevating operation means (59) for elevating and lowering the coil winding bundle (23) along the elevating guide means (57).

Images