JP5586716B2 - How to wind the belt - Google Patents

Description

  The present invention relates to a method for winding a band such as a carrier tape.

  A carrier tape used for mounting electronic components on a circuit board is wound around a winding core of a winding reel. Here, in the carrier tape production process and the electronic component storage process, a longer carrier tape is wound from the viewpoint of reducing the replacement frequency of the take-up reel and improving the production efficiency. As shown in FIGS. 21 and 22, this type of take-up reel is a take-up core 1A and a carrier tape 10 that traverses and winds around the take-up core 1A and stores a plurality of electronic components. And.

  As shown in FIG. 21 and FIG. 22, the winding core 1 </ b> A is formed in a cylindrical shape and is provided with flanges 3 on both left and right end surfaces thereof, and is wider than the width of the carrier tape 10. Further, as shown in FIG. 21, the carrier tape 10 has a plurality of pockets 12 for storing electronic components arranged in the longitudinal direction of the long tape 11, and a plurality of sprocket holes on one side in the longitudinal direction of the tape 11. 13 is perforated at intervals, and is continuously wound around the peripheral surface 2A of the winding core 1A.

The cover tape is detachably adhered to the surface of the tape 11 after the electronic component is stored in the pocket 12, and this cover tape prevents the electronic component from falling off the pocket 12, and the tape 11 is pulled out when the carrier tape 10 is fed. Is peeled off.
Such a take-up reel has a viewpoint of improving the winding density of the carrier tape 10 when the carrier tape 10 is traversed and wound around the empty take-up core 1A and preventing collapse during storage and transportation. Then, one side portion of the carrier tape 10 is overlapped and wound on the other side portion of the wound carrier tape 10 (see Patent Documents 1 and 2).

Japanese Patent Laid-Open No. 2001-247158 Japanese Patent Laid-Open No. 9-315628

  The conventional take-up reel is configured as described above, and one side of the carrier tape 10 is simply overlapped and wound on the other side of the wound carrier tape 10. The side portion of the carrier tape 10 is inclined with respect to the peripheral surface 2A of the core 1A, causing the winding length to be different, so that the winding of the carrier tape 10 is distorted and easily bent in a certain direction.

  As a result, when the pocket 12 of the carrier tape 10 is positioned and an electronic component is inserted into the pocket 12, an error occurs, or the work of sticking the cover tape to the surface of the tape 11 of the carrier tape 10 is hindered. There is a possibility that the carrier tape 10 cannot be smoothly fed out during mounting.

The present invention has been made in view of the above, can carrier tape cause difference in by the winding length inclined, to suppress the distortion in the wound of the carrier tape is bend easily in a predetermined direction occurs The object is to provide a method of winding the band.

In the present invention, in order to solve the above-mentioned problem, it is a winding method for a belt body that traverses and winds a carrier tape on a curved peripheral surface of a winding core,
The circumferential surface is inclined radially outwardly from one end portion of the winding core toward the other end portion, and the inclination θ of the circumferential surface is based on 0 <θ ≦ 2 arctan ( carrier tape thickness / traverse pitch). Shall be
When the carrier tape is traversed and wound from the circumferential surface on the one end side with a small diameter of the winding core to the circumferential surface on the other end side with a large diameter, the carrier tape is placed on the side of the wound carrier tape. When the carrier tape is traversed and wound from the circumferential surface on the other end side of the winding core to the circumferential surface on the one end side, the side portions are overlapped and wound on the side portion of the wound carrier tape. Wind up with normal winding without overlapping the sides of the carrier tape,
When the carrier tape is overwrapped, the inclination angle of the winding core is always set to a constant inclination angle .

In addition, flanges are respectively attached to both end faces of the winding core, and at least one of the flange and the peripheral surface of the winding core is provided with an erroneous attachment preventing means, and the carrier is disposed in the circumferential direction of the winding core. A non-slip groove for the tape can be formed, and the non-slip groove can be arranged from one end of the winding core to the other end.

Further, the winding core can be constituted by a cylindrical inner core and a cylindrical outer core fitted to the inner core, and the outer peripheral surface of the outer core can be inclined radially outward.
Furthermore, a long tape wound around the core for winding the carrier tape, a plurality of storage recesses for storing electronic components formed at intervals in the longitudinal direction of the tape, and a tape in the longitudinal direction of the tape It is also possible to provide a configuration including a plurality of feed holes provided at intervals on at least one side, and a cover tape for preventing the electronic components from falling off may be provided on the surface of the tape.

Here, the winding core in the claims may be hollow or solid. The winding core is not particularly limited to paper, cardboard, metal, resin or the like. The carrier tape includes at least an embossed carrier tape, a punched carrier tape, a surf tape, and the like.

When the carrier tape is provided with a plurality of feed holes, it can be provided on one side or both sides of the longitudinal direction of the tape. Further, the erroneous attachment preventing means is formed by providing a plurality of markings, concave portions such as locking holes, convex portions such as locking claws, etc. on the winding core, flange, winding core and flange. Can do.

  According to the present invention, when winding the band, the peripheral surface of the winding core is inclined in the direction opposite to the inclination of the overlapping portion of the band, so The side part of the belt body is inclined with respect to the peripheral surface of the core, and the winding length is less likely to be different.

According to the present invention, in the case of lap winding of a carrier tape, the inclination angle of the winding core does not become smaller than 0 °, and a constant inclination angle (0 <θ <2θ _c ) can always be maintained. it can. Thereby, there exists an effect that the bending of a carrier tape can be reduced effectively. In addition, when winding the carrier tape, the peripheral surface of the winding core is inclined in the direction opposite to the inclination of the overlapping portion of the carrier tape, so that the inclination of the overlapping portion of the carrier tape can be relaxed. With winding, the side portion of the carrier tape is inclined with respect to the peripheral surface of the winding core, and the winding length and diameter are less likely to be different. Therefore, the winding of the carrier tape can be prevented from being distorted and greatly bent in a certain direction. As a result, an error occurs when the carrier tape pocket is positioned and an electronic component is inserted into the pocket. Can be suppressed.

Also, if a flange is attached to each end face of the winding core, and an erroneous attachment preventing means is provided on at least one of the flange and the peripheral surface of the winding core, the mounting direction and the circumference of the winding core can be reduced. It is possible to grasp the inclination direction of the surface and the setting direction of the take-up reel with respect to various devices and attach it in an appropriate direction. Also, if a carrier tape anti-slip groove is formed in the circumferential direction of the winding core, and this anti-slip groove is arranged from one end of the winding core to the other end, the carrier tape slips. The accompanying collapse can be prevented.

  Furthermore, if the winding core is composed of a cylindrical inner core and a cylindrical outer core fitted to the inner core, and the outer peripheral surface of the outer core is inclined radially outward, the existing core The winding core can be used as the inner core, and cost reduction can be expected.

It is explanatory drawing which shows typically the overlapping winding state of the carrier tape in embodiment of the winding method of the strip | belt body which concerns on this invention. It is explanatory drawing which shows typically the normal winding state of the carrier tape in embodiment of the winding method of the strip | belt body which concerns on this invention. It is explanatory drawing which shows typically the relationship between the winding core which concerns on this invention, and a carrier tape. It is explanatory drawing which shows typically the inclination at the time of the lap | wrapping of the carrier tape in embodiment of the winding method of the strip | belt body which concerns on this invention. It is explanatory drawing which shows typically the core for winding in embodiment of the winding method of the strip | belt body which concerns on this invention. It is a perspective explanatory view showing typically the carrier tape in the embodiment of the winding method of the belt concerning the present invention. It is a perspective explanatory view showing typically a 2nd embodiment of the winding method of the belt concerning the present invention. It is principal part explanatory drawing which shows typically 2nd Embodiment of the winding method of the strip | belt body which concerns on this invention. It is explanatory drawing which shows typically 3rd Embodiment of the winding method of the strip | belt body which concerns on this invention. It is explanatory drawing which shows typically the other marking in 3rd Embodiment of the winding method of the strip | belt body which concerns on this invention. It is explanatory drawing which shows typically 4th Embodiment of the winding method of the strip | belt body which concerns on this invention. It is explanatory drawing which shows typically 5th Embodiment of the winding method of the strip | belt body which concerns on this invention. It is explanatory drawing which shows the winding state of the Example of the winding method of the band which concerns on this invention, and the carrier tape of a comparative example. It is a graph which shows the measurement result of the Example and comparative example of the winding method of the strip which concern on this invention. It is a graph which shows the measurement result of Example 1 of the winding method of the belt concerning the present invention. It is a graph which shows the measurement result of Example 2 of the winding method of the strip concerning the present invention. It is a graph which shows the measurement result of the comparative example 1 of the winding method of the strip | belt body which concerns on this invention. It is a graph which shows the measurement result of the comparative example 2 of the winding method of the strip | belt body which concerns on this invention. It is a graph which shows the measurement result of the comparative example 3 of the winding method of the strip | belt body which concerns on this invention. It is a graph which shows the measurement result of the comparative example 4 of the winding method of the strip | belt body which concerns on this invention. It is explanatory drawing which shows the conventional winding reel typically. It is explanatory drawing which shows the conventional winding core typically.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. A belt winding method according to the present embodiment has different axial diameters and directivity windings as shown in FIGS. A take-up core 1 and a carrier tape 10 traversed and wound around the take-up core 1 and storing a plurality of electronic components are provided. When the electronic components are mounted on a circuit board, the take-up core 1 Then, the carrier tape 10 is rewound and sequentially fed out, and the electronic components of the carrier tape 10 are mounted on the circuit board.

  As shown in FIGS. 1, 2, and 5, the winding core 1 is formed into a hollow substantially truncated cone shape using a molding material containing a predetermined resin, for example, from the left and right ends to the other end. In other words, the circumferential surface 2 is gradually inclined outward in the radial direction along the axial direction, and is set on the drive shaft of the winding device. The molding material of the winding core 1 is not particularly limited, and examples thereof include ABS resin, polystyrene, expanded polystyrene (PSP), polyolefin, and expanded polyolefin that are excellent in moldability and light weight. The left and right end surfaces of the winding core 1 are respectively formed with openings, and disc-shaped flanges 3 are detachably attached thereto.

  When the flange 3 is mounted, a plurality of locking claws are formed to protrude from the end face of the winding core 1, and a locking hole 9 to be locked to each locking claw is formed in the flange 3 or the winding is wound. A plurality of locking grooves may be formed on the end surface of the take-up core 1, and locking claws that lock the locking grooves may be formed on the flange 3.

  As shown in FIGS. 1, 2, and 6, the carrier tape 10 is provided with a long tape 11 having flexibility, and in the longitudinal direction of the tape 11, a bottomed rectangular tube shape that accommodates electronic components is provided. A plurality of pockets 12 are formed in an array, and a plurality of sprocket holes 13 are perforated on one side in the longitudinal direction of the tape 11 for winding by a guide roller 20 slidable in the left-right direction of the winding device. The core 1 is continuously wound on the curved peripheral surface 2 of the winding core 1 while moving in the horizontal direction of the core 1.

  The carrier tape 10 is formed to a length of 1200 m or more by a molding material made of, for example, polystyrene, polyethylene terephthalate, polycarbonate, etc., and conductivity or the like is selectively given as necessary. A cover tape (not shown) is heated, ultrasonically sealed, or detachably adhered to the surface of the tape 11 after the electronic component is stored in the pocket 12, and the cover tape prevents the electronic component from dropping from the pocket 12. To prevent the carrier tape 10 from being peeled off. The electronic component is not particularly limited, and examples thereof include an LED, a ceramic capacitor, a chip resistor, an electrical connector, and a transistor.

  When winding the carrier tape 10, a lap winding (see FIG. 1) in which one side portion of the carrier tape 10 is overlapped and wound on the other side portion of the wound carrier tape 10, and the wound carrier tape 10 is wound. Ordinary winding (see FIG. 2) in which the carrier tape 10 is wound adjacently without overlapping the other side portion is repeated alternately. For example, when the carrier tape 10 is wound from the left end to the right end of the winding core 1, the carrier tape 10 is overwrapped, and when the carrier tape 10 is wound from the right end to the left end of the winding core 1, The carrier tape 10 is normally wound.

Now, the winding core 1 has a circumferential surface 2 tapered in a direction opposite to the inclination of the overlapping portion of the carrier tape 10 (see FIG. 3). The inclination θ of the circumferential surface 2 is 0 <θ. ≦ 2 arctan [carrier tape thickness / traverse pitch] This is because the inclination θ _c of the carrier tape 10 is considered to be θ _c = arctan [carrier tape thickness / traverse pitch] during lap winding (see FIG. 4).

For example the inclination theta _c of the carrier tape 10, the thickness of the carrier tape 10 is 0.25 mm, if the traverse pitch of 5.7 mm, a theta _c ≒ 2.5. Thus, although the optimum inclination θ of the peripheral surface 2 of the winding core 1 varies depending on the thickness of the carrier tape 10, the traverse pitch, and the embossed shape of the product, it is considered that 0 <θ ≦ 2θ _c is appropriate. Specifically, it is 1 ° to 5 °, preferably 1.5 ° to 5 °, more preferably about 1.5 °.

  In the above configuration, when the carrier tape 10 is traversed and wound on the winding core 1 of the winding reel, the empty winding core 1 is fitted to the drive shaft of the winding device, and this winding is performed. The end of the carrier tape 10 is wound around the core 1 and the carrier tape 10 is tensioned around the guide roller 20 of the winding device, and then the winding device is driven to drive the peripheral surface 2 of the winding core 1. In addition, the carrier tape 10 may be wound while moving the carrier tape 10 leftward or rightward.

  Then, the winding core 1 rotates to wind up the carrier tape 10, and the carrier tape 10 is wound on the winding core 1 by alternately repeating lap winding, normal winding, lap winding, normal winding,. The tape 10 traverses and is completely wound up. That is, the carrier tape 10 is lap-wound from the left end portion where the diameter of the winding core 1 is small to the right end portion where the diameter is large, and is normally wound from the right end portion to the left end portion, and these different winding methods are alternated. Repeated.

Therefore, in the case of lap winding of the carrier tape 10, the inclination angle of the winding core 1 does not become smaller than 0 °, and a constant inclination angle (0 <θ <2θ _c ) can always be maintained. Thereby, it can be greatly expected that the bending of the carrier tape 10 is effectively reduced.

  When winding the carrier tape 10, the peripheral surface 2 of the winding core 1 is inclined in a direction opposite to the inclination of the overlapping portion of the carrier tape 10, so that the inclination of the overlapping portion of the carrier tape 10 is remarkably reduced. Thus, the side portions of the carrier tape 10 are not inclined with respect to the peripheral surface 2 of the winding core 1 with the lap winding so that the winding length and the diameter are not different.

  Accordingly, the winding of the carrier tape 10 can be reliably prevented from being bent and greatly bent in a certain direction. As a result, the pocket 12 of the carrier tape 10 is positioned and an electronic component is inserted into the pocket 12. It is possible to suppress and prevent the occurrence of errors when In addition, the cover tape can be easily and easily adhered to the surface of the tape 11 of the carrier tape 10, or the carrier tape 10 wound up when the electronic component is mounted can be smoothly fed out.

  Next, FIGS. 7 and 8 show a second embodiment of the present invention. In this case, the winding core 1 is made up of a cylindrical inner core 4 having a circumferential inclination of 0 °, and The outer peripheral surface 6 of the outer core 5 is inclined in the radially outward direction, and the non-slip groove 7 is formed in the circumferential direction of the inclined outer peripheral surface 6. In addition, a plurality of the anti-slip grooves 7 are arranged in the direction from the one end of the outer core 5 to the other end, that is, in the axial direction, so as to have a substantially stepped shape.

  The inner core 4 may be a new core, but the existing winding core 1 can be diverted and used. The outer core 5 is detachably fitted to the inner core 4 or is bonded and fixed to the inner core 4. The anti-slip groove 7 is formed by notching a step directly on the outer peripheral surface 6 of the outer core 5 or winding a linear body such as a tape or string. The other parts are substantially the same as those in the above embodiment, and thus description thereof is omitted.

  Also in this embodiment, the same effect as the above embodiment can be expected, and the winding core 1 is composed of the separate inner core 4 and outer core 5, so that the existing general-purpose winding core It is obvious that the core 1 can be used as the inner core 4 to reduce the cost. Moreover, since the several anti-skid groove | channel 7 is formed in the outer peripheral surface 6 of the outer core 5, the collapse by the slip of the carrier tape 10 can be prevented.

  Next, FIG. 9 and FIG. 10 show a third embodiment of the present invention. In this case, at least one of the winding core 1 and the flange 3 having directionality has a predetermined significance. The marking 8 shown is formed.

  The marking 8 is formed in a predetermined pattern (for example, a character, a figure, an arrow, etc.) visible on the peripheral surface of the winding core 1 by, for example, a laser marking method, an inkjet method, a pad printing method, a two-color molding method, or the like. It functions to indicate the direction in which the take-up core 1 is attached, the taper direction of the take-up core 1, the direction in which the take-up reel is inserted into the take-up device, or the carrier tape 10 molding machine. The other parts are substantially the same as those in the above embodiment, and thus description thereof is omitted.

  In this embodiment, the same effect as that of the above embodiment can be expected, and the marking 8 is provided on the winding core 1 and the flange 3, so that the inclination direction of the peripheral surface 2 of the winding core 1 can be easily determined. Obviously, it is possible to smoothly proceed with the operation of attaching the take-up reel, and to easily prevent an installation error.

  Next, FIG. 11 shows a fourth embodiment of the present invention. In this case, the attachment engagement with the engaging claws on the end face of the winding core 1 is provided near the center of the pair of flanges 3. A plurality of stop holes 9 are perforated, and the locking hole 9 of the flange 3 on the diameter-expanding side of the winding core 1 is different from the locking hole 9 of the flange 3 on the diameter-reducing side of the winding core 1. It is formed in a shape, and an artificial mistake that attaches the take-up reel in reverse is prevented in advance.

  Each locking hole 9 of the flange 3 on the enlarged diameter side of the winding core 1 is formed in a triangular shape, and each locking hole 9 of the flange 3 on the reduced diameter side of the winding core 1 is formed in a long hole. The other parts are substantially the same as those in the above embodiment, and thus description thereof is omitted.

  Also in this embodiment, the same effect as the above embodiment can be expected, and when the flanges 3 are locked by making the shapes of the locking holes 9 of the pair of flanges 3 different, it is impossible to mount them in the opposite direction. Therefore, it can always be installed in the correct orientation.

  Next, FIG. 12 shows a fifth embodiment of the present invention. In this case, a pair of flanges 3 are provided with locking holes 9 for mounting on the locking claws on the end surface of the winding core 1. A plurality of holes are drilled, and the locking holes 9 of the flange 3 on the diameter expansion side of the winding core 1 and the locking holes 9 of the flange 3 on the diameter reduction side of the winding core 1 are arranged at different positions. In addition, the human error that causes the take-up reel to be mounted in reverse is prevented.

Each locking hole 9 of the flange 3 on the diameter expansion side of the winding core 1 is formed in the vicinity of the boundary between the center portion and the peripheral portion of the flange 3, and each of the flanges 3 on the diameter reduction side of the winding core 1. The locking hole 9 is formed near the center of the flange 3. The other parts are substantially the same as those in the above embodiment, and thus description thereof is omitted.
In this embodiment, the same effect as that of the above embodiment can be expected. Moreover, when the positions of the locking holes 9 of the pair of flanges 3 are made different so that the flanges 3 are locked, the mounting in the reverse direction is not possible. Because it is possible, it can always be mounted in the proper orientation.

  In the above embodiment, the winding core 1 is formed in a hollow substantially truncated cone shape, but may be a solid substantially truncated cone shape. Further, the peripheral surface 2 of the winding core 1 may be tapered outward in the radial direction, and the peripheral surface 2 may be subjected to anti-slip processing such as embossing. In the above-described embodiment, the peripheral surface 2 of the winding core 1 is inclined outward in the radial direction. However, the peripheral surface 2 of the winding core 1 may be inclined outward in the radial direction with a curvature.

  Further, the circumferential surface 2 of the winding core 1 is inclined outward in the radial direction, and a non-slip groove 7 is formed in the circumferential direction of the inclined circumferential surface 2. It can also be arranged in the direction. Further, the winding core 1 and the flange 3 may be integrated, or the flange 3 may be formed in a polygon other than a disk or other shapes.

  Furthermore, a required number of through holes are drilled in the pair of flanges 3 respectively, and a separate plug that is detachable is selectively inserted into the through holes of the flange 3 on the diameter expansion side or the diameter reduction side of the winding core 1. When the take-up reel is set in the take-up device, the inserted plug can be detected by a sensor. In this way, when the take-up reel is set in the take-up device, the plug inserted into the flange 3 can be detected by the sensor, and an alarm can be sounded when the take-up reel is set due to an error. Can be set appropriately.

Hereinafter, the Example of the winding method of the strip | belt body which concerns on this invention is described with a comparative example.
Example 1
First, an empty winding core was fitted to the drive shaft of the winding device, the end of the carrier tape was wound around the winding core, and the carrier tape was tensioned and wound around the guide roller of the winding device. . On the peripheral surface of the winding core, a taper of 1.5 ° was formed in the radially outward direction. The carrier tape used was a type in which the tape width was 8 mm, the depth of each pocket was 1.42 mm, and a plurality of sprocket holes were perforated at one side in the longitudinal direction of the tape.

  When the carrier tape is wound around the guide roller of the winding device, the winding device is driven to wind the carrier tape around the winding core while moving the carrier tape leftward or rightward to measure the bending of the carrier tape. The measurement results are summarized in the graphs of FIGS. When winding the carrier tape, as shown in FIG. 13, the overlap winding and the normal winding of the carrier tape were alternately repeated.

At the time of lap winding, the inclination θ _{c of the} carrier tape was θ _c ≈2.5. Moreover, in measuring the bending of the carrier tape, the measurement was started from the end portion of the overlapped winding layer, and finished by measuring to the original end portion of the normal winding layer. The bending of the carrier tape was measured as positive when one side of the sprocket hole was extended and negative when the other side without the sprocket hole was extended. The left end of FIG. 14 indicates the measurement start point, the dotted line near the center indicates the vicinity of the opposite flange, and the right end indicates the measurement start point side flange. Moreover, the dotted line near the center of FIG. 15 shows the change point from the overlapping winding of the carrier tape to the normal winding.

  As a result of measuring the bending of the carrier tape, the bending of the carrier tape was very small and a very good result was obtained.

Example 2
Basically the same as in Example 1, but a 5 ° taper was formed in the radially outward direction on the peripheral surface of the winding core. Otherwise, the bending of the carrier tape was measured in the same manner as in Example 1, and the measurement results are summarized in the graphs of FIGS. The dotted line near the center of FIG. 16 shows the change point from the overlapping winding of the carrier tape to the normal winding.
As a result of measuring the bending of the carrier tape, the bending of the carrier tape was very small and a very good result was obtained.

Comparative Example 1
Basically the same as in Example 1, but a taper of 8 ° was formed radially outward on the peripheral surface of the winding core. Otherwise, the bending of the carrier tape was measured in the same manner as in Example 1, and the measurement results are summarized in the graphs of FIGS. The dotted line near the center of FIG. 17 shows the change point from the overlapping winding of the carrier tape to the normal winding.
A result of measuring the bending of the carrier tape, the inclination of the peripheral surface of the core for winding θ is larger than 2 [Theta] _c, the carrier tape is bent to the negative side as a whole, to give undesirable results.

Comparative Example 2
Basically the same as in Example 1, but the taper of the peripheral surface of the winding core was set to 0 °. That is, a conventional general-purpose winding core was used, and the bending of the carrier tape was measured in the same manner as in Example 1, and the measurement results were summarized in the graphs of FIGS. A dotted line in the vicinity of the center in FIG. 18 indicates a change point from the overlap winding of the carrier tape to the normal winding.
As a result of measuring the bending of the carrier tape, the carrier tape bent and an undesirable result was obtained.

Comparative Example 3
Basically the same as in Example 1, but a reverse taper of −1.5 ° was formed radially inward on the peripheral surface of the winding core. Otherwise, the bending of the carrier tape was measured in the same manner as in Example 1, and the measurement results are summarized in the graphs of FIGS. A dotted line in the vicinity of the center in FIG. 19 indicates a change point from the overlap winding of the carrier tape to the normal winding.
As a result of measuring the bending of the carrier tape, the carrier tape was bent more than when it was 0 °, and an undesirable result was obtained.

Comparative Example 4
Basically the same as in Example 1, but a taper of -3 ° opposite direction was formed on the peripheral surface of the winding core. Otherwise, the bending of the carrier tape was measured in the same manner as in Example 1, and the measurement results are summarized in the graphs of FIGS. A dotted line in the vicinity of the center in FIG. 20 indicates a change point from the overlap winding of the carrier tape to the normal winding.
As a result of measuring the bending of the carrier tape, the carrier tape was bent more to the plus side than the case of 0 °, and an undesirable result was obtained.

If the above Examples and Comparative Examples, the inclination of the circumferential surface of the core for winding in the range of 0 <θ ≦ 2θ _c, and confirmed that the bending of the carrier tape can be greatly suppressed.

  The strip winding method according to the present invention is used in the field of manufacturing electrical parts, electronic parts, precision parts and the like.

DESCRIPTION OF SYMBOLS 1 Winding core 1A Winding core 2 Peripheral surface 2A Peripheral surface 3 Flange 4 Inner core 5 Outer core 6 Outer peripheral surface 7 Anti-slip groove 8 Marking (Incorrect mounting prevention means)
9 Locking hole (Incorrect mounting prevention means)
10 Carrier tape (band)
11 Tape 12 Pocket (storage recess)
13 Sprocket hole (feed hole)

Claims (1)

It is a winding method of a belt body that traverses and winds a carrier tape on a curved peripheral surface of a winding core,
The circumferential surface is inclined radially outwardly from one end portion of the winding core toward the other end portion, and the inclination θ of the circumferential surface is based on 0 <θ ≦ 2 arctan ( carrier tape thickness / traverse pitch). Shall be
When the carrier tape is traversed and wound from the circumferential surface on the one end side with a small diameter of the winding core to the circumferential surface on the other end side with a large diameter, the carrier tape is placed on the side of the wound carrier tape. When the carrier tape is traversed and wound from the circumferential surface on the other end side of the winding core to the circumferential surface on the one end side, the side portions are overlapped and wound on the side portion of the wound carrier tape. Wind up with normal winding without overlapping the sides of the carrier tape,
A method of winding a band , wherein when the carrier tape is overwrapped, the inclination angle of the winding core is always set to a constant inclination angle .

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