JPH0676387U - Braider - Google Patents

Abstract

(57) [Summary] [Construction] The present invention relates to a braider BR provided with a braid having a composition and a cutting device S for cutting and separating a yarn connected to the braid. [Effect] The braid or the yarn connected to the braid can be reliably cut and the cutting time can be shortened. Further, since the tension applied to the braid when the braid or the yarn connected to the braid is cut can be reduced, it is possible to prevent the shape of the braid from collapsing.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a braider for forming various braids by assembling a plurality of yarns or fiber bundles (hereinafter, simply referred to as “yarns”).

[0002]

[Prior art]

 Conventionally, various braiders are known in which a braid is formed by assembling a plurality of yarns or fiber bundles on a mandrel having a circular or rectangular cross section.

[0003]

[Problems to be solved by the device]

 However, in the conventional braider, there is no efficient cutting device with excellent workability for cutting the braid or the yarn connected to the braid whose composition has been completed. There is a problem that the time becomes long, and when the braid or the yarn connected to the braid is cut, excessive tension is applied to the yarn and the shape of the braid collapses.

An object of the present invention is to solve the problems of the conventional braider as described above and to provide an automated braider having excellent productivity or workability.

[0005]

[Means for Solving the Problems]

 According to the present invention, in order to achieve the above-mentioned object, a braider is provided with a cutting device for cutting and separating a braid having a composition and a yarn connected to the braid.

[0006]

【Example】

 Examples of the present invention will be described below, but the present invention is not limited to these examples as long as the gist of the present invention is not exceeded.

First, referring to FIG. 1 which is a front view of the braider of the present invention and FIG. 2 which is a side view thereof, the overall configuration of the braider of the present invention and each device and each member constituting the braider of the present invention Will be outlined. 1, 2 and 3, the rectangular portion shown by the dotted line on the upper portion of the bobbin carrier C is shown by omitting a yarn guide portion c3 described later.

The braider BR is composed of a braider body Bb and a mandrel device Bm. The braider body Bb is formed in the curved upper plate U and the upper plate U having a predetermined radius of curvature R, which is arranged in a substantially cylindrical machine base Fb having a horizontal axis and an opening e on one side. From the bobbin carrier C traveling along the track, the drive device D for traveling the bobbin carrier C along the track, the composition position stabilizing guide member G, the cutting device S, and the bobbin supporting device I for the middle thread or the reinforcement. The mandrel device Bm is composed of a machine base Fm and a mandrel moving device M.

The above-mentioned devices and members will be described below. First, mainly using FIG. 3 which is an enlarged front view of the drive device D for causing the bobbin carrier C including the I-I cross section of FIG. 2 and FIG. 2 to travel along the track, FIG. A drive device D for causing the upper plate U and the bobbin carrier C to travel along the track will be described.

As shown in FIG. 2, the curved upper plate U is appropriately fixed to a substantially cylindrical machine frame f1 arranged in a substantially cylindrical machine base Fb with a predetermined interval. It is attached by members f2 and f2 ', and a known track is provided in the upper plate U in the circumferential direction. f3 is a hollow bolt attached to the machine frame f1 by a nut f4, a gear d1 is fitted to the hollow bolt f3 via an appropriate bearing f5, and the gear d1 has a bobbin to be described later on its upper surface. An impeller d2 having a groove into which the engaging shaft c1 of the carrier C fits is fixed so as to rotate integrally with the gear d1.

Y is a yarn that is unwound from the bobbin placed on the bobbin carrier C and heads to the composition point P on the mandrel m supported by the mandrel device Bm, and y is a substantially cylindrical machine base. After being unwound from the bobbin carrier C arranged substantially horizontally on the side wall Fb ′ of Fb, and set in a substantially perpendicular direction by the guide roller f6 attached to the machine base Fb, after being inserted into the hollow bolt f3. , A yarn for a middle yarn or a yarn for reinforcement (hereinafter, simply referred to as “a yarn for a middle yarn”) toward the composition point P on the mandrel m.

The gear shaft d1 is rotated by an appropriate driving means such as a motor to rotate the impeller d2, whereby the engagement shaft of the bobbin carrier C fitted in the groove formed in the impeller d2. The c1 is moved so that the bobbin carrier C travels along the track. As described above, the bobbin carrier C is caused to travel along the track formed in the curved upper plate U, whereby a large number of yarns Y are interlaced to form a braid on the mandrel m. If necessary, the yarn y for the middle thread is wound from the bobbin carrier C arranged substantially horizontally on the side wall Fb ′ of the machine base Fb, and the yarn is rewound from the bobbin carrier C running along the track. Intertwist with Article Y to form a braid.

FIG. 4 is an enlarged front view of a drive device D showing another embodiment of the drive device D for causing the bobbin carrier C to travel along the track, and d1 ′ is different from the gear d1 described above. The disk-shaped friction roller has no teeth and is fitted to the hollow bolt f3 via the bearing f5 like the gear d1. Further, the impeller d2 'is fixed to the friction roller d1' similarly to the gear d1.

D3 is an impeller fitted to the hollow bolt f3 via a bearing f5 and having a flange portion d3 ′ at its lower end. The outer peripheral surface of the impeller d3 is suitable along the axial direction of the impeller d3. A number of key grooves d3 ″ are provided. D4 is a disk-shaped sliding friction roller fitted in the impeller d3, and the sliding friction roller d4 is formed in the impeller d3. A ridge d4 'that fits into the key groove d3 "is provided so as to project, and is configured to be slidable in the axial direction of the impeller d3 with respect to the impeller d3. A compression spring d5 is arranged between the lower surface of the sliding friction roller d4 and the collar portion d3 ′ of the impeller d3, and is configured to urge the sliding friction roller d4 upward. There is.

As shown in FIG. 4, the friction roller d1 ′ and the sliding friction roller d4 are alternately arranged, and the friction roller d1 ′ is made of iron or a hard synthetic resin, and It is preferable that the sliding friction roller d4 is formed of urethane rubber or the like having a large friction coefficient.

By rotating and driving an appropriate friction roller d1 ′ by an appropriate driving means such as a motor, a sliding friction roller d4 that is in frictional contact with the friction roller d1 ′ is driven. . Since the sliding friction roller d4 is biased upward by the compression spring d5, the sliding friction roller d4 is constantly pressed against the friction roller d1 'at an appropriate pressure, so that the driving force is reliably transmitted.

Since the bobbin carrier C is made to travel by the friction roller d1 ′ and the sliding friction roller d4 as described above, the generation of noise due to the backlash of the teeth of the gear d1 is prevented. be able to.

As shown in FIGS. 1 and 2, the bobbin carrier C is arranged along the track formed on the peripheral surface of the curved upper plate U, and is mounted on the bobbin carrier C. The yarns Y drawn out from the placed bobbin in the axial direction of the bobbin are configured to gather at the center of the curved upper plate U. The position of the mandrel m is controlled so that the composition point P of the braid formed on the mandrel m attached to the mandrel device Bm described later is located at the center of the curved upper plate U. It

Next, FIG. 5 which is a front view of the bobbin carrier C, FIG. 6 which is a front view of the bobbin holding portion, FIG. 7 which is a II-II cross-sectional view of FIG. 6, and the rotation portion of the yarn guide portion. The bobbin carrier C will be described with reference to FIG. 8 which is a perspective view.

In FIG. 5, c2 is an upper flange, and a mast c4 having a U-shaped cross section and a spindle c5 having a yarn guide portion c3 rotatably arranged at the tip end thereof are erected on the upper flange c2. There is. A bobbin c6 around which the yarn Y is wound is inserted in the spindle c5, and a flyer c8 having a bearing c7 is rotatably fitted in the tip of the spindle c5.

As shown in FIG. 6 and FIG. 7, a slit c9 extending in the vertical direction is provided at the tip of the spindle c5, and a substantially triangular bulging portion is provided at the tip in the slit c9. A pair of hook members c11, c11 'having c10, c10' is arranged, and the lower ends of the hook members c11, c11 'are pivotally supported by a shaft c12 attached to a spindle c5. Respective concave portions c13 and c13 'are provided near the middle of the hook members c11 and c11', respectively. Since the compression spring c14 is inserted into the recesses c13, c13 'of the hook members c11, c11', the hook members c11, c11 'are always urged in directions away from each other. The hook members c11 and c11 'are configured so as not to separate from each other by a predetermined stopper (not shown). Therefore, when the bobbin c6 or the fryer c8 is inserted into the bulging portions c10, c10 'of the hook members c11, c11', the hook members c11, c11 'rotate in the direction toward each other, and the bobbin c6 or the fryer c8. Is configured to be mounted on the spindle c5. When the bobbin c6 or the fryer c8 is mounted on the spindle c5, the compression spring c14 expands the bulged portions c10, c10 'of the hook members c11, c11' in a direction away from each other, and the bobbin c6 or the fryer c8 is pulled out from the spindle c5. It is configured so as not to run out.

A cylindrical bobbin cover c6 'is attached to the upper flange c2. The cylindrical bobbin cover c6 'pulls out or hangs down the yarn Y wound around the bobbin c6 when the bobbin carrier C is tilted or positioned upside down, so that the bobbin carrier c6' can be attached to an adjacent bobbin. This prevents troubles such as being entangled with the wound yarn or entangled with other members of the braider.

A tension washer c16, a guide roller c17, a slack eliminating member c18, and a guide roller c19 are arranged in this order from the bottom on the substantially U-shaped frame c15 of the yarn guide portion c3 arranged at the tip of the mast c4. It is arranged. A guide portion c20 having a guide roller c20 ′ is attached to the tip of the slack eliminating member c18, one end of a coil spring c21 is attached to the other end of the slack eliminating member c18, and the other end of the coil spring c21 is attached. The end is attached to the frame c15. The slack eliminating member c18 is pivotally supported on the frame c15 via a shaft member c22 ′ attached to a bearing member c22 arranged on the frame c15, and is constantly supported by a coil spring c21 in FIG. It is biased to rotate in the direction. Therefore, when the yarn Y unwound from the bobbin c6 becomes loose, the slack eliminating member c18 rotates counterclockwise about the shaft member c22 'in FIG. 5 to absorb the looseness of the yarn Y. Is configured. Further, adjacent to the tension washer c16 and the guide roller c19, the frame c15 has through holes c16 'and c19' through which the yarn Y is inserted.

As shown in FIG. 8, the lower horizontal portion c15 ′ of the substantially U-shaped frame c15 extends through the cutout portion of the front end portion of the mast c4, and the end portion of the lower horizontal portion c15 ′ of the frame c15. Is pivotally supported by a shaft member c4 'arranged at the tip of the mast c4. The vicinity of the end portion of the lower horizontal portion c15 ′ of the frame c15 is placed on the lower end edge c4 ″ of the cutout portion of the tip portion of the mast c4 so that the lower horizontal portion c15 ′ of the frame c15 maintains a horizontal state. The width w1 of the vertical portion c15 ″ of the frame c15 is configured to be narrower than the width w2 of the cutout portion at the tip of the mast c4. A vertically elongated through hole c23 is formed in the vertical portion c15 ″ of the frame c15, and a guide knob c24 ′ of a slider c24 arranged behind the vertical portion c15 ″ of the frame c15 is formed in the through hole c23. It is fitted. The width w3 of the slider c24 is substantially equal to the width w4 of the mast c4, and the slider c24 is normally placed on the notch step c25 at the tip of the mast c4.

Therefore, when the slider c24 is placed on the notch step c25 at the tip of the mast c4, the frame c15 is a slider c24 having a width w3 substantially the same as the width w4 of the mast c4. It does not rotate in the clockwise direction in FIG. 5 because it acts as a stopper. On the other hand, when the slider c24 is moved upward along the through hole c23 formed in the vertical portion c15 ″ of the frame c15 and the lower end of the slider c24 is disengaged from the tip of the mast c4, the frame c15 is In FIG. 5, it is configured so that it can be rotated clockwise.

With the above configuration, when the bobbin c6 or the fryer c8 is mounted on the spindle c5, the slider c24 is moved upward and the frame c15 is rotated clockwise in FIG. As a result, a space is created above the spindle c5, and the bobbin c6 or the fryer c8 is mounted on the spindle c5. After mounting the bobbin c6 or the fryer c8 on the spindle c5, rotate the frame c15 counterclockwise in FIG. 5, and then place the slider c24 on the notch step c25 at the tip of the mast c4. Thus, the frame c15 is held by the tip of the mast c4 so as not to rotate. Although not shown, the slider c24 is preferably configured to be biased downward by a suitable means such as a spring.

As described above, when the bobbin c6 is mounted on the spindle c5, the space above the spindle c5 can be completely emptied, so that the large bobbin c6 having a large number of the yarns Y wound thereon can be used as the bobbin carrier. Since it is possible to place it on C, the bobbin c6 can be replaced less frequently than the conventional one, and the productivity of the braider BR can be improved.

In FIG. 5, c26 is a substantially elliptical lower flange, and c27 is disposed between an upper flange c2 and a lower flange c26 which are slidably fitted into a track formed in the upper plate U. It is a guide part. The bobbin carrier C is configured to hold the upper plate U between the upper flange c2 and the lower flange c26 so that the bobbin carrier C can run along the track while being held substantially perpendicular to the upper plate U.

FIG. 9 which is a front view of the bobbin carrier C and FIG. 10 which is a sectional view taken along the line III-III of FIG. 9 show another embodiment of the bobbin carrier C, and the bobbin carrier C shown in FIG. Instead of the cylindrical bobbin cover c6 'of the bobbin carrier C described above, an elastic plate c28 made of synthetic resin or the like that contacts the surface of the yarn Y wound on the bobbin c6 is attached to the mast c4. It has the same structure as the bobbin carrier C described above. By constantly contacting the elastic plate c28 with the surface of the yarn Y wound around the bobbin c6, the bobbin carrier C is inclined or positioned upside down like the cylindrical bobbin cover c6 ′ described above. At this time, the yarn Y wound on the bobbin c6 is pulled out or droops, and is entangled with the yarn wound on the adjacent bobbin or entangled with other members of the braider. It is to prevent such troubles.

11 is a front view of the bobbin supporting device I for the middle thread or the reinforcing bobbin supporting device I, and FIG. 12 is a sectional view taken along the line IV-IV of FIG. 11. Use to explain. A bobbin carrier holding member c29 having a longitudinal groove c29 'having a width substantially equal to the diameter of the guide portion c27 into which the guide portion c27 of the bobbin carrier C can be inserted is fixed to the side wall Fb' of the machine base Fb. ing. Therefore, by inserting the guide portion c27 of the bobbin carrier C into the longitudinal groove c29 ′ of the bobbin carrier holding member c29 and holding the bobbin carrier holding member c29 by the upper flange c2 and the lower flange c26, the bobbin carrier C can be moved to the position shown in FIG. As shown in FIG. 2, it is configured so that it can be held in a substantially horizontal state.

Next, the composition position stability guide member G will be described with reference to FIG. 2 and FIG. 13 which is a front view of the composition position stability guide member G. The composition position stability guide member G is different from the first composition position stability guide member g1 and the first composition position stability guide member g1 attached to the frame g1 ′ extending substantially horizontally from the intermediate side wall Fb ″ of the machine base Fb. The second composition position stabilizing guide member g2 is attached to the tip of a frame g2 'which is erected on the floor member Fr arranged at a predetermined interval.

The first composition position stability guide member g1 and the second composition position stability guide member g2 are moved along the lateral direction of the bobbin carrier C that travels while meandering along the track formed in the upper plate U. The swaying yarn Y is guided by the first composition position stability guide member g1 and the second composition position stability guide member g2 which are arranged at a predetermined interval, and the composition point is substantially constant by regulating the swaying. By maintaining the composition point at a substantially constant position in this way, a stable composition is realized without the yarn Y to be composed being entangled in an irregular state near the composition point. Therefore, it is possible to manufacture a braid with a uniform braid having a uniform shape.

Further, by disposing the composition position stabilizing guide member G, when the mandrel m is moved to the right in FIG. 2 after the composition is completed, the composition is performed by the second composition position stabilizing guide member g2. A large number of yarns Y connected to the braid can be bundled, and the yarns Y can be effectively cut by the cutting device S described later.

There are various composition position stability guide members G that achieve the above functions, and an example of the composition position stability guide member G will be described with reference to FIG. Since the first composition position stability guide member g1 and the second composition position stability guide member g2 are preferably formed in the same shape, only the shape of the first composition position stability guide member g1 will be described with reference to FIG. .

The composition position stabilizing guide member G shown in FIG. 13 (a) is composed of a circular guide member g3 and horizontal members g4 that extend in a substantially horizontal direction and are arranged at predetermined intervals. This is applied to a case where a braid is formed on a T-shaped mandrel m as shown in FIG. 13 (b).

Further, the composition position stability guide member G shown in FIG. 13 (c) has a cross shape formed by four substantially L-shaped guide members g5 arranged inside a circular guide member g3. Is formed so that the braid is formed on the mandrel m in which the cross-shaped members are orthogonal to each other as shown in FIG. 13 (d). is there.

Next, mainly a side view including a partial cross section of the cutting device S, FIG. 15 which is a partially enlarged front view of the cutting device S, and a side face of the cutting device S opposite to FIG. The cutting device S will be described with reference to FIG. As shown in FIG. 2, the cutting device S is arranged at the lower end portion of the frame s1 hanging on the front surface of the machine base Fb, and the motor s3 with the reduction gear s2 is arranged on the frame s1. There is. A pulley s5 is attached to the output shaft s4 of the motor s3 that does not have the speed reducer s2 and rotates at high speed, and a substantially egg-shaped cam s7 is installed to the output shaft s6 that is decelerated by the speed reducer s2 and rotates at low speed. It is worn.

A lever s9 is pivotally attached to the output shaft s4 that rotates at a high speed via a bearing s8. Since the lever s9 is pivotally attached to the output shaft s4 via a bearing s8, rotation of the output shaft s 4 It is configured not to be affected by. A horizontal shaft s10 is attached to the free end of the lever s9, and a pulley s13 to which a disc cutter s12 is attached via a bearing s11 is attached to one end of the horizontal shaft s10. A guide roller s12 'is attached to the other end of the shaft s10 via a suitable bearing. Further, as shown in FIG. 15, a guide member s14 having a horizontal guide groove s14 'which is formed wider toward the tip end is attached to the free end of the lever s9. There is. A belt s15 is stretched around a pulley s5 attached to an output shaft s4 which rotates at a high speed and a pulley s13 pivotally attached to one end of a horizontal shaft s10. The pulley s5 and the belt s15 are fastened by a high speed rotation of the output shaft s4. The pulley s13 is rotated via the pulley s13, and thus the disc cutter s12 attached to the pulley s13 is rotated at a high speed.

On the other hand, a horizontal shaft s16 is attached to the lower end of a frame s1 hanging on the front surface of the machine base Fb, and a lever s17 is pivotally attached to the horizontal shaft s16. As shown in FIG. 16, at the end of the substantially horizontal portion s17 ′ of the lever s17, the other end of the coil spring s18 having one end attached to the frame s1 is attached. It is configured so as to urge it clockwise in FIG. 16 about the horizontal axis s16.

A long hole s19 is formed at the tip of the substantially vertical portion s17 ″ of the lever s17, and one end of a horizontal shaft s10 attached to the free end of the lever s9 is fitted into the long hole s19. The guide roller s12 'is attached to the horizontal shaft s20 attached to the middle of the lever s17, and the substantially egg-shaped cam s7 attached to the output shaft s6 rotating at a low speed. The cam follower s21 that is in pressure contact is attached.As described above, since the lever s17 is biased clockwise by the coil spring s18 in FIG. It is configured to press.

The operation of the cutting device S configured as described above will be described below. When the composition of the braid is completed on the mandrel m, and the mandrel moving device M of the mandrel device Bm described later moves the mandrel m horizontally beyond the disk cutter s12 of the cutting device S in the right direction in FIG. A large number of yarns Y are also bent and converged by the second composition position stability guide member g2 of the composition position stability guide member G while moving horizontally to the right.

When a large number of yarns Y connected to the braid that is bent and focused by the second composition position stability guide member g2 reach the vicinity of the disk cutter s12 of the cutting device S, the motor s3 rotates at high speed. The disk cutter s12 rotates at high speed via the pulley s5, the belt s15, and the pulley s13 attached to the output shaft s4. On the other hand, the substantially egg-shaped cam s7 rotates with the rotation of the output shaft s6 that rotates at a low speed by the motor s3 via the reduction gear s2, and the lever s17 is moved from the standby position shown by the chain double-dashed line in FIG. Pivot towards the operating position indicated by the solid line.

With the clockwise rotation of the lever s17 in FIG. 16, the lever s9 also moves through the guide roller s12 ′ fitted in the elongated hole s19 of the lever s17, similarly to the lever s17. At clockwise. Note that the lever s9 is omitted in FIG. By the rotation of the lever s9, a large number of yarns connected to the braid which is bent and converged by the second composition position stabilizing guide member g2 is inserted into the horizontal guide groove s14 ′ of the guide member s14 attached to the tip of the lever s9. The yarn Y is guided and brought into contact with the disk cutter s12 attached to the pulley s13 and rotating at high speed to cut a large number of yarns Y connected to the braid.

After the many yarns Y connected to the braid are cut, the lever s17 is rotated counterclockwise in FIG. 16 by the substantially egg-shaped cam s7 to return to the standby position shown by the chain double-dashed line. . Along with the counterclockwise rotation of the lever s17, the lever s9 also rotates counterclockwise and returns to the standby position. The state where the lever s17 and the lever s9 have returned to the standby position is detected by an appropriate detection means (not shown), and the driving of the motor s3 is stopped.

In the above description, the case where a large number of yarns Y connected to the braid is cut has been described, but it is also possible to cut the long braid itself.

Next, the mandrel device Bm will be described mainly with reference to FIG. 17 which is a side view of the mandrel device Bm and FIG. 18 which is a schematic enlarged plan view of the mandrel moving device M.

The machine base Fm of the mandrel device Bm is arranged on the front surface of the braider body Bb as shown in FIGS. 1 and 2, and the upper part of the machine base Fm is inside the braider body Bb. A horizontal movement frame b1 is arranged which is horizontally movable toward the approximate center of a curved upper plate U on which the arranged track is formed. Recesses b 2 are provided on both side walls of the horizontal moving frame b 1, and the recess b 2 has a guide pivotally attached to a horizontal shaft arranged on the upper part of the machine base Fm as shown in FIG. The rollers b3, b3 'and the guide rollers b4, b4' pivotally mounted on the vertical axis are fitted.

A rack b5 is attached to the lower part of the horizontal moving frame b1 in parallel with the horizontal moving frame b1, and a forward / reverse rotatable motor b6 attached to the machine base Fm is attached to the rack b5. The pinion b7 attached to the output shaft b6 'of the above is screwed. Therefore, the pinion b7 is rotationally driven by driving the motor b6 that can rotate in the normal and reverse directions, and the rack b5 screwed with the pinion b7 is horizontally driven to guide the guide rollers b3, b3 'and the guide roller b4. , B4 ′, the horizontal movement frame b1 is horizontally moved.

A fan-shaped frame b8 is attached to the tip of the horizontal movement frame b1, and a motor b9 capable of rotating in the normal and reverse directions is arranged on the fan-shaped frame b8. A pinion b10 is attached to the output shaft b9 'of the motor b9 capable of rotating in the forward and reverse directions.

As shown in FIG. 17, horizontal axes b11 and b12 are attached to the tip end of the horizontal moving frame b1 and the fan-shaped frame b8, and the horizontal axes b11 and b12 are respectively attached. , Guide rollers b13, b14 are attached, a vertical shaft b15 is provided upright on the fan-shaped frame b8, and a guide roller b16 is attached to the vertical shaft b15. In addition, such guide rollers b13, b14, b16 are arranged in an appropriate number along the longitudinal direction of the fan-shaped frame b8 so that the fan-shaped moving member b17 described later can be stably held. .

As shown in FIG. 17, the fan-shaped moving member b17 is composed of a frame member having a substantially rectangular cross section, and is suitable for horizontal or vertical direction from the outer wall of the fan-shaped moving member b17. By projecting a certain number of edges, the rail members b18, b19, b20 to which the guide rollers b13, b14, b16 arranged on the tip of the horizontal moving frame b1 and the fan-shaped frame b8 described above are fitted are formed. To do. Further, a fan-shaped rack b22 is attached to a vertical shaft b21 hanging from a lower side wall of the fan-shaped moving member b17, and the fan-shaped rack b22 has an output shaft b9 ′ of the above-described forward / reverse rotatable motor b9. The pinion b10 attached to is screwed. Therefore, the pinion b10 is rotationally driven by the rotation of the motor b9 that can rotate in the normal and reverse directions, and the fan-shaped rack b22 screwed to the pinion b10 is driven to move the fan-shaped moving member b17 to the fan-shaped moving member b17. The tip ends of the horizontal moving frame b1 fitted to the rail members b18, b19, b20 and the guide rollers b13, b14, b16 arranged on the fan-shaped frame b8 are moved horizontally while being held in a horizontal state.

As shown in FIG. 18, the pulleys b23 and b23 ′ are rotatably attached to both ends of the fan-shaped moving member b17 in the longitudinal direction, and the pulleys b23 and b23 ′ are disposed between the pulleys b23 and b23 ′. An endless belt b24 is stretched around. Then, the endless belt b24 is fixed at one place to a frame b25 'attached to a vertical shaft b25 that is erected at the tip of the horizontal moving frame b1 as shown in FIG. In another place, it is fixed to a mandrel support moving member b26 described later.

Next, the mandrel support moving member b26 will be described. As shown in FIG. 17, the mandrel support moving member b26 is provided with a vertical shaft b28 having a guide roller b27 attached to its tip and a horizontal shaft b30 having a guide roller b29 attached to its tip. The guide rollers b27, b29 are fitted to the rail members b31, b32 formed by an appropriate number of edges protruding horizontally or vertically from the outer wall of the fan-shaped moving member b17 described above. The mandrel support moving member b26 is configured to be horizontally movable along the rail members b31 and b32 of the fan-shaped moving member b17. The guide rollers b27, b29 are arranged in an appropriate number on the mandrel support moving member b26 so as to be stably held by the rail members b31, b32 of the fan-shaped moving member b17.

Further, a vertical frame b33 is hung on the mandrel support moving member b26, and one portion of the endless belt b24 is fixed to the vertical frame b33 as described above. In FIG. 18, point X indicates that the endless belt b24 is fixed to a frame b25 ′ attached to a vertical axis b25 that is erected at the tip of the horizontal moving frame b1, and point Z is the point. It shows that the endless belt b24 is fixed to the vertical frame b33 of the mandrel support moving member b26.

Further, b34 is a supporting rod detachably attached to the mandrel support moving member b26, and a mandrel mounting plate b34 'is attached to the tip end of the supporting rod b34. The support rod b34 is attached to the support frames b26 'and b26 "provided upright on the mandrel support moving member b26 by an appropriate fixing means.

The operation of the mandrel device Bm 1 which controls the movement of the mandrel m during the composition of the braid will be described below. Horizontal movement for moving the mandrel m horizontally toward and away from the curved upper plate U having a track formed in the braider body Bb. The horizontal movement of the frame b1 is described above. Thus, the pinion b7 is rotationally driven by driving the motor b6 capable of rotating in the forward and reverse directions, and the rack b5 screwed to the pinion b7 is horizontally driven.

Next, the movement of the mandrel m in a direction substantially orthogonal to the horizontal movement toward or away from the curved upper plate U (direction orthogonal to the paper surface of FIG. 7) will be described. . From the state shown by the solid line in FIG. 18, when the pinion b10 is rotated counterclockwise in FIG. 18 by the rotation of the motor b9 capable of rotating in the forward and reverse directions, the fan-shaped rack b22 screwed to the pinion b10. Is driven, and the fan-shaped moving member b17 moves downward in FIG.

When the fan-shaped moving member b17 moves downward and the pulley b23 attached to the fan-shaped moving member b17 also moves downward, the endless belt b24 is fixed to the tip of the horizontal moving frame b1 at the point X. Therefore, the endless belt b24 on the opposite side across the pulley b23 is pulled downward in FIG. 18 to rotate the endless belt b24 counterclockwise. Since the mandrel support moving member b26 is fixed to the endless belt b24 at the point Z, the mandrel support moving member b26 also moves downward in FIG. 18 when the endless belt b24 rotates counterclockwise. Become. At this time, with the above configuration, the mandrel support moving member b26 is moved twice as much as the moving amount of the pulley b23, and the mandrel support moving member b26 can be moved quickly.

Further, when the pinion b10 is rotated counterclockwise in FIG. 18 by the rotation of the motor b9 capable of rotating in the normal and reverse directions, the fan-shaped rack b22 screwed to the pinion b10 is driven, and the fan-shaped moving member. 18, b17 moves further downward, and the mandrel support moving member b26 is configured to be rotatable to the lowermost position shown by the chain double-dashed line in FIG. Further, in order to move the mandrel support moving member b26 upward from the lowermost position shown by the chain double-dashed line, the forward / reverse rotatable motor b9 is reversely rotated and the pinion b10 is rotated clockwise in FIG. Let

As described above, the attitude of the mandrel m can be freely two-dimensionally controlled by the horizontal movement of the horizontal movement frame b1 and the movement of the mandrel support movement member b26. It is also possible to control the mandrel m three-dimensionally by disposing an appropriate actuator or the like on the mandrel mounting plate b34 'attached to the tip of the mandrel and attaching the mandrel m to the output shaft of the actuator or the like. .

FIG. 19 is a plan view showing a means for attaching the mandrel m to the mandrel mounting plate b34 '. In FIG. 19, b35 is a peg provided upright on the mandrel mounting plate b34 ′, and balls b37 and b37 ′ are freely retractable with a compression coil spring b36 sandwiched in a through hole b35 ′ formed in the peg b35. A peg b35 is provided with a knob b38 at the base thereof. On the other hand, in the vicinity of the open end of the hollow mandrel m, a circumferential groove b39 into which the balls b37 and b37 'provided on the peg b35 can be fitted is bored, and the open end of the hollow mandrel m is also formed. A groove b40 into which a knob b38 arranged at the base of the peg b35 can be inserted is formed in the portion. Therefore, by inserting the hollow mandrel m into the peg b35 and fitting the balls b37 and b37 'provided in the peg b35 into the circumferential groove b39 formed near the open end of the hollow mandrel m. By easily attaching the mandrel m to the mandrel mounting plate b34 'and inserting the knob b38 projecting at the base of the peg b35 into the groove b40 bored at the open end of the hollow mandrel m, It is possible to prevent the mandrel m from rotating with respect to the mandrel mounting plate b34 '.

FIG. 20 is a plan view of another embodiment showing the attachment means of the mandrel m to the mandrel mounting plate b34 '. In the attachment means shown in FIG. 20, the pegs b41 and b42 having the circumferential grooves b41 'and b42' are attached to the end side of the mandrel m, and the peg b41, b42 'is attached to the mandrel mounting plate b34' side. A female member b43 having a recess b43 'into which b42 can be inserted is attached. A recess b44 'is provided in the recess b43' of the female member b43, and a compression coil spring b45 and a ball b46 are installed in the recess b44 so that the ball b46 can be retracted from the recess b44 by the compression coil spring b45. Is configured to be. In addition, b47 and b47 'are knobs projectingly provided at the bases of the pegs b41 and b42, respectively, which are fitted into the groove b48 formed in the opening of the female member b43 and are attached to the mandrel mounting plate b34'. It prevents the mandrel m from rotating.

Therefore, the pegs b41, b42 of the mandrel m are inserted into the recesses b43 'of the female member b43, and the balls b46 urged by the compression coil springs b45 in the circumferential grooves b41', b42 'of the pegs b41, b42. The mandrel m can be easily attached to the mandrel mounting plate b34 'by fitting the.

Next, using the braider BR of the present invention with reference to FIGS. 21 to 23, which are schematic plan views showing the composition process, a T-shaped mask as shown in FIG. 18 is used as an example. The sequence of steps for forming the braid on the ndrel m will be described. (A) First, the horizontal moving frame b1 is moved to the right in FIG. 2 in a state where the drive of the braider body Bb is stopped and the traveling of the bobbin carrier C is stopped, as shown in FIG. 21 (a). One end (1) of the T-shaped mandrel m (hereinafter, simply referred to as "mandrel m". The short part m1 orthogonal to the long part of the T-shaped mandrel m is referred to as a "branching part"). To the mandrel mounting plate b34 'shown in FIG. After that, the horizontal moving frame b1 is moved to the left in FIG. 2 and the fan-shaped moving member b17 is appropriately moved to set the composition point P to one end (1) of the mandrel m as shown in FIG. 21 (a). (For convenience of explanation, the end of the mandrel m attached to the mandrel mounting plate b34 ′ is marked with an inverted triangle (∇).). (B) From this state, the driving device D is driven to move the bobbin carrier C along the track to start composition, and the horizontal moving frame b1 is gradually moved to the right in FIG. The composition is performed toward the joint j of the mandrel m as shown in FIG.

(C) After composition to the joint j of the mandrel m, the movement of the horizontal moving frame b1 is stopped, and then the fan-shaped moving member b17 is moved upward in FIG. 18 to obtain the state shown in FIG. 21 (c). The mandrel m is rotated as shown to bring it into the state shown in FIG. From this state, the horizontal moving frame b1 is moved further to the right in FIG. 2 to form the branch portion m1 of the mandrel m as shown in FIG. It is also possible to slow down the moving speed without stopping the movement of the horizontal moving frame b 1 and simultaneously move the fan-shaped moving member b 17.

(D) As shown in FIG. 21 (e), when the composition reaches the end of the branching portion m1 of the mandrel m, the movement of the horizontal moving frame b1 is stopped and the driving device D is stopped to stop the bobbin. Stop traveling of the carrier C. Then, as shown in FIG. 21 (f), one end (1) of the mandrel m is detached from the mandrel mounting plate b34 ′, the mandrel m is rotated 180 degrees, and the side opposite to the one end (1) of the mandrel m. One end (2) is attached to the mandrel mounting plate b34 '.

(E) After attaching one end (2) of the mandrel m to the mandrel mounting plate b34 ', the drive of the drive device D is restarted to start the traveling of the bobbin carrier C and the horizontal moving frame b1 is moved to the position shown in FIG. In FIG. 22 (a), the branch portion m1 of the mandrel m is recomposed as shown in FIG. 22 (a).

(F) After composition to the joint j of the mandrel m, the drive device D is stopped to stop the traveling of the bobbin carrier C and the movement of the horizontal movement frame b1 to stop the fan-shaped movement member b17. At 18, the mandrel m is rotated to the position shown in FIG. 22 (b). In this state, the driving device D is driven to resume the traveling of the bobbin carrier C to start the composition, and the fan-shaped moving member b17 is moved further downward to the state shown in FIG. , The horizontal moving frame b1 is moved to the left in FIG. 2 to form the composition up to the end of the mandrel m, as shown in FIG. 22 (d).

(G) As shown in FIG. 22 (d), after composition to the end of the mandrel m, the horizontal moving frame b1 is moved rightward in FIG. As shown, the composition is directed towards the junction j of the mandrel m.

(H) While the composition has advanced to the vicinity of the joint j of the mandrel m, the fan-shaped moving member b17 is moved upward while moving the horizontal moving frame b1 to the right in FIG. In the state shown in b), the movement of the horizontal moving frame b1 is stopped and the drive unit D is stopped to stop the traveling of the bin carrier C in this state.

(I) Next, the fan-shaped moving member b17 is moved downward to bring the mandrel m into the state shown in FIG. 23 (c). After that, the drive of the drive device D is restarted, the traveling of the bobbin carrier C is started, and the horizontal moving frame b1 is moved to the right in FIG. 2 to move the mandrel m of the mandrel m as shown in FIG. The joint j is assembled.

(E) Next, the fan-shaped moving member b17 is moved upward to bring the mandrel m into the state as shown in FIG. 23 (e), and the horizontal moving frame b1 in FIG. 23F, the composition is performed up to the end of the mandrel m, and the composition to the mandrel m is completed.

(L) After the composition of the mandrel m is completed, the drive unit D is stopped and the traveling of the bin carrier C is stopped.

(E) Next, the horizontal moving frame b1 is largely moved to the right in FIG. 2 to move the mandrel m to a position beyond the disc cutter s12 of the cutting device S. From this state, the motor s3 is rotated to rotate the disk cutter s12 at high speed as described above. On the other hand, with the rotation of the output shaft s6 rotated at a low speed by the motor s3 via the speed reducer s2, the lever s17 is moved from the standby position shown by the chain double-dashed line in FIG. 16 to the operating position shown by the solid line. To rotate. Along with the clockwise rotation of the lever s17 in FIG. 16, the lever s9 also rotates toward the operating position similarly to the lever s17. By the rotation of the lever s9, the braid that is bent and converged by the second composition position stabilizing guide member g2 is connected to the horizontal guide groove s14 ′ of the guide member s14 attached to the tip of the lever s9. The large number of yarns Y 1 are guided and brought into contact with the disk cutter s 12 attached to the pulley s 13 and rotating at a high speed to cut the large number of yarns Y 1 connected to the braid.

With the above, all steps of the composition step are completed. The composition steps (a) to (nu) described above are merely examples, and are T-shaped by various steps including the moving / stopping order of the horizontal moving frame b1 and the fan-shaped moving member b17. The composition can be performed on the mandrel m, and is not limited to the above-described composition process.

In the above step (d), one end (1) of the mandrel m is removed from the mandrel mounting plate b34 ', the mandrel m is rotated 180 degrees, and the other end (2) of the mandrel m is attached to the mandrel mounting plate b34'. The mandrel m can be easily attached to the mandrel mounting plate b34 'by the means for attaching the mandrel m to the mandrel mounting plate b34' described with reference to Figs. 19 and 20. This process can be performed quickly.

Further, by disposing another mandrel device on the opposite side of the mandrel device Bm with the curved upper plate U interposed therebetween, it is possible to remove the mandrel m from the mandrel mounting plate b34 ′ of the mandrel device Bm. At the same time, it is also possible to attach the mandrel m to the mandrel mounting plate b34 'of the other mandrel device and continue the composition. By arranging two mandrel devices in this way, the mandrel m used in the next composition step can be attached to the mandrel device and prepared in advance.

In the above embodiments, the case where the composition is performed on the T-shaped mandrel m has been described, but the composition can be performed not only on the T-shaped mandrel m but also on the mandrel m having various shapes. It is a thing.

When the rod-shaped mandrel m is used, a plurality of braider bodies Bb can be arranged and a multiple braid can be formed on the rod-shaped mandrel m.

The following is a list of operational effects achieved by the above-described embodiments of the present invention. Since the composition point on the mandrel is at the position where the axis of the bobbin placed on the bobbin carrier and the axis of the mandrel where the composition is performed intersect, the yarn unwound from the bobbin does not bend. Therefore, the yarn can be smoothly unwound and excessive tension is not applied to the yarn, so that an appropriate composition of the braid can be obtained.

Since the composition point on the mandrel is located at the position where the axis of the bobbin placed on the bobbin carrier and the axis of the mandrel on which the composition is performed intersect, the braider is downsized, so that the operability of the braider is improved. It will improve and the installation area of the braider will decrease.

Since the amount of yarn wound on the bobbin can be increased, the number of times the bobbin is replaced can be reduced, and thus the productivity of the braider can be improved.

Since the bobbin carrier is configured to travel by the friction roller and the sliding friction roller, it is possible to prevent the generation of noise due to the backlash of the gear teeth.

By arranging the composition position stabilizing guide member, it is possible to regulate the swaying of the yarn swaying along with the lateral movement of the bobbin carrier traveling meandering along the track formed in the upper plate. In addition, the fluctuation of the composition point due to the movement of the mandrel can be suppressed, so that a stable composition can be realized without entanglement of the yarn to be composed in an irregular state near the composition point. It is possible to manufacture a braid in which the shape of the braid is uniform and stable.

Further, by disposing the composition position stabilizing guide member, when the mandrel is moved after the composition is completed, a large number of yarns connected to the braid composed by the second composition position stabilizing guide member are connected. Since the yarn can be focused, the yarn can be effectively cut by the cutting device.

Since the mandrel can be easily and quickly attached to the mandrel mounting plate, the productivity of the braider can be improved.

Since the cylindrical bobbin cover or elastic plate is provided, when the bobbin carrier is tilted or positioned upside down, the yarn wound around the bobbin is pulled out or droops so that it is adjacent to the bobbin. Problems such as being entangled with the yarn wound around the bobbin or entangled with other members of the braider can be prevented.

Since the bobbin placed on the bobbin carrier and the bobbin wound with the middle yarn or the reinforcing yarn are shared, the bobbin and the bobbin wound with the middle yarn or the reinforcing yarn are used. It is not necessary to distinguish it from the bobbin that is mounted on the carrier.

Since the cutting device having the disc cutter for cutting the braid or the yarn connected to the braid which has been completed is provided, the braid or the yarn connected to the braid can be surely cut and the cutting time is shortened. be able to. Further, since the tension applied to the braid when the braid or the yarn connected to the braid is cut can be reduced, it is possible to prevent the shape of the braid from collapsing.

[0090]

[Effect of device]

 Since the present invention is configured as described above, it has the following effects.

Since the cutting device having the disk cutter for cutting the braid or the yarn connected to the braid which has been finished is provided, the braid or the yarn connected to the braid can be surely cut and the cutting time is shortened. be able to. Further, since the tension applied to the braid when the braid or the yarn connected to the braid is cut can be reduced, it is possible to prevent the shape of the braid from collapsing.

Since the disk cutter is rotated and the disk cutter is rotated by one motor, the braider can be downsized, the operability of the braider can be improved, and the installation area of the braider can be reduced. it can.

[Brief description of drawings]

FIG. 1 is a front view of a braider of the present invention.

FIG. 2 is a side view of the braider of the present invention.

FIG. 3 is an enlarged front view of a driving device for causing the bobbin carrier to travel along the track, including the I-I cross section of FIG. 2.

FIG. 4 is another embodiment of a drive device for running a bobbin carrier along a track.

FIG. 5 is a front view of the bobbin carrier.

FIG. 6 is a front view of a bobbin holding portion.

FIG. 7 is a sectional view taken along line II-II of FIG.

FIG. 8 is a perspective view of a rotating portion of the yarn guide portion.

FIG. 9 is a front view showing another embodiment of the bobbin carrier.

10 is a sectional view taken along line III-III in FIG.

FIG. 11 is a front view of a bobbin support device for a middle thread or for reinforcement.

12 is a sectional view taken along line IV-IV in FIG.

FIG. 13 is a front view of a composition position stabilizing guide member and a perspective view of a mandrel.

FIG. 14 is a side view including a partial cross section of the cutting device.

FIG. 15 is a partially enlarged front view of the cutting device.

FIG. 16 is a side view of the cutting device on the side opposite to that of FIG. 14;

FIG. 17 is a side view of the mandrel device.

FIG. 18 is a schematic enlarged plan view of the mandrel moving device.

FIG. 19 is a plan view including a partial cross section showing a means for attaching the mandrel to the mandrel mounting plate.

FIG. 20 is a plan view including a partial cross section of another embodiment showing a means for attaching a mandrel to a mandrel mounting plate.

FIG. 21 is a plan view of a mandrel showing a braiding composition process.

22 is a plan view of the mandrel showing the braiding composition process similar to FIG. 21. FIG.

23 is a plan view of the mandrel showing the braiding composition process as in FIG. 21. FIG.

[Explanation of symbols]

BR: Braider Bb: Braider body Bm: Mandrel device C: Bobbin carrier D: ················· Drive device Fm ············· Bobbin support device for middle thread or reinforcement M ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ Mandrel moving device S ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ Cutting device U ・ ・ ・ ・ ・ ・ ・ ・ ・ ・ Upper plate

Claims (1)

[Scope of utility model registration request] 1. A braider characterized by comprising a cutting device for cutting and separating a braid having a composition and a yarn continuous with the braid.