This application is based upon and claims the benefit of priority from Chinese Patent Application No. 201510083704.4, filed on Feb. 16, 2015; the entire contents of which are incorporated herein by reference.
The present invention relates to a loop material sewing method and a loop sewing machine for sewing a loop material on a fabric.
A loop sewing machine has been used to sew a loop material through which a belt passes on a fabric such as pants and skirts (for example, see JP-A-2010-075382).
The loop sewing machine includes a loop clamp that clamps the loop material and a fork member that folds an end of the loop material by clamping and rotating a belt loop clamped by the loop clamp, and sews the end on a fabric using a needle in a state in which the loop material is folded in a loop shape.
In general, a loop through which a shoelace passes is formed in a tongue of a shoe such as sneakers. It is desired to make the loop as small as possible to the extent that the shoelace passes therethrough in order to reduce misalignment of the tongue.
The present invention is made in consideration of the above-mentioned circumstances and an object thereof is to provide a loop material sewing method and a loop sewing machine capable of making a length of a loop as small as possible.
A loop material sewing method of the present invention sews both ends of a belt-shaped loop material on a fabric. The loop material sewing method includes: a one end sewing step of sewing one end of the loop material on the fabric in a state where a front side of the loop material faces the fabric; a fork arranging step of arranging a fork member that includes a pair of fork pins which are extending in parallel, so as to arrange the loop material between the pair of fork pins; a loop folding step of folding an opposite end of the loop material to a back side of the loop material using the pair of fork pins by rotating the fork member around an axial line which is parallel to an extending direction of the pair of fork pins, and relatively moving the fabric and the fork member in a length direction of the loop material; and an opposite end sewing step of arranging the folded opposite end of the loop material on the fabric, pulling out the fork pins from a folded portion at the opposite end of the loop material by moving the fork member in a width direction of the loop material, and sewing the folded opposite end on the fabric.
According to this loop material sewing method, even though a loop material has a short length in the length direction thereof, one end is sewn and then the opposite end is reliably folded using the fork member and is sewn on the fabric. As a result, it is possible to form a loop having a short length by sewing a short loop material on a tongue of a shoe such as a sneaker and to suppress misalignment of the tongue in a state in which a shoelace passes through the loop.
In the loop material sewing method, the pair of fork pins includes a long fork pin and a short fork pin. The long fork pin is longer than the short fork pin by a width of the loop material or more. The fork arranging step arranges the fork member so as to arrange the loop material between the long fork pin and the short fork pin and so as to arrange the long fork pin on the back side of the loop material. The opposite end sewing step arranges the folded opposite end of the loop material on the fabric, pulls out the short fork pin from the folded portion at the opposite end of the loop material by moving the fork member in the width direction of the loop material, pulls out the long fork pin from the folded portion at the opposite end of the loop material by moving the long fork pin to be separated from the one end in the length direction of the loop material and by further moving the fork member in the width direction of the loop material, and sews the folded opposite end on the fabric.
In the loop material sewing method, the pair of fork pins includes a long fork pin and a short fork pin. The long fork pin is longer than the short fork pin by a width of the loop material or more. The fork arranging step arranges the fork member so as to arrange the loop material between the long fork pin and the short fork pin and so as to arrange the long fork pin on the back side of the loop material. The opposite end sewing step arranges the folded opposite end of the loop material on the fabric, pulls out the short fork pin from the folded portion at the opposite end of the loop material by moving the fork member in the width direction of the loop material, pulls out the long fork pin from the folded portion at the opposite end of the loop material by moving the fabric to be separated from the opposite end in the length direction of the loop material and by further moving the fork member in the width direction of the loop material, and sews the folded opposite end on the fabric.
According to this loop material sewing method, in the opposite end sewing step, only the short fork pin is pulled out from the folded portion of the opposite end. Accordingly, it is possible to move the long fork pin to be separated from the one end in the length direction of the loop material while reducing friction between the long fork pin and the loop material, and to form a loop in which the folded portion of the opposite end of the loop material has a short length. As a result, it is possible to suppress a problem in that a folded portion of a loop material interferes with a shoelace for example, when the shoelace passes through the loop.
A loop sewing machine of the present invention sews both ends of a belt-shaped loop material on a fabric. The loop sewing machine includes a sewing mechanism, a clamping mechanism and a fork mechanism. The sewing mechanism sews the loop material on the fabric. The clamping mechanism arranges the loop material at a sewing position of the sewing mechanism by clamping and moving the loop material. The fork mechanism includes a fork member having a pair of fork pins which are extending in parallel and that folds the loop material using the pair of fork pins by rotating the fork member around an axial line parallel to an extending direction of the pair of fork pins in a state where the loop material is between the pair of fork pins. The pair of fork pins includes a long fork pin and a short fork pin. The long fork pin is longer than the short fork pin by a width of the loop material or more.
According to this loop sewing machine, one end of the loop material is arranged at the sewing position and is sewn on the fabric using the sewing mechanism in a state in which the front side of the loop material faces the fabric using the clamping mechanism. Then, the fork member of the fork mechanism is arranged to allow the loop material to pass between the pair of fork pins of the fork member, then the opposite end of the loop material is involved and folded to the back side using the fork pins by rotating the fork member, and the one end of the loop material is folded by relatively moving the fabric and the fork member in the length direction of the loop material. Then, the opposite end of the loop material is arranged on the fabric and the fork pins are pulled out from the folded portion of the opposite end by moving the fork member in the width direction of the loop material and then the folded other end is sewn on the fabric using the sewing mechanism, thereby reliably sewing a short loop material on a fabric. Accordingly, it is possible to form a loop having a short length by sewing a short loop material on the tongue of a shoe such as a sneaker and to suppress misalignment of the tongue in a state in which a shoelace passes through the loop.
A portion in the vicinity of the opposite end of the loop material is caused to pass between the long fork pin and the short fork pin so as to arrange the long fork pin on the back side of the loop material, the opposite end of the loop material which is folded is arranged on the fabric, the fork member is moved in the width direction of the loop material so as to pull out the short fork pin from the folded portion of the opposite end, then the long fork pin is moved to be separated from the one end in the length direction of the loop material, and the fork member is further moved in the width direction of the loop material so as to pull out the long fork pin from the folded portion of the opposite end, the folded other end is sewn on the fabric using the sewing mechanism, thereby forming a loop with the short folded portion. As a result, for example, it is possible to suppress a problem in that a folded portion of the loop material interferes with a shoelace passing through the loop.
According to the present invention, it is possible to provide a loop sewing method and a loop sewing machine capable of decreasing a length of a loop material in the length direction of the loop material.
Hereinafter, a loop sewing method and a loop sewing machine according to an embodiment of the present invention will be descried with reference to the accompanying drawings.
As illustrated in
The loop sewing machine 10 includes a clamping mechanism 30 having a loop clamp 31 that clamps the loop material L facing a predetermined direction, a fork mechanism 40 that folds the loop material L, a loop feed mechanism 60 that feeds the loop material L to the clamping mechanism 30, a loop pressing mechanism 50 including a body feed under-plate 51 supported on a needle plate 3 on which the fabric on which the loop material L is sewn is placed and a loop presser foot 52 that presses down the loop material L by downward movement to the body feed under-plate 51, and a fabric pressing mechanism 70 having a fabric presser foot 71 that holds the fabric M. The loop sewing machine 10 includes a shuttle mechanism (not illustrated) and a controller (not illustrated) that controls the above-mentioned elements.
In the following description, a direction horizontal and parallel to a length direction of the arm portion 13 is defined as an Y-axis direction, a direction horizontal and perpendicular to the Y-axis direction is defined as an X-axis direction, and a vertical direction is defined as a Z-axis direction. If necessary, a surface side of the arm portion 13 as one side in the Y-axis direction is defined as “a near side”, and the vertical body portion 12 side as the opposite side in the Y-axis direction is defined as “a deep side”. When “right” is mentioned, it represents a direction that is parallel to the X-axis direction and faces the right side when the deep side is viewed from the near side (the surface side), and when “left” is mentioned, it represents a direction that is parallel to the X-axis direction and faces the left side when the deep side is viewed from the near side (the surface side).
Clamping Mechanism
The clamping mechanism 30 is arranged on the right side of the sewing machine frame 14 when the deep side is viewed from the near side (the surface side).
As illustrated in
Fork Mechanism
The fork mechanism 40 is disposed on the deep side in the Y-axis direction of the clamping mechanism 30. The fork mechanism 40 includes a fork member 41 extending to the left side.
As illustrated in
In the long fork pin 41a and the short fork pin 41b, an axial direction which is an extending direction thereof is set to be parallel to the width direction of the loop material L clamped by the clamping mechanism 30. A base of the fork member 41 is supported by a fork mount 42 disposed in the back of the fork member 41 so as to rotate around an axial line along the extending direction of the long fork pin 41a and the short fork pin 41b. The fork member 41 is coupled to a rotational drive mechanism 43 for causing the fork member 41 to rotate via the fork mount 42.
The rotational drive mechanism 43 includes a motor 44 of which a rotation phase can be controlled. The motor 44 has a rotary shaft 44a arranged to be parallel to the X direction. The rotary shaft 44a of the motor 44 is connected to an actuator-side gear 45. The actuator-side gear 45 is rotatably supported by the fork mount 42. A fork-side gear 46 is fixed to a base of the fork member 41 which is rotatably supported by the fork mount 42, and the actuator-side gear 45 engages with the fork side gear 46. The actuator-side gear 45 and the fork-side gear 46 are formed, for example, to have a gear ratio of 3:1. A controller controls the rotational drive of the motor 44 so as to rotate the rotary shaft 44a in the forward and reverse directions. As a result, the fork member 41 rotates in the forward and reverse directions via the actuator-side gear 45 and the fork-side gear 46.
An X-direction drive cylinder 47 for causing the fork member 41 to reciprocate in the X direction is disposed in the back of the fork member 41, and a cylinder rod 47a of the X-direction drive cylinder 47 is coupled to the fork mount 42. The controller causes the fork member 41 to reciprocate in the X direction via the fork mount 42 by causing the cylinder rod 47a of the X-direction drive cylinder 47 to move forward and backward. The fork mechanism 40 is supported by a fork frame 48. The fork frame 48 is movable in the Y-axis direction and the Z-axis direction. Accordingly, the fork mechanism 40 moves to a position in the Y-axis direction and to a height in the Z-axis direction.
Loop Feed Mechanism
As illustrated in
Loop Pressing Mechanism
As illustrated in
A presser foot mount 58 supporting the loop presser foot 52 to be vertically movable is disposed at an operator-side tip of the fabric feed table 59, and the loop presser foot 52 is supported by the fabric feed table 59 via the presser foot mount 58. The body feed under-plate 51 is coupled to a support 72 mounted on the fabric feed table 59 via a connecting plate 51a, and the body feed under-plate 51 integrally moves with the fabric feed table 59 in the X-Y directions. Accordingly, the body feed under-plate 51 and the loop presser foot 52 supported by the fabric feed table 59 integrally move with the fabric feed table 59 in the X-Y directions with the movement of the fabric feed table 59. The loop presser foot 52 includes a frame 52a having a substantially rectangular shape with a width slightly larger than the width of the loop material L therebelow. The loop presser foot 52 is vertically moved by a pulse motor (not illustrated), holds the loop material L and the fabric M from top to bottom by moving downward, and releases the loop material L and the fabric M by moving upward. The loop pressing mechanism 50 causes the fabric feed table 50 to move in the X-Y directions to arrange the loop material L and the fabric M, which are held on the body feed under-plate 51 by the loop presser 52, at a certain position on the X-Y plane.
Fabric Pressing Mechanism
As illustrated in
As illustrated in
A case in which a belt-shaped loop material L is sewn on a fabric M using the loop sewing machine 10 having the above-mentioned configuration will be described below.
One End Sewing Step
As illustrated in
As illustrated in
In this state, sewing by the sewing mechanism 2 is started. Then, in the sewing mechanism 2, the sewing needle 1 moves up and down and the fabric presser 71 and the loop presser 52 move to convey the fabric M. Accordingly, the one end L1 of the loop material L is sewn on the fabric M.
Fork Arranging Step
As illustrated in
Loop Folding Step
As illustrated in
As illustrated in
As illustrated in
As illustrated in
Opposite End Sewing Step
As illustrated in
As illustrated in
As illustrated in
As illustrated in
By performing the above-mentioned steps, the loop material L having a loop shape in which both ends of the loop material L are folded in a U shape is sewn on the fabric M, and thus a loop is formed on the fabric M.
In this embodiment, as described above, the one end L1 of the loop material L is arranged at the sewing position by the clamping mechanism 30 so that the front side faces the fabric M, and is sewn on the fabric M by using the sewing mechanism 2. By arranging the loop material L between the long fork pin 41a and the short fork pin 41b of the fork member 41 of the fork mechanism 40 and causing the fork member 41 to rotate, the opposite end L2 of the loop material L is folded to the back side using the long fork pin 41a and the short fork pin 41b. The opposite end L2 of the loop material L is arranged on the fabric M, and the fabric M and the fork member 41 move in the length direction of the loop material L relative to each other. The fork member 41 moves in the width direction of the loop material L to pull out the long fork pin 41a and the short fork pin 41b from the folded portion of the opposite end L2, and the folded opposite end L2 is sewn on the fabric M using the sewing mechanism 2. By sewing the loop material L on the fabric M through such steps, even though the length of the loop material L is small, the one end L1 is first sewn, then the opposite end L2 is reliably folded by the fork member 41, and the opposite end L2 is sewn on the fabric M. Accordingly, for example, a short loop having a small length of 15 mm to 20 mm can be formed. As a result, it is possible to form a loop having a small length by sewing a short loop material L on a tongue of a shoe such as sneakers and to suppress misalignment of the tongue in a state in which a shoelace passes through the loop.
In the opposite end sewing step, since only the short fork pin 41b is pulled out from the folded portion of the opposite end L2 of the loop material L, the friction between the long fork pin 41a and the loop material L can be reduced and the long fork pin 41a can move in the length direction of the loop material L so as to be separated away from the one end L1. By causing the long fork pin 41a to move in the length direction of the loop material L so as to be separated away from the one end L1, it is possible to form a loop L in which the length of the folded portion of the opposite end L2 of the loop material L decreases to about, for example, 5 mm which is the same length as the folded portion of the one end L1. Accordingly, for example, it is possible to suppress a problem in that a folded portion of a loop material interferes with a shoelace passing through the loop.
Number | Date | Country | Kind |
---|---|---|---|
2015 1 0083704 | Feb 2015 | CN | national |
Number | Name | Date | Kind |
---|---|---|---|
3699907 | Anderson | Oct 1972 | A |
4048931 | Hodgins | Sep 1977 | A |
4137857 | Miyachi | Feb 1979 | A |
4279209 | Diacont, Jr. | Jul 1981 | A |
6035793 | Nishio | Mar 2000 | A |
6305304 | Tanaka | Oct 2001 | B1 |
Number | Date | Country |
---|---|---|
2369806 | Jun 1978 | FR |
2010-075382 | Apr 2010 | JP |
Number | Date | Country | |
---|---|---|---|
20160237605 A1 | Aug 2016 | US |