KR20100002138A - Feeder for feeding fabric during the operation of a sewing machine - Google Patents

Abstract

PURPOSE: A feeder for feeding fabric during operation of a sewing machine and a sewing machine including the same are provided to reduce risks for damage of needles and/or stitch failure, and to make an adjusting device with reduce manufacturing costs. CONSTITUTION: A feeder(17) for feeding fabric during operation of a sewing machine at least one supplying part(28), a base body(30), and a feeder wall(32). The supply part is directly in contact with the fabric, and which is adjacent to a needle movement region. The base body connects the supply part to the feeder carrier. The feeder includes an adjusting device(33) adjusting the distance of the feeder wall. The adjusting device includes an adjusting part(34) and an adjusting unit(35). The feeder wall has a support part and an attenuator(40).

Description

Feeder for feeding fabric during the operation of a sewing machine}

The present invention relates to a feeder for feeding a fabric during operation of a sewing machine, the feeder being designed to frictionally contact the fabric and to feed within the needleplate ablation portion of the needleplate and disposed adjacent to the needle movement zone. At least one feed portion, a base body for firmly connecting the feed portion to the feeder carrier, and extending from the needle side opposite the stitch forming tool disposed below the feed portion adjacent to the needle movement zone to interact with the needle during the sewing process Includes feeder walls to be fitted. The invention also relates to a sewing machine comprising this type of feeder.

Feeders of this type are known, for example, from Japanese Patent Laid-Open No. 2004-174120.

During operation of the sewing machine, the sewing needle can be deformed, especially when handling heavy materials such as leather. In addition, when the sewing needle is deformed by the fabric, a loop of the needle thread guided by the sewing needle is caused by a poor stitch since the loop of the needle thread is not correctly caught by the stitch forming tool interacting with the needle thread.

It is an object of the present invention to improve the feeder of the type mentioned at the outset in such a way as to reduce the possibility of needle breakage and / or bad stitches.

This object is achieved by a feeder comprising an adjusting device capable of adjusting the distance of the feeder wall to the needle movement zone.

 According to the present invention, the adjustable feeder wall effectively protects the sewing needle during operation from the opposite side of the stitch forming tool, which interacts with the needle in the sewing process, against unwanted bending caused by, for example, heavy fabrics. Found that it can. The feeder wall is adjusted in such a manner that the feeder wall supports the sewing needle even if the sewing needle is bent slightly in the direction of the feeder wall, thereby preventing the sewing needle from being broken or bent. In addition, the adjustable feeder wall prevents the seal loop from moving unnecessarily to the opposite side of the stitch forming tool which interacts with the needle. As a result, the seal is reliably held by the stitch forming tool. The sewing machine can be a single needle or a double needle sewing machine. If the sewing machine is designed as a double needle sewing machine, two feeder walls may be provided, when the feeder is installed in a double needle sewing machine, the two feeder walls may in any case be associated with a stitch forming tool, for example a hook. On the opposite side, ie far away. Instead of two feeder walls, the double needle sewing machine can also have a common feeder wall, both sides being configured to support one of the two needles of the double needle sewing machine in either case.

Being able to adjust the distance continuously by means of the adjusting device makes it possible to set the distance of the feeder wall with respect to the needle movement area in a particularly fine and precise manner. As another method, one-step or multi-step distance adjustment can be considered as well.

It is possible to meet a low cost adjustment device including an adjustment part fixed to the carrier and an adjustment part supported on the feeder wall while being supported on the adjustment part fixed to the carrier with adjustable support force.

The damping portion of the feeder wall with reduced wall thickness between the support on which the adjuster is supported and the transition to the base body side is a solid joint which allows the feeder wall to be bent and adjusted as defined.

In order to allow the feeder wall to move and adjust elastically, it has proved particularly suitable to reduce the wall thickness of the damping part by 50%.

The passage wall separating the feeder wall from the adjacent portion of the base body improves the deflection of the feeder wall during adjustment. The passageway groove is specifically a groove whose one end is closed, which allows the feeder wall to be integrally connected with the adjacent part of the base body despite the passageway wall.

The improved deflection of the feeder wall applies in particular to the embodiment of the adjusting device in which the adjusting body is supported at the free end of the feeder wall between the two passage grooves.

The adjusting body is a setting screw which is screwed into the screw of the adjusting part fixed to the carrier, and the free end of the setting screw is facilitated by the design of the adjusting device which is supported on the feeder wall.

 Embodiments of the adjusting part fixed to the carrier are particularly stable when the adjusting part is integrally connected to the base body. In this embodiment, the adjustment part fixed to the carrier is not a component separated from the feeder. The adjusting part may be an integral part of the base body. Mobility to the feeder wall of the adjustment part fixed to the carrier can be obtained by solid joint. The solid joint can be an attenuation part of the transition region between the feeder wall and the feeder base body. Designing a feeder in multiple parts is likewise generally conceived, for example an adjustment part is a part that can be released from the rest of the feeder. It is similarly conceivable to design the adjuster as a pivotable element connected via a pivot joint to the base body of the feeder.

Advantages of a sewing machine comprising a needle plate having a needle plate cutout portion, a sewing needle can be attached, a needle rod driven to move up and down on the stitch plate, and a feeder according to the present invention disposed in the needle plate for feeding movement. Corresponds to that described above with reference to the feeder according to the invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

The sewing machine 1 includes a base plate 2, a stand 3 extending upward from the base plate 2, and a bending arm 4. The arm 4 ends with a head 5. An arm shaft 6 is rotatably mounted to the arm 4, which drives the crank drive 7 with the seal lever 8 in the head 5. The crank drive 7 is operably connected to the needle bar 9 movably mounted in the head 5. The needle bar 9 has a sewing needle 10 at its lower end. The sewing needle 10 may be driven up and down by the crank drive 7, wherein the sewing needle 10 passing through the needle movement region will be described below. The needle thread 13 supplied by the bobbin 12 through the thread tensioning device and the thread lever 8 is guided into the eye of the sewing needle 10.

On the base plate 2, a support plate 14 on which the fabric piece 15 is placed, i.e. a needle plate, is mounted. The support plate 14 has a feed dog opening, ie a needle plate cutout 16, designed for the feeder or feed dog 17 to pass through. The feeder 17 has a needle hole 18 that allows the needle 10 to pass through. The feeder 17 is driven through a feed and lift drive driven under the base plate 2.

Under the support plate 14, a hook 19 including a hook body 20 having a hook tip 21 is disposed. The hook body 20 is firmly connected to a shaft having a vertical axis of rotation 22 extending parallel to the needle bar 9. The shaft is rotatably mounted to a mounting support 23 screwed to the base plate 2. In addition, the mounting support 23 is mounted with a drive shaft 24, the drive shaft 24 is connected to the gear drive disposed inside the mounting support (23). The drive shaft 24 is operably connected to the arm shaft 6 via the belt drive 25.

2 shows a more detailed view of the stitch forming area of the sewing machine 1, which shows the state after the sewing needle 10 is withdrawn from the needle hole 18 in the direction of top dead center. Below the stitch hole 18, the needle thread 13 forms a needle thread loop 26 which is interlaced with the bobbin thread 27 during the subsequent interlacing process. The bobbin seal 27 is supplied to the stitch forming region by a bobbin housing, that is, a seal spool housing, located in the hook body 20. In Fig. 2, the sewing direction is indicated by the direction arrow (N).

3 to 6 show detailed views of the feeder 17. The feeder 17 has an upper feed 28 having a serrated surface on both sides of the needle hole 18 in frictional contact with the fabric 15. The supply part 28 makes a feeding motion in the feed dog opening 16, ie, the needle plate ablation part. Since the supply portion 28 surrounds the needle hole 18 in a ring shape, the supply portion 28 is disposed adjacent to the needle movement region 29 shown by the dotted line in FIG.

The supply unit 28 is firmly connected to the feeder carrier in the form of a carrier bar 31 which is part of the feed for the feeder 17 and the lift drive unit through the base body 30.

The feeder wall 32 is arranged adjacent to the needle movement region 29 under the supply portion 28. When the feeder 17 is installed (see FIG. 2), the feeder wall 32 is from a stitch forming tool which interacts with the needle 10 during the sewing process, ie the opposite side of the hook tip 21 of the hook 19. Extends from the needle 10 side. Thus, the needle 10 is located at the bottom dead center between the feeder wall 32 and the optional needle protection plate of the hook 19.

The distance A (see FIG. 6) from the needle movement area 29 of the feeder wall 32 can be adjusted by the adjusting device 33. The adjusting device 33 is designed to adjust the distance A continuously. The adjusting device 33 has an adjusting unit 34 fixed to the carrier 31. The adjusting section 34 is designed as a web extending in the horizontal direction when the feeder 17 is installed and integrally connected to the base body 30 of the feeder 17. The adjusting device 33 further has an adjusting body 35 in the form of a hexagon socket screw serving as a setting screw. The adjuster 35 is screwed into the corresponding female thread 36 of the adjuster 34 fixed to the carrier 31. The free end 37 of the adjuster 35 is supported on the feeder wall 32 side opposite to the needle movement area 29. According to the threading depth of the adjuster 35 in the female screw 36, the adjuster 35 is supported by the feeder wall 32 while being supported by the adjuster 34 fixed to the carrier 31, the support force of which is Can be adjusted.

The feeder wall 32 has an attenuation portion 40 having a reduced wall thickness between the support portion 38 on which the adjuster 35 is supported and the transition portion 39 (see FIG. 6) toward the supply portion 28. In the damping portion 40, the wall thickness of the feeder wall 32 is reduced by approximately half.

The feeder wall 32 is separated from the adjacent portion 41 by the passage groove 42 (see FIG. 4). The adjuster 35 is supported between the two passage grooves 42 by the support 38 of the feeder wall 32, that is, the free end of the feeder wall 32.

When adjusting the feeder wall 32, the adjuster, ie the hexagonal socket screw 35, is screwed only until it can pass through the feeder wall 32 when the needle 10 is at its bottom dead center. The feeder wall 32 is moved in the direction of the needle movement region 29. Compared to the neutral position where no force is applied according to FIG. 6, the adjusted feeder wall 32 is attenuated towards the needle movement region 29 by the force of the adjuster 35 acting in the region of the support 38. It pivoted about the part 34. Thus, the damping portion 40 acts as a solid joint.

If the needle 10 is bent away from the hook 19, for example, when drilling a heavy material such as leather, the undesirable deflection of the needle 10 is in contact with the adjusted feeder wall 32. (10) is prevented. The feeder wall 32 thus acts as a corresponding support for the needle 10 in the direction opposite to the support influence given by the selective needle protection plate of the hook 19.

In addition, since the deflection movement is stopped by the feeder wall 32, the adjusted feeder wall 32 may cause the needle thread loop 26 formed at the loop ascending position shown in FIG. Prevents you from moving away from it.

Depending on the thickness of the sewing needle 10 used, the feeder wall 32 can be finely adjusted in a simple manner by the adjuster 35.

1 is a side view of a sewing machine showing a part of a detail inside.

Figure 2 is an enlarged detail of the stitch forming area of the sewing machine according to Figure 1 having a sewing needle, a hook and a feeder for the fabric.

3 is a perspective view of the feeder viewed obliquely from the opposite side of the needle movement region;

4 is a perspective view of the feeder viewed from the viewing direction on the opposite side of FIG.

5 is a plan view of the feeder;

6 is a sectional view taken along the line VI-VI of FIG. 5;

Claims (10)

As a feeder 17 for supplying the fabric 15 during the operation of the sewing machine 1, At least one feed portion 28 which is in frictional contact with the fabric 15 and designed to feed within the needle plate ablation portion 16 of the needle plate 14 and adjacent the needle movement region 29; A base body 30 which firmly connects the supply part 28 to the feeder carrier 31; And The needle opposite to the stitch forming tool 19 disposed below the supply portion 28 and adjacent to the needle movement area 29 to interact with the needle 10 during the sewing process when the feeder 17 is installed ( In the feeder 17 comprising a feeder wall 32 extending from the 10) side, And an adjusting device (33) for adjusting the distance (A) of the feeder wall (32) with respect to the needle movement area (29). 2. The feeder as claimed in claim 1, wherein the adjusting device (33) is designed to continuously adjust the distance (A). The method of claim 1, wherein the adjusting device 33, An adjusting unit 34 fixed to the carrier 31; And And an adjuster (35) fixed to the carrier (31) and an adjuster (35) supported by an adjustable support force on the feeder wall (32). 4. The damper according to claim 3, wherein the feeder wall (32) has a reduced wall thickness between the support (38) on which the adjuster (35) is supported and the transition (39) toward the base body (30). A feeder, characterized by having 40. 5. The feeder according to claim 4, wherein the wall thickness of the feeder wall (32) is reduced by half in the damping portion (40). 2. The feeder as claimed in claim 1, wherein the feeder wall (32) is separated from the adjacent portion (41) of the base body (30) by a passage groove (42). 7. The feeder of claim 6, wherein the adjuster (35) is supported at the free end (38) of the feeder wall (32) between the two passage grooves (42). 4. The set screw according to claim 3, wherein the adjuster (35) is a setting screw screwed into the screw (36) of the adjuster (34) fixed to the carrier (31), and the free end (37) of the set screw is The feeder, characterized in that it is further supported on the wall (32). 4. A feeder according to claim 3, wherein the adjusting part (34) fixed to the carrier (31) is integrally connected to the base sieve (30). A needle plate 14 having a needle plate ablation portion 16; A needle bar (9) attached to the sewing needle (10) and driven to move up and down on the stitch plate (14); And And a feeder (17) according to the invention disposed in the needle plate ablation section (16) to perform a feeding motion.

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