BR102014031601A2 - differential feeding device for a sewing machine - Google Patents

Abstract

differential feeding device for a sewing machine. The present invention provides a differential feeding device for a sewing machine, including a lower feeding mechanism, a coupling mechanism, a differential adjustment mechanism and an upper feeding mechanism. the lower feed mechanism is formed together as the lower feed axis is formed by a first feed axis and a second feed axis which is on the same geometrical axis as the first feed axis. The first power shaft is connected to and passes through a first clutch assembly. The second power shaft is connected to and goes through a second clutch assembly. furthermore, the coupling mechanism includes a coupling shaft which is parallel to the lower feed shaft, and the coupling shaft is respectively connected to the first clutch assembly and the second clutch assembly. The differential adjustment mechanism is mounted between the coupling shaft and the first clutch assembly. In addition, the upper feed mechanism includes an upper feed shaft. The upper feed shaft is connected to the first feed shaft through a transmission assembly to allow the upper feed mechanism and the lower feed mechanism to operate simultaneously. furthermore, the differential adjustment mechanism of the present invention is capable of selectively increasing or decreasing the angle of rotation of the first feed shaft operated by the first clutch assembly and producing a positive differential feed or a negative differential feed. that correspond to the second feed axis.

Description

"DIFFERENTIAL FEEDING DEVICE FOR A SEWING MACHINE" FIELD OF THE INVENTION

The present invention generally relates to a sewing machine for changing the relative speed between an upper feed gear and a lower feed gear, and more particularly, the present invention relates to a differential feed device. for a sewing machine by design the design of a coaxial clutch assembly that co-operates with a differential adjustment mechanism to enable both an upper feed gear and a lower feed gear to generate a relative speed between the gear upper feed gear and lower feed gear.

BACKGROUND OF THE INVENTION

In general, the feeding process of a common sewing machine essentially involves two parts: a lower feeding procedure and an upper feeding procedure. The bottom feeding procedure is involved with sewing fabrics and other materials together using a piece of thread, and the sewing direction is top to bottom; while on the other hand the upper feeding process is related to stitching fabrics and other materials together using a piece of thread, but stitching is from the bottom up and out of the direction of the fabrics. In addition, during the lower feed process, the needle and fabrics move at the same time, such that the upper feed gear and lower feed gear are required to move at the same time. Therefore, the hole and needle of the machine would not be deflected by the upper fabric and the lower fabric. In addition, during the upper feed process, the needle may include a return action such that the upper feed gear and lower feed gear may be adjusted at different feed speeds. Therefore, the upper tissue feeding quality relative to the lower tissue feeding quality can be controlled.

Generally, for a sewing machine, the rotational speeds of the upper feed gear and lower feed gear can be changed accordingly to generate a differential speed effect by adjusting the length of an upper feed arm of the sewing machine mechanism, based on the distance from the machine needle and the default rotation speed of the lower feed gear. Accordingly, the rotation speed of the upper feed gear can be changed. In addition, if the upper feed gear rotation speed and the lower feed gear rotation speed are the same, the upper feed gear and lower feed gear have simultaneous rotation speeds. On the other hand, if the rotation speed of the upper feed gear is faster than the simultaneous rotation speed, the rotation speed of the upper feed gear is called positive differential feed. If the rotation speed of the upper feed gear is slower than the simultaneous rotation speed, the rotation speed of the upper feed gear is called negative differential feed.

However, the feed devices of conventional roll-fed sewing machines employ the one-way rolling principle. That is, even if differential feed devices can perform positive or negative feed feed, feed gear rotation speeds must be adjusted by tools, and feed gear rotation speeds cannot be adjusted during food. In addition, the rotation speeds of the feed gears can be adjusted by trial and error. In addition, since the operating position of the differential adjustment may be far from the stitch length operating position of the sewing machines, users may not be able to perform differential adjustment quickly and easily.

In view of the prior drawbacks of performing differential feed on the differential feed device of conventional sewing machines, it is necessary to provide a better design for a sewing machine to perform differential feed on a differential incorporated in the adjusting device feed. .

SUMMARY OF THE INVENTION

[0006] The main object of the present invention is to provide a sewing machine that can allow a feed differential. This can be achieved by installing the two bidirectional clutch assemblies that are on the same geometry axis as the lower feed shaft, thus allowing the adjusting mechanism to form a differential effect. The presence of a differential effect of the sewing machine of the present invention may allow the total number of structural elements of the sewing machine to be reduced, thereby simplifying the overall structure of the sewing machine. The presence of a sewing machine with a differential effect of the present invention can effectively lower the sewing machine's center of gravity.

[0007] The other object of the present invention is to allow the operator to still be able to directly change the amount of feed that is differential between the upper feed gear and lower feed gear during the sewing period. In particular, the differential effect of the sewing machine of the present invention may allow the operator to directly change the amount of differential feed between the upper feed gear and lower feed gear without stopping the sewing action.

In order to achieve the above objective, the present invention is primarily involved with providing a differential feeding device of a sewing machine which is comprised of a lower feeding mechanism, a coupling mechanism, a differential adjustment mechanism as well as a superior feed mechanism.

According to a preferred exemplary embodiment of the present invention, with respect to the lower feed mechanism, a lower feed axis is formed together by a first feed axis and a second feed axis which is on the same axis. geometric than the first feed axis; the first feed shaft is connected to and passes through a first clutch assembly, the second feed shaft is connected to and passes through a second clutch assembly; a coupling mechanism includes a coupling shaft that is parallel with the lower feed shaft, and the coupling shaft is connected respectively with the first clutch assembly and the second clutch assembly; a differential adjustment mechanism that is mounted between the coupling shaft and the first clutch assembly; and an upper feed mechanism including an upper feed shaft; and the upper feed shaft is connected to the first feed shaft by means of a transmission assembly to allow the upper and lower feed mechanism of the feed mechanism to be operated simultaneously;

Preferably, the differential adjustment mechanism of the present invention is capable of selectively increasing or decreasing the angle of rotation of the first feed shaft, which is operated by the first clutch assembly, and producing a positive differential feed or a differential feed. negative that corresponds to the second feed axis.

According to one embodiment of the present invention, the differential adjustment mechanism of the present invention includes a differential arm; and wherein an axis of one end of the differential arm is positioned on the coupling axis; the differential adjustment mechanism includes a guide channel, wherein the interior of the guide channel includes a sliding block; and the sliding block is connected respectively to the first clutch assembly and to an adjustable device by means of a connecting rod.

In one aspect of the present invention, the adjustable device may include a sliding connecting rod, an output arm, an adjustable handle, a disc and a locating element. One end of the sliding connecting rod is connected to the sliding block; and an outlet arm is mounted at the other end of the sliding connecting rod; The output arm pivot is connected to a transmission lever, and the transmission lever and an adjustable handle are mutually connected. The locating disk is located on one side of the adjustable handle, and includes at least one sliding track; the fixed member and adjustable handle respectively, located on two different sides of the locating disc, and are screwed together by means of the sliding track and the adjustable handle. In a preferred exemplary embodiment of the present invention, the fixed adjustable strap, disc and locating element are all exposed outside the sewing machine.

Preferably, in accordance with a preferred exemplary embodiment of the present invention, the adjustable strap of the present invention is exposed on the machine body of the sewing machine. In addition, the adjustable handle of the present invention is adjacent to the sewing machine's adjustable needle operating location. In addition, the transmission assembly may include one of a belt group, a chain group, a gear group, in order to achieve the effect of being operated at the same time.

The special technical differential of the present invention is the respective positioning of the two bidirectional clutch assemblies on the second feed axis and the first feed axis which is on the same geometrical axis as the second feed axis. Driving the differential arm through the adjustable device may alter the action of the first clutch assembly with respect to the needle at the angle of rotation during the feeding process. This has the effect of allowing the sewing machine operator to directly change the rotation speed of the upper feed gear relative to the lower feed gear while the operator is sewing without the need to stop. This creates a differential effect as a result.

In addition, because the two clutch assemblies are both located at the sewing machine base position, the total number of structural elements of the sewing machine can be reduced, thus simplifying the overall machine structure. sewing. The presence of a sewing machine with a differential effect can effectively reduce the sewing machine's center of gravity. In addition, the handle, adjustable locating disc and fixed member are exposed on the outside of the sewing machine. The foregoing components are also close to the adjustable needle operating position, and as a result, the convenience of use can be significantly improved.

BRIEF DESCRIPTION OF DRAWINGS

[0016] The present invention may be more fully understood by reading the following detailed description in conjunction with the preferred exemplary examples and embodiments made for the accompanying drawings, wherein: Fig. 1 is a diagram. three-dimensional perspective schematic illustrating a differential feeding device in conjunction with other mechanisms installed within a sewing machine in accordance with the preferred exemplary embodiment of the present invention.

Fig. 2 is a three-dimensional perspective schematic diagram illustrating the differential feeding device for the sewing machine according to the preferred exemplary embodiment of the present invention.

Fig. 3 is a three-dimensional schematic diagram in exploded view illustrating a lower feed mechanism, a coupling mechanism, a differential adjustment mechanism, a transmission assembly and an upper feed mechanism according to the embodiment. preferred exemplary embodiment of the present invention.

Fig. 4 is an exploded three-dimensional schematic diagram illustrating the lower feed mechanism corresponding to fig. 3 according to the preferred exemplary embodiment of the present invention.

Fig. 5 is an exploded three-dimensional schematic diagram illustrating the coupling mechanism corresponding to fig. 3 according to the preferred exemplary embodiment of the present invention.

Fig. 6 is an exploded three-dimensional schematic diagram illustrating the differential adjustment mechanism corresponding to fig. 3 according to the preferred exemplary embodiment of the present invention.

Fig. 7 is a side schematic diagram illustrating the differential adjustment mechanism with respect to the lower feed mechanism and with respect to the coupling mechanism according to the preferred exemplary embodiment of the present invention.

Fig. 8 is a schematic diagram illustrating an increase in the feed amount of the upper feeder for subsequent adjustment by the differential handle compared to the feed amount of the lower feeder in accordance with the embodiment. Fig. 9 is a schematic diagram illustrating a reduced feed amount of the upper feeder for subsequent adjustment by the differential handle compared to the feed amount of the lower feeder according to the invention. with another preferred exemplary embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The accompanying drawings are included to provide a greater understanding of the invention, and are incorporated into and constitute a part of this specification. The drawings illustrate preferred exemplary embodiments of the invention and, together with the description, serve to explain the principles of the invention.

As shown in Fig. 1 and Fig. 2, the sewing machine 10 of the present invention may include mainly a sewing head 11, a machine bed 12 and a machine body 13.

According to a preferred exemplary embodiment of the present invention, also with reference to Fig. 1 and Fig. 2, an upper feed mechanism 20 may be installed within the sewing head 11. The upper feed mechanism 20 can stimulate upper feed gear and lead to rotation. A lower feed mechanism 30 and a coupling mechanism 40 may be installed within the machine bed 12. The lower feed mechanism 30 drives the lower feed gear 31 causing rotation. In addition, the lower feed mechanism 30 may be connected to the coupling mechanism 40, and these components may be actuated simultaneously. The machine body 13 may be installed with a transmission assembly 50 and a differential adjustment mechanism 60, wherein one end of the transmission assembly 50 may be connected to the upper feed mechanism 20; and the other end of the transmission assembly 50 may be connected to the lower feeder mechanism 30. Said arrangement allows the upper feeder mechanism 20 and the lower feeder mechanism 30 to be driven simultaneously. In addition, according to the preferred exemplary embodiment of the present invention, the differential adjustment mechanism 60 may be installed in pairs between the coupling mechanism 40 and the lower feed mechanism 30. This mechanism may allow the feed gear upper 21 and lower feed gear 31 produce corresponding speed changes, and as such create a differential effect.

Referring to Fig. 3, this shows a schematic exploded three-dimensional diagram of a mechanism of a lower feed mechanism 30, a coupling mechanism 40, a differential adjustment mechanism 60, a transmission assembly 50 and a transmission mechanism. upper feed 20 according to the preferred exemplary embodiment of the present invention.

As shown in Fig. 2 and fig. 3, the upper feed mechanism 20 of the present invention may include an upper feed shaft 22; one end of the upper feed shaft 22 may control the upper feed gear 21 via the upper drive element 23. The other end of the upper feed shaft 22 may be mounted with a drive assembly 50. According to an exemplary embodiment of the present invention, the drive assembly 50 includes a belt roll 51 which may be mounted with the feed shaft 22. The upper belt roll 51 may be mounted with a first belt 52. The second belt 54 may be driven to the at the same time by means of rollers 53 which may be mounted on the first belt 52. Lastly, the second belt 54 and the belt roll 55 may be connected to the lower feed mechanism 30.

However, also with reference to Fig. 2 and Fig. 3, it should be noted that the above-mentioned transmission assembly 50, being formed of a belt group only acts as a practical example, and is not intended to In addition, according to the preferred exemplary embodiment of the present invention, it should be noted that the transmission assembly 50 may be formed of a straight chain group or a group. gear, and the effect of having simultaneous operation can be achieved with the transmission assembly which can be made of a chain group or a gear assembly.

As shown in Fig. 3, the lower feed mechanism 30 of the present invention may be composed primarily of a first feed axis 32 and a second feed axis 33, which are on the same geometrical axis as the first feed axis 32. , and a lower feed shaft 34 may be formed together by the first feed shaft 32 and the second feed shaft 33. Then, the first feed shaft 32 may be connected and pass through the first clutch assembly 35; the first feed shaft 32 may also be mutually mounted with the belt roll 55. In addition, the second feed shaft 33 may be connected and pass through the second clutch assembly 36, and the second feed shaft 33 may control the pair of lower feed gears 31 by means of a lower drive element 37.

In the preferred exemplary embodiment of the present invention, as shown in Fig. 3, the first clutch assembly 35 and the second clutch assembly 36 of the present invention, which may be bi-directional and in the state of being pushed may be be composed primarily of a rocking device 351 (which is equivalent to 361), two clutch groups 352 (which are equivalent to 362) as well as two connecting rod 353 (which are equivalent to 363). Because the first clutch assembly 35 and the second clutch assembly 36 have exactly the same structure, the only difference between them may be their link ratio. As such, any subsequent further design of the present invention is based solely on the second clutch assembly 36.

According to a preferred exemplary embodiment of the present invention, as shown in Fig. 4, the rocker 361 of the second clutch assembly 36 includes a cam 361a, a pivot arm 361b, a thrust ring 361c and a wheel 361 d. It is apparent from Fig. 4 that the lower axis 38 of the driven rotary shuttle can pass through the cam 361a, and the cam surface 361a has arcuate guide channel changes. Subsequently, the swingarm 361b may be connected to the thrust ring 361c in the direction of the oscillation axis. The second feed shaft 33 may pass through the snap ring 361c. The wheel 361d may be connected to one end of the swingarm 361b, and may be incorporated within the guide channel of the cam 361a. Accordingly, the other end of the swingarm 361b forms a shaft hole which allows the support shaft 361e to traverse it.

In the preferred exemplary embodiment of the present invention, as shown in Fig. 4, the two clutch groups 362 may be installed on the second feed shaft 33. In addition, the two clutch groups 362, respectively, incline at each other. two sides of snap ring 361c of oscillating device 361. Clutch groups 362 include an outer retaining ring 362a, 363b a rotor, a plurality of elastic elements (not shown in the drawings), a plurality of rollers 362c, a plurality locating jaws 362d, a cap 362e, as well as a connecting rod pin 362f that can be attached to the outer snap ring 362a. The rotor may be fixed 362b and mounted on the second feed shaft 33. In addition, the rotor 362b may be located within the outer retaining ring 362a. A plurality of depressions 362g may be formed on the outer periphery of the rotor 362b for installation of the elastic member as well as the roll 362c. The interior of each of the plurality of depressions 362g has one pin (not shown in the drawings), and each of the plurality of support pins may pass through two locating jaws 362d which may be opposite each other. The roll 362c, which may be located between the outer peripheral ring wall 362a and the rotor wall 362b, may be pushed by the locating claw 362d, and the roll 362c may be compressed by the elastic member. Cover 362e may be in connection with outer retaining ring 362a. The outer retaining ring 362a has an opening 362h to allow each location of the jaw 362 to pass through. In addition, the outer retaining ring 362a and the thrust ring 361c mutually abut one another.

In an exemplary preferred embodiment of the present invention, also with reference to Fig. 4, the cam 361A rotates in accordance with the lower axis 38, and directs the swinging action of the swingarm 361b to drive the ring. thrust 361c to produce axial movement. When the thrust ring 361c may be near one of two clutch groups 362, the outer retaining ring 362a and the thrust ring rotor 362b may both be in a released state. The other clutch group 362, which may be away from the thrust ring 361c, may be in a fixed state.

As shown in Fig. 4, one end of the two connecting rods 363 to jointly connect the coupling mechanism 40, and the other end of the two connecting rods 363 can be mutually supportive and can be connected to the coupling rod pin. connection 362f of the two clutch groups 362 respectively. This arrangement allows intermittent rotations to drive both clutch groups 362. This also has the effect of allowing the second feed shaft 33 to have intermittent rotational motions in the same direction, and to allow the lower feed gear to be driven 31, [0038 Also, also with reference to Fig. 4, according to one embodiment of the present invention, one end of the two connecting bars 353 of the first clutch assembly 35 may be connected to the coupling mechanism 40 and the coupling mechanism. differential adjustment 60, respectively; and similarly, the other end of the two connecting rods 353 of the first clutch assembly 35 may be connected to and supported by the connecting rod pin (not shown in the drawings) between the two clutch groups 352. This arrangement allows Intermittent rotations driving the two clutch groups 352. This also has the effect of allowing the first feed shaft 32 to have intermittent rotational motions of the same direction, and allowing the upper feed gear 21 to be driven.

According to a preferred exemplary embodiment of the present invention, as shown in Fig. 5, the coupling mechanism 40 of the present invention has a coupling shaft 41 which can be parallel to the lower feed shaft 34. In addition , the coupling shaft 41 performs an oscillating repeated action. The amount of oscillation exerted by the coupling rod 41 can be controlled by a screw adjusting mechanism (not shown in the drawings). In addition, the coupling shaft mechanism 41 has a first swingarm 42 and a second swingarm 43. The first swingarm 42 and the first clutch assembly 35 can be connected together, and the second swingarm 43 and the second clutch assembly 36 can be mutually connected. As can be seen from Fig. 2, one of the connecting bars 353 of the first clutch assembly 35 may be connected to the first swingarm 42; another of the connecting rods 353 of the first clutch assembly 35 may be mutually connected with the differential adjusting mechanism 60. In addition, the two connecting rods 363 of the second clutch assembly 36 may be connected to either side of the second swingarm 43. at the same time.

According to a preferred exemplary embodiment of the present invention, as shown in Fig. 6 and Fig. 7, the differential adjustment mechanism 60 of the present invention may include a differential arm 61. One end of the differential arm 61 may be be positioned on the coupling shaft 41; and a guide channel 611 extends toward the other end of arm 61. The differential within guide channel 611 has a sliding block 62 which may be relative to sliding. In addition, the sliding block 62 may be connected respectively to the connecting bars 353 of the first clutch assembly 35 as well as to the adjustable device 63 by means of the connecting rod.

In one aspect of the present invention, also with reference to Fig. 6 and Fig. 7, the adjustable device 63 may include a vertically configured sliding connecting rod 64. The lower end of the sliding connecting rod 64 may be located at the the base of the machine 12 of the sewing machine 10, and may be connected to the sliding block 62. On the other hand, the upper end of the sliding connecting rod 64 extends upwardly extending into the body of the machine 13 at an outlet arm 65 can be mounted. The output arm pivot 65 can be connected to the transmission lever 66 which can be extended to the outside of the machine body 13. Finally, the transmission lever pivot 66 can be connected to the adjustable cable 67 to allow the assembly of the adjustable strap 67 is exposed on the machine body 13 of the sewing machine. This arrangement may be convenient for users, where users may be able to adjust the differential amount immediately according to their sewing needs. In a preferred exemplary embodiment, the adjustable loop exposure position 67 may be close to the adjustable needle operating position.

Furthermore, according to a preferred exemplary embodiment of the present invention, as shown in Fig. 6 and fig. 7, the adjustable device 63 further includes a locating disc 68 as well as a fixed member 69, and an adjustable handle location 67 may be formed. The location of the disc 68 may be located on one side of the adjustable handle 67, and includes at least one sliding track 681. In addition, the fixed member 69 and the handle 67 may be adjustable respectively located on the two different sides of the locating disk. 68. Subsequently, the fixed member 69 passing through the sliding strip 681 can be screwed into the adjustable handle 67. This means that, on the one hand, the adjustable handle 67 can be tightened by the fixed member 69, such that the position The adjustable strap 67 can be attached. On the other hand, the adjustable handle 67 may be released by the fixed member 69, such that the oscillation displacement may be generated by the adjustable handle 67 relative to the sliding track 681 of the locating disc 68.

As shown in Fig. 8, when the adjustable handle 67 can be swung up, the transmission lever 66 can be simultaneously rotated to allow the output arm 65 to swing down. Subsequently, the sliding connecting rod 64 may allow the sliding block 62 to follow the guide channel 611 of the differential arm 61 and the connecting rods 353 to generate a simultaneous downward displacement. Since the differential arm exit procedure 62 may be increased, the angle of rotation of the first clutch assembly 35 may be increased during the upper feed process. As such, the feed amount of the upper feeder 21 may be greater than the feed amount of the lower feeder 31, such that a positive differential feed effect can be achieved.

As shown in Fig. 9, by contrast, when the adjustable handle 67 can be swung down, the transmission lever 66 can be simultaneously rotated to allow the output arm 65 to swing up. Subsequently, the sliding connecting rod 64 may allow the sliding block 62 to follow the guide channel 611 of the differential arm 61 and the connecting rods 353 to generate a simultaneous upward displacement. Since the differential arm exit procedure 62 may be decreased, the angle of rotation of the first clutch assembly 35 may be decreased during the upper feed process. As such, the feed amount of the upper feeder apparatus 21 may be less than the feed amount of the lower feeder apparatus 31, such that a negative differential feed effect may be achieved.

While preferred exemplary embodiments of the present invention have been described with reference to preferred exemplary embodiments thereof, it may be apparent to those of ordinary skill in the art that a variety of modifications and alterations may be made without departing from the present invention. scope of the present invention which is to be defined by the appended claims.

Claims (5)

1. Differential feeding device for a sewing machine, comprising: a lower feeding mechanism comprising a lower feeding axis which is formed together by a first feeding axis and a second feeding axis which is in the same geometry axis that the first feed axis, wherein the first feed axis is connected to and passes through a first clutch assembly the second feed axis is connected to and passes a second clutch assembly; a coupling mechanism comprising a coupling shaft that is parallel with the lower feed shaft, wherein the coupling shaft is respectively connected to the first clutch assembly and the second clutch assembly; a differential adjustment mechanism that is mounted between the coupling shaft and the first clutch assembly; and an upper feed mechanism comprising an upper feed shaft, wherein the upper feed shaft is connected to the first feed shaft by means of a transmission assembly to allow the upper feed mechanism and the lower feed mechanism. operated simultaneously, wherein the differential adjustment mechanism is capable of selectively increasing or decreasing the angle of rotation of the first feed shaft, which is operated by the first clutch assembly, and producing a positive differential feed or a negative differential feed corresponding to each other. to the second feed axis. Sewing machine differential feeding device according to claim 1, characterized in that the differential adjustment mechanism comprises a differential arm defining a guide channel; one end of the differential arm is pivoted to the coupling shaft; the interior of the guide channel comprises a sliding block; and the sliding block is connected, respectively, to the first clutch assembly and an adjustable device by means of a connecting rod. Sewing machine differential feeding device according to claim 1, characterized in that the device comprises a sliding connecting rod, and one end of the sliding connecting rod is connected to the sliding block on which an output arm is mounted. at the other end of the sliding connection rod; the output arm pivot is connected to a transmission lever; and the transmission lever and adjustable handle are mutually connected to each other to allow the entire adjustable handle to be exposed outside the sewing machine. Sewing machine differential feeding device according to claim 1, characterized in that the adjusting device further comprises a locating disc and a fixed member; the locating disc is located on one side of the adjustable strap and comprises at least one sliding track; the fixed member and the adjustable strap are respectively located on two different sides of the locating disc and are screwed together by means of the sliding track and the adjustable strap. Sewing machine differential feeding device according to Claim 1, characterized in that a transmission assembly comprises one of a belt group, a chain group or a gear group to form a simultaneous mechanism.