KR200478819Y1 - Insole sewing machine - Google Patents

Abstract

An insole sewing machine includes a main feed mechanism positioned within the main body and having feed spindles connected to a first drive mechanism and a feed wheel at two ends; A feed movement mechanism having a presser wheel and a moveable rack mounted thereon with a second drive mechanism such that the presser wheel can be rotationally driven by a second drive mechanism coupled to the second drive mechanism; And transmitting signals of the first drive mechanism to the second drive mechanism to control the feed wheel and the presser wheel to rotate at the same speed and to change the momentum difference between the two wheels without using any adjustment tools And a control unit. By driving the feed wheel and the presser wheel through two independent drive mechanisms, the mechanical transmission section can be simplified and the insole sewing machine can be used more conveniently.

Description

Insole sewing machine {INSOLE SEWING MACHINE}

The present invention relates to a sewing machine for sewing shoe insole and upper together or sewing other leather and plastic materials together; And more particularly, to an insole sewing machine including a feed wheel rotated by two independent driving mechanisms and a presser wheel.

A conventional insole sewing machine includes a belt pulley on the right side which is driven by a spindle of a sewing machine to drive a needle bar shaft and a hook shaft to perform a sewing motion, To supply a material piece. A presser wheel composed of idle wheels is rotatably mounted on the underside of a moveable rack to be positioned adjacent to the feed wheel to press the feed wheel. To sew two pieces of material together, the movable rack is pulled outward to cause two pieces of material to be clamped between the feed wheel and the presser wheel. When the presser wheel rotates intermittently synchronously with the feed wheel, the user grasps the two ends of the piece of material with both hands and cooperates with the feed wheel to push the piece of material forward, Complete.

While a conventional insole sewing machine having the above-described structure has already been widely used, the sewing machine has some disadvantages. First, the presser wheel consists of an idle wheel that does not transmit any power at all. When sewing together two pieces of material having a relatively small frictional force between two pieces of material, the feed wheel and the presser wheel may not rotate synchronously so that during the sewing operation, the feed wheel and the presser wheel Carefully and firmly hold the two ends of the piece of material so that they overlap precisely. If the user is neglected to hold the piece of material, the sewed piece may twist or other defects may occur during the sewing operation, thereby reducing the operating speed and lowering the production efficiency. Second, to hold the nested material pieces firmly and to push this material piece forward for timing at the time of the sewing operation, a mark may be made on the ends of the material piece or manually stitching at a certain locating point of the material piece To ensure an accurate sewing path. Thus, conventional insole sewing machines involve complicated sewing procedures and fail to ensure consistent quality for the sewn pieces.

In view of the disadvantages inherent in the conventional insole sewing machine having a presser wheel as an idle wheel, another insole sewing machine having an auxiliary supply mechanism has been developed and introduced to the market. This modified insole sewing machine includes a transmission mechanism extending outwardly from a spindle driven by a belt-pulley of a sewing machine and connected to a presser wheel so that the belt pulley not only rotates the feed wheel, And drives the wheel to rotate. In this manner, the presser wheel assists in pushing the piece of material into the sewing operation, thereby causing a defective sewing piece, e.g., twisted, wrinkled, or other factors that cause it to form an overlaid sewed piece, So that the piece of material can always be supplied smoothly for sewing, without being influenced by the difference in thickness or the difference in the type of material piece, the difference in the sewing path or the difference in the area of the material piece.

An insole sewing machine having an auxiliary feed mechanism improves the disadvantage of asynchronously feeding two pieces of material, but the transmission mechanism must extend to the outside of the insole sewing machine and be connected to the presser wheel. This alignment involves a complex architectural design. Further, since both the feed wheel and the presser wheel are rotationally driven by the belt pulley, it is necessary to carry out the additional mechanical means to adjust the transmission mechanism to change the difference between the momentum of the two wheels so that the insole sewing machine Making it inconvenient to use. In view of the above-mentioned disadvantages, it is required to further improve the insole sewing machine of the prior art.

The main purpose of the present invention is to provide an insole sewing machine including a feed wheel and a presser wheel rotationally driven by two independent drive mechanisms. Thus, unlike a conventional insole sewing machine, the feed wheel and the presser wheel in the insole sewing machine of the present invention can rotate in the same time sequence without having to provide a complex transmission mechanism between them. Thus, the mechanical transmission portion of the insole sewing machine can be effectively simplified.

Another object of the present invention is to provide an insole sewing machine including a control unit to which two independent driving mechanisms for driving a feed wheel and a presser wheel, respectively, are connected. The user can change the momentum difference between the feed wheel and the presser wheel by adjusting the rotational speed of the presser wheel by operating the key provided to the control unit without using any mechanical adjustment tool. Thus, the insole sewing machine can be used more conveniently.

In order to achieve the above objects and other objects, an insole sewing machine according to a preferred embodiment of the present invention includes a main body, a main feed mechanism, a needle bar mechanism, a hook transmission mechanism, a material piece stop mechanism, a feed moving mechanism, And a control unit. The main feed mechanism includes a feed spindle located in the main body and connected to a first drive mechanism at one end and to a feed wheel located outside the main body at the other end such that the feed wheel is rotated and driven by a first drive mechanism . The insole sewing machine according to the present invention is characterized in that the feed moving mechanism includes a movable rack mounted on the outer side of the main body, a presser wheel mounted on the movable rack and a second driving mechanism; A presser wheel is coupled to the second drive mechanism through a transmission mechanism provided therebetween such that the presser wheel can be rotationally driven by the second drive mechanism.

The control unit transmits the signal of the first driving mechanism to the second driving mechanism to control the rotation of the second driving mechanism. The user can operate the control unit to adjust the rotational speed of the presser wheel and change the difference between the momentum of the presser wheel and the feed wheel. The control unit according to the present invention can have two different configurations. When the first drive mechanism includes a conventional clutch motor as a spindle motor, the control unit includes an operation display panel, a presser wheel controller, and a location encoder. The presser wheel controller receives the setting set in the operation display panel and outputs the received setting to the second driving mechanism. The position encoder includes a rotational shaft coupled to the first drive mechanism and transmits a signal to the press wheel controller to cause the press wheel controller receiving the signal of the position encoder to rotate the press wheel in the same time sequence as the feed wheel can do.

On the other hand, when the first drive mechanism includes a spindle motor that is electronically controlled and driven, the control unit includes an operation display panel, a spindle motor controller, a presser wheel controller, and a position encoder. The spindle motor controller drives the first drive mechanism, reads the signal of the position encoder, and transmits the received signal to the press wheel controller. The presser wheel controller receives the setting set in the operation display panel and outputs the received setting to the second driving mechanism. The position encoder includes a rotating shaft connected to the first drive mechanism. With this arrangement, the presser wheel controller can read the signal of the spindle motor controller directly and rotate the presser wheel in the same time sequence as the feed wheel.

The transmission mechanism provided between the presser wheel and the second drive mechanism may comprise two operable embodiments. In a first embodiment, the transmission mechanism includes a first rotating shaft having a first end engaged with a presser wheel and a second end engaged with a second driving mechanism, whereby the presser wheel is driven by a second drive mechanism So that it can be rotationally driven.

In a first embodiment of the transmission mechanism, the first rotating shaft engages the presser wheel via a spur gear, and the first rotating shaft and the second driving mechanism are engaged with each other via two bevel gears. Further, in conjunction with the first embodiment of the transmission mechanism, the movable rack has a vertical mounting hole and an inclined opening. The first rotating shaft is assembled in the vertical mounting hole while the second driving mechanism extends and remains through the tilted opening.

In a second embodiment, the transmission mechanism includes a first rotating shaft and a second rotating shaft. The first rotating shaft has a first end engaged with the bottom of the presser wheel and a second end engaged with the first end of the second rotating shaft, the second rotating shaft engaging with the second driving mechanism And a second end to allow the presser wheel to be rotationally driven by the second drive mechanism.

In a second embodiment of the transmission mechanism, the first rotating shaft is engaged with the bottom of the presser wheel through two spur gears meshed with each other, and the first rotating shaft rotates perpendicularly to the second rotating shaft through two bevel gears meshed with each other. And the second rotating shaft is engaged with the second driving mechanism through two bevel gears meshing with each other. Further, in cooperation with the second embodiment of the transmission mechanism, the movable rack has two mounting holes extending in two vertical directions. The first rotating shaft and the second rotating shaft are respectively extended and held through the vertical holes and the horizontal holes of the two mounting holes.

The insole sewing machine of the present invention is characterized in that the feed wheel and the presser wheel are respectively driven to rotate by first and second drive mechanisms which are two independent drive mechanisms. Further, the second driving mechanism is provided on the movable rack to directly drive and rotate the presser wheel. In this way, there is no need to provide a relatively complicated transmission mechanism between the feed wheel and the presser wheel to cause the two wheels to rotate in the same time sequence. Thus, the insole sewing machine of the present invention has an effectively simplified mechanical transmission portion.

Moreover, in the present invention, both the first and second drive mechanisms are connected to the control unit, so that the user can adjust the rotational speed of the presser wheel to directly between the supply wheel and the momentum of the presser wheel on the operation display panel of the control unit Can be changed. Thus, the present invention can be used more conveniently.

The structure and technical means employed by the present invention to achieve the above and other objects will be best understood by referring to the following detailed description of the preferred embodiments and accompanying drawings.
1 is an assembled perspective view of an insole sewing machine according to a first preferred embodiment of the present invention;
Figure 2 is a partial exploded view of Figure 1;
Figure 3 is an exploded perspective view of the feed transport mechanism shown in Figure 2;
Figs. 4A and 4B are conceptual diagrams showing two different types of in-line sewing machines of the present invention and usable spindle motors, and connecting these spindle motors to corresponding control units, respectively; Fig.
Figures 5A and 5B show the feeding mechanism and the main feeding mechanism of the insole sewing machine of the present invention with different moments in the course of feeding two pieces of material;
6 is a perspective view of an insole sewing machine according to a second preferred embodiment of the present invention; And
Figure 7 is an exploded view of the feed movement mechanism shown in Figure 6;

The present design is now described with reference to the accompanying drawings for some preferred embodiments of the present invention. In order to facilitate understanding, the same elements in the preferred embodiment are denoted by the same reference numerals.

Please refer to Fig. 1 and Fig. The insole sewing machine according to the present invention is used to sew the insole and upper of the shoe together. In the first preferred embodiment of the present invention, the insole sewing machine mainly comprises a main body 10, a main feed mechanism 20, a needle bar mechanism 30, a hook transmission mechanism 40, a material piece stop mechanism 50, A mechanism (not shown), a feed movement mechanism 60, and a first drive mechanism 70.

The present invention is characterized in that the feed motion mechanism 60 is driven by an independent drive source. 2 shows the needle bar mechanism 30, the hook transmission mechanism 40 and the material chopping stop mechanism 50 (Fig. 2) to more clearly show the characteristics of the present invention, since all other mechanisms of the present invention are similar to those in a conventional insole sewing machine. ) Is omitted. However, the manner in which the mechanisms 30, 40 and 50 are mounted to the main body 10 will be briefly further described in the following paragraphs.

In the illustrated inhaler sewing machine, the main body 10 includes a case 11 and an upper cover 12. The case 11 has a front side forming a sewing operation side on which a needle bar hole 13, a hook hole 14, an opening 15 and a spindle seat 16 are provided .

The main feed mechanism 20 is located within the main body 10 but has a feed spindle 21 mounted on the spindle seat 16. The feed spindle 21 is shown in Fig. The feed spindle 21 includes one end connected to the feed wheel 22 located outside the main body 10 and the other end having a transmission member (not shown) to which a first drive mechanism The needle bar mechanism 30 and the hook transmission mechanism 40 are connected in common so that the supply spindle 21, the needle bar and the hook are driven to move synchronously by the first drive mechanism 70 The supply wheel 22 is directly rotationally driven by the first drive mechanism 70. [

The needle bar mechanism 30 and the hook transmission mechanism 40 are exposed from the main body 10 but extend rearward to the main body 10 via the needle bar hole 13 and the hook hole 14, To the transmission member. The material scraping stop mechanism 50 is mounted on the outer side of the main body 10 so as to be positioned adjacent to the supply wheel 22. The lubrication mechanism (not shown) is arranged in the upper cover 12 of the main body 10.

See FIG. In a first preferred embodiment, the feed movement mechanism 60 includes a movable rack 61 on which a presser wheel 62 and an independent second drive mechanism 63 are mounted; And a transmission mechanism (64) mounted on the movable rack (61), which is positioned between the presser wheel (62) and the second drive mechanism (63) such that the second drive mechanism (63) rotatably drives the presser wheel ). The movable rack 61 includes a motion spindle 610 having one end extending through the opening 15 into the main body 10 and a rack body 611 located outside the main body 10 . The rack body 611 is substantially n-shaped to define a workspace 612 through which a user can conveniently perform a sewing operation. shaped rack body 611 has one end connected to the motion spindle 610 and the other end of the rack body 611 is connected to the presser wheel 62 and a vertical mounting hole 613 is formed . Further, the rack body 611 has an intermediate portion positioned between the two ends. In the middle portion of the rack body 611, a mounting seat 614 is integrally formed to mount a second driving mechanism 63 thereon, and the inclined opening 615 is formed by the second driving mechanism 63, .

The second driving mechanism 63 includes a motor 630 having a rotating shaft 631. [ The motor 630 assembles the rotating shaft 631 to the shaft member 632 which extends through the inclined opening 615 and has a bevel gear 633 provided at the free end thereof, do. The transmission mechanism 64 includes a first rotating shaft 640 having a first end 641 and an opposite second end 642. The first end 641 has a spur gear 644 mounted thereon for engaging the presser wheel 62. The second end 642 is assembled to the vertical mounting hole 613 and the shaft member And a bevel gear 643 mounted thereon for engagement with the bevel gear 633 provided on the first drive mechanism 632 so that the presser wheel 62 can be independently rotationally driven by the second drive mechanism 63 .

4A and 4B. The first drive mechanism 70 includes a transmission spindle 71 and a spindle motor 72 that extend into the main body 10. The belt 73 is mounted between the transmission spindle 71 and the spindle motor 72 so that the transmission spindle 71 can be rotationally driven by the spindle motor 72. With this arrangement, the feed wheel 22 can be independently rotationally driven by the spindle motor 72 while the presser wheel 62 can be independently driven by the motor 630 of the second drive mechanism 63 And can be rotationally driven. That is, the feed wheel 22 and the presser wheel 62 are rotationally driven by two independent drive mechanisms.

The insole sewing machine according to the present invention may further include a control unit 80 and the control unit 80 may transmit the driving signal of the first driving mechanism 70 to the second driving mechanism 63, (63) rotates in the same time sequence as the first driving mechanism (70). The control unit 80 allows the user to manually adjust the rotational speed of the presser wheel 62 relative to the feed wheel 22 without the need to use any other mechanical adjustment tool to move the presser wheel 62 and the feed wheel 22). ≪ / RTI > Thus, the insole sewing machine of the present invention can be very conveniently used for sewing together shoe insole and upper of different materials.

In the present invention, the spindle motor 72 may be a servomotor that is electronically controlled and driven, or a conventional clutch motor. 4A, when the spindle motor 72 is a servomotor that is electronically controlled and driven, the cooperation control unit 80 controls the operation display panel 81, the spindle motor controller 82, A controller 83 and a position encoder 84. [ The operation display panel 81 is provided with a key (not shown) and a display screen 810 for adjusting the rotational speed of the presser wheel 62. The spindle motor controller 82 drives the spindle motor 72 of the first drive mechanism 70, reads the signal of the position encoder 84, and transmits the read signal to the press wheel controller 83 Is used. The presser wheel controller 83 is used to receive the setting set in the operation display panel 81 and output the received setting to the second driving mechanism 63. [ The position encoder 84 includes a rotary shaft 841 connected to the transmission spindle 71 of the first drive mechanism 70.

4B, when the spindle motor 72 is a conventional clutch motor, the control unit 80 includes an operation display panel 81, a presser wheel controller 83 and a position encoder 84. [ The operation display panel 81 is provided with a plurality of keys (not shown) for controlling the rotational speed of the display screen 810 and the presser wheel 62. The presser wheel controller 83 is used to receive the signal of the position encoder 84, receive the setting set in the operation display panel 81, and output the received setting to the second driving mechanism 63. [ The position encoder 84 includes a rotary shaft 841 connected to the transmission spindle 71 of the first drive mechanism 70.

When using the insole sewing machine of the present invention, the user can adjust the rotational speed of the presser wheel 62 through the control unit 80. 5A. The sewed piece 91 formed by sewing together the two pieces of material 90 is bent bending toward the feed wheel 22 when the presser wheel 62 has a linear velocity that is greater than the speed of the feed wheel 22. [ . On the other hand, when the feed wheel 22 has a linear velocity that is greater than the speed of the presser wheel 62, the tailored piece 91 formed by sewing together the two pieces of material 90 is shown in Figure 5b And can be bent toward the presser wheel 62 as well. It is understood that the bended sewn piece 91 has a varying curvature as a difference between the momentum of the two wheels 22,

Figures 6 and 7 show a second preferred embodiment of the present invention. As shown, the insole sewing machine in the second embodiment includes a main body 10, a main feed mechanism 20, a needle bar mechanism 30, a hook transmission mechanism 40, a material piece stop mechanism 50, Mechanism (not shown), a feed transfer mechanism 60 and a first drive mechanism 70. [ The main body 10, the main feed mechanism 20, the needle bar mechanism 30, the hook transmission mechanism 40, the material piece stopping mechanism 50, the lubrication mechanism and the first drive mechanism 70 in the second embodiment ) Are the same as those in the first embodiment, and these components are not repeatedly described in this specification. And, only the feed movement mechanism 60 in the second embodiment will be described below.

6 and 7, the feed movement mechanism 60 in the second embodiment includes a presser wheel 62 functioning as an independent drive source and a second drive mechanism 63 mounted thereon And further comprises a movable rack (61). Further, a transmission mechanism 64 is further provided between the presser wheel 62 and the second drive mechanism 63.

The movable rack 61 includes a motion spindle 610 having one end extending through the opening 15 into the main body 10 and a rack body 611 located outside the main body 10 . The rack body 611 is substantially n-shaped to define a workspace 612 through which a user can conveniently perform a sewing operation. The n-shaped rack body 611 has one end connected to the motion spindle 610 and the other end of the rack body 611 is connected to the press wheel 62 and two vertically extending two A mounting hole 616 is formed. Further, the rack body 611 has an intermediate portion positioned between the two ends. In the middle portion of the rack body 611, the mounting seat 614 is assembled so that the second driving mechanism 63 is mounted thereon.

The second driving mechanism 63 includes a motor 630 having a rotating shaft 631. [ The motor 630 is fixedly mounted on the mounting seat 614 by assembling the rotating shaft 631 to the bevel gear 633. [ The transmission mechanism 64 includes a first rotating shaft 640 and a second rotating shaft 645 that extend through the vertical and horizontal holes of the two mounting holes 616 in the rack body 611, respectively. The first rotating shaft 640 includes a first end 641 that engages the bottom of the presser wheel 62 and a second end 642 that engages the first end 646 of the second rotating shaft 645. [ Respectively. The second end 647 of the second rotating shaft 645 is engaged with the second driving mechanism 63 so that the presser wheel 62 can be rotationally driven by the second driving mechanism 63. 7, the bottom of the first rotating shaft 640 and the presser wheel 62 are engaged with each other through engagement of the spur gear 644 with another spur gear 621; The second end 642 of the first rotating shaft 640 engages the first end 646 of the second rotating shaft 645 through engagement of the bevel gear 643 and another bevel gear 648. The second end portion 647 of the second rotating shaft 645 is connected to the second driving mechanism 63 through the engagement of the bevel gear 639 provided on the rotating shaft 631 of the motor 630 and the bevel gear 649 ).

This invention has been described in terms of some preferred embodiments, but it is understood that many modifications and variations can be made in the described embodiments without departing from the scope and spirit of the invention, which is intended to be limited only by the appended claims.

Claims (10)

As an insole sewing machine,
A main body, a main feed mechanism, a needle bar mechanism, a hook transmission mechanism, a material piece stop mechanism, a feed movement mechanism, a first drive mechanism, and a control unit;
Wherein the main supply mechanism is located within the main body and has a supply spindle and a supply wheel, the supply spindle is connected to the first drive mechanism, and the supply wheel is located outside the main body and connected to the supply spindle Thereby enabling the feed wheel to be rotationally driven by the first drive mechanism;
In the insole sewing machine,
Wherein the feed mechanism comprises a movable rack mounted on an outer side of the main body, a presser wheel and a second drive mechanism mounted on the movable rack, and a second drive mechanism mounted on the presser wheel and the second drive mechanism, Including a transmission mounted on a movable rack; Wherein the presser wheel is rotatably driven by the second drive mechanism and the control unit transmits a signal of the first drive mechanism to the second drive mechanism such that the second drive mechanism drives the first drive mechanism and the second drive mechanism, And to vary the momentum difference between the presser wheel and the supply wheel by controlling the rotational speed of the presser wheel relative to the supply wheel. delete 2. The apparatus of claim 1, wherein the control unit comprises an operation display panel, a presser wheel controller and a position encoder; The presser wheel controller receives a signal of the position encoder, receives a setting set on the operation display panel, and outputs the received setting to the second driving mechanism; Wherein the position encoder includes a rotating shaft connected to the first driving mechanism. 2. The apparatus of claim 1, wherein the control unit includes an operation display panel, a spindle motor controller, a presser wheel controller, and a position encoder; The spindle motor controller actuating the first drive mechanism, reading a signal of the position encoder, and transmitting the received signal to the presser wheel controller; The presser wheel controller receives the setting set on the operation display panel and outputs the received setting to the second driving mechanism; Wherein the position encoder includes a rotating shaft connected to the first driving mechanism. 2. The apparatus of claim 1, wherein the transmission mechanism comprises a first rotating shaft; The first rotating shaft having a first end engaged with the presser wheel and a second end engaged with the second drive mechanism such that the presser wheel is rotationally driven by the second drive mechanism Wherein the insole is sewn. 5. The apparatus of claim 4, wherein the first rotating shaft of the transmission mechanism engages the presser wheel via a spur gear, and wherein the first rotating shaft and the second driving mechanism engage each other via two bevel gears Insole sewing machine. 5. The apparatus of claim 4, wherein the moveable rack has a vertical mounting hole and an angled opening; Wherein the first rotating shaft of the transmission mechanism is assembled to the vertical mounting hole and the second driving mechanism is extended and held through the tilted opening. The transmission mechanism of claim 1, wherein the transmission mechanism includes a first rotating shaft and a second rotating shaft; Wherein the first rotating shaft has a first end engaged with a bottom of the presser wheel and a second end engaged with a first end of the second rotating shaft and the second rotating shaft is connected to the second driving mechanism And an engaging second end, whereby the presser wheel can be rotationally driven by the second driving mechanism. 8. The spindle according to claim 7, wherein the first rotating shaft is engaged with the bottom of the presser wheel through two spur gears meshed with each other, and the first rotating shaft is engaged with the second rotating shaft through two bevel gears meshing with each other And the second rotating shaft is engaged with the second driving mechanism through two bevel gears meshed with each other. 8. The apparatus of claim 7, wherein the moveable rack has two mounting holes extending in two vertical directions; Wherein the first rotating shaft and the second rotating shaft are extended and held through vertical and horizontal holes of the two mounting holes, respectively.

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