KR101365479B1 - Thread tension adjusting device, head of embroidering machine using the same and apparatus for controlling thread tension of embroidering machine therefor - Google Patents

Abstract

Disclosed are a mounting force adjusting device of a embroidery machine, a head of a embroidery machine, and a tension control device using the same.
The tension adjusting device includes a tension adjusting shaft connected to one end of the tension adjusting plate and installed through the support frame; A tension control eccentric shaft which has an eccentricity and the other end of the tension control shaft is in contact with the circumference; And an eccentric shaft bracket for rotatably supporting the tension adjusting eccentric shaft.

Description

Thread tension adjusting device, head of embroidering machine using the same and apparatus for controlling thread tension of embroidering machine therefor}

The present invention relates to a tension control device of the embroidery machine, and more particularly, a tension control device for adjusting the tension applied to the thread by using a tension control motor and a tension control eccentric shaft, the head of the embroidery machine including the same and the tension control of the embroidery machine suitable thereto Relates to a device.

Embroidery machine is a device that embroiders the selected pattern by using the embroidery thread (or the upper thread) while fixing the fabric to the frame device to make it flat and moving the frame freely in any X, Y direction in the plane. .

For example, more than 6 or 12 types of threads can be used, and it is common to supply each thread with a constant value of tension in order to maintain a constant pattern of embroidery in the process of embroidering.

When the tension of the thread is weak in the embroidery machine, the embroidery pattern is loosened while the tension is high, and the embroidery pattern is dense and the thread is easily broken in the embroidery process.

In addition, the material used in the embroidery machine may have a different material and thickness. As the type of the fabric is changed, the tension value of each thread to be supplied must be adjusted differently, so that the tension value of each thread is used to repeatedly produce the same pattern embroidery. The tension control device to adjust the constant is one of the important components of the embroidery machine.

1 is a front view and a perspective view showing the configuration of a tension control device of the embroidery machine in the prior art.

In the embroidery machine, the thread is sewn on the needle and the embroidery is embroidered on the fabric by the lowering of the needle bar.

In the process of embroidering the fabric by the embroidery machine, for example, by repeatedly embroidering the embroidery pattern in one position, the tension of the thread increases, the thread is broken.

That is, in the case of producing embroidery products in the embroidery machine, the tension of the thread is often changed due to various causes, so that the thread may be broken in the process of producing the embroidery product by the embroidery machine.

In addition, the embroidery machine uses a plurality of threads of various colors, each thread is not constant because the thickness may vary in the tensile strength due to differences in thickness, etc., if the type of fabric (fabric) to be sewn In addition, the thread tension must be adjusted to change together.

In addition, in the case of changing the thread of the embroidery machine to a different kind or the fabric (fabric) to a different kind, it is necessary to operate the tension adjusting device attached to each thread to adjust the tension of the thread to an appropriate value.

Referring to FIG. 1, a plurality of tension adjusting devices 3 are provided for adjusting the tension of a thread provided to each needle bar. The device shown in Figure 1 may be installed on the head of the embroidery machine.

A conventional tension adjusting device includes a tension adjusting plate through which a thread passes, a spring for elastically supporting the tension adjusting plate, and a tension adjusting nut for adjusting the elastic force of the spring in close contact with the tension adjusting plate. A plurality of tension adjusting devices are provided for each thread.

When the tension adjusting nut of the tension adjusting device is rotated from side to side, the elastic force by the spring is adjusted, and the friction force of the tension adjusting plate, that is, the tension applied to the thread passing through the tension adjusting plate is changed by this elastic force.

If it is necessary to adjust the tension, the operator adjusts the tension by rotating the tension adjustment knob left and right so that the desired tension is obtained.

The tension control operation by the conventional tension control device as shown in FIG. 1 requires a lot of time, and the more unskilled people take more time than the skilled person. In particular, in the embroidery machine having a head in which a plurality of needle bars are installed, it is practically impossible to uniformly adjust the tension of the threads corresponding to the respective needle bars.

As described above, in the conventional tension control device, since the tension of each thread cannot be uniformly maintained in response to the request for changing the tension value of the thread generated during the embroidery process, the thread is broken due to the tension difference between the threads. There was a problem such as the frequent occurrence of the embroidery production takes a lot of time and the occurrence of defects.

Therefore, it is necessary to develop a technology to reduce the production time of embroidery products by reducing the time required to adjust the tension of each thread in response to the demand for changing the tension value of the thread in the embroidery machine.

In addition, there is a need to develop a technique that does not break the thread due to the tension between the threads by maintaining a uniform tension value of the thread in response to the request to change the tension value of the thread in the process of producing the embroidery product by the embroidery machine.

The present invention has been made to solve the problems of the prior art as described above is provided with a tension control shaft to be advanced by the tension control eccentric shaft and the tension control to adjust the tension applied to the thread by adjusting the rotation angle of the tension control eccentric shaft It is an object to provide a device.

Another object of the present invention is to provide a tension control device that can easily adjust the tension for a plurality of yarns by having a tension control eccentric shaft extending in the longitudinal direction and a plurality of tension control shaft to be advanced by the tension control eccentric shaft. Is in.

Still another object of the present invention is to provide a head of an embroidery machine provided with the tension adjusting device.

It is still another object of the present invention to provide a tension control device of an embroidery machine capable of detecting a tension applied to a thread and automatically maintaining a constant applied to the thread.

The above objects and advantages of the present invention will become apparent to those skilled in the art from the detailed description of the invention.

And a control unit.

Here, it is preferable to further include a tension control eccentric shaft drive means for rotating the tension control eccentric shaft.

Here, the tension control eccentric shaft drive means

A driven pulley coupled to the tension control eccentric shaft;

A drive pulley operatively connected to the driven pulley; And

A tension control motor for rotating the drive pulley; .

Here, it is preferable to further include a tension control shaft return spring for elastically supporting the tension control shaft.

Here, the other end of the tension control shaft in contact with the tension control eccentric shaft is formed with a flange for smooth contact with the tension control eccentric shaft and the tension control shaft return spring is installed between the flange and the support frame It is preferable to be.

The tension control eccentric shaft extends in the longitudinal direction, it is preferable that a plurality of tension control shafts corresponding to each of the plurality of yarns are installed on the tension control eccentric shaft.

The eccentric shaft bracket is preferably supported by the support frame, and is installed to support the tension control motor.

Here, the sensor sensing plate is coupled to the tension control eccentric shaft to rotate; And

An eccentric shaft sensor for detecting a position of the sensor sensing plate;

As shown in Fig.

The head of the embroidery machine according to the present invention to achieve the above another object

In the head of the embroidery machine comprising a needle bar support for supporting a plurality of needle bar,

A plurality of tension adjusting plates respectively corresponding to the plurality of needle bars;

A support frame on which the tension adjusting plate is supported;

A plurality of tension adjusting shafts connected to each of the plurality of tension adjusting plates and installed to penetrate the support frame;

A tension control eccentric shaft which has an eccentricity and the other end of the tension control shaft is in contact with the circumference; And

An eccentric shaft bracket for rotatably supporting the tension adjusting eccentric shaft;

And a control unit.

Here, it is preferable to further provide the auxiliary tension adjusting device.

Tension control device of the embroidery machine according to the present invention for achieving the above another object

A tension adjusting device for adjusting the tension applied to the thread;

A tension detector for detecting a tension applied to the thread;

A control unit which monitors the tension detected by the tension detector and controls the tension adjusting device so that a change in tension is reduced; / RTI >

Here, the tension adjusting device

A support frame on which the tension adjusting plate is supported;

A tension control shaft connected to one end of the tension control plate and installed to penetrate the support frame;

A tension control eccentric shaft which has an eccentricity and the other end of the tension control shaft is in contact with the circumference;

An eccentric shaft bracket for rotatably supporting the tension adjusting eccentric shaft; And

Tension control eccentric shaft drive means for rotating the tension control eccentric shaft under control of the controller;

And a control unit.

The tension adjusting device according to the present invention includes a motor driven in response to a control signal and a tension adjusting eccentric shaft driven by the motor to adjust the elastic force applied to the tension adjusting plate, thereby automatically adjusting the tension applied to the upper thread. Has the effect of

On the other hand, the tension control device of the embroidery machine according to the present invention detects the tension value of each thread by the sensor unit, and automatically adjusts the tension value of each thread by the motor and the tension control eccentric shaft to adjust the tension value of each thread It can reduce the time to do it.

In addition, the present invention can automatically adjust the tension value of each thread to a set value even in the working environment conditions change frequently from the embroidery machine can reduce the production time of embroidery products, increase productivity and stabilize the quality.

1 is a front view and a perspective view showing the configuration of a tension control device of the embroidery machine in the prior art.
2 and 3 are a front perspective view and a rear perspective view showing an embodiment of the tension adjusting device according to the present invention, respectively.
4 is a perspective view showing the configuration of the tension control device shown in FIG.
5 is a rear perspective view showing the configuration of the tension control device shown in FIG.
6 is a side view showing the configuration of the tension control device shown in FIG.
7 is a front view and a partially enlarged view showing the configuration of the embroidery machine head according to the present invention.
8 is a side view and a partially enlarged view showing the configuration of the tension detector shown in FIG.
9A and 9B are side views illustrating the embroidery machine head according to the present invention.
Figure 10 schematically shows a mounting force control device of the embroidery machine according to the present invention.
11 shows an application example of the mounting force adjusting device according to the present invention.
12 shows an application example of the mounting force adjusting device according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

As the inventive concept allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all transformations, equivalents, and substitutes included in the spirit and scope of the present invention. In addition, in describing the present invention, when it is determined that the detailed description of the related known technology may obscure the gist of the present invention, the detailed description and illustration thereof will be omitted.

On the other hand, since the embroidery machine uses a plurality of threads and is a device for producing embroidery of a design pattern selected on a fabric in various colors, the threads are described in the singular or plural in the following description as appropriate to the context.

On the other hand, in the specification and the summary of the invention, the yarn may be supplied from the top of the head or may be supplied from the bottom.

2 and 3 are a front perspective view and a rear perspective view showing an embodiment of the tension adjusting device according to the present invention, respectively.

2 and 3, an embodiment 100 of the tension control device according to the present invention is a tension control device 130 for adjusting the tension applied to the thread by the action of the tension control motor and the tension control eccentric shaft and Auxiliary tension adjusting device (115).

The auxiliary tension adjusting device 115 corresponds to a conventional tension adjusting device including a tension adjusting plate and a tension adjusting knob for adjusting an elastic force of a spring in close contact with the tension adjusting plate, and to assist the tension adjusting device 130. will be.

As will be described later, although the tension adjusting knob 139 is also provided in the tension adjusting device 130, since it is for fine-tuning the tension adjusted by the tension adjusting eccentric shaft 134, the tension adjusting motor 131 When the tension control device 130 becomes inoperable due to a failure of the device, it may be difficult to apply sufficient tension to the thread only by the tension control knob 139 provided on the tension control device 130. In this case, the tension is imparted to the seal 50 by the auxiliary tension adjusting device 115.

4 is a perspective view showing the configuration of the tension control device shown in FIG.

Referring to FIG. 4, the tension adjusting device 130 according to the present invention includes a tension adjusting plate 137, a tension adjusting shaft 135, a tension adjusting eccentric shaft 134, a sensor sensing plate 134b, and an eccentric shaft sensor ( 134c), tension adjusting spring 138, tension adjusting shaft return spring 136 and tension adjusting knob 139.

The tension adjusting dish 137 is supported by the tension adjusting shaft 135.

The tension adjusting shaft 135 is installed through the support frame 418 and one end thereof is connected to the tension adjusting plate 137 and the other end thereof is in surface contact with the tension adjusting eccentric shaft 134, so that the tension adjusting eccentric shaft ( In accordance with the rotation of the 134, it slides up and down in the direction perpendicular to the tension control eccentric shaft 134. According to the sliding movement of the tension adjusting shaft 135, the tension adjusting plate 137 connected thereto is advanced and thus the tension applied to the thread is adjusted.

The tension control shaft return spring 136 is installed to facilitate the return of the tension control shaft 135. The tension adjusting shaft return spring 136 is installed between the support frame 418 and the end of the tension adjusting shaft 135, and the tension adjusting plate 137 when the tension adjusting shaft 135 is slid to the left maximum. The maximum elastic force is applied to the tension control shaft 135 and the minimum elastic force is applied to the tension adjusting plate 137 when the maximum sliding to the right.

By the tension control shaft return spring 136, the sliding movement is performed with the end of the tension control shaft 135 in close contact with the surface of the tension control eccentric shaft 134. As shown in FIG. 4, an end of the tension adjusting shaft 135 may allow a flange to be formed so that the tension adjusting return spring 136 may be easily installed.

The tension adjusting shaft 135 is connected to the tension adjusting plate 137. As the tension adjusting shaft 135 slides, the elastic force of the tension adjusting spring 138 applied to the tension adjusting dish 137 is changed, and accordingly, the tension applied to the thread passing through the tension adjusting dish 137 is adjusted.

At the other end of the tension adjustment plate 137, a tension adjustment spring 138 is installed. The tension adjusting spring elastically supports the tension adjusting plate 137.

The sensor detecting plate 134b and the eccentric shaft sensor 134c are provided to detect the rotational position of the tension adjusting eccentric shaft 134.

5 is a rear perspective view showing the configuration of the tension control device shown in FIG. Referring to FIG. 5, a driven pulley 133, a driving pulley 132, and a motor 131 are provided to rotate the tension control eccentric shaft 134.

The tension adjusting eccentric shaft 134 is rotated by the driven pulley 133. The driven pulley 133 is coupled to the eccentric shaft of the tension control eccentric shaft 134 and is operatively coupled to the drive pulley 132 through a timing belt. The driving pulley 132 is rotated by the rotation of the tension control motor 131.

The tension control eccentric shaft 134 has a cam shape, that is, has an eccentricity. The cross section of the tension control eccentric shaft 134 may be circular or elliptical. The tension control shaft 135 is in contact with the surface of the tension control eccentric shaft 134 in a state of being elastically supported by the tension control shaft return spring 136.

Therefore, as the tension control eccentric shaft 134 rotates, the tension control shaft 135 shows a sliding motion in the vertical direction with respect to the tension control eccentric shaft 134. That is, the tension adjusting eccentric shaft 135 and the tension adjusting shaft 135 serve as a cam and a push rod.

The distance in which the tension control shaft 135 slides to the maximum corresponds to the distance from the eccentricity of the tension control eccentric shaft 134 to the furthest circumference, and the distance sliding to the minimum corresponds to the distance from the eccentric to the nearest circumference.

Accordingly, the cross-sectional shape of the tension adjusting eccentric shaft 134, the position of the eccentric, and the like are determined so that an appropriate sliding limit is obtained.

The tension applied to the thread corresponds to the frictional force of the tension adjusting plate 137, that is, the elastic force applied to the tension adjusting plate through which the thread passes, and this elastic force is applied to the slide distance of the tension adjusting shaft 135 coupled to the tension adjusting plate. Is determined by.

Therefore, the tension applied to the thread can be controlled by controlling the rotation angle of the tension control motor 131.

The driven pulley 133, drive pulley 132, tension control motor 131 and timing belt 508 correspond to the tension control eccentric shaft drive means in the summary of the present invention. Although not described in detail, the driven pulley 133 and the driving pulley 132 are operatively connected by the timing belt 508.

Another example of the tension control eccentric shaft drive means is to use a tooth. Specifically, the driven gear may be coupled to one end of the tension control eccentric shaft 134, and a driving gear engaged with the driven gear and a motor for driving the driving gear may be provided. Here, the driven gear may be installed on the eccentric shaft, the position may be the edge or the center of the tension control eccentric shaft 134. However, in view of the fact that the rotation angle of the tension control eccentric shaft 134 can be controlled substantially discretely according to the dimensions of the gear, the driving force of the timing belt shows excellent driving ability, and the like. It is more effective to use 133 and 132 and timing belt 508.

On the other hand, referring to Figure 4, a plurality of tension control shaft 135 is provided with respect to one tension control eccentric shaft 134, the slide movement of the plurality of tension control shaft 135 is tension adjustment eccentric The same aspect can be controlled by the rotational movement of the shaft 134.

Each tension adjusting shaft 135 corresponds to each of a plurality of needle bars (not shown) installed in the head, so that the plurality of needle bars are controlled by controlling the rotation angle of the tension control motor 131 rotating the tension adjusting eccentric shaft 134. The tension of the yarns provided to each of them can be easily controlled.

Accordingly, even if the needle bar is used a lot after the initial tension setting or the working conditions change from time to time, the tension for each of the plurality of needle bars installed in the head can be easily adjusted by a simple operation, thereby reducing work time and increasing efficiency of product production.

In addition, since the tension can be set regardless of the skill of the operator, uniform embroidery quality can be obtained.

6 is a side view showing the configuration of the tension control device shown in FIG.

Referring to FIG. 6, the sensor sensing plate 134b is implemented as a semicircular rotating plate. The reference position for driving the tension control eccentric shaft 134 is determined by detecting the positions of two sides of the sensor sensing plate 134b by the eccentric shaft sensor 134c while rotating the tension control eccentric shaft 134. By grasping the rotational driving force required between the positions of the two sides, it is possible to grasp the driving amount to be applied to the tension control motor 131 to set the required tension.

The support frame 418 supports the tension adjusting device 130. The eccentric shaft bracket 420 is supported by the support frame 418, the tension control eccentric shaft 134 is rotatably supported by the eccentric shaft bracket 420. The eccentric shaft bracket 420 also supports the tension control motor 131.

7 is a front view and a partially enlarged view showing the configuration of the embroidery machine head according to the present invention.

Referring to FIG. 7, the head 110 of the embroidery machine according to the present invention includes a tension adjusting device 130 and a tension detector 120.

Embroidery head 110 is a needle bar that is driven up and down by a needle bar drive device not shown in the drawing to constitute a part by embroidering the fabric using the color thread 150 guided through the upper thread hanger 170 And is provided at the bottom of the needle bar is provided with a plurality of fabric pressing portion 160, the presser foot (160) to press the fabric so as not to move while the needle 150 is sewn and the embroidery fabric is embroidered.

The upper thread hanger 170 guides the thread released from the failure (not shown) to the embroidery machine head 110. The thread tension adjusting device 130 is installed on a part of the upper side of the embroidery machine head 110 and adjusts the tension applied to the thread 150 guided through the upper thread hanger 170.

The mounting force adjusting device 130 is shown and described with reference to FIGS. 2 to 4 and is installed on the upper portion of the embroidery machine head 110 and includes a tension control motor and a tension control eccentric shaft. The tension control motor rotates the tension control eccentric shaft in response to a control signal for controlling the tension of the seal 150. According to the rotation of the tension control eccentric shaft is adjusted the elastic force of the spring (not shown) in close contact with the tension adjusting plate 137, the tension applied to the seal 150 is controlled.

The auxiliary mounting force adjusting device 115 corresponds to a conventional tension adjusting device having a tension adjusting plate and a mounting force adjusting dial for adjusting an elastic force of a spring in close contact with the tension adjusting plate. It is to assist.

As will be described later, the tension adjusting knob 139 is also provided in the mounting force adjusting device 130, but because this is to fine-tune the tension adjusted by the tension control eccentric shaft 134, the failure of the tension control motor When the mounting force adjusting device 130 becomes inoperable due to the like, it may be difficult to apply sufficient tension to the color chamber 150 only with the tension adjusting knob installed in the mounting force adjusting device 130. In this case, the tension is imparted to the seal 150 by the auxiliary mounting force adjusting device 115.

The tension detector 120 detects a tension applied to the thread 150, and the detected tension of the colored yarn is provided to the embroidery machine controller.

8 is a side view and a partially enlarged view showing the configuration of the tension detector shown in FIG.

Referring to FIG. 8, the tension detecting unit 120 is installed at the lower side of the embroidery machine head 110 to automatically detect the tension of each thread 150. 124, the second height fixing unit 126, and the sensor unit 128.

Positioning unit 122 is installed on the front of the embroidery machine head 110 is supplied with a thread 150 from the tension adjusting device 130 and the position and direction of the supply of each thread 150 is the corresponding position guide hole ( Each of them is specified through 121).

The first height fixing portion 124 is installed below the position fixing portion 122, and the seal 150 supplied from the position designated by the position fixing portion 122 passes through the first height fixing hole 123 to a predetermined height. Do it.

The second height fixing part 126 is installed below the first height fixing part 124 so that the thread 150 passed by the first height fixing part 124 passes through the second height fixing hole 125 to a predetermined height. do.

The sensor unit 128 is installed between the first height fixing part 124 and the second height fixing part 126, and the chamber 150 passes through the first height fixing hole 123 and the second height fixing hole 125. ) Tension is detected.

The sensor unit 128 for detecting the tension of the seal 150 may be implemented by any one selected from a pressure sensor and a tension sensor.

In addition, the sensor unit 128 may be implemented by any one selected from a wheel-type or a pin type. 8 illustrates a pin type sensor unit 128.

9A and 9B are side views illustrating the embroidery machine head according to the present invention.

9A and 9B, the tension adjusting device 130 is installed on the upper side of the embroidery machine head 110 and drives the tension control motor in response to the control signal to rotate the tension control eccentric shaft.

The tension control motor 131 is installed in a fixed state on the support frame 418 of the embroidery machine head 110 and rotates in a left turn direction or a right turn direction to a size corresponding to a control signal applied to the tension adjusting device 130.

The driving pulley 132 is installed in a fixed state at one end of the rotation shaft constituting the tension control motor 131 and rotates together with the rotation shaft of the tension control motor 131.

The driven pulley 133 is installed in a fixed state at one end of the tension control eccentric shaft 134 and transmits a driving force to the tension control eccentric shaft 134 in conjunction with the timing belt 140 and the drive pulley 132.

The tension control eccentric shaft 134 is installed in a state of being fixed to the rotating shaft of the driven pulley 133 and rotates by the rotation of the driven pulley 133, the circular or oval having an eccentric cross section of the tension control eccentric shaft 134 Becomes In addition, the sensor sensing plate 134b, the eccentric shaft sensor 134c, and the bushing 134d are installed in the eccentric shaft bracket 420 installed in the support frame 418.

The sensor sensing plate 134b is installed in a fixed state at one end of the rotation shaft of the tension control eccentric shaft 134, and thus, the rotation position of the tension control eccentric shaft 134 may be confirmed.

The eccentric shaft sensor 134c is installed in a fixed state on one side of the embroidery machine head 110 and detects a rotation position of the sensor sensing plate 134b.

The eccentric shaft sensor 134c outputs a detection signal to the embroidery machine control unit 140 when detecting both sides of the semi-circular sensor detection plate 134b, and the embroidery machine control unit 140 analyzes the signal to adjust the tension control eccentric shaft 134. Check the rotation position of, and based on this can output a control signal to rotate the tension control eccentric shaft 134 to the desired rotation position.

Bushings (134d) are respectively installed at both ends of the eccentric shaft of the tension control eccentric shaft (134) to rotatably support the tension control eccentric shaft (134).

The tension adjusting shaft 135 is installed to penetrate the support frame 418 of the embroidery machine head 110, and one end thereof is in contact with the tension adjusting eccentric shaft 134 and is advanced by the rotation of the tension adjusting eccentric shaft 134. The tension of the seal 150 can be adjusted.

The tension control shaft return spring 136 is installed between one end of the tension control shaft 135 in the state penetrating the embroidery machine head 110 and the support frame 418 of the embroidery machine head 110 to generate tension. One end of the shaft 135 acts in close contact with the surface of the tension control eccentric shaft 134.

The tension adjusting plate 137 may be installed on the other side of the tension adjusting shaft 135 to adjust the tension of the seal 150.

The tension adjustment spring 138 is inserted in the next order of the tension adjustment plate 137 in the other part of the tension adjustment shaft 135 to generate an elastic force, the tension as the operator manually operates the tension adjustment knob 139 The tension applied to the seal 150 may be finely adjusted by increasing or decreasing the pressing force applied to the adjustment dish 137.

The tension adjusting knob 139 is installed in a state fixed to the other end of the tension control shaft 135 in a state in which the tension adjustment plate 137 and the tension control spring 138 are sequentially installed on the tension control shaft 135. Allows the user to manually adjust the tension of the thread.

The tension adjusting knob 139 enables to manually adjust the tension of the seal 150 even when it is impossible to adjust by the tension control motor 131.

The embroidery machine control unit 140 receives the tension value of the thread 150 detected by the tension detection unit 120 and analyzes it to output a corresponding control signal for adjusting the tension of the thread 150 to the tension control device 130.

The yarn 150 is a yarn having any one color among a plurality of colors, and may vary in thickness, tensile strength, and the like.

The fabric pressing unit 160 may press the fabric so that the fabric does not move while the needle squeezing the thread 150 passes through the fabric to embroider.

The operation of the apparatus shown in FIG. 9 will be described in detail.

Embroidery machine is provided with a plurality of threads 150, but while the selected one of the threads 150 to produce the embroidery by the sewing operation, the other thread is a standby state is not able to place the embroidery.

The embroidery machine is supplied from a spool type thread in which the thread 150 is installed on the upper side of the embroidery machine head 110.

Since the thread 150 passes through the tension adjusting device 130 and the auxiliary tension adjusting device 115, the thread 150 is supplied to the needle at the position where the tension is adjusted.

Embroidery machine can be repeatedly embroidered in a specific part of the fabric due to the design pattern of the embroidery to be produced and in this part can be increased tension of the thread 150, and in addition to the tension of the thread 150 due to various other causes have.

The thread 150 of the embroidery machine may repeat a state in which the tension is increased and then lowered and raised again according to a design pattern of the embroidery at an unspecified period. In addition, each thread 150 may have a different tension in nature.

The present invention detects the tension of each thread 150 and automatically adjusts the tension of each thread 150 using the tension control eccentric shaft 134.

The thread 150 passing through the tension adjusting device 130 and the auxiliary tension adjusting device 115 passes through the position guide hole 121 of the position fixing part 122 and fixes the first height of the first height fixing part 124. It passes through the hole 123 and contacts the sensor unit 128.

After the thread 150 is in contact with the sensor unit 128 and passes through the second height fixing hole 125 of the second height fixing part 126 again, the thread 150 is threaded to the needle at the corresponding position via the direction guide part 129. do.

The height formed by the first height fixing hole 123 and the second height fixing hole 125 from the front and the surface of the embroidery machine head 110 is the height formed by the corresponding portion of the sensor unit 128 that the thread 150 contacts. Lower is preferred.

Therefore, the seal 150 is always maintained in close contact with the sensor unit 128 while passing through the first height fixing hole 123 and the second height fixing hole 125.

When the embroidery machine produces embroidery products, the tension of each thread 150 may be changed by various causes, such as the type of fabric and the position of the design pattern on which the embroidery is placed.

The sensor unit 128 detects a corresponding tension value of the thread 150 for producing embroidery and supplies or applies the detected tension value to the embroidery machine control unit 140.

One embroidery machine head 110 cannot embroider with two or more threads 150 at the same time and must be embroidered using one thread 150 at a time. Therefore, the sensor unit 128 can detect the tension of each thread 150, respectively, and the embroidery machine control unit 140 can output a corresponding control signal for automatically adjusting the tension value of each thread 150, respectively. .

The embroidery machine control unit 140 analyzes the tension value applied from the sensor unit 128 and compares it with a predetermined tension value set in the thread 150 and sets a predetermined value when the embroidery machine control unit is larger or smaller than the predetermined tension value set in the thread. The control signal to generate a tension value is generated and supplied to or applied to the tension adjusting device 130.

Since the tension control device 130 applies the corresponding control signal applied from the embroidery machine control unit 140 to the tension control motor 131, the tension control motor 131 is driven to rotate left or right at a controlled angle or size.

The driving pulley 132 and the driven pulley 133 are rotated together by the rotational drive of the tension control motor 131.

The driving pulley 132 and the driven pulley 133 transmit the rotational power of the tension control motor 131 to the tension control eccentric shaft 134.

That is, when the tension control motor 131 rotates in the left turn or right turn direction, the tension control eccentric shaft 134 rotates correspondingly.

Since the tension control eccentric shaft 134 rotates by a rotation amount corresponding to the rotation amount of the tension control motor 131, the tension control eccentric shaft 134 pushes one end of the tension control shaft 135 to return the tension control shaft spring ( The compression control shaft 135 is moved forward while the compression state is released or the compression state is released. The tension control shaft 135 is retracted by the elastic force that the tension control shaft return spring 136 extends.

Here, the advance of the tension control shaft 135 is to proceed in the direction in which the tension control knob 139 is located, the reverse will be described as proceeding in the direction in which the tension control eccentric shaft 134 is located.

When the tension adjusting eccentric shaft 134 is rotated and the tension adjusting shaft 135 is advanced toward the tension adjusting knob 139, the tension adjusting spring 138 is pushed toward the tension adjusting knob 130 to thereby be tensioned by the tension adjusting spring 138. It is possible to reduce the pressing force applied to the tension adjusting plate () and, accordingly, to lower the tension value of the seal 150.

On the other hand, when the tension control eccentric shaft 134 is rotated and the tension control shaft 135 retreats, the retraction toward the tension control eccentric shaft 134 increases the pressing force applied to the tension control dish () by the tension adjustment spring 130. The tension value of the seal 150 can be adjusted to be high.

In addition, the tension value of the seal 150 may be finely adjusted by the driving pulley 132 and the driven pulley 133, and the adjusted tension value may be kept constant even in an environment having vibration.

Therefore, according to the present invention, the tension value of the thread 150 detected by the tension detection unit 120 is analyzed by the embroidery machine control unit 140, and the control signal is output to the tension control device 130 to automatically output the tension of the thread 150. There is an advantage that can be precisely adjusted.

In addition, there is an advantage that the adjusted tension value of the seal 150 is stably maintained by the driving pulley 132 and the driven pulley 133.

9A and 9B, the tension control eccentric shaft 134 extends in the longitudinal direction, and a plurality of tension control shafts are installed on the tension control eccentric shaft 134, but is not limited thereto.

Figure 10 schematically shows a mounting force control device of the embroidery machine according to the present invention.

Referring to FIG. 10, the embroidery machine control unit 140 generates a control signal for controlling the mounting force controller 130 based on the tension of the color thread detected by the tension detection unit 120.

Although the mounting force adjuster 130 is shown to be controlled based on the tension of the color yarn detected by the tension detector 120 in FIG. 10, the mounting force adjuster 130 is also controlled by a remotely connected control device (not shown). Can be.

Figure 11 shows an application example of the mounting force adjusting device according to the present invention, in particular an example of a multi-head embroidery machine. Referring to FIG. 11, a plurality of embroidery machine heads 110 each including a plurality of needle bars are provided. An upper thread hanger 170 is formed on the upper side of the embroidery machine head 110 to guide the thread 150 provided from the failure (not shown) to the embroidery machine head 110.

Figure 12 shows an application example of the mounting force adjusting device according to the present invention, in particular an example of a chenille embroidery machine. 12, it can be seen that the thread is provided under the embroidery machine differently from that shown in FIG.

As such, the mounting force adjusting device according to the present invention can be applied to both cases where the seal is provided above or below the head.

While the present invention has been described in detail with respect to the embodiments described, it will be apparent to those skilled in the art that various modifications and variations are possible within the technical spirit of the present invention, and such modifications and modifications belong to the appended claims.

100: tension control device 110: embroidery machine head
115: auxiliary tension adjusting device 120: tension detection unit
121: location guide hall 122: location
123: first height fixing hole 124: first height fixing
125: second height fixing hole 126: second height adjustment unit
128: sensor portion 129: direction guide portion
130: tension control device 131: tension control motor
132: driven pulley 133: driven pulley
134: tension control eccentric shaft
134b: sensor detection plate 134c: eccentric shaft sensor
134d: bushing 135: tensioning shaft
136: tension control shaft return spring 137: tension adjustment plate
138: tension adjustment spring 139: tension adjustment knob
140: embroidery machine control section 150: thread
160: fabric pressing part 170 ... upper thread hanger

Claims (11)

In the tension control device for controlling the tension applied to the thread by controlling the friction force between the tension adjusting plate passing through the thread,
A tension adjusting shaft connected to one end of the tension adjusting dish and penetrating the support frame;
A tension control eccentric shaft which has an eccentricity and the other end of the tension control shaft is in contact with the circumference; And
An eccentric shaft bracket for rotatably supporting the tension adjusting eccentric shaft;
Mounting force adjusting device comprising a.
The mounting force adjusting device according to claim 1, further comprising tension adjusting eccentric shaft driving means for rotating the tension adjusting eccentric shaft.
According to claim 2, wherein the tension control eccentric shaft drive means
A driven pulley coupled to the tension control eccentric shaft;
A drive pulley operatively connected to the driven pulley; And
A tension control motor for rotating the drive pulley;
Mounting force adjusting device comprising a.
The mounting force adjusting device of claim 3, wherein the eccentric shaft bracket is supported by the support frame and is installed to support the tension control motor.
The method of claim 1,
A tension control shaft return spring for elastically supporting the tension control shaft;
Mounting force adjusting device characterized in that it further comprises.
The method of claim 1,
The other end of the tension control shaft in contact with the tension control eccentric shaft is formed with a flange for smooth contact with the tension control eccentric shaft and the tension control shaft return spring is installed between the flange and the support frame Mounting force adjusting device characterized in that.
The method of claim 1,
The tension adjusting eccentric shaft extends in the longitudinal direction, and a mounting force adjusting device, characterized in that a plurality of tension adjusting shafts corresponding to each of the plurality of threads are installed on the tension adjusting eccentric shaft.
The method of claim 1,
A sensor sensing plate coupled to the tension adjusting eccentric shaft and rotating; And
An eccentric shaft sensor for detecting a position of the sensor sensing plate;
Mounting force adjusting device characterized in that it further comprises.
In the head of the embroidery machine comprising a needle bar support for supporting a plurality of needle bar,
A plurality of tension adjusting plates corresponding to each of the plurality of needle bars;
A support frame on which the tension adjusting plate is supported;
A plurality of tension adjusting shafts connected to each of the plurality of tension adjusting plates and installed to penetrate the support frame;
A tension control eccentric shaft which has an eccentricity and the other end of the tension control shaft is in contact with the circumference; And
An eccentric shaft bracket for rotatably supporting the tension adjusting eccentric shaft;
Head of the embroidery machine comprising a.
10. The method of claim 9,
The head of the embroidery machine further comprises an auxiliary tension adjusting device having a tension adjusting knob for adjusting the elastic force of the spring in close contact with the tension adjusting plate and the tension adjusting plate.
In the tension control device of the embroidery machine for controlling the tension applied to the thread,
A tension adjusting device for adjusting the tension applied to the thread;
A tension detector for detecting a tension applied to the thread; And
A control unit which monitors the tension detected by the tension detector and controls the tension adjusting device so that a change in tension is reduced; Including;
Here, the tension adjusting device
A support frame on which the tension adjusting plate is supported;
A tension control shaft connected to one end of the tension control plate and installed to penetrate the support frame;
A tension control eccentric shaft which has an eccentricity and the other end of the tension control shaft is in contact with the circumference;
An eccentric shaft bracket for rotatably supporting the tension adjusting eccentric shaft; And
Tension control eccentric shaft drive means for rotating the tension control eccentric shaft under control of the controller;
Tension control method of the embroidery machine comprising a.

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