CN112921525A

CN112921525A - Sewing machine control system and sewing machine control method

Info

Publication number: CN112921525A
Application number: CN201911231172.9A
Authority: CN
Inventors: 金琳; 徐永明
Original assignee: Jack Sewing Machine Co Ltd
Current assignee: Jack Technology Co Ltd
Priority date: 2019-12-05
Filing date: 2019-12-05
Publication date: 2021-06-08
Anticipated expiration: 2039-12-05
Also published as: CN112921525B

Abstract

The invention provides a sewing machine control system and a sewing machine control method. Wherein, this sewing machine control system includes: a first inductor 3, a second inductor 4 and a controller; the first inductor 3 and the second inductor 4 are respectively coupled with the controller, wherein the first inductor 3 and the second inductor 4 are arranged on a sewing table 1 of the sewing machine, and a straight line where the first inductor 3 and the second inductor 4 are located and a feeding direction of the sewing machine form a preset included angle; and the controller is used for carrying out front trimming control according to the first detection results of the first inductor 3 and the second inductor 4. According to the invention, the problem that the sewing machine in the related art cannot perform normal sewing and thread cutting on the triangular fabric is solved, and cloth cutting during sewing of the triangular fabric is avoided.

Description

Sewing machine control system and sewing machine control method

Technical Field

The invention relates to the technical field of sewing machines, in particular to a sewing machine control system and a sewing machine control method.

Background

The existing automatic thread trimming sewing machine generally adopts a photoelectric correlation sensor to sense, after a fabric passes through the sensor, the fabric is judged and controlled by electric control, and after a plurality of needle numbers are delayed through the sensor, a thread trimming cutter realizes the thread trimming function. The existing overedger generally adopts a line cutting mode of a chopper or a side suction cutter, and fabric with a normal front end flush can be normally sewn and cut, but because the distribution of the positions of the sensors is generally in a linear mode, when the fabric is triangular, the front end head of the triangular fabric with the triangular front end is easily cut off by mistake during front line cutting, and the rear end tail of the triangular fabric with the triangular rear end is easily cut off during rear line cutting. This problem can lead to the user's surface fabric to scrap, causes the loss, and can't carry out the normal sewing trimming of triangle surface fabric.

Aiming at the problem that a sewing machine in the related art cannot perform normal sewing and thread cutting of triangular fabric, an effective solution is not provided at present.

Disclosure of Invention

In view of the above, it is necessary to provide a sewing machine control system and a sewing machine control method for solving the problem that the sewing machine in the related art cannot perform normal sewing and trimming of the triangular fabric.

In a first aspect, the present embodiment provides a sewing machine control system, including: a first inductor 3, a second inductor 4 and a controller; the first inductor 3 and the second inductor 4 are respectively coupled with the controller, wherein the first inductor 3 and the second inductor 4 are arranged on a sewing table 1 of a sewing machine, and a straight line where the first inductor 3 and the second inductor 4 are located and a feeding direction of the sewing machine form a preset included angle; the controller is configured to perform front trimming control according to first detection results of the first sensor 3 and the second sensor 4.

In one embodiment, the sewing machine control system further comprises: a third inductor 5 and a fourth inductor 7, the third inductor 5 and the fourth inductor 7 being coupled to the controller, respectively; the third inductor 5 is arranged at the tail end of the needle plate 8 and is positioned on one side of a thread cutting cutter meshing surface 6 of the sewing machine; the fourth inductor 7 is arranged on the sewing table 1 and is positioned on an extension line of the meshing surface 6 of the thread cutting knife; the controller is further configured to perform post trimming control according to second detection results of the third sensor 5 and the fourth sensor 7.

In one embodiment, the sewing machine control system further comprises: a fifth inductor 2, the fifth inductor 2 being coupled with the controller; wherein the fifth inductor 2 is arranged on the sewing table 1.

In one embodiment, the predetermined included angle is 90 °.

In a second aspect, the present embodiment further provides a sewing machine control method of a sewing machine control system, including: a first inductor 3, a second inductor 4 and a controller; the first inductor 3 and the second inductor 4 are respectively coupled with the controller, wherein the first inductor 3 and the second inductor 4 are arranged on a sewing table 1 of a sewing machine, a preset included angle is formed between a straight line where the first inductor 3 and the second inductor 4 are located and a feeding direction of the sewing machine, and the control method of the sewing machine comprises the following steps: detecting the cloth through the first inductor 3 and the second inductor 4 to obtain a first detection result; and performing front trimming control according to the first detection result.

In one embodiment, in the case that the predetermined included angle is 90 °, performing front trimming control according to the first detection result includes: judging whether the front end of the cloth exceeds the meshing surface 6 of the trimming cutter when the second sensor 4 detects the cloth according to the first detection result; when the front end of the cloth is judged to exceed the meshing surface 6 of the thread trimming cutter when the second sensor 4 detects the cloth, front thread trimming is not executed; otherwise, determining a second trimming delay stitch number according to the first detection result, and executing front trimming after sewing the second trimming delay stitch number after the first sensor 3 detects the cloth.

In one embodiment, determining the second number of trimming delay pins according to the first detection result includes: determining the second trimming delay pin number N according to the following formula_{Front side}：

Wherein the content of the first and second substances,

l' represents the second inductor 4 to the scissorsDistance of the meshing surface 6 of the line cutter; d represents the current stitch length value of the sewing machine; y is₁Represents the distance from the first inductor 3 to the second inductor 4; y is₂Indicating the distance from the first inductor 3 to the edge of the needle board 8 at one side of the cutting notch of the needle board 8; v represents the rotation speed of the sewing machine when the second sensor 4 detects the cloth; a represents an acceleration of the sewing machine; Δ t represents a time difference from the detection of the cloth by the second sensor 4 to the detection of the cloth by the first sensor 3;

indicating a rounding down.

In one embodiment, the sewing machine control system further comprises: a third inductor 5 and a fourth inductor 7, the third inductor 5 and the fourth inductor 7 being coupled to the controller, respectively; the third inductor 5 is arranged at the tail end of the needle plate 8 and is positioned on one side of a thread cutting cutter meshing surface 6 of the sewing machine; the fourth inductor 7 is arranged on the sewing table 1 and is positioned on an extension line of the meshing surface 6 of the thread cutting knife; after performing the front cut control according to the first detection result, the sewing machine control method further includes: detecting the cloth through the third inductor 5 and the fourth inductor 7 to obtain a second detection result; and performing rear trimming control according to the second detection result.

In one embodiment, the performing post trimming control according to the second detection result includes: according to the second detection result, whether the fourth inductor 7 detects that the cloth leaves before the third inductor 5 is judged; when the fourth sensor 7 detects that the fabric leaves before the third sensor 5, determining a third trimming delay stitch number according to the first detection result, and performing post trimming after sewing the third trimming delay stitch number after the third sensor 5 detects that the fabric leaves; otherwise, determining a fourth trimming delay stitch number according to the first detection result, and executing the post trimming after sewing the fourth trimming delay stitch number after the fourth sensor 7 detects that the cloth leaves.

In one embodiment, the determining the third number of trimming delay pins according to the first detection result includes: determining the third trimming delay pin number N according to the following formula_{Rear end}：

Wherein the content of the first and second substances,

L₄the distance from the third inductor 5 to the meshing surface 6 of the thread cutting cutter is shown; d represents the current stitch length value of the sewing machine; y is₃Represents the distance of the fourth inductor 7 to the third inductor 5 in the feeding direction; y is₄The distance from the third inductor 5 to the edge of the needle plate 8 positioned on one side of the notch of the cutter of the needle plate 8 is shown; v represents the rotation speed of the sewing machine when the fourth sensor 7 detects that the cloth is off; a represents an acceleration of the sewing machine; Δ t represents a time difference from when the fourth sensor 7 detects the departure of the cloth to when the third sensor 5 detects the departure of the cloth;

indicating rounding up.

In one embodiment, the determining the fourth trimming delay pin number according to the first detection result includes: determining the fourth trimming delay pin number N according to the following formula_{Rear end}：

Wherein the content of the first and second substances,

L₄the distance from the third inductor 5 to the meshing surface 6 of the thread cutting cutter is shown; d represents the current stitch length value of the sewing machine; y is₃Represents the aboveThe distance from the fourth inductor 7 to the third inductor 5 in the feeding direction; y is₄The distance from the third inductor 5 to the edge of the needle plate 8 positioned on one side of the notch of the cutter of the needle plate 8 is shown; v represents the rotation speed of the sewing machine when the fourth sensor 7 detects that the cloth is off; a represents an acceleration of the sewing machine; Δ t represents a time difference from when the third sensor 5 detects the departure of the cloth to when the fourth sensor 7 detects the departure of the cloth;

indicating rounding up.

In one embodiment, in the case where the predetermined included angle is 90 °, after performing the front trimming control according to the first detection result, the sewing machine control method further includes: detecting the cloth through the first inductor 3 and the second inductor 4 to obtain a third detection result; and performing rear trimming control according to the third detection result.

In one embodiment, the performing post trimming control according to the third detection result includes: and determining a fifth trimming delay stitch number according to the third detection result, and performing post trimming after sewing the fifth trimming delay stitch number after the first sensor 3 detects that the cloth leaves.

In one embodiment, the determining the fifth trimming delay pin number according to the third detection result includes: determining the number N of the fifth trimming delay pins according to the following formula_{Rear end}：

Wherein the content of the first and second substances,

l' represents the distance from the second inductor 4 to the thread cutting knife engagement surface 6; d represents the current stitch length value of the sewing machine; y is₁Represents the distance from the first inductor 3 to the second inductor 4; y is₂Represents the firstThe distance from the inductor 3 to the edge of the needle plate 8 positioned on one side of the notch of the cutter of the needle plate 8; v represents the rotation speed of the sewing machine when the second sensor 4 detects the cloth; a represents an acceleration of the sewing machine; Δ t represents a time difference from when the first sensor 3 detects the departure of the cloth to when the second sensor 4 detects the departure of the cloth;

indicating rounding up.

According to the sewing machine control system and the sewing machine control method provided by the embodiment of the invention, the adopted sewing machine control system comprises: a first inductor 3, a second inductor 4 and a controller; first inductor 3 and second inductor 4 respectively with the controller coupling, wherein, first inductor 3 and second inductor 4 set up on sewing machine's seam platform 1, and the straight line at first inductor 3 and second inductor 4 place is predetermined contained angle with sewing machine's pay-off direction, the mode of front trimming control is carried out according to first testing result of first inductor 3 and second inductor 4 to the controller, has solved the problem that the sewing machine among the correlation technique can't carry out the normal sewing trimming of triangle surface fabric, has avoided the cloth of cutting when sewing the triangle surface fabric.

Drawings

FIG. 1 is a schematic view of a sewing table 1 of a sewing machine control system according to an embodiment of the present invention;

FIG. 2 is a flowchart of a sewing machine control method according to an embodiment of the present invention;

FIG. 3 is a preferred flow chart of a sewing machine control method according to an embodiment of the present invention;

FIG. 4 is a schematic view of a sewing table 1 of a sewing machine of another sewing machine control system according to an embodiment of the present invention;

FIG. 5 is a schematic view showing a positional relationship between a sewing table 1 and a fabric A and a fabric B of a sewing machine control system according to an embodiment of the present invention;

FIG. 6 is a schematic view showing a positional relationship between a sewing table 1 and a fabric A of a sewing machine control system according to an embodiment of the present invention;

FIG. 7 is a schematic view showing a positional relationship between a sewing table 1 and a fabric B of a sewing machine control system according to an embodiment of the present invention;

FIG. 8 is a schematic diagram showing the positional relationship of the

sensors

3, 4 and 5 of the sewing machine control system according to the embodiment of the present invention;

FIG. 9 is a schematic diagram showing the positional relationship between the

sensors

3 and 4 of the sewing machine control system according to the embodiment of the present invention;

FIG. 10 is a schematic view showing a positional relationship between a sewing table 1 and a fabric C of a sewing machine control system according to an embodiment of the present invention;

FIG. 11 is a schematic view showing a positional relationship between a sewing table 1 and a fabric D of a sewing machine control system according to an embodiment of the present invention;

FIG. 12 is a schematic view showing a positional relationship between a sewing table 1 and a fabric A and a fabric B of a sewing machine of another sewing machine control system according to the embodiment of the present invention;

FIG. 13 is a schematic view showing a positional relationship between a sewing table 1 and a fabric A of a sewing machine of another sewing machine control system according to the embodiment of the present invention;

FIG. 14 is a schematic view showing a positional relationship between a sewing table 1 and a fabric B of a sewing machine of another sewing machine control system according to the embodiment of the present invention;

FIG. 15 is a schematic diagram showing the positional relationship between the

sensors

4 and 5 of another sewing machine control system according to the embodiment of the present invention;

FIG. 16 is a schematic diagram showing the positional relationship between

sensors

3 and 4 of another sewing machine control system according to the embodiment of the present invention;

FIG. 17 is a schematic view showing a positional relationship between a sewing table 1 and a fabric C of a sewing machine of another sewing machine control system according to the embodiment of the present invention;

FIG. 18 is a schematic view showing a positional relationship between a sewing table 1 and a fabric D of a sewing machine of another sewing machine control system according to the embodiment of the present invention;

FIG. 19 is a schematic view showing a positional relationship between a sewing table 1 and a fabric C of a sewing machine of another sewing machine control system according to the embodiment of the present invention;

fig. 20 is a flowchart of a front trimming control method according to a preferred embodiment of the present invention;

fig. 21 is a flowchart of a rear trimming control method according to a preferred embodiment of the present invention.

Detailed Description

In the present embodiment, there is provided a sewing machine control system, fig. 1 is a schematic view of a sewing table 1 of a sewing machine of the sewing machine control system according to the embodiment of the present invention, as shown in fig. 1, the sewing machine control system including: a first inductor 3, a second inductor 4, and a controller (not shown in fig. 1); the first inductor 3 and the second inductor 4 are respectively coupled with the controller, wherein the first inductor 3 and the second inductor 4 are arranged on a sewing table 1 of the sewing machine, and a straight line where the first inductor 3 and the second inductor 4 are located and a feeding direction of the sewing machine form a preset included angle; and the controller is used for carrying out front trimming control according to the first detection results of the first inductor 3 and the second inductor 4.

Wherein the first inductor 3 and the second inductor 4 are preferably arranged on the same side of the needle board (8). The first sensor 3 and the second sensor 4 are used for detecting the arrival or departure time of the cloth, and the controller estimates the shape of the irregular cloth by using the detection results detected by the first sensor 3 and the second sensor 4 and combining the known sewing speed and the position relation set by the sensors.

In one embodiment, the sewing machine control system further comprises: a third inductor 5 and a fourth inductor 7, wherein the third inductor 5 and the fourth inductor 7 are coupled to the controller, respectively; the third inductor 5 is arranged at the tail end of the needle plate 8 and is positioned on one side of a meshing surface 6 of a thread cutting cutter of the sewing machine; the fourth inductor 7 is arranged on the sewing table 1 and is positioned on the extension line of the meshing surface 6 of the thread cutting cutter; and the controller is also used for carrying out rear trimming control according to the second detection results of the third sensor 5 and the fourth sensor 7.

The third sensor 5 and the fourth sensor 7 are used for detecting the arrival or departure time of the cloth, and the controller estimates the shape of the irregular cloth by using the detection results detected by the third sensor 5 and the fourth sensor 7 and combining the known sewing speed and the position relation of the sensor arrangement.

In one embodiment, the sewing machine control system further comprises: a fifth inductor 2, the fifth inductor 2 being coupled to the controller; wherein, the fifth inductor 2 is arranged on the sewing table 1. The fifth sensor 2 is used for detecting the feeding direction of the cloth and judging whether the current control of the thread to be cut is the front thread cutting control. For example, in the case where the fifth sensor 2 detects the cloth before the first sensor 3, it may be determined that the current thread to be cut is the front cut control.

The fifth inductor 2 is disposed at the left or right side of the first inductor 3. In one embodiment, the fifth inductor 2 and the second inductor 4 are disposed on a first straight line parallel to the feeding direction, and the first inductor 3 is disposed on the opposite side of the first straight line from the needle plate 8.

In one embodiment, a first projection point of the first sensor 3 on the first straight line is located between a second projection point and the second sensor 4, wherein the second projection point refers to a projection point of the front end of the cutting notch of the needle board 8 of the sewing machine on the first straight line.

In one embodiment, first inductor 3, second inductor 4, and third inductor 5 are arranged co-linearly.

The sewing machine control method of the present embodiment will be described and explained with reference to the sewing machine control system shown in fig. 1.

Fig. 2 is a flowchart of a sewing machine control method according to an embodiment of the present invention, as shown in fig. 2, the flowchart includes the steps of:

step S201, detecting the cloth through a first inductor 3 and a second inductor 4 to obtain a first detection result;

and step S202, performing front trimming control according to the first detection result.

In one embodiment, in the case that a first projection point of the first sensor 3 on a first straight line is located between a second projection point and the second sensor 4, wherein the second projection point is a projection point of the front end of a cutter notch of a needle plate 8 of the sewing machine on the first straight line, performing front trimming control according to a first detection result comprises: according to the first detection result, whether the second sensor 4 detects the cloth before the first sensor 3 is judged; when the second sensor 4 detects cloth before the first sensor 3, front trimming is not executed; otherwise, the first trimming delay stitch number is determined according to the first detection result, and the front trimming is executed after the second sensor 4 detects the cloth and sews the first trimming delay stitch number.

In one embodiment, determining the first number of trimming delay pins according to the first detection result includes: determining the number of first trimming delay pins N according to the following formula_{Front side}：

Wherein the content of the first and second substances,

l' represents the distance from the second inductor 4 to the meshing surface 6 of the trimming cutter; d represents the current stitch length value of the sewing machine; l is₀Represents the distance from the first projection point to the second sensor 4; y is₁Represents the distance from the first sensor 3 to the first projection point; y is₂Indicating the distance from the first inductor 3 to the edge of the needle board 8 on one side of the notch of the cutter of the needle board 8; v represents the rotational speed of the sewing machine when the first sensor 3 detects the cloth; a represents the acceleration of the sewing machine; Δ t represents a time difference from when the first sensor 3 detects the cloth to when the second sensor 4 detects the cloth;

indicating a rounding down.

Fig. 3 is a preferred flowchart of a sewing machine control method according to an embodiment of the present invention, as shown in fig. 3, the flowchart includes the steps of:

step S301, detecting the cloth through the first inductor 3 and the second inductor 4 to obtain a first detection result.

And step S302, performing front trimming control according to the first detection result.

Step S303, detecting the cloth through the third inductor 5 and the fourth inductor 7 to obtain a second detection result.

And step S304, performing post trimming control according to the second detection result.

In one embodiment, the performing post trimming control according to the second detection result includes: according to the second detection result, whether the fourth sensor 7 detects that the cloth leaves before the third sensor 5 is judged; when the fourth sensor 7 detects that the cloth leaves before the third sensor 5, determining the third trimming delay stitch number according to the first detection result, and sewing the third trimming delay stitch number after the third sensor 5 detects that the cloth leaves; otherwise, determining the fourth trimming delay stitch number according to the first detection result, and executing the post trimming after sewing the fourth trimming delay stitch number after the fourth sensor 7 detects that the cloth leaves.

Wherein the content of the first and second substances,

L₄the distance from the third inductor 5 to the meshing surface 6 of the thread cutting cutter is shown; d represents the current stitch length value of the sewing machine; y is₃Represents the distance from the fourth inductor 7 to the third inductor 5 in the feeding direction; y is₄Showing the distance from the third inductor 5 to the edge of the needle plate 8 on one side of the notch of the cutter of the needle plate 8; v represents the rotating speed of the sewing machine when the fourth sensor 7 detects that the cloth leaves; a represents the acceleration of the sewing machine; Δ t represents a time difference from when the fourth sensor 7 detects the departure of the cloth to when the third sensor 5 detects the departure of the cloth;

indicating rounding up.

Wherein the content of the first and second substances,

L₄the distance from the third inductor 5 to the meshing surface 6 of the thread cutting cutter is shown; d represents the current stitch length value of the sewing machine; y is₃Represents the distance from the fourth inductor 7 to the third inductor 5 in the feeding direction; y is₄Showing the distance from the third inductor 5 to the edge of the needle plate 8 on one side of the notch of the cutter of the needle plate 8; v represents the rotating speed of the sewing machine when the fourth sensor 7 detects that the cloth leaves; a represents the acceleration of the sewing machine; Δ t represents a time difference from when the third sensor 5 detects the departure of the cloth to when the fourth sensor 7 detects the departure of the cloth;

indicating rounding up.

In the present embodiment, there is also provided a sewing machine control system, and fig. 4 is a schematic view of a sewing table 1 of a sewing machine of the sewing machine control system according to the embodiment of the present invention, and as shown in fig. 4, the sewing machine control system is structurally different from the sewing machine control system shown in fig. 1 mainly in that a line in which a first inductor 3 and a second inductor 4 are located has a predetermined angle of 90 ° with a feeding direction of the sewing machine.

The sewing machine control method of the present embodiment will be described and explained with reference to the sewing machine control system shown in fig. 4.

The flow of the sewing machine control method of the sewing machine control system shown in fig. 4 is substantially the same as the flow of the sewing machine control method shown in fig. 2, except that the performing of the front trimming control based on the first detection result in step S202 includes: judging whether the front end of the cloth exceeds the meshing surface 6 of the thread trimming cutter when the second sensor 4 detects the cloth according to the first detection result; when the front end of the cloth is judged to exceed the meshing surface 6 of the thread trimming cutter when the second sensor 4 detects the cloth, the front thread trimming is not executed; otherwise, the second trimming delay needle number is determined according to the first detection result, and the front trimming is executed after the first sensor 3 detects the cloth and the second trimming delay needle number is sewn.

In one embodiment, the determining the second number of trimming delay pins according to the first detection result comprises: determining the second trimming delay pin number N according to the following formula_{Front side}：

Wherein the content of the first and second substances,

l' represents the distance from the second inductor 4 to the meshing surface 6 of the trimming cutter; d represents the current stitch length value of the sewing machine; y is₁Represents the distance from the first inductor 3 to the second inductor 4; y is₂Indicating the distance from the first inductor 3 to the edge of the needle board 8 on one side of the notch of the cutter of the needle board 8; v represents the rotational speed of the sewing machine when the second sensor 4 detects the cloth; a represents the acceleration of the sewing machine; Δ t represents a time difference from when the second sensor 4 detects the cloth to when the first sensor 3 detects the cloth;

indicating a rounding down.

The method of controlling the back cut line of the sewing machine control system shown in fig. 4 may be the same as the method of controlling the back cut line of the sewing machine control system shown in fig. 1.

In one embodiment, after the front trimming control is performed based on the first detection result, the sewing machine control method further includes: detecting the cloth through a third inductor 5 and a fourth inductor 7 to obtain a second detection result; and performing post trimming control according to the second detection result.

Wherein the content of the first and second substances,

indicating rounding up.

Wherein the content of the first and second substances,

indicating rounding up.

In one embodiment, the back trimming control method of the sewing machine control system shown in fig. 4 can also be controlled by using the first sensor 3 and the second sensor 4. For example, the first sensor 3 and the second sensor 4 are used for detecting the cloth to obtain a third detection result; and performing post trimming control according to the third detection result.

In one embodiment, the performing post trimming control according to the third detection result includes: and determining the fifth trimming delay stitch number according to the third detection result, and sewing the fifth trimming delay stitch number after the first sensor 3 detects that the cloth leaves, and then performing post trimming.

In one embodiment, the determining the fifth trimming delay pin number according to the third detection result includes: determining the number of the fifth trimming delay pins N according to the following formula_{Rear end}：

Wherein the content of the first and second substances,

l' represents the distance from the second inductor 4 to the meshing surface 6 of the trimming cutter; d represents the current stitch length value of the sewing machine; y is₁Represents the distance from the first inductor 3 to the second inductor 4; y is₂Indicating the distance from the first inductor 3 to the edge of the needle board 8 on one side of the notch of the cutter of the needle board 8; v represents the rotational speed of the sewing machine when the second sensor 4 detects the cloth; a represents the acceleration of the sewing machine; Δ t represents a time difference from when the first sensor 3 detects the departure of the cloth to when the second sensor 4 detects the departure of the cloth;

indicating rounding up.

The embodiments of the invention will be described and illustrated below in conjunction with the preferred embodiments.

The parts related to the preferred embodiment of the invention comprise the following parts: the device comprises a sewing table 1, a sensor 2, a sensor 3, a sensor 4, a sensor 5, a cutter meshing surface 6, a sensor 7, a needle plate 8, a controller, and related simulation fabrics A, B, C and D.

Preferred embodiment 1

As shown in figure 1, 3 sensors, namely a sensor 2, a sensor 3 and a sensor 4, are arranged on a sewing platform 1, a sensor 5 is arranged on a needle plate 8, a cutter meshing surface 6 is arranged at the rear end of the needle plate 8, and a sensor 7 is level to the cutter meshing surface 6. As shown in fig. 5, the inductor 2 and the inductor 4 are linearly distributed, the inductor 3 is offset from the inductor 2 and the inductor 4, and the linear direction of the two points of the inductor 3 and the inductor 4 forms a C-angle with the linear direction of the feeding direction. In order to solve the problem that front-end fabrics can be cut during front-end thread cutting, the triangular fabrics can have various shapes after being analyzed, and the triangular fabrics are classified into two types of fabrics A and B, namely the triangular included angle of the fabrics A is set as & lt B, and the angle of the triangular included angle is larger than & lt C of sensor arrangement; the included angle of the triangle of the fabric B is less than the angle C of the sensor arrangement. In the sewing process of the fabric A and the fabric B, a process that a triangular side line passes through the inductor 3 and the inductor 4 respectively appears. As shown in FIG. 6, taking fabric A as an example, the M points of the fabric first shield the sensor 3, and at this timeThe controller will record the signal of the sensor 3, and the fabric N in the straight line direction with the sensor 4 at this time₁The point position is closer to the rear part of the needle plate 8 than the M point position, and the distance between the two is set to be L₂. The fabric is sewn continuously from N₁Moving a point to N₂The sensor 4 is shielded at this time, and the controller records the signal of the sensor 4 at this time. N is a radical of₁Point sum N₂The distance in the moving direction of the point is set to L₁The exercise completion time is Deltat₁When the current rotation speed is V and the acceleration is a, L₁＝V×Δt₁+aΔt₁ ². Due to L₁+L₂The distance between the inductor 3 and the inductor 4 is constant, the initial speed of the M point is V at the moment, and the distance between the M point of the fabric moving from the inductor 3 to the inductor 4 in the linear direction is L₁+L₂Let the arrival time be Δ t₂Then L is₁+L₂＝V×Δt₂+aΔt₂ ². From which L can be solved₁And L₂The value of (c). From the principle of similar triangles, L₂/x₁＝y₁/y₂-y₁. Therein is given by₁Is the parallel direction distance between the inductor 3 and the inductor 4, y₂The two values are known and customized for the distance of the sensor 3 from the edge of the seam material. From this, X can be derived₁The value of (c). In the same way, the movement direction distance C between the inductor 4 and the sharp corner of the triangular fabric can be obtained, and the distance from the inductor 4 to the trimming knife edge 6 is set to be L'. Therefore, on the basis of the existing thread cutting logic, the controller judges how to carry out thread cutting by judging the difference between the fabric distance C and the distance L' of the thread cutting knife edge 6. If the distance C is larger than L ', thread cutting is not executed, if the distance C is smaller than L ', thread cutting is executed, and the thread cutting delay needle number N1 is determined according to the ratio of the difference value of L ' and the distance C to the current needle pitch d of the sewing machine. Namely N₁< L' -C/existing gauge, if N₁If the number is less than 1, the thread cutting treatment is not carried out, so that the problem of cutting the fabric is solved. As shown in fig. 7, since the included angle of triangle a of the fabric B is smaller than angle C, the fabric B can firstly shield the sensor 4 and then shield the sensor 3 when sewing, so that the problem that the prejudgment cannot be performed can be caused. In order to solve the problem, the B type fabric is ensuredCan meet the requirements and is provided with an inductor 5. When the fabric B is sewn, before the sensor 4 is shielded, the fabric can firstly shield the sensor 5 and then shield the sensor 4, so that the controller can judge that the fabric is of the fabric B type, and the included angle is smaller than the angle C, so that the front trimming action is not performed, and then the requirement that the fabric is not cut is met. As shown in fig. 8, the best position for placing the inductor 5 is the angle position between the straight extension line of the inductor 3 and the inductor 4 and the braided wire area, and is behind the notch 8 of the cutter of the needle plate 8. As shown in FIG. 9, the sensor 3 is preferably placed in a region from the front end of the notch 8 of the needle plate 8 to the sensor 4.

The back trimming triangular fabric is summarized into fabric C and fabric D types, and in order to ensure that the fabric C and the fabric D of the two types can be prevented from being trimmed when the back trimming is performed, the sensor 5 and the sensor 7 are arranged for judgment. As shown in fig. 10 and fig. 11, the position straight lines of the sensor 5 and the sensor 7 are arranged to form an included angle ≧ D with the feeding direction straight line, wherein the triangular included angle of the fabric C is ≦ E, and then the ≦ E is less than ≦ D, when the fabric C is being sewn, the fabric C firstly leaves the sensor 7 and then leaves the sensor 5, so as to determine that the fabric type is the fabric C, and by the same method, X can be obtained₂Value of (1), thus the number of post trimming delay pins N₂＞X₂+L₄Current gauge, controller set at N₂And executing post-trimming action after the number of the needles is delayed. As shown in fig. 11, when the included angle of the triangle of the fabric D is ≥ F, and then ≤ F is greater than ≤ D, when the fabric D starts to be sewn, the fabric D firstly leaves the sensor 5 and then the sensor 7, and according to the above principle, X can be obtained₃And the same can obtain N₃＞X₃Current needle pitch. At the moment, the minimum delay needle number N of sewing before leaving the inductor 7 can be set by electric control₃And performing cloth shearing prevention. Wherein N is₁、N₂、N₃Is an integer, and has a remainder plus 1.

The principle logic sequence for realizing the effect of the embodiment of the invention is as follows:

FIG. 20 is a flowchart of a front trimming control method according to a preferred embodiment of the present invention, as shown in FIG. 20, when sewing is started, if it is doneThe material shelters from inductor 3 and inductor 4 in proper order, and automatically controlled record shelters from inductor 3 and inductor 4's time to whether calculation shelters from inductor 4 and is faster than normal sewing speed, if detect and be faster than normal sewing speed, judge that the surface fabric type is A surface fabric, according to N surface fabric₁Pre-trimming is performed to compensate for the number of delayed stitches. If N is present₁If the number is less than 1, the thread cutting processing is not carried out. After sewing is started, if the fabric sequentially covers the inductor 4 and the inductor 3, the electronic control can judge that the fabric being sewn is the fabric B, and the front thread trimming action is not performed at the moment.

Fig. 21 is a flowchart of a rear trimming control method according to a preferred embodiment of the present invention, and as shown in fig. 21, the rear trimming logic aspect: after the current thread cutting action is finished, if the fabric leaves the inductor 7 and then leaves the inductor 5, the fabric type is judged to be C, and the thread cutting delay needle number is N₂Executing; after the current thread cutting action is finished, if the fabric leaves the sensor 5 and then leaves the sensor 7 at a speed exceeding the normal sewing cloth feeding speed, the fabric type can be judged to be D, and the thread cutting delay needle number is N₃Executing;

preferred embodiment two

As shown in fig. 4, 3 sensors, namely a sensor 2, a sensor 3 and a sensor 4, are arranged on the sewing platform 1, a sensor 5 is arranged on a needle plate 8, a cutter meshing surface 6 is arranged at the rear end of the needle plate 8, and a sensor 7 is level to the cutter meshing surface 6. As shown in fig. 12, the sensors 2 and 4 are linearly arranged in parallel to the sewing direction, and the

sensors

3 and 4 are linearly arranged in perpendicular to the sewing direction. The linear distance between two points of the inductor 3 and the inductor 4 is known as L. In order to solve the problem that front-end fabrics can be cut during front-end thread cutting, the triangular fabrics can have various shapes after being analyzed, and the triangular fabrics are classified into two types of fabrics A and B, namely the triangular included angle of the fabrics A is set as & lt B, and the angle of the triangular included angle is larger than & lt C of sensor arrangement; the included angle of the triangle of the fabric B is less than the angle C of the sensor arrangement. In the sewing process of the fabric A and the fabric B, a process that a triangular side line passes through the inductor 3 and the inductor 4 respectively appears. As shown in FIG. 13, taking fabric A as an example, the sensor 4 is first shielded by the fabric N points, and the controller records the data of the sensor 4Signal, this time with the material N of the inductor 4 in the direction of the straight line₁The point location is on the same line as the location of the M point of the sensor 3, at a known distance L. The fabric is sewn continuously from N₁Moving a point to N₂And at this point, the sensor 4 will be shielded continuously, and the sensor 3 will be shielded by the fabric M point, and at this time, the controller will record the signal of the sensor 3. N is a radical of₁Point sum N₂The distance in the moving direction of the point is set to L₁When the exercise completion time is delta t, the current rotating speed is V, the acceleration is a, and then L₁＝VΔt+aΔt². Due to y₁And y₂Is a distance constant of known value, and therefore, can be derived from the principle of similar triangles₁/d₁＝y₁/y₂From this, d can be derived₁The value of (c). In the same way, d can be obtained₂＝L₁+d₁. Therefore, the controller can judge the fabric distance d on the basis of the existing thread cutting logic₂The difference in distance from the trimming edge 6 is used to determine how trimming is to be performed, and the distance from the trimming edge 6 is set to be L'. If the distance d₂If the distance is larger than L', the thread cutting is not executed, and if the distance d₂If less than L', trimming is performed and the trimming is delayed by the number of pins N₁According to the ratio of the difference value of L' and the distance d2 to the current needle pitch d of the sewing machine. Namely N₁＜L’-d₂Existing needle pitch, if N₁If the number is less than 1, the thread cutting treatment is not carried out, so that the problem of cutting the fabric is solved. As shown in fig. 14, since the included angle of triangle a of the fabric B is smaller than angle C, the fabric B can firstly shield the sensor 3 and then shield the sensor 4 when sewing, but can directly shield the sensor 5 due to the angle problem, thereby causing the problem that the prejudgment cannot be performed. In order to solve the problem, the shielding logic of the sensor 5 is set for judging to ensure that the fabric B type can meet the requirement. When the fabric B is sewn, before the sensor 4 is shielded, the fabric can firstly shield the sensor 5 and then shield the sensor 4, so that the controller can judge that the fabric is of the fabric B type, and the included angle is smaller than the angle C, so that the front trimming action is not performed, and then the requirement that the fabric is not cut is met. As shown in FIG. 15, the best placement positions for inductor 5 are generally inductor 4 and needle board 8The linear included angle A of the sewing movement direction is generally between 15 degrees and 45 degrees and is arranged at the rear position of the notch 8 of the cutter of the needle plate 8. As shown in FIG. 16, the best placement position of the

sensors

3 and 4 is from the front end of the cutter notch 8 of the needle board 8 to the beginning of the auxiliary notch of the needle board 8.

The back trimming triangular fabric is summarized into fabric C and fabric D types, and in order to ensure that the fabric C and the fabric D of the two types can be prevented from being trimmed when the back trimming is performed, the sensor 5 and the sensor 7 are arranged for judgment. As shown in fig. 17 and fig. 18, the position straight lines of the sensor 5 and the sensor 7 are arranged to form an included angle ≧ D with the feeding direction straight line, wherein the triangular included angle of the fabric C is ≦ E, and then the ≦ E is less than ≦ D, when the fabric C is being sewn, the fabric C firstly leaves the sensor 7 and then leaves the sensor 5, so as to determine that the fabric type is the fabric C, and by the same method, X can be obtained₂Value of (1), thus the number of post trimming delay pins N₂＞X₂+L₄Current gauge, controller set at N₂And executing post-trimming action after the number of the needles is delayed. As shown in fig. 18, when the included angle of the triangle of the fabric D is ≥ F, and then ≤ F is greater than ≤ D, when the fabric D starts to be sewn, the fabric D firstly leaves the sensor 5 and then leaves the sensor 7, and according to the above principle, X can be obtained₃And the same can obtain N₃＞X₃Current needle pitch. At the moment, the minimum delay needle number N of sewing before leaving the inductor 7 can be set by electric control₃And performing cloth shearing prevention. Wherein N is₁、N₂、N₃Is an integer, and has a remainder plus 1.

Meanwhile, the inductor 3 and the inductor 4 can also be used for judging and realizing the trimming of the back trimming triangular fabric, as shown in fig. 19. By the same method, L can be calculated₆To thereby yield d₃A value of (d)₃The value and the current known sewing parameter condition can carry out delay thread cutting on the back thread cutting of the triangular fabric. Let the number of delay pins implemented be N₄Then N is₄＞d₃And if the remainder exists, adding 1 to the current stitch length.

fig. 20 is a flowchart of a front trimming control method according to a preferred embodiment of the present invention, and as shown in fig. 20, when the fabric covers the sensor 5 and then covers the sensor 3 after the sewing is started, it is determined as a triangular fabric and it is determined as a B fabric. If the fabric shields the sensor 3 first and then shields the sensor 4, the fabric is judged to be a triangular fabric and judged to be an A fabric. If the shielding sensor 4 and the sensor 3 are judged to be shielded simultaneously, the front end of the fabric is flush. If the fabric is A, press N₁Pre-trimming is performed to compensate for the number of delayed stitches. If N is present₁If the number is less than 1, the thread cutting processing is not carried out. When sewing is started, if the electronic control judges that the fabric is sewn as the B fabric, the front thread trimming action is not performed at the moment.

in the preferred embodiment, there is also provided a preferred back trimming method: after the current thread cutting action is executed and completed, whether the fabric is C or D, the fabric must be separated from the inductor 4 and then the inductor 3, and at the moment, the fabric can be separated from the inductor 3 through N₄The number of stitches is delayed to perform post trimming.

The technical features of the above embodiments can be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the above embodiments are not described, but should be considered as the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above examples only show some embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims

1. A sewing machine control system, comprising: the device comprises a first inductor (3), a second inductor (4) and a controller; the first inductor (3) and the second inductor (4) are respectively coupled with the controller, wherein the first inductor (3) and the second inductor (4) are arranged on a sewing table (1) of the sewing machine, and a straight line where the first inductor (3) and the second inductor (4) are located forms a preset included angle with the feeding direction of the sewing machine; the controller is used for performing front trimming control according to first detection results of the first sensor (3) and the second sensor (4).

2. The sewing machine control system of claim 1, further comprising: a third inductor (5) and a fourth inductor (7), the third inductor (5) and the fourth inductor (7) being coupled to the controller, respectively; the third inductor (5) is arranged at the tail end of the needle plate (8) and is positioned on one side of a thread cutting cutter meshing surface (6) of the sewing machine; the fourth inductor (7) is arranged on the sewing table (1) and is positioned on an extension line of the meshing surface (6) of the thread cutting cutter; the controller is further used for performing rear trimming control according to second detection results of the third sensor (5) and the fourth sensor (7).

3. The sewing machine control system of claim 1, further comprising: a fifth inductor (2), the fifth inductor (2) being coupled with the controller; wherein the fifth inductor (2) is arranged on the sewing table (1).

4. The sewing machine control system of any of claims 1-3, wherein the predetermined included angle is 90 °.

5. A sewing machine control method of a sewing machine control system, the sewing machine control system comprising: the device comprises a first inductor (3), a second inductor (4) and a controller; the first inductor (3) and the second inductor (4) are respectively coupled with the controller, wherein the first inductor (3) and the second inductor (4) are arranged on a sewing table (1) of the sewing machine, and a straight line where the first inductor (3) and the second inductor (4) are located and a feeding direction of the sewing machine form a preset included angle, and the sewing machine control method is characterized by comprising the following steps of:

detecting the cloth through the first inductor (3) and the second inductor (4) to obtain a first detection result;

and performing front trimming control according to the first detection result.

6. The sewing machine control method according to claim 5, wherein performing the front cut control based on the first detection result in a case where the predetermined angle is 90 ° includes:

judging whether the front end of the cloth exceeds the meshing surface (6) of the trimming cutter or not when the second sensor (4) detects the cloth according to the first detection result;

when the fact that the front end of the cloth exceeds the meshing surface (6) of the thread trimming cutter when the second sensor (4) detects the cloth is judged, front thread trimming is not executed; otherwise, determining a second trimming delay needle number according to the first detection result, and sewing the second trimming delay needle number after the first sensor (3) detects the cloth, and then executing front trimming.

7. The sewing machine control method according to claim 6, wherein determining a second number of trimming delay stitches based on the first detection result includes:

determining the second trimming delay pin number N according to the following formula_{Front side}：

Wherein the content of the first and second substances,

l' represents the distance from the second inductor (4) to the meshing surface (6) of the thread cutting knife; d represents the current stitch length value of the sewing machine; y is₁Represents the distance of the first inductor (3) to the second inductor (4); y is₂Indicating the distance from the first inductor (3) to the edge of the needle plate (8) on one side of the cutting notch of the needle plate (8); v represents the rotating speed of the sewing machine when the second sensor (4) detects cloth; a represents an acceleration of the sewing machine; Δ t represents a time difference from the detection of the cloth by the second sensor (4) to the detection of the cloth by the first sensor (3);

indicating a rounding down.

8. The sewing machine control method according to claim 5, wherein the sewing machine control system further comprises: a third inductor (5) and a fourth inductor (7), the third inductor (5) and the fourth inductor (7) being coupled to the controller, respectively; the third inductor (5) is arranged at the tail end of the needle plate (8) and is positioned on one side of a thread cutting cutter meshing surface (6) of the sewing machine; the fourth inductor (7) is arranged on the sewing table (1) and is positioned on an extension line of the meshing surface (6) of the thread cutting cutter; after performing the front cut control according to the first detection result, the sewing machine control method further includes:

detecting the cloth through the third inductor (5) and the fourth inductor (7) to obtain a second detection result;

and performing rear trimming control according to the second detection result.

9. The sewing machine control method according to claim 8, wherein performing post-cut control according to the second detection result includes:

according to the second detection result, whether the fourth inductor (7) detects that the cloth leaves before the third inductor (5) is judged;

when the fourth sensor (7) detects that the cloth leaves before the third sensor (5) is judged, determining a third trimming delay needle number according to the first detection result, and performing post trimming after the third trimming delay needle number is sewn after the third sensor (5) detects that the cloth leaves; otherwise, determining a fourth trimming delay needle number according to the first detection result, and executing the rear trimming after sewing the fourth trimming delay needle number after the fourth sensor (7) detects that the cloth leaves.

10. The sewing machine control method according to claim 9, wherein determining a third trimming delay needle count based on the first detection result includes:

determining the third trimming delay pin number N according to the following formula_{Rear end}：

Wherein the content of the first and second substances,

L₄the distance between the third inductor (5) and the meshing surface (6) of the thread cutting cutter is shown; d represents the current stitch length value of the sewing machine; y is₃Represents the distance of the fourth inductor (7) to the third inductor (5) in the feeding direction; y is₄Indicating the distance from the third inductor (5) to the edge of the needle plate (8) on one side of the cutting notch of the needle plate (8); v represents the rotating speed of the sewing machine when the fourth sensor (7) detects that the cloth leaves; a represents an acceleration of the sewing machine; deltat represents the distance from the fourth sensor (7) to the fourth sensorThe three sensors (5) detect the time difference until the cloth leaves;

indicating rounding up.

11. The sewing machine control method according to claim 9, wherein determining a fourth trimming delay needle count according to the first detection result includes:

determining the fourth trimming delay pin number N according to the following formula_{Rear end}：

Wherein the content of the first and second substances,

L₄the distance between the third inductor (5) and the meshing surface (6) of the thread cutting cutter is shown; d represents the current stitch length value of the sewing machine; y is₃Represents the distance of the fourth inductor (7) to the third inductor (5) in the feeding direction; y is₄Indicating the distance from the third inductor (5) to the edge of the needle plate (8) on one side of the cutting notch of the needle plate (8); v represents the rotating speed of the sewing machine when the fourth sensor (7) detects that the cloth leaves; a represents an acceleration of the sewing machine; Δ t represents a time difference from when the third sensor (5) detects the departure of the cloth to when the fourth sensor (7) detects the departure of the cloth;

indicating rounding up.

12. The sewing machine control method according to claim 5, wherein in the case where the predetermined angle is 90 °, after performing front cut control based on the first detection result, the sewing machine control method further comprises:

detecting the cloth through the first inductor (3) and the second inductor (4) to obtain a third detection result;

and performing rear trimming control according to the third detection result.

13. The sewing machine control method according to claim 12, wherein performing the post-cut control based on the third detection result includes:

and determining a fifth trimming delay needle number according to the third detection result, and sewing the fifth trimming delay needle number after the first sensor (3) detects that the cloth leaves, and then performing post trimming.

14. The sewing machine control method according to claim 13, wherein determining a fifth trimming delay needle count according to the third detection result includes:

determining the number N of the fifth trimming delay pins according to the following formula_{Rear end}：

Wherein the content of the first and second substances,

l' represents the distance from the second inductor (4) to the meshing surface (6) of the thread cutting cutter; d represents the current stitch length value of the sewing machine; y is₁Represents the distance of the first inductor (3) to the second inductor (4); y is₂The distance from the first inductor (3) to the edge of the needle plate (8) positioned on one side of the notch of the cutter of the needle plate (8) is shown; v represents the rotating speed of the sewing machine when the second sensor (4) detects cloth; a represents an acceleration of the sewing machine; Δ t represents a time difference from when the first sensor (3) detects the departure of the cloth to when the second sensor (4) detects the departure of the cloth;

indicating rounding up.