JPS5824546B2 - Loop length correction device for continuous processing machines for textile products - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention connects long textile products such as knitted fabrics, and allows the connected textile products to be fed in a rope-like bundle. This invention relates to a loop length correction device for a continuous processing machine for textile products, which performs processes such as carpet washing, washing, dyeing, scouring, and bleaching.

More specifically, a processing chamber installed in the textile product feeding route,
a textile product feeding means provided above the processing chamber, the continuous textile products introduced from one end side of the processing chamber;
In a continuous processing machine for textile products, the textile products are processed in a spiral shape so as to pass through a processing chamber and a feeding means to form a plurality of loops, and are processed while being led out from the other end of the processing chamber. This invention relates to a device for correcting the loop length of each textile product set to a set length.

A continuous processing machine with such a configuration can be used, for example, by connecting textile products (hereinafter referred to as cloth) to form a rope, and then spirally forming a plurality of loops on a squeezing roll or win reel. A conventional technique has been proposed in which the processing is carried out while being fed in one direction.

In addition, there is a method in which a cloth set in a spiral is processed while being reciprocated so that the amount of feed in the forward direction is larger than the amount of feed in the backward direction, which is related to an earlier application filed by the present applicant in JP-A-51- No. 47189.

In such a continuous processing machine, the fabric is transferred as the squeezing roller or win reel rotates, but the fabric sandwiched between the squeezing rollers may slip, and the fabric may slip at each nip point. Since the amount of slip is different, the length of each loop fluctuates drastically due to long-term processing, resulting in tangles of the fabric in the processing chamber, wrapping of the fabric around the squeezing roller, and damage to the fabric and deterioration of quality. In extreme cases, the fabric may be cut, and furthermore, it may become impossible to operate.

Similar drawbacks also existed in the case of Winsreel.

For this reason, it is necessary to correct each loop length before extreme loop length fluctuations occur, but conventional correction work is performed by the operator's visual intuition, so it is impossible to ensure accuracy. In addition, the processing solution in the processing chamber becomes polluted and foamed due to long-term processing, which increases the difficulty of processing, resulting in quality deterioration and long-term shutdowns.

Furthermore, since the straightening work involved pulling wet and heavy cloth, it was extremely labor-intensive and the environment was bad.

For this reason, the applicant proposed a device that accurately corrects the loop length.

An example of such a device is disclosed in Japanese Patent Laid-Open No. 52-27883.

To put it simply, one invention of this cited application reciprocates a rope-like cloth set in a spiral shape so as to pass through a squeezing liquid roller and a processing chamber, and the feeding is performed for a set time or a set number of times. When this is reached, the machine is stopped, and then the process continues on the fabric inlet and outlet sides of the processing chamber.

The filter cloth is separated, and a detectable part such as metal foil is placed at a predetermined distance (an interval corresponding to the specified loop length) from the end of the separated cloth in the processing chamber. Connect the guiding cloth to make it endless, and while moving this endless thing, correct the individual loop lengths one by one.
After straightening, the connected portions are separated and the straightened ends of the cloth are reconnected to the ends of the cloth waiting on the cloth inlet and outlet sides of the processing chamber for processing.

Although such a device can accurately correct the loop length, it is necessary to temporarily separate the continuous fabric, and after correction, it is necessary to return the corrected fabric to its original position. This method requires human labor to separate and connect the cloth, which reduces productivity and cannot be fully automated.

Furthermore, a continuous processing device capable of correcting the loop length while performing normal processing without cutting the fabric was proposed in Japanese Patent Application Laid-open No. 53-24473, which was previously filed by the present applicant.

In the invention of this cited application, a rotary hook is used to separate the corresponding portion of the fabric from the guide adder when correcting the loop length, but such a rotary hook is as follows. There was a risk that an inconvenient situation would occur.

In other words, in order to provide a large number of nips with a small number of liquid squeezing rollers, it is desirable to arrange the cloth in a spiral shape as densely as possible. In the case of fabrics, or fabrics that have high elasticity and spread easily, such as irregular twill fabrics or Amundsen fabrics, adjacent fabrics may overlap, and in such cases, rotating type fabrics such as the cited invention do not allow the fabric to When hooking, there is a risk of damaging the fabric or hooking adjacent fabrics at the same time.

The present invention basically utilizes the cited invention described above, but it corrects the loop length without damaging the fabrics even when they overlap, and without simultaneously separating adjacent fabrics. The aim is to provide a device that can do this.

The present invention will be described below with reference to illustrated embodiments, but the figures are merely examples and are not limited thereto, and design changes or alternative means can be used within the scope of the following explanation. .

Figures 1 and 2 show an example of a continuous processing machine used in the present invention, which is a type that reciprocates the fabric so that the amount of fabric fed in the forward direction is smaller than the amount of fabric fed in the backward direction. belongs to.

Reference numeral 1 designates a processing chamber that stores a processing solution, and storage chambers 3 and 3' for cloth 2 are preferably provided on both sides of the processing chamber 1, and these chambers are supported by frames 4 and 4', and the processing chamber 1 stores a processing solution. The surface is boundary 6
, 6' are made of porous material so that they can be adjusted to the same level.

A liquid squeezing roller 7 is provided above the processing chamber 1 for feeding the cloth 2 and removing the treatment liquid impregnated into the cloth.

In the embodiment, the liquid squeezing roller 7 includes two upper and lower rollers 7'.
.

The upper roller 7/ is pressed against the lower roller 7'' by a pressure means (not shown), and the lower roller 7'' drives the reducers 9 and 10 by a drive device 8 that can be rotated forward and backward. Then, it is actively rotated via a chain wheel 12 provided on a roller shaft 11.

The squeezing fluid roller 7 rotates normally (the direction in which the cloth 2 is moved in the direction of the arrow in FIG. 2, that is, in the forward direction) and the amount of cloth feed is reversed (the amount of cloth 2 is moved in the direction of the arrow B in FIG. 2, that is, in the backward direction). The feed amount is set to be larger than the feed amount according to the direction of movement).

A guide roller 1 for the cloth 2 is installed before and after the squeezing roller 7.
3, 13' are provided.

This guide roller 13.13' is a chain wheel 1 provided on the roller shaft 11 below the liquid squeezing roller I.
2, it is rotated in the forward and reverse directions together with the squeezing roller 7, but when the squeezing roller 7 rotates forward (when the cloth moves forward), it takes over one guide roller 18' (the left side in FIG. 2). The other guide roller 1°3 actively rotates as a roller, and the clutch 30 operated by a control device (not shown) disconnects the transmission from the chain wheel 12 and makes it free, thereby preventing the transfer of the cloth 2. It is designed to passively rotate with the movement.

Also, when the squeezing roller 7 reverses (when the cloth moves backward), one guide roller 13' is disconnected from the chain wheel 12 by the clutch 30' and becomes free, and the other guide roller 13 is used as a take-up roller. I try to rotate actively.

When the guide roller 13, 13' is configured in this way, the fabric hangs between the squeezing roller 7 and the guide roller 13 or 13' when the squeezing roller 7 rotates forward or backward, causing the squeezing roller 7 to move up and down by %.

This is to prevent it from getting wrapped around the other roller 7''.

14.14' is the squeezing roller 7 and the guide roller 1
3.13' is a supporting frame, 15a to 15h and 16a to 16h are ring-shaped guides provided between the liquid squeezing rollers 13 and 13', 17.17' is a fabric feeding roller, and 18.18' is a feeding roller. Roller, 21a-21
h and 22a to 22h are grid-like guides, 24, 25
, 26. 27 is a guide on the cloth feeding side, 28 is a dipping tank,
29 is a guide on the cloth feeding side.

At the time of processing, at least the same amount of cloth is stored in the storage chambers 3 and 3' as the forward rotation of the squeezing roller 7, that is, the forward movement of the cloth 2, and The cloth is squeezed by the liquid roller 7 and the guide roller 13.13'
In this state, the cloth is moved forward and backward by rotating the squeezing liquid roller 7 in a spiral manner, and the treatment is carried out by repeating the treatment liquid impregnation and squeezing process many times during this period.

Such a type of continuous processing machine is disclosed in Japanese Patent Application Laid-Open No. 51-47189, which was previously filed by the present applicant. Easily and easily adjust the loop length of the set cloth.
The aim is to correct the problem accurately, and the details will be explained below.

FIG. 3 shows a guide cloth 40 used for correcting the loop length, and the guide cloth 40 is connected to the treated cloth 2 at an appropriate time.

In the embodiment, two detected objects 41.
41' is provided.

Detected object 41.41' is metal foil, metal type, fluorescent dyed thread,
Fluorescent dyed cloth, metal netting, etc. can be used, but in this embodiment aluminum foil is arranged over the entire width of the guiding cloth 40, a cloth is placed on top of the aluminum foil, and the material is sewn with a sewing machine.

Note that the object to be detected may be directly attached to the treated cloth 2 without using the guiding cloth, but in this case, since there is a risk of damaging the treated cloth, it is preferable to use the aforementioned guiding cloth.

FIG. 4, FIG. 5, and FIG. 6 are a side view, a plan view, and a schematic front view showing an example of the loop length correcting means.

In these figures, 47.47' is a detector for detecting the object to be detected 41.41' attached to the guiding cloth 40, and this detector is connected to the feeding path of the processing cloth 2 (in the illustrated example, the diaphragm). The treated cloth 2 is placed between the liquid roller 7 and the guide roller 18'.
Two pieces are provided so that the spacing is the same as that of .

The detectors 47, 47' are attached to a trolley 50 placed on rails 48, 48' installed above the processing chamber 1 via pulleys 49, 49', and as the trolley 50 moves, and is moved in the axial direction of the squeezing roller 7 (movement positions are indicated by 47a to 47h in the developed view shown in FIG. 8).

The detector 47.47' is an edge current type proximity switch when the detected object 41.41' is a metal foil, an iron piece detection type when the detected object 41.41' is metal or a metal mesh, a fluorescent dyed thread,
In the case of fluorescent dyed cloth, a fluorescent detection type is used.
In the embodiment, a proximity switch is used.

55, 56, 55', and 56' are for stopping the running of the corresponding portion of cloth when the head side 41 of the detected object is detected by one side 47 of the detector during loop length correction. The stopping means is provided in the feeding path of the processing cloth 2 (in the illustrated example, near the guide rollers 13 and 13').

The stopping means 55 includes a gripping member 57 (details will be described later) for gripping the cloth 2 hanging down from the guide roller 18', and a control member 58 for controlling the operation of the gripping member 57.
(details will be described later), one end of which is connected to the control member 58, and the other end of which is supported by a lever 60.60 which is pivotally supported by a shaft 59 provided on the truck 50. 59 as a fulcrum and is configured to be swingable by a swinging means to be described later.

On the truck 50 is the lever 60, that is, the stop means 55.
A geared motor 61 is provided as a source of rocking, and a driven shaft 64 is provided with a driven pulley 63 which is transmitted and driven from a pulley 62 provided on the motor shaft. Rope locking member 66 provided in
A rope winding pulley 67 facing the is provided,
The lever 60, that is, the stopping means 55 is driven by the geared motor 61 to stop the pulley 62 and the driven pulley 6.
3. The hook between the rope winding pulley 67 and the rope locking member 66 is swung to the position indicated by the two-dot chain line using the shaft 59 as a fulcrum via the rope 68 passed therebetween.

Further, the other stopping means 56 is constituted by a cloth gripping member 69 and an operation control member 70 for the gripping member 69, similarly to the aforementioned stopping means 55, and is operated integrally with the stopping means 55. However, in this case, the stop means 56 is positioned between the liquid squeezing roller 7 and the guide roller 13' to move it up and down.

Elevating guides 71a and 71b for the operation control member 70 are provided on the sides of the truck 50, and the operation control member 70 includes a rope winding pulley 72 provided on the driven shaft 64 described above.
The shaft 65 of the aforementioned rope anchoring member 66 is anchored at one end to
A locking member 75 is provided for locking the other end of the rope 74 stretched through a guide pulley 73 provided at the By driving the pulley 61, the pulley 62,
The rope 74 hooked between the driven pulley 63, the rope take-up pulley 72, and the rope locking member 75 is raised and lowered to the position indicated by the two-dot chain line.

In addition, the stop means 55' on the guide roller 13 side.

56' is constructed similarly to the previously described stop means 55,56.

As the means for swinging and raising and lowering the stopping means 55, 56 and 55', 56', a cylinder or a rotary set of actuators may be used, and in the illustrated example, the stopping means are provided near the guide rollers 13, 13', respectively. Although two guide rollers are shown, one guide roller may be used as long as it can separate the cloth from the guide roller.

A motor 76 capable of forward and reverse rotation is provided on the trolley 50, and one drive of the motor 76 causes the pulley 49 to be moved through a Boo'J-77 provided on the motor shaft and a pulley 78 coaxial with the aforementioned pulley 49. is rotated, thereby moving the carriage 50 in the axial direction of the liquid squeezing roller 7.

Therefore, in the embodiment, as the trolley 50 moves, the stopping means 5
5, 56, 55', and 56' are also moved in the axial direction of the squeezing roller T (movement positions are 55a to 55g, t 56a to 56g, and 55'a to 55' in Fig. 8).
55'g.

56'a to 56'g).

Next, FIG. 7 is a detailed view of the stopping means in the above-described embodiment, but only one stopping means 55 is shown here.

One end of the cloth gripping lever (gripping member) 57 is connected to a cylinder (operation control member) 5 that operates the lever 57.
The shafts 81, 81 each have a lever 81, 81 fixed to the box 80 containing the cylinder 58, and a lever having one end pivoted to the tip of the rond 82, 82 of the cylinder 58. 83.83 is fixed.

Therefore, when the ronds 82.82 of the cylinder 58 are projected, the levers 57.57 are swung in the direction of the arrow by the levers 83.83 about the shafts 81.81, so that the cloth is gripped between the levers 57.57. held.

The tip of the lever 57.57 may have a spherical or cylindrical shape, for example, so as not to damage the cloth even if the cloth overlaps.
In short, it is desirable to have a shape that allows the lever 57 to be easily pushed apart without damaging the cloth when it is projected against the cloth.

Although the illustrated example has two levers for gripping and holding the cloth, it is also possible to use only one lever if the swinging angle of the levers is set to the same angle.

Furthermore, the actuation control member is not limited to a cylinder, but may also be a rope, a spring, or a combination of these.

Further, it is desirable to provide a sensor (for example, a limit switch) on the front side of the box 80 (on the side of the lever 5γ) to confirm that the cloth is securely gripped by the gripping member.

Next, the loop length correction operation when using two objects to be detected is as follows.
This will be explained mainly using FIG.

During correction, a guiding cloth 40 shown in FIG. 3 is connected in advance to the processing cloth 2 introduced into the processing chamber 1, and a detector 4
7.47' to the positions 47b and 47a, and the stop means 55
, 56 and 55', 56' to 55a.

56a, 55'a, and 56'a, and the detectors 47, 47' are kept in an operable state.

Here, the loop length immediately before correction (the length of the cloth between adjacent detectors in the example) is 25 m, 45 m from the entrance side,
25m, 25m, 45m, 25m, 25m, and the distance between the detected objects 41.41' is 35m.
1, that is, the prescribed loop length is 35 m.

In this state, processing is performed while moving the cloth 2 forward and backward, and when the cloth 2 moves forward, the head side 41 of the object to be detected is detected by the two detectors 47 and 47' provided in the feeding path of the cloth 2. When detected by the fabric stop detector (detector 47 in this example) inside, the machine is stopped and the squeezing roller 7 and guide adder are stopped.

13. Stop 13'.

After the machine stops, the roller 7 above the squeezing roller 7
2' is lifted up and separated from the lower roller 7'' (the separated state is shown by the dotted line in FIG. 4, and the cloth is now in the position 2' shown by the dotted line) to put the squeezing roller 7 into the inactive state.

Make it.

Next, the geared motor 61 on the trolley 50 is driven to swing the stop means 55, 55' to the position indicated by the two-dot chain line in FIG. 4, and the other stop means 56, 56' to the position indicated by the two-dot chain line in FIG. lower it.

Lever 57 , 57 ′, 69 , 69 for gripping the cloth of each stopping means during rocking/swinging and lowering of the stopping means
' is protruded from both sides of the cloth in the width direction, and when it reaches the fixed position (the position indicated by the two-dot chain line), the geared motor 6
1 is stopped.

After the motor 61 is stopped, the cylinder 58 is actuated to swing the levers 57, 57' and 69.degree. 69' toward each other to grip and hold the cloth.

Next, the geared motor 61 is driven in the opposite direction to swing the stop means 55, 55' to the position shown by the solid line in FIG. 4, and the other stop means 56, 56' is raised to the position shown by the solid line. .

This allows the corresponding part of the cloth to be moved around the guide adder 13.13.
(The separated state is 2'' in Figure 4.
).

The machine is restarted in this state, but since the first loop length is shorter than the specified length, the head side 41 of the detected object is connected to the detector 47' located at 47a with the butt end. Before side 41' is reached, detector 47 located at 47b is reached.

Therefore, in this case, the guide rollers 13, 13' are driven one time in the forward rotation direction to move the cloth 2 in the forward direction, but in this case as well, the guide rollers 55a, 56a and 55'a are rotated as described above.

Stop means 55, 56 and 55' located at 56'a.

56' keeps the part of the fabric separated from the guide roller 13.13' stationary.

When the butt side 41' of the object to be detected reaches the detector 47' located at 47a during the forward movement of other parts of the cloth, the machine is stopped and the guide rollers 13 and 13' are stopped. do.

This means that the first loop length correction has been completed.

After the correction is completed, the cloth gripping levers 57, 57', 69
．． The grip of the cloth by 69' is released, thereby allowing the cloth to fall under its own weight and return to the state of 2'.

In addition, the detector 47.47' is moved (47 is moved to the position 47c and 47' is moved to the position 47b), and the stopping means 55.5 is moved.
6, 55' and 56' are also moved (55, 55' is moved to 55b
, 56.56' in position 55'b, 56b.

56'b).

Also, the roller 7' above the liquid squeezing roller 7 is returned to its original position.

Next, the machine is driven again to correct the second loop length when the cloth 2 moves forward, but since the second loop length is longer than the specified length, in this case, the butt part of the object to be detected is The side 41' reaches the detector 47' located at 47b before the head side 41 reaches the detector 47 located at 47c.

However, in this case, the machine continues to be driven without being stopped.

Then, when the head side 41 of the object to be detected reaches the detector 47 located at 41c, the machine is stopped, and after stopping the machine, the liquid squeezing roller T is made inactive in the same manner as described above, and it is not used again. The machine is restarted in such a state that the fabric in the corresponding part is kept in a stopped state, but in this case, as mentioned above, the second loop length is longer than the specified length, so in this case, the guide roller 13 13' is driven in the reverse direction to move the cloth 2 in the backward direction.

At this time, 55b, 56b and 55'b. 56'
The part of the fabric pulled away from the guide roller 13.13' is kept at rest by the stop means 55.56 and 55'56' located at b.

Then, when the other portion of the cloth moves backward, the machine is stopped when the butt side 41' of the object to be detected reaches the detector 47' located at 47b.

This completes the correction of the second loop length, and after the correction is completed, the squeezing roller 7 is returned to its original position in the same way as described above, and the detectors 47, 47' and the stop means 55, 56 and 55', 56' Move to the next position.

Thereafter, the loop length is sequentially corrected in the same manner.

The above explanation is about the loop length correction operation when two objects are used, but it can also be performed when there is only one object to be detected, and this will be explained below.

FIG. 9 shows a guiding cloth connected to the treated cloth 2, and this guiding cloth 140 is provided with one detected object 141.

The loop length correction operation in this embodiment is performed in substantially the same manner as when two detection objects are used, but in this example, when the first loop length is corrected, when the cloth 2 moves forward, When the detected object 141 passes the detector 47' (see FIG. 8) located at 47a, a counter (not shown) is activated, and the cloth 2 is controlled until the detected object 141 reaches the detector 47 located at 47b. The amount of migration is measured (counted).

An example of such length measuring means is shown in FIG.

That is, a disk with a protrusion T is provided on the roll shaft 11 below the squeezing roller 7, and a detected object S' such as a metal foil is provided on the protrusion T, and the rotation path of the detected object S' is A detector S such as a proximity switch is provided to detect the detected object S', and a counter (not shown) is activated via the detector S when the detected object 141 is detected by the detector 47'. This is how it was done.

Then, when the cloth 2 moves forward, the detected object 141 is 47
The machine is stopped when detected by the detector 47 located at point b.

At this time, the number of rotations of the squeezing roller 7 required for the cloth 2 to reach the detector 47' from the detector 47' is counted on the counter.

After the machine is stopped, the squeezing roller 7 is made inactive, and the corresponding portion of the cloth is maintained in a stopped state, as in the previous embodiment.

Next, the machine is restarted in this state, but here the specified loop length is set to 35 m, and the number of rotations of the squeezing fluid roller 7 required for this loop length to shift from the detector 47' to the detector 47 is set to 20 m, for example. If the first loop length is shorter than the specified length, the number will be smaller than the set count number, for example 15 times, so in this case, the difference between the set count number and the length measurement count number will be The cloth 2 is moved in the forward direction by (20-15 m 5 times), and the machine is stopped when the count number on the counter reaches the set count number (20 times).

As a result, correction of the first loop length is completed, and after the correction is completed, the squeezing fluid roller 7 is returned to its original position, and the detector 47
．． 47' and stop means 55, 56 and 55', 56
' to the next position.

The loop length is longer than the specified length, for example, the count number is 25.
When the number of counts is reached, the difference between the set count number and the length measurement count number is (20-25--5 times). Therefore, in this case, the cloth 2 is moved in the backward direction, and the count number on the counter becomes the set count number. Stop the machine when

Thereafter, the loop length is sequentially corrected in the same manner.

Note that although a counter is used in the embodiment, the invention is not limited to this, and for example, a timer may be used.

Furthermore, in the embodiments described above, two detectors were used, but if a detector is also provided in front of the detector for stopping the cloth (the 4γ detector in the embodiment), it is possible to correct the part to be corrected. You can measure the front loop length of the fabric in advance.
This makes it possible to predict the excess or deficiency of the loop length before straightening and control the amount of fabric remaining in the storage chamber. If the length is such that it does not affect the tangle of the cloth, the loop length of this portion can be transferred as is without being straightened.

In addition, in the two embodiments described above, the detector 47°47'
Although the stop means 55, 56, 55', and 56' are both moved in the axial direction of the squeezing roller 7, the present invention is not limited to this. For example, as shown in FIG. Place the containers at equal intervals and in the same number as the nip portion of the cloth 2 in the 7 portions of squeezing rollers (47a to 4 in the example).
It is also possible to provide eight stopping means and move only the detector, or it is possible to provide eight stopping means and move only the detector, or to move both the detector and the stopping means. You may also provide one.

In this case, the cloth stop detectors are changed in the order of 47b to 47h.

Furthermore, as shown in FIGS. 12 and 13, the processing machine used in the present invention can be configured to have an arbitrary number of rollers (the same number as the nip portion of the cloth 2) so that the rollers above the squeezing roller 7 can be rotated individually. , therefore, in the illustrated example, it is divided into 8 pieces),
These rollers γ'a to 7'h may be configured to be able to move toward and away from the drive roller 90 and the lower roller 7'' individually.

In this case, only the rollers corresponding to the cloth kept in a stopped state can be made inactive.

. Further, the present invention can also be applied to a type of processing machine that mainly transfers the cloth in only one direction, such as a processing machine in which a guide roller is provided only on one side of the squeezing roller 7 as shown in Fig. 14. be.

In this case, cloth stopping means as shown in FIG. 4 is provided near the guide roller 13, for example.

In addition, as shown in FIG. 15, a cylindrical win reel 10
The present invention can also be applied to a win reel 100, in which case a cloth stopping means as shown in FIG. 4 is provided near the win reel 100.

In addition, as shown in FIG. 16, a cylindrical win reel 10
The present invention can also be applied to a wince machine using only 0. In this case, for example, as shown in the figure, the cloth stopping means 5
5.55' are each configured to be swingable.

Furthermore, as shown in FIGS. 17 and 18, it can also be applied to a Wins machine using an elliptical Wins reel 101.
In this case, for example, the first
Cloth stop means as shown in FIG. 6 are provided.

Since the present invention is as described above, the loop length can be corrected in a short time and accurately while performing normal processing.
Moreover, it can be carried out automatically, and even if the cloth overlaps, it can now be corrected without damaging the cloth.

[Brief explanation of drawings]

Fig. 1 is a plan view showing an example of a continuous processing machine used in the present invention, Fig. 2 is a sectional view taken along line II-II in Fig. 1, and Fig. 3 is an explanation of a guiding cloth provided with two detection objects. FIG. 4 is a side view showing an example of the loop length correcting means, and a portion thereof is shown in cross section. 5 is a plan view of FIG. 4, FIG. 6 is a schematic front view of FIG. 4, and FIG. 7 is a plan view showing an example of the cloth stopping means, partially in section. FIG. 8 is a developed view of FIG. 1, showing a state in which a loop length correction means is provided. FIG. 9 is an explanatory diagram of a guiding cloth provided with one object to be detected, FIG. 10 is a side view showing an example of a means for measuring the amount of cloth migration,
Figure 1 is a front view showing another example of the arrangement state of the detector;
The figure is a schematic side view showing another example of the continuous processing machine used in the present invention, FIG. 18 is a plan view of FIG. 12, and FIGS.
FIG. 8 is a schematic side view showing still another example of the continuous processing machine used in the present invention. 1... Processing room, 2... Textile products, 7.
... Squeezing roller, 13.13'... Guide roller, 40... Guide cloth, 41.41',
141...Object to be detected, 47°47'...
・Detector, 55.55', 56, 56'...Textile product stopping means, 57, 57', 69, 69'・
...Textile product gripping member, 58.58', 70.7
0'...operation control means, 100, 101...
...Winsliel.

Claims (1)

[Scope of Claims] 1. A processing chamber provided in a textile product feeding path, and a textile product feeding means provided above the processing chamber, and continuous fibers introduced from one end side of the processing chamber. In a continuous processing machine for textile products, the product is spirally arranged to pass through a processing chamber and a feeding means to form a plurality of loops, and is processed while being led out from the other end of the processing chamber,
A detector for detecting a detected object attached to the textile product or a guiding cloth connected to the textile product is provided on the textile product feeding route, and a detector for detecting the detected object attached to the textile product or a guiding cloth connected to the textile product is provided on the textile product feeding route. stop means actuated to stop the feeding of the textile product in the corresponding portion of the spirally arranged textile product in response to said stop means being activated to stop the feeding of the textile product in the corresponding portion of said spirally arranged textile product; 1. A loop length correction device for a continuous processing machine for textile products, characterized in that the device is configured to protrude and grip the textile product, and to separate the gripped textile product from the feeding means. 2. A loop in the continuous processing machine for textile products according to claim 1, wherein the feeding means includes a squeezing roller provided above the processing chamber and a guide roller provided on one or both sides of the squeezing roller. Length correction device. 3. A loop length correction device in a continuous processing machine for textile products according to claim 1, wherein the feeding means is a win reel. 4. A patent claim in which the stopping means includes a textile product gripping member that protrudes from one or both sides in the width direction of the spirally set textile product, and an operation control means that operates this gripping member. A loop length correction device in a continuous processing machine for textile products according to item 1. 5. The loop length correction device in a continuous processing machine for textile products according to claim 1, wherein the detector and the stop means are configured to be movable in the axial direction of the feeding means. 6. The loop length correction device in a continuous processing machine for textile products according to claim 4, wherein the tip of the textile product gripping member is formed in a spherical or cylindrical shape.