JPH02176505A - Device and method for detection - Google Patents

Abstract

PURPOSE:To detect with high accuracy side edge rubber width dimension of a band-like body which is in the course of running in the longitudinal direction or in a stop state by providing a width measuring sensor, a metallic quantum detecting sensor and an arithmetic part. CONSTITUTION:By a width measuring sensor 13, a distance l1 extending from the side end of a band-like object being in the course of running in the longitudinal direction or in a stop state to a prescribed part of the band-like object 3 is detected. By this metallic quantum detecting sensor 14, a distance l2 extending from the nearest metallic wire to the side end of the band-like body 3 to a prescribed part is detected. Subsequently, the subtracting the detected distance l2 from the sensor 14 from the detected distance l1 from the sensor 13 by an arithmetic part, the side edge rubber width dimension L is detected. Also, by bringing the cutting quantum of side edge rubber of the band-like body 3 to fine adjustment, a desired side edge rubber width dimension can be detected with high accuracy.

Description

Detailed Description of the Invention [Industrial Application Field] The present invention is directed to the side of a belt-shaped body made of a plurality of metal wires arranged in parallel and coated with raw rubber material while running in the longitudinal direction or in a stopped state. The present invention relates to a detection device and a detection method for measuring the side edge rubber width dimension from the end to the metal wire closest to the side edge.

[Prior art and problems to be solved] -Finally, metal wires such as steel wires are arranged in parallel and rubber-coated in reinforcing layers such as various fibers that reinforce the belt layer of the tire and furthermore the bead portion. Cord ply is often used.

This cord ply is produced by cutting diagonally at a predetermined inclination and width a so-called long belt-shaped body topped with rubber on both sides of a sheet base on which metal wires are arranged in parallel, and then cut into rectangular or parallelogram shapes. After forming the pieces, the cut pieces are joined together at the uncut edges, that is, at the side ends, so-called ears (side edge rubber) to form a long strip again.

Therefore, when topping is applied to a sheet base, the ears, that is, the side edge rubber formed outward from the metal wire located at the sidemost end of the metal wires arranged in parallel, are moved to a predetermined position while traveling in the longitudinal direction in the topping process. Cut in advance in the longitudinal direction leaving the joint dimension (width) of
Therefore, it was necessary to measure the width of the cough-side edge rubber of the running band immediately after the ear was cut.

However, in the past, there was no suitable method, and the inspection was carried out by visual inspection by a worker or by using X-rays.

However, visual inspection is inaccurate, causes individual differences among workers, and is difficult to constantly check. Furthermore, methods using X-rays have the drawbacks of high equipment costs and lack of safety.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a detection device and a detection method that can detect with high precision the side edge rubber width dimension of a belt-shaped body running in the longitudinal direction or in a stopped state.

[Means to solve the problem]

In order to achieve the above-mentioned object, the detection device of the present invention has a detection device that extends from the side edge of a band-shaped body made of a plurality of metal wires arranged in parallel and coated with raw rubber material to the metal wire closest to the cough side edge. A detection device for measuring the side edge rubber width dimension; a width measurement sensor that detects the distance between the side edge of the strip-like body and a predetermined portion of the strip-like body by irradiating a light beam and; generates a voltage according to the number of metal wires disposed on both sides of the strip, and calculates the distance between the metal wire and the predetermined portion from the metal wire closest to the side edge of the strip to the predetermined portion. a pair of metal amount detection sensors for detection; and a calculation unit that calculates the side edge rubber width dimension based on the distance detected from the metal amount detection sensor and the distance detected from the width measurement sensor. It is something that

The detection method of the present invention also includes the side edge rubber width dimension from the side edge of a band-shaped body formed by covering raw rubber material to a plurality of metal wires arranged in parallel to the metal wire adjacent to the side edge. A detection method for measuring the distance between the side edge and a predetermined portion of the strip by irradiating the strip with a light beam, and detecting the distance between the side edge of the strip and a predetermined portion of the strip, and determining the number of metal wires. Based on a metal amount detection sensor that generates a voltage according to The side edge rubber width dimension is detected by subtracting the metal wire/predetermined portion open circuit kI from the distance between the portions.

[For production]

According to the detection method and device according to the present invention, the width measuring sensor detects the distance from the side end of the strip-shaped body running or stopped in the longitudinal direction to a predetermined part of the strip-shaped body, and
The metal amount detection sensor can detect the distance from the metal wire closest to the side edge of the strip to the above-mentioned predetermined portion.Furthermore, the calculation section calculates the distance from the metal depth detection sensor from the detection distance from the width measurement sensor. By subtracting the detection distance, the side edge rubber width dimension is detected.

Further, from the measured side edge rubber width dimension, the desired side edge rubber width dimension (joint width) can be obtained by finely adjusting the cutting amount of the side edge rubber of the band-shaped body.

〔Example] Examples will be described below with reference to the drawings.

Figure 3 shows a plurality of metal wires l... (first
A manufacturing device for manufacturing a band-shaped body 3 (see FIG. 18) made by coating raw rubber material 2 (see FIG. 1A) on a raw rubber material 2 (see FIG. 1A) is shown, and this manufacturing device is arranged in parallel. A delivery roll 4 on which a plurality of metal wires 1 are wound, a topping calender 5 that coats raw rubber material 2 on the metal wires 1 sent out from the delivery roll 4 to form a band-shaped body 3, and a one-carrier calender. 5
A cutter 7 cuts the rubber on both sides of the belt-shaped body 3 sent out from the belt, leaving a predetermined joining dimension (width), and the remaining side edge rubber of the belt-shaped body 3 after the side edge rubber is canted by the cutter 7. It is equipped with a detection device 8 according to the present invention that measures the width dimension L (see FIG. 18), and a winding roll 9 that winds up the strip 3. In FIG. 3, IO is an adjustment mechanism that adjusts the amount of metal wire 1 detected from the delivery roll 4 to be supplied to the topping calender 5, and 11 is a cooling drum. Note that the metal wires l are wound around the delivery roll 9 in a parallel manner.

As shown in FIGS. 1A and 1B[I, the detection device 8 detects the distance l from the side edge 12 of the strip 3 to the predetermined portion S of the strip 3 (distance between the side edge and the predetermined portion). and a pair of gold 1fiffi detection sensors 1 that detect the distance 12 from the metal wire l closest to the side edge 12 of the strip 3 to the predetermined portion S (distance between the metal wire and the predetermined portion).
Eddy current displacement sensor as 4.14, distance 11 between side edge and predetermined part, and distance 2 between metal wire and predetermined part! and a calculation section 15 (see FIG. 2) that calculates the side edge width dimension based on the following.

Note that a high frequency sensor may be used as the metal amount detection sensor.

Here, the width measurement sensor 13 is, for example, a laser type discrimination sensor, and includes an irradiation section 16 that irradiates a laser beam.
and a light receiving section 1 that receives the laser beam from the irradiating section 16.
7, and detects the distance 11 between the side edge and the predetermined portion based on the amount of light shielded by the object. That is, since the irradiation width dimension of the laser beam is constant, by extracting the amount of light shielded by the object as an analog output within a predetermined range, the light shielding dimension can be detected. Specifically, in the example, the irradiation width dimension is 10+wm, and the predetermined range of sensor output is 1v~
It is set to 5V. Therefore, input the data that forms the graph as shown in Fig. 4, and calculate the light shielding dimension i+ (i.e., the distance between the side edge and the predetermined part if
) is detected. Note that the width measurement sensor 13 is of course not limited to a laser type discrimination sensor.

Next, the metal quantity detection sensor 14 outputs a voltage proportional to the distance to the object (strip body 3) and generates a voltage corresponding to the number of metal wires l. In other words, the relationship between the output voltage and the distance 2□ between the gold i-wire and the predetermined portion is determined manually, and the distance 12 between the metal wire and the predetermined portion is detected from the detected output voltage.

That is, FIG. 5 shows a relationship curve between the output voltage and the distance i2 between the metal wire and the predetermined part when the distance H from the strip 3 to the metal amount detection sensor 14 is changed in the range of 1 m+ to 7 mm. , the y-axis indicates the distance 2□ between the metal wire and the predetermined part, and y
The axis shows the output voltage.

Then, set the distance H to the reference position (i.e., the total distance #H of the upper and lower metal quantity detection sensors 14, 6ffi+l+, and the thickness dimension of the strip 3, 11m1, for a total distance of 7 mm) between the upper and lower pair. Note that the relational expression in the graph shown in FIG. 5 can be approximated by y=ax+bx3+c. a, b.

C is a constant.

Therefore, from the reference position in the longitudinal direction (that is, the 18th
The band-shaped body 3 traveling in the direction of the arrow
If there is a deviation of 1, the upper sensor 14 detects this and outputs the voltage ■1, and the lower sensor 14 detects this and outputs the voltage ■2. Then, points P on the reference curve at the output level of vl and the output level of v2, and P2
Find the point Q between these two points (straight line part) to 1.
Find the distance 1 between the metal wire and the predetermined part on the y-axis from this point Q.
．． Calculate. Incidentally, the upper and lower sensors 14.14 are shifted in the longitudinal direction as shown in FIG. 2 so as not to interfere with each other. In addition, in Fig. 5, ■ indicates the case where the distance is #H month long, n indicates the case where the distance is 2 m, and ■ indicates the case where the distance is #H months.
■ indicates the case of i11, ■ indicates the case of 4m11, ■ indicates the case of 51, ■ indicates the case of 6I1m, ■ indicates the case of 7
The case of mm is shown.

Then, the calculation unit 15 calculates the side edge width by subtracting the distance 12 between the metal wire and the predetermined portion from the distance 2 between the side edge and the predetermined portion. That is, the data from each sensor 1314.14 is input to the computer 19 via the A/D converter 18, as shown in FIG. 2, and is processed by the computer 19. The computer 19 is also provided with a recording section 20, a display section 21, and a cutter 7 control section 22.

Next, a method of manufacturing the strip 3 using the detection bag "fL8" configured as described above will be explained.

First, a large number of metal wires 1 that are aligned and sent out from the delivery roll 4 are supplied to the topping calender 5 via the adjustment mechanism 10, where they are covered with raw rubber material 2 to form the band-shaped body 3. . Next, this strip-shaped body 3 passes through a cutter 7 to cut off the excess rubber on both sides leaving a predetermined bonding dimension, and then passes through a detection device 8, and this strip-shaped body 3
The width of the remaining side edge rubber is measured, and the rubber is wound onto the winding drum 9 via the cooling drum 11.

According to the detection device 8, the distance 11 between the side edge and the predetermined portion is detected by irradiating the laser beam onto the strip 3 traveling in the longitudinal direction (arrow X direction), and the metal amount detection sensor 14 Based on .14, the pressure Hp between the metal wire and the specified part
-z is detected, and then the distance between the side edge and the predetermined part! By subtracting the distance 12 between the metal wire and the predetermined portion from , the width of the side edge rubber after canting is detected. Incidentally, the width of the side edge rubber can also be detected using a similar method for the belt-shaped body 3 in a stopped state.

Further, the detection device 8 operates according to the flowchart shown in FIG.

That is, since the strips 3 to be detected differ in side edge width and metal content (size and number) for each strip,
Data for determining the distance 21 between the side edge and the specified part (4th
(see figure) and data for determining the distance 2□ between the metal wire and the predetermined portion (see Fig. 5) are different for each strip 3. Therefore, the setting value of the side edge width dimension, the name of the strip 3 to be detected, and the above-mentioned data are input in advance, respectively, and the detection device 8 operates normally.
This refers to a case where the detected side edge width dimension and the set value of the band-shaped body are the same. ), the detected side edge width dimension is recorded in the recording section 20 shown in FIG. 2 and displayed on the display section 21. In addition, an abnormality (a case where the detected side edge width dimension and the setting value of the band-shaped body 3 are different)
), an abnormality is displayed on the winding roll 9, a signal is fed back to the moving mechanism before and after the cutter 7, and the control unit 22 finely adjusts the cut width by the cutter to make the side edge width a predetermined size. do.

Therefore, if the belt-shaped body 3 is manufactured using this detection device 8, the side edge rubber (edge portion) will be cut so that the side edge rubber width dimension for joining becomes a predetermined dimension. Become.

Note that the present invention is not limited to the above-described embodiments, and may be modified without departing from the gist of the present invention. For example, the irradiation width dimension of the width measurement sensor 13 may be limited to lhm as in the embodiments. The output voltage of the width measurement sensor 13 is also 1V.
It is not limited to the range of ~5v. Furthermore, the distance H between the metal amount detection sensor 14 and the band-shaped body 3 is also 1 m+m ~
The range is not limited to 7 mm.

〔Effect of the invention〕

The present invention produces effects as described below.

According to the detection method and device according to the present invention, the side edge rubber width dimension of the strip 3 running or stopped in the longitudinal direction can be automatically detected with high precision, and moreover, it does not use X-rays. , it is not expensive and is safe.

In addition, since the side edge rubber width dimension can be constantly detected while traveling in the longitudinal direction, abnormalities (referring to cases where the side edge rubber width dimension differs from the set value) will not be overlooked. Since the cut amount can be controlled by feeding back the detected value to the cutter, the width of the side edge rubber can be made uniform.
Uniform joint dimensions can be obtained and the product becomes stable.

[Brief explanation of the drawing]

FIG. 18 is a front view of essential parts of an embodiment of the detection device according to the present invention, FIG. 1B is a perspective view of the detection device, FIG. 2 is a bronchial view, and FIG. Figure 4 is a graph showing the relationship between the light-shielding dimension of the width measurement sensor and its output voltage, and Figure 5 is a graph showing the relationship between the output voltage of the metal amount detection sensor and the distance between the metal wire and a predetermined part. The graph shown in FIG. 6 is a flowchart showing the operation of the detection device. DESCRIPTION OF SYMBOLS 1... Metal wire, 2... Raw rubber material, 3... Band-shaped body, 12... Side end,
13... Width measurement sensor, 14... Metal plate detection sensor, 15... Calculation unit, 1. ...Distance between side edge and predetermined portion, 12...Distance between metal wire and predetermined portion, L...Side edge width dimension, S...Predetermined portion. ...Predetermined part. Patent applicant Sumitomo Rubber Industries Ltd.

Claims (1)

[Claims] 1. A raw rubber material 2 is attached to a plurality of metal wires 1 arranged in parallel.
A detection device for measuring the side edge rubber width dimension L from the side edge 12 of a strip-shaped body 3 coated with a metal wire 1 closest to the side edge 12, comprising: A width measuring sensor 13 is provided for detecting the distance l_1 between the side edge and the predetermined portion from the side edge 12 of the body 3 to the predetermined portion S of the strip 3; A pair of metal amount detection sensors 14, 14 that generate a voltage corresponding to the number of metal wires and detect a distance l_2 between the metal wire and the predetermined portion from the metal wire 1 closest to the side end 12 of the strip body 3 to the predetermined portion S. and the distance l_ detected from the metal amount detection sensors 14, 14.
2 and the distance l_1 detected from the width measurement sensor 13, a calculation unit 1 that calculates the side edge rubber width dimension L;
5. A detection device comprising: 2. Raw rubber material 2 is attached to multiple metal wires 1 arranged in parallel.
A detection method for measuring the side edge rubber width dimension L from the side edge 12 of a strip 3 coated with a metal wire 1 closest to the side edge 12, the detection method comprising: irradiating the strip 3 with a light beam; , the side edge 12 of the strip 3
Based on the metal amount detection sensor 14 that detects the distance l_1 between the side edge and the predetermined portion from the predetermined portion S of the strip 3 and generates a voltage according to the number of metal wires 1, the strip 3
Detect the metal wire-to-predetermined portion distance l_2 from the metal wire 1 closest to the side edge 12 of A detection method characterized by detecting the side edge rubber width dimension L by subtracting the side edge rubber width dimension L.