JPH05278916A - Ceramic sheet takeup device - Google Patents

Abstract

PURPOSE:To take up a ceramic sheet with a low tension by measuring the dangling distance of the sheet which dangles between a feed roll and a takeup core, and feedback controlling the revolving speed of a motor so that the distance measured is constant at all times. CONSTITUTION:A takeup device 10 takes up a ceramic sheet S for use in an IC board or semiconductor chip of a computer, wherein the sheet guided from a feed roll 12 reaches a takeup core 14 while forming a loop dangling approx. plumb end is taken up on the takeup core 14 which is rotated by a motor 16. Therein a distance sensor 20 is installed to measure the dangling distance of the loop, and the result from measuring is fed to a control device 18. The control device 18 makes feedback control of the motor 16 to increase and decrease its revolving speed so that the distance A of the loop is always constant. Thereby the sheet S can be wound with a constant tension at all times.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a winding device for a ceramic sheet.

[0002]

2. Description of the Related Art There is a ceramic sheet used for an IC substrate of a computer or a semiconductor chip.

Conventionally, as a method of manufacturing this ceramic sheet, ceramics such as alumina and zirconia are dissolved in a solvent to form a solution. This solution has a viscosity of 10.0.
It has a relatively high viscosity of 00 cps to 20,000 cps and is called a slurry. Then, the slurry is applied onto a synthetic resin sheet such as a polyester film and dried in a dryer to form a flexible ceramic sheet. The dried ceramic sheet is once wound on a winding core, then unwound from the winding core again and sent to a heat treatment device to be thermally cured to be used as a ceramic for an IC substrate or the like.

The winding device for winding the dried ceramic sheet on the winding core is as follows.

FIG. 5 shows a sheet-shaped ceramic sheet.
The winding device 200 winds the toe S.

The winding device 200 comprises a ceramic sheet S.
And a winding core 204 of a ceramic sheet S.

The winding state of the winding device 200 will be described.

When winding the ceramic sheet S, it is necessary to wind it with a certain low tension because it cannot be wound with a high tension like a cloth or a thin sheet. That is, since the ceramic sheet S is not as light as a web, it hangs down by its own weight, and therefore, it is necessary to wind the ceramic sheet S around the winding core once.

Therefore, as shown in FIG. 5, during winding, the ceramic sheet S is in a state of being hung between the feed roll 202 and the winding core 204 due to its own weight. (Hereafter, the hanging part
Called).

The winding device 200 detects the hanging distance of the loop by the two sensors 206 and 208. These two sensors 206, 20
8 is connected to the control device 212 of the motor 210 that drives the winding core 204. The controller 212 has two
By the signals of the two sensors 206 and 208, as shown by the solid line in FIG. 5, the state where the loop hangs downward (hereinafter, referred to as the lowest descent distance) and the state where the loop hangs up the most (hereinafter, the highest descent) (Referred to as "distance"), the motor 210 is intermittently rotated so that the loop hanging distance is accommodated as shown by the dotted line in FIG.
It is controlling the feedback.

That is, when the winding core 204 winds up the ceramic sheet S and the loop reaches the uppermost hanging distance, the sensor 206 detects it and the motor 210.
Stop driving. As a result, the feed roll 20
Since only 2 rotates, the ceramic sheet S
The drooping distance of gradually increases and becomes the lowest drooping distance. When the ceramic sheet S reaches the lowest hanging distance, the sensor 208 detects it and drives the motor 210 to rotate the winding core 204. Then, the ceramic sheet S is rewound and the hanging distance is shortened.

As described above, the loop is controlled between the lowermost hanging distance and the uppermost hanging distance and is wound with a constant low tension.

However, in the winding device 200, since it is necessary to drive or stop the rotation of the winding core 204, there is a problem that the tension applied to the ceramic sheet S changes. Therefore, the ceramic sheet
However, there is a problem in that the sheet S cannot be manufactured uniformly.

Next, a winding device 3 for winding the multi-row ceramic sheet S cut into a comb shape by a slitter.
00 will be described.

The winding device 300 is also a feeder 30.
2 and a winding core 304 are provided,
In the state in which the ceramic sheet S is hung between the reel 302 and the winding core 304, the winding core 304 winds up the multiple strips of the ceramic sheet S (see FIG. 6).

In this case, since the ceramic sheet S travels in a free manner, the ceramic sheet S meanders up to the winding core 304, as shown in FIG. , The loop becomes unstable, and in the winding core 304, adjacent tape portions (hereinafter, referred to as tape portions) T in the multi-row ceramic sheet S overlap each other to form an overlapping portion 319. There was a problem of formation.

When the tape portion T overlaps, the operator conventionally corrects the overlap portion 310.

[0018]

SUMMARY OF THE INVENTION In view of the above problems, the present invention provides a winding device capable of stably winding a ceramic sheet with low tension.

[0019]

A ceramic sheet winding device according to claim 1 of the present invention is a device for winding one sheet-shaped ceramic sheet. Guiding roll, a winding core that winds the ceramic sheet, a motor that rotates the winding core, and a ceramic sheet that hangs between the feeding roll and the winding core. -A sensor that measures the drooping distance of the motor, and a signal from the sensor that keeps the drooping distance constant.
The control means controls the feedback speed of the rotation speed of the rotor.

According to a second aspect of the present invention, a winding device for a ceramic sheet is a device for winding a multi-row ceramic sheet in the shape of a blind, which guides the multi-row ceramic sheet. A reel, a winding core of a multi-row ceramic sheet having partition walls at required intervals, a motor for rotating the winding core, and a motor for rotating in the winding direction. rear,
The control means is configured to rotate in a direction opposite to the winding direction by a certain angle and then rotate in the winding direction again.

[0021]

[Operation] The winding operation of the winding apparatus for the ceramic sheet according to claim 1 having the above construction will be described.

When winding one sheet of ceramic sheet, one sheet of ceramic sheet is used as a feeder.
From the loop to the winding core while forming a loop. The take-up core is rotated by the motor and the ceramic sheet is taken up. In this case, the sensor detects the distance from the sensor to the loop (hereinafter referred to as the drooping distance),
The detected signal is output to the control means, and the control means feedback-controls the rotation speed of the motor so that the hanging distance is always constant.

Next, the winding operation of the ceramic sheet winding device of claim 2 will be described.

A multi-row ceramic sheet cut into a comb shape by a slitter or the like is fed from a feed roll to a rule.
And guide it to the winding core while forming a loop. The ceramic sheet is wound by rotating the winding core in the winding direction with a motor. In this case, the tape portion of the ceramic sheet is wound around the winding portion defined by each partition wall.
The winding core rotates in the winding direction to wind the ceramic sheet for a certain length, and then rotates in a direction opposite to the winding direction (hereinafter, referred to as unwinding direction) to move the ceramic sheet. Rewind some. Then, the winding core is again rotated in the winding direction to wind the ceramic sheet.

[0025]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described below with reference to FIG.

The winding device 10 for the ceramic sheet S of the first embodiment is a device for winding one sheet-shaped ceramic sheet.

The winding device 10 includes a feeder 12
The winding core 14, a motor 16 for rotating the winding core 14, and a controller 18 for controlling the motor 16. Further, a distance sensor 20 that detects the distance to the loop is connected to the control device 18.

The winding operation of the ceramic sheet S of the winding device 10 will be described.

The ceramic sheet S guided from the feed roller 12 forms a loop and reaches the winding core 14. The loop leading to the winding core 14 hangs substantially vertically. The distance sensor 20 is set to measure the distance to the lowest point of the loop.

The controller 18 drives the motor 16 to rotate the winding core 14 in the winding direction. This speed is
The ceramic sheet S is wound at a speed of about 30 cm for 1 minute so that the speed is slow. The distance sensor 20 constantly detects the distance A to the lowest point of the loop and outputs the detection signal to the control device 18. The controller 18 drives the motor 16 in accordance with this signal, and controls the feedback by increasing or decreasing the rotation speed of the motor 16 so that the distance A is always constant.

As a result, the loop of the ceramic sheet S is always in a stable state. Further, the winding core 14 is
Since the ceramic sheet S is wound vertically, the traveling of the ceramic sheet S is always stable and can be wound with a constant tension. That is, since the self-weight of the ceramic sheet S is heavy, a stable tension can be obtained when it is wound vertically. Furthermore, the winding core 14 can be wound in a state where the winding core 14 does not collapse.

Next, the winding device 100 of the second embodiment will be described.

The winding device 100 is a device for winding the ceramic sheet S, which is cut into multiple threads by a slitter or the like.

This winding device 100 also includes a feed roll 12, a winding core 14, and a drive motor 1 for the winding core 14.
6 and the controller of the motor 16.

In the winding core 14, partition walls 22 are formed at required intervals in order to form winding portions 24 for winding the tape portions T of the multi-row ceramic sheet S, respectively. There is.

The tape portion T of the multi-row ceramic sheet S sent from the feed roll 12 is wound around each winding portion 24 of the winding core 14 while forming a loop. The motor 16 slowly rotates the winding core 14 in the winding direction and winds the winding core 14 at a constant angle, and then about 30% of the winding angle.
Rewind in the unwinding direction. And again the winding core 1
4 is rotated in the winding direction.

As a result, even if the tape portion T of the multi-row ceramic sheet S is wound around the winding portion 24 in an unstable state due to running such as meandering, it is once unwound and then unwound. Since the meandering state is eliminated, when it is rewound on the winding portion 24, the overlapped portion and the like unlike the conventional winding device cannot be formed. In addition, stable winding can be performed with low tension.

Therefore, there is no correction of the operator due to the collapse of the winding of the ceramic sheet S, so that unmanned operation is possible.

[0039]

As described above, in the winding apparatus for the ceramic sheet according to the first aspect of the present invention, the looping distance of the loop is monitored by the signal from the sensor so that the looping distance is always constant. Since the winding core is formed, the winding core can be wound with a constant tension, and winding can be performed without collapse.

According to the ceramic sheet winding device of the present invention, since the winding core is wound in the winding direction, it is once rotated in the unwinding direction, and then rotated again in the winding direction. The ceramic sheet can be stably wound with a low tension, and the operator does not have to correct it due to the collapse of the winding.

[Brief description of drawings]

FIG. 1 is an explanatory view of a winding device showing a first embodiment of the present invention.

FIG. 2 is an explanatory view of a winding device showing a second embodiment of the present invention.

FIG. 3 is a perspective view of a winding core.

FIG. 4 is a front view of a winding core in a state where a multi-row ceramic sheet is wound.

FIG. 5 is an explanatory view of a conventional winding device that winds one ceramic sheet.

FIG. 6 is a perspective view of a winding device for winding a conventional multi-row ceramic sheet.

FIG. 7 is an enlarged perspective view of a winding core in a state in which a conventional multi-row ceramic sheet is wound.

[Explanation of symbols]

 10 ... Winding device 12 ... Feed roll 14 ... Winding core 16 ... Motor 18 ... Control device 20 ... Distance sensor 22 ... Partition wall 24 ... Winding part S ... Ceramic Sheet T ... Tape section

Claims (2)

[Claims] 1. A device for winding one sheet-shaped ceramic sheet, comprising: a feeder for guiding the ceramic sheet; and a winding core for winding the ceramic sheet. , A motor that rotates the take-up core, a sensor that measures the drooping distance of the ceramic sheet that hangs between the field roll and the take-up core, and a drooping distance that depends on the signal from the sensor. A winding device for a ceramic sheet, which comprises a control means for feedback controlling the rotation speed of the motor so that the rotation speed is always constant. 2. A device for winding a comb-shaped multi-row ceramic sheet, comprising a feeder for guiding the multi-row ceramic sheet and partition walls at required intervals. A winding core of a multi-row ceramic sheet, a motor for rotating the winding core, and after rotating the motor in the winding direction, it is rotated at a constant angle in the opposite direction to the winding direction. A winding device for a ceramic sheet, comprising: a control unit for rotating the winding member in the winding direction again.