JP2006214967A - Apparatus for measuring quantity of peel charge in carrier tape - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a measurement apparatus and a method for measuring the quantity of charge generated, when a carrier tape is peeled from a cover tape. <P>SOLUTION: The measurement apparatus has a metal plate 6 fixed to the carrier tape 5 by using a double-sided adhesive tape 7 having the conductivity on both sides, a coulombmeter 12 connected to the metal plate 6 by a conductive wire 8 and a switch 9 and measuring the quantity of charge, or a coulombmeter 27 connected to the conductive gripping jig 20 for gripping the cover tape 1 at one end by a conductive wire 23 and a switch 24 and measuring the quantity of charge, and sequentially measures the quantity of charge, respectively generated in a bottom tape 4 and the cover tape 1, when the cover tape 1 is peeled from the carrier tape 5. The method measures the quantity of charge, respectively generated in the bottom tape 4 by coulombmeters 12, 27 and the cover tape 1 using the measuring apparatus. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

The present invention relates to a measuring apparatus and method for measuring the amount of charge generated on a bottom tape and the amount of each charge generated on a cover tape when the cover tape is peeled from the carrier tape. The bottom tape is a tape in which concave portions called pocket portions are arranged at regular intervals on a long sheet having an arbitrary width as a container for transporting electronic components such as ICs and LEDs. Electronic parts are housed in pockets and covered with an adhesive film called a cover tape to form a carrier tape. In general, the carrier tape is stored and transported while being wound around a reel. The electronic component is removed from the cover tape and taken out of the pocket portion for use.
This measuring apparatus and method can suitably measure the charge amounts of the bottom tape and the cover tape, which are generated when the cover tape is peeled from the carrier tape.

  It is well known that a phenomenon called peeling charging occurs when the cover tape is peeled from the bottom tape. When mounting electronic components, the peeling charge generated by the bottom tape or the cover tape itself may cause problems such as misalignment of the electronic components in the bottom tape and mounting defects due to adhesion to the peeled cover tape. Therefore, it has become necessary to examine the charge amount due to peeling charging.

  In FIG. 3, in order to measure the degree of charge generated when the cover tape 1 is peeled from the carrier tape 5, the charged voltage is applied to the bottom tape 4 and the cover tape 1 by peeling the cover tape 1 from the carrier tape 5. It is common to use a charged voltage measuring device 2 that measures the above.

  When measuring using this measuring device, there is a drawback that the charged voltage varies depending on the distance between the measuring device and the bottom tape 4 or the cover tape 1 as the object to be measured. Since this is measured by the method of measuring the induced current in principle, it is inevitable that the charged voltage measured changes as the distance to the object to be measured changes. As can be seen from the equation Q = CV, where V is the charged voltage of the object to be measured, C is the capacitance of the object to be measured, and Q is the charge amount of the object to be measured. There is a problem that the amount of charge that the object to be measured is actually charged varies depending on the electrostatic capacity. Further, when the object to be measured is insulative, the capacitance C of the object to be measured changes if there is a conductor in the vicinity of the object. Therefore, even if the charge amount Q of the object to be measured is the same, There is a problem that the charging voltage V of the object to be measured varies depending on the distance between the objects to be measured. Furthermore, the measurable range is narrow, and there is a problem that the amount of peel charge generated in the entire object to be measured cannot be measured quantitatively. In addition, there is a problem that it is impossible to know in what profile the amount of charge to be peeled off during peeling of the object to be measured changes.

  In order to measure the degree of charging that occurs when the cover tape 1 is peeled off from the carrier tape 5, the cover tape 1 is peeled off from the carrier tape 5, and the bottom tape 4 and the cover tape 1 are put into a Faraday cup. There is a method for measuring the charge amount. However, when measuring the amount of charged charges by this method, the bottom tape 4 and the cover tape 1 are gripped and peeled off using insulating tweezers and the like, and each of the bottom tape 4 and the cover tape 1 is put into the Faraday cup. Therefore, the measured charge amount is a value obtained by adding the charge generated by the peeling of the bottom tape 4 or the cover tape 1 and the insulating tweezers, and the cover tape 1 is peeled off from the carrier tape 5. It is hard to say that the charge generated during the measurement is accurately measured.

As a method for directly measuring the peel charge amount, a method for evaluating the peel charge amount when peeling an adhesive film attached to an object has been proposed (see Patent Documents 1 and 2). However, these patents are limited to measuring only the amount of charge generated on one adherend among the charges generated upon peeling. In these patents, it was not known in the measurement of the peeling charge amount of the carrier tape.
JP 2002-365323 A JP 2004-61162 A

  In the present invention, the bottom tape 4 and the cover tape 1 are not affected by the distance, the capacitance of the bottom tape 4 and the cover tape 1 which are measured objects, or the influence of peeling charging from the insulating tweezers. Providing a measuring device capable of measuring the amount of peel charge generated in each case individually and simultaneously, and measuring the profile of the peel charge amount generated while peeling the cover tape 1 from the carrier tape 5 It is.

  The present invention is an apparatus and method for measuring the amount of charge peeled when the cover tape 1 is peeled from the carrier tape 5, and further measures the amount of peel charge generated when the cover tape 1 is peeled from the carrier tape 5 sequentially. A measuring apparatus and a method thereof characterized by being capable of being performed.

  FIG. 1 and FIG. 2 show an example of a peeling charge amount measuring apparatus according to the present invention. The bottom tape 4 in the carrier tape 5 has conductivity on both sides, and is fixed to the metal plate 6 by a double-sided adhesive tape 7 that can be energized between both surfaces. As a result, when the bottom tape 4 has conductivity, the charge generated on the bottom tape 4 due to peeling can be directly measured.

  The bottom tape 4 is not particularly limited in its material, presence or absence of conductivity, and shape. As the material, plastics such as polystyrene, polycarbonate, polyethylene terephthalate, and polypropylene can be suitably measured. It is also possible to measure plastics mixed with conductive materials such as carbon black, and those coated with antistatic agents or conductive paints on the surface. However, when the non-conductive bottom tape 4 is used, if the distance between the peeled surface of the cover tape 1 and the metal plate 6 is large, it is difficult in principle to measure all the charge amount generated on the peeled surface. The pocket depth is preferably 5 mm or less, but it is not impossible to measure.

  The metal plate 6 may be anything as long as it is a metal plate. However, in consideration of long-term use, a metal of a material that does not generate rust is preferable, and a stainless plate or the like is preferably used. The metal plate 6 preferably has an area larger than that of the bottom tape 4. This is because when the bottom tape 4 is insulative, all the lines of electric force generated by the peeling electrification on the side of the bottom tape 4 in contact with the metal plate 6 are captured to increase measurement accuracy.

  A metal wire 6 and a measurement probe 11 of a coulomb meter 12 which is a charge amount measuring device are connected by a conductive wire 8. A coulomb meter is a measuring device based on the principle that the detected charge is temporarily stored in a capacitor and the amount of stored charge is measured. Commercially available products can be used as they are.

  Further, the metal plate 6 can be connected to the ground via the switch 9 by the conducting wires 8 and 10. After fixing the carrier tape 5 to the metal plate 6 using the double-sided adhesive tape 7 having conductivity on both sides, the charged charge generated when the carrier tape 5 is attached is removed by connecting the switch 9 to the ground. I can do it. The lead wire 8 and the switch 9 can connect the metal plate 6 and the measurement probe 11 of the coulomb meter 12 which is a charge amount measuring device. The coulomb meter 11 is always connected to the ground by conducting wires 13 and 15. The metal plate 6 is fixed to a metal measurement base plate 19 without an electrical connection through an insulator 13. The measurement base plate is grounded by a conducting wire 18. The insulator 13 may be anything as long as it can electrically insulate the metal plate 6 and is not easily charged. For example, ceramics or glass can be used, and ceramics is preferable.

  Further, one end of the cover tape 1 is fixed by a conductive pinching jig 20, and the pinching jig 20 is attached with a string 21 for pulling and peeling the cover tape 1, and at the same time, a coulomb meter 27. The conducting wire 23 connected to the is attached. At this time, in order to prevent the exfoliation charge from flowing out through the cord 21, it is essential that the cord 21 is insulative.

  The material of the cover tape 1 is not particularly limited. As the material, it is possible to suitably measure polystyrene, ethylene vinyl acetate resin, acrylic resin, or the like. It is possible to suitably measure plastics in which conductive materials such as conductive tin oxide, titanium oxide, and conductive zinc oxide are mixed, and those in which an antistatic agent or conductive paint is applied to the surface. However, when the cover tape 1 is insulative, in order to measure the charge generated on the peeled surface of the cover tape 1 due to the peeling from the carrier tape 5, the cover tape 1 on the surface opposite to the bottom tape 4 of the cover tape 1 is used. An adhesive tape 31 having the same size as that of the adhesive tape 31 is attached, and a conductive portion of the adhesive tape 31 and a coulomb meter 27 for measuring the charge amount need to be connected by a conductor 23. As another method, it is necessary to apply a conductive material to the surface of the cover tape 1 opposite to the bottom tape 4, and to connect the coated conductive material and a coulomb meter 27 for measuring the charge amount by the conductive wire 23. There is.

  The pinching jig 20 can be connected to the ground via the switch 24 by the conducting wires 23 and 25. After the cover tape 1 is attached to the jig 20, the charged charge generated when the cover tape 1 is attached can be removed by connecting the switch 24 to the ground. The conductive jig 23 and the switch 24 can be connected to the sandwiching jig 20 having conductivity and the measurement probe 26 of the coulomb meter 27 which is a charge amount measuring device. The coulomb meter 27 is always connected to the ground by conducting wires 28 and 30. The conductive clamping jig 20 should not touch the surrounding objects so that it does not have an electrical connection and does not cause frictional charging due to contact with an object other than the cover tape 1. There is.

  When the cover tape 1 is peeled from the carrier tape 5 fixed by the double-sided pressure-sensitive adhesive tape 7 having conductivity on both sides, charges generated by the peeling are generated on the bottom tape 4 and the cover tape 1. At this time, if the bottom tape 4 is conductive, the peeling charge of the bottom tape 4 is transmitted to the measurement probe 11 of the coulomb meter 12 through the metal plate 6, the conductive wire 8 and the switch 9, and the peeling charge at that time. The amount of charge is displayed on the coulomb meter 12. When the bottom tape 4 is not conductive, the metal plate 6 is charged with the opposite polarity to the charged charge of the bottom tape 4 and at the same time has the same polarity as the charge generated on the bottom tape 4. It is transmitted to the measurement probe 11 of the coulomb meter 12 through the lead wire 8 and the switch 9, and is displayed on the coulomb meter 12 as the amount of the peeled charge at that time.

  By using the metal plate 6 and the double-sided adhesive tape 7 having conductivity on both sides, it is possible to capture the charge generated in the bottom tape 4 due to peeling charging as described above. Charge amount can be measured.

  When the cover tape 1 has conductivity, the peeling charge of the cover tape 1 passes through the conductive sandwich jig 20, the conductive wire 23, and the switch 24. It is transmitted to the measurement probe 26 of the coulomb meter 27, and is displayed on the coulomb meter 27 as the amount of peeled charge at that time. When the cover tape 1 does not have conductivity, an adhesive tape 31 having the same shape as that of the cover tape 1 is pasted on the surface opposite to the bottom tape 4 of the cover tape 1, and the conductive portion of the adhesive tape and the charge amount The measuring probe 26 of the coulomb meter 27 for measuring the resistance is connected by the conductive wire 23 and the switch 24, or the conductive material is applied to the surface opposite to the bottom tape 4 of the cover tape 1, and the applied conductive material. By connecting the measurement probe 26 of the coulomb meter 27 for measuring the charge amount with the conductive wire 23 and the switch 24, the cover tape 1 is charged on the conductive surface of the adhesive tape 31 or the conductive material coating surface. At the same time, a charge having the opposite polarity to the charge is generated, and at the same time, a charge having the same polarity as the charge generated on the cover tape 1 is transferred to the conductor 23 and the switch. It is transmitted to the measuring probe 26 of the Coulomb meter 27 through 24 is displayed on the coulomb meter 27 as a release charge amount at that time.

The coulomb meter 12 is connected to the chart recorder 14 by a conducting wire 13 and is always connected to the ground by a conducting wire 15 so that the profile of the charge amount of the bottom tape 4 when the cover tape 1 is peeled can be recorded sequentially. In addition, the coulomb meter 27 is connected to the chart recorder 29 by a conductive wire 28 and is always connected to the ground from the conductive wire 30.
The profile of the charge amount of the cover tape 1 at the time of peeling can be recorded sequentially. The metal plate 6 is placed on the insulator 13. The insulator is a non-conductive material, and examples thereof include wood and ceramic, but are not limited thereto. The conductive clamping jig 20 is in a floating state and is not touched by anything other than the cover tape 1, the conductive wire 23, and the insulating string 21.

  It is preferable to shield the measuring device from the surrounding electrical influence with a shield 16 made of a conductive material connected to the ground by a conducting wire 17 on the metal plate 6. The conductive material is a conductive material, and for example, a metal plate or a metal plate having a hole that does not affect the measurement can be used, but is not limited thereto. Of the measuring devices, products using resin such as the above-described coulomb meters 12 and 27, measuring probes 11 and 26, and switches 9 and 24 are preferably placed outside the shield 16, and unavoidably placed inside the shield 16. Is preferably covered with a grounded conductive material.

  When the cover tape 1 is peeled from the carrier tape 5 in the shield 16 to measure the peel charge amount, the cover tape 1 is held with a sandwiching jig 20 of a conductive material such as a clip, and the sandwiching jig is held. This is carried out by pulling the insulating string 21 connected to 20. The conductive material is a conductive material, and for example, a metal can be used, but is not limited thereto. The insulating string 21 may be a string 21 made of cotton, for example, but is not limited thereto. The insulating string 21 connected to the conductive pinching jig 20 does not need to be in a string shape, and any means can be used as long as the cover tape 1 can be peeled from the shield 16 from the carrier tape 5 in the shield 16. It is not limited.

  Before fixing the carrier tape 5 to the metal plate 6 by using the double-sided adhesive tape 7 having conductivity on both sides, it is possible to confirm that the charged voltage is 0 V by previously removing electricity using an ionizer or the like. desirable. At this time, in order to prevent the electric charge from flowing into the carrier tape 5, it is desirable to remove electricity while holding it with a tweezer made of ceramics or glass that can be electrically insulated and hardly charged. Furthermore, it is desirable to fix the carrier tape 5 to the metal plate 6, peel off one end of the cover tape 1, and pinch it with the pinching jig 20, and then remove the charge again using an ionizer or the like. Even if this operation is not performed, it is possible to measure the peel charge amount using this measuring apparatus, but it is desirable to perform this operation when the accuracy of the measurement result is required.

  By using the measuring apparatus of the present invention, unlike the apparatus for measuring the charged voltage conventionally used, the bottom tape and the cover tape are not affected by the influence of the distance and the capacitance of the bottom tape and the cover tape. It is possible to measure the amount of peel charge generated at each time, and to measure the profile of the peel charge amount generated while peeling the cover tape. As a result, when mounting electronic components, the peeling charge generated by the bottom tape or the cover tape itself may cause problems such as misalignment of the electronic components in the bottom tape and adhesion to the peeled cover tape. A measuring apparatus capable of measuring the amount of charge is provided.

The present invention will be specifically described below with reference to examples.
Example 1
As bottom tape 4, trade name “Clearen CST-100V” (insulation, tape width 8 mm, pocket depth 1.5 mm) manufactured by Denki Kagaku Kogyo Co., Ltd., as cover tape 1, “Sumilite CSL-Z7302” manufactured by Sumitomo Bakelite Co., Ltd. The bottom tape 4 and the cover tape 1 were heat-sealed using a taping machine (systemation ST-60) to obtain a carrier tape 5. The carrier tape 5 was cut to a length of 100 mm to obtain a sample for measuring the peeled charge amount, and an ionizer was sprayed in a state where the carrier tape 5 was sandwiched between insulating tweezers to remove the charge from the carrier tape 5.
Using the peeling charge amount measuring apparatus having the structure shown in FIG. 1, using the double-sided adhesive tape 7 having conductivity on both sides (product name: WMFT791, size: width 10 mm, length 125 mm, manufactured by Teraoka Seisakusho), the carrier tape described above 5 sample bottom tape 4 pocket bottom surface and 125 mm x 50 mm size metal plate 6 (JIS G 4305 stainless steel thickness is 1.5 mm, surface condition is 280 R water-resistant abrasive paper described in JIS R 6253 Then, an indicator was lightly attached with abrasive paper in the width direction of the test plate, and the indicator was fixed uniformly over the entire length until the indicator disappeared. At this time, all the pockets of the bottom tape 4 were fixed by the double-sided adhesive tape.
Further, the carrier tape 5 and the double-sided conductive double-sided pressure-sensitive adhesive tape 7 were adhered to each other by rolling the upper surface of the cover tape 1 of the carrier tape 5 with a roller conforming to JIS Z-0237.

  Next, one end of the cover tape 1 was peeled off by 10 mm using insulating tweezers, and the cover tape 1 was gripped with a conductive pinching jig 20. The ionizer was sprayed on the carrier tape 5 to remove the charge from the carrier tape 5, and the switches 9 and 24 were switched to connect the metal plate 6 and the conductive clamping jig 20 to the ground. Thereafter, the switches 9 and 24 are switched to disconnect the metal plate 6 and the conductive clamping jig 20 from the ground, connect the metal plate 6 and the measuring probe 11, and connect the conductive clamping jig 20 and the measuring probe 26. Connected. By operating the automatic peeling device 22 and pulling the insulating string 21 at a speed of 3000 mm / min, the cover tape 1 is peeled off from the carrier tape 5 and the peeling charge amount generated on the bottom tape 4 and the cover tape 1 is measured. did. As the coulomb meters 12 and 27, NK-1001 manufactured by Kasuga Electric Co., Ltd. was used.

(Example 2)
Conductive bottom tape 4 using a peeling charge measuring device having the structure shown in FIG. 2 (a molded product of a conductive sheet obtained by kneading carbon black into PS manufactured by Denki Kagaku Kogyo Co., Ltd., tape width 8 mm, pocket depth 1.5 mm) And insulating cover tape 1 (DENKA THERMO FILM ALS-S, manufactured by Denki Kagaku Kogyo Co., Ltd.), heat-bonding the bottom tape 4 and the cover tape 1 using a taping machine (Systemation ST-60) Tape 5 was obtained. The carrier tape 5 was cut to a length of 100 mm, and an ionizer was sprayed in a state where the carrier tape 5 was sandwiched between insulating tweezers, and the carrier tape 5 was discharged. Thereafter, a conductive adhesive tape 31 (Nitto Denko product name: Nitofoil) was attached to the surface of the cover tape 1 opposite to the bottom tape 4 according to the size of the cover tape 1. Double-sided adhesive tape 7 having conductivity on both sides (product name: WMFT791, manufactured by Teraoka Seisakusho, size: width 10 mm, length 125 mm) and the bottom surface of the bottom tape 4 of the carrier tape 5 and a metal plate 6 of 125 mm × 50 mm size. (Thickness made of stainless steel as described in JIS G 4305 is 1.5 mm, and the surface condition is lightly polished paper of No. 280 as described in JIS R 6253. Until it disappeared, and was uniformly polished in the length direction over the entire length). At this time, all the pockets of the bottom tape 4 were fixed by the double-sided adhesive tape.

  Further, the carrier tape 5 and the double-sided conductive double-sided pressure-sensitive adhesive tape 7 were adhered to each other by rolling the upper surface of the cover tape 1 of the carrier tape 5 with a roller conforming to JIS Z-0237. One end of the cover tape 1 was peeled 10 mm long using insulating tweezers, and the cover tape 1 was gripped with a conductive pinching jig 20. The ionizer was sprayed on the carrier tape 5 to remove the charge from the carrier tape 5, and the switches 9 and 24 were switched to connect the metal plate 6 and the conductive clamping jig 20 to the ground. Thereafter, the switches 9 and 24 are switched to disconnect the metal plate 6 and the conductive clamping jig 20 from the ground, connect the metal plate 6 and the measuring probe 11, and connect the conductive clamping jig 20 and the measuring probe 26. Connected. The automatic peeling device 22 is operated and 3000 mm / min. The cover tape 1 was peeled from the carrier tape 5 by pulling the insulative string 21 at a speed of 5 mm, and the peel charge amount generated on the bottom tape 4 and the cover tape 1 was measured. As the coulomb meters 12 and 27, NK-1001 manufactured by Kasuga Electric Co., Ltd. was used.

Schematic of an example of the peeling charge amount measuring apparatus of the present invention. Schematic of another example of the peeling charge amount measuring device of the present invention. Schematic of the conventional charged voltage measuring apparatus.

Explanation of symbols

1, cover tape 2, voltage measuring device 3, observation window 4, bottom tape 5, carrier tape 6, metal plate 7, double-sided conductive, double-sided adhesive tape 8, conducting wire 9, switch 10, conducting wire 11, measuring probe 12, coulomb Meter 13, Conductor 14, Chart recorder 15, Conductor 16, Shield 17, Conductor 18, Conductor 19, Metal measuring base plate 20, Switch 21, Clamping jig 22, Automatic peeling device 23, Conductor 24, Switch 25, Conductor 26 , Measuring probe 27, coulomb meter 28, conducting wire 29, chart recorder 30, conducting wire 31, conductive adhesive tape

Claims (10)

  A device for measuring the amount of peeled charge that can measure the amount of charge generated on the bottom tape and cover tape when the cover tape is peeled off from the carrier tape.   A peeling charge amount measuring device capable of sequentially measuring each charge amount generated on a bottom tape and a cover tape when the cover tape is peeled from the carrier tape.   Using conductive double-sided adhesive tape that is conductive on both sides and adhesive on both sides, the bottom of the carrier tape and the metal plate are fixed, and the amount of charge connected by the metal plate and the conductor is measured. 3. The measuring apparatus according to claim 1, further comprising a coulomb meter, wherein the metal plate is on an insulator.   The measuring device according to claim 3, wherein the area of the metal plate is larger than that of the carrier tape.   3. The measuring apparatus according to claim 1, further comprising a coulomb meter for measuring a charge amount that is connected to the metal sandwich jig by electrical conduction by sandwiching one end of the cover tape with an ungrounded metal sandwich jig. .   An adhesive tape with the same shape as the cover tape is attached to the surface opposite to the bottom tape of the cover tape, and a coulomb meter is provided to measure the amount of charge connected by the conductive part of the adhesive tape and the conductive wire. The measuring apparatus according to claim 1 or 2.   2. A coulomb meter for coating a conductive substance on a surface opposite to the bottom tape of the cover tape and measuring a charge amount connected by the coated conductive substance and the conductive wire. Or the measuring device of 2.   The measuring apparatus according to any one of claims 1 to 7, wherein one end of the cover tape is sandwiched with a metal sandwich jig that is not grounded, and the jig is pulled at a constant speed to peel off the cover tape. .   9. The measuring apparatus according to claim 2, wherein the measuring apparatus is covered with a conductive material that is grounded.   Using the measuring device according to any one of claims 1 to 9, the charge amount of each of the carrier tape and the cover tape generated when the cover tape is peeled from the carrier tape placed on a metal plate is measured. how to.

Images