KR20050048466A - Exposure device for printed circuit board corresponding to the constructing of the circuit board - Google Patents

Abstract

The purpose of the present invention is to provide an exposure apparatus for a printed wiring board which suppresses the positional shift of the pattern due to the increase and decrease of the substrate and to manufacture an efficient and high-density printed wiring board. It is made in the form of a continuous film, wound around the photomask rollers 10 and 10, and is configured to be positioned on the substrate 50 on the stage 4 by rollers 11 and 11.

The photomask film 1 is drawn with a standard photomask 15 having an exposure pattern created in a design value dimension, and a plurality of photomasks 15 'having patterns of different sizes drawn at a small size with respect to the standard pattern.

The controller 3 calculates the amount of expansion and contraction by the image signal of the substrate mark 51 from the CCD camera 2, and from the result of this calculation, the most suitable dimension of the photomask film 1 is obtained. The photomask roller 10 is drive-controlled so that the photomask 15 having the exposure pattern is positioned on the substrate 50 to control rotation, stoppage, and the like.

Description

Exposure device for printed circuit board corresponding to stretching of substrate {Exposure device for printed circuit board corresponding to the constructing of the circuit board}

The present invention relates to an exposure apparatus for a printed wiring board corresponding to stretching and shrinking of the substrate.

Recently, due to the light weight, thinning, shortening, and high functionality of electronic products, printed wiring boards are becoming more and more highly precise and high density. A photolithography method is used for manufacturing a printed wiring board, in which a predetermined pattern is photographed and printed on a surface of a substrate coated with a photosensitive material such as a photoresist, and a pattern is formed on the substrate by an etching process. It is becoming.

However, since the printed wiring board is made of a plastic material, when the material is passed through the manufacturing process, the substrate may be stretched or contracted due to the impact of chemicals or heat.

When a pattern, such as wiring and a soldering resist, is drawn on a printed wiring board by a photolithography method, it is normally manufactured by several photolithography.

 In a close contact method where a photomask and a printed wiring board are generally used to be exposed, when a high precision and high density printed wiring board is manufactured, the expansion and contraction of the substrate may be adversely affected and the pattern may be placed at an appropriate position. In the case of a multi-layered board, there is a problem that the position of the slits or the opening of the solder resist are shifted in order to maintain the bonding between the layers.

Therefore, in order to prevent this, a design having a margin in the pattern must be performed, and as a result, it has a bad effect on high precision and high density.

In order to solve such a problem, the following solution has been conventionally adopted.

<Prior Art 1>

The amount of expansion or contraction of printed wiring boards is measured in a separate process and divided into groups. A method of fixing an optimal photomask to an exposure apparatus for every group of several types of photomasks having different dimensions in advance and inserting a printed wiring board into the exposure apparatus for each group.

<Prior Art 2>

A method of reducing the positional deviation of a pattern by providing a split shutter function in an exposure apparatus and dividing the exposure with a plurality of error words without performing collective exposure over the entire area.

<Prior Art 3>

In a method using a projection exposure apparatus, the magnification of the mask can be corrected by moving the lens up and down, so that the mask is corrected according to the amount of expansion and contraction of the printed wiring board and then exposed.

The conventional solution described above is described in Japanese Patent Laid-Open No. 2000-250227.

However, the above conventional techniques have the following problems, respectively.

Prior art 1 has a problem in the work to measure the amount of stretching before the input of the printed wiring board to the exposure apparatus, and to classify by group.

The prior art 2 does not collectively cover the entire area at the time of exposure, but divides and exposes the light several times, so that the time required for exposure becomes long and the processing time becomes long.

In the prior art 3, the unit cost is high and the adhesion method requires several exposure apparatuses in order to obtain an equivalent processing time, and thus the apparatus introduction cost is about 10 times higher than that of the adhesion method.

The present invention aims to solve such problems of the prior art.

In order to achieve the above object, the present invention provides an exposure apparatus for a printed wiring board, comprising: a plurality of photomasks having exposed patterns of different sizes drawn corresponding to the stretching of the printed wiring board, and the stretching of the printed wiring board before exposure. A detection means for detecting a state, a means for selecting the most suitable photomask among a plurality of photomasks from the stretched state of the pre-exposure printed wiring board by the detection means, and a printed wiring board using a photomask provided in the exposure part. And exposure means for exposing the light.

In the above-described configuration, the stretched state of the printed wiring board is detected before exposure, and a photomask suitable for this stretched state is selected and installed in the exposure unit, so that the exposure can be performed efficiently and with high accuracy and high density.

The above-mentioned plurality of photomasks can be used as a continuous film-like photomask, and the photomask in the form of a film can be moved so that the selected photomask can be installed in the exposure unit. You can do it.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described in detail according to drawing.

1, the exposure apparatus for printed wiring boards has the injection | throwing-in part A and the exposure part B. As shown in FIG. The substrate 50 subjected to the photoresist in the previous step is placed on the stage 4 of the exposure part B via the injection part A, whereby the substrate 50 can be exposed. The stage 4 is movable in the XYZ and θ directions, and is configured to be able to align the placed substrate mark 51 with the photomask film 1.

The conveyance roller 20 is provided in the input part A, and the board | substrate 50 which moves on it can read the board | substrate marks 51 and 51 by two or four CCD cameras 2. .

The substrate mark 51 is provided at a predetermined position on the substrate 50 in advance, and the amount of expansion and contraction of the substrate 50 can be calculated by detecting the positional relationship between the substrate marks 51 and 51.

The image of the substrate mark 51 from the CCD camera 2 is sent to the control apparatus 3, and it is comprised so that a stretch amount can be calculated here. In addition, the substrate mark 51 may use a alignment mark of the photomask.

The photomask film 1 is comprised in the form of a continuous film, and wound around the photomask rollers 10 and 10. Thus, the rollers 11 and 11 are configured to be positioned on the substrate 50 on the stage 4.

The photomask film 1 is provided with several photomasks 15. In other words, a number of standard photomasks 15 having an exposure pattern created with design value dimensions and photomasks 15 'drawn with patterns having different sizes with different dimensions are drawn. For example, it is preferable that the micro-dimension method prepares a predetermined number of reduced and enlarged patterns at a constant ratio of about 10 microns in the XY direction with respect to the exposure size 500 mm. In addition, when it is possible to predict in advance that the stretching ratio in the XY direction is not constant due to the stretching tendency of the substrate material or the drawn pattern, it is more preferable to prepare a photomask having a size corresponding to each stretching of the XY.

The controller 3 drives the photomask roller 10 to drive and control rotation, stop, and the like, and allows the photomask 15 having a mask pattern having a predetermined dimension to be positioned on the substrate 50.

As described above, the control device 3 calculates the amount of expansion and contraction based on the image signal of the substrate mark 51 in the CCD camera 2 and, based on this calculation result, the exposure pattern having the most suitable dimension among the photomask films 1 is obtained. It is possible to position the photomask 15 having on the substrate 50.

The substrate 50 is placed on the stage 4, and when the photomask 15 best suited for the substrate 50 is positioned on the substrate 50, the substrate mark 51 and the photomask 15 are positioned in advance. The decision marks (not shown) are read by the CCD camera 43, respectively, and the stage 4 is moved in the XY and θ directions so that the substrate 50 can be positioned with the photomask 15.

Thus, the stage 4 is raised together with the photomask film 1 and the packing 41 on four sides so that the stage 4 can be raised in the Z direction so as to surround the glass plate 40 and the circumference of the glass plate 40 as shown in FIG. 2. ). At the same time, the photomask 15 and the substrate 50 are brought into close contact with each other by changing from the suction hole 42, and after the CCD camera 43 withdraws from the exposure area, ultraviolet light is emitted from the light source 5 for exposure. .

After the exposure ends, the substrate 50 is discharged. Typically, the substrate is inverted by an inverter to expose the backside. Instead of the glass plate 40, a plastic product capable of transmitting ultraviolet rays such as acrylic may also be used.

In the above-described embodiment, the amount of expansion and contraction of the substrate 50 is calculated in the injection portion A, and the photomask 15 is used for exposure according to the amount of expansion and contraction, so that the exposure can be performed efficiently and with high accuracy. .

According to the exposure apparatus for a printed wiring board of the present invention, the amount of expansion is measured in advance, and the duct time is made almost the same as that of a conventional close-type exposure apparatus, without requiring extra labor and time by dividing into groups. In terms of the same price, the non-slip of the pattern due to the expansion and contraction of the substrate can be minimized to enable the production of high efficiency and to efficiently manufacture the high precision and high density printed wiring board.

1 is a schematic view showing one embodiment of the present invention.

2 is an explanatory diagram showing an operation of one embodiment of the present invention.

* Explanation of symbols for the main parts of the drawings

    1 photomask film 2 CCD camera

    3: controller 4: stage

    5: light source 10: photomask roller

    15 photomask 20 bounce roller

    40: glass plate 41: packing

    42: suction hole 43: CCD camera

    50: substrate 51: substrate mark

Claims (6)

A plurality of photomasks having exposed patterns having different sizes drawn in response to expansion and contraction of the printed wiring board; Detecting means for detecting a stretch state of the printed wiring board before exposure;      Means for selecting the most optimal photomask among the plurality of photomasks in the stretched state of the printed wiring board before exposure by the detection means; Means for attaching the selected photomask to an exposure portion;      An exposure apparatus for a printed wiring board, further comprising exposure means for exposing the printed wiring board to an exposure using a photomask provided in the exposure section. The exposure apparatus for a printed wiring board according to claim 1, wherein the plurality of photomasks is a continuous film type photomask, and the installation means moves the film type photomask to install a selected photomask. The photomask according to claim 1, wherein the plurality of photomasks is a continuous film type photomask, and the installation means is constituted by a pair of photomask rollers for winding or releasing the film type photomask. An exposure apparatus for a printed wiring board, characterized in that the driving of the mask roller is suppressed to move the photomask in the form of a film, and the photomask selected by the selection means is provided in the exposure unit. The exposure apparatus for a printed wiring board according to claim 1, wherein the plurality of photomasks comprises a standard photomask having a standard pattern created by a design value dimension and another photomask having a pattern drawn in a different dimension from the standard pattern. . The exposure apparatus for a printed wiring board according to claim 1, wherein the detecting means for detecting the stretched state of the printed wiring board detects the stretch amount of the printed wiring board. The printed wiring board according to claim 1, wherein the detecting means for detecting the stretched state of the printed wiring board is provided in an input portion in front of the exposed portion, and detects the stretched state of the printed wiring board fed to the exposed portion. Exposure apparatus.