JPS63299191A - Thick film circuit lithography apparatus - Google Patents

Abstract

PURPOSE:To enhance an accuracy by measuring a lithography beam width with paste discharged from a nozzle, and feeding back a signal of its beam width to control the sections of a lithography apparatus. CONSTITUTION:When a target beam width to be formed on a substrate 18 with paste 19 is input to a controller 21, the height of a nozzle 3, the temperature, applying pressure in a syringe 1 and the moving speed of the nozzle 3 are set to predetermined initial conditions. When the discharge of the paste 19 on the substrate 18 is started, a lithography beam width is simultaneously sensed by a visual sensor 17, and output to an image processor 20. The processor 20 processes it, measures the beam width, and outputs it to the controller 21. The controller 21 compares the beam width input from the processor 20 with a target beam width, and forms it on the substrate 18 under the same conditions if the difference between both falls within an allowable range. If the difference is out of the allowable range, data is read out from data base 22 contained in the controller 21 to control a pressure controller 24 and a controller 26 of a pulse motor 14 by the controller 21 on the basis of the data. Thus, a lithography having high accuracy and high reliability can be obtained.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a thick film circuit drawing device, and is particularly suitable for highly accurate thick film circuit drawing by stabilizing the discharge width of paste for forming a circuit. The present invention relates to a thick film circuit drawing apparatus.

[Conventional technology]

Thick film circuits used in radio receivers, television receivers, calculators, etc. are made by forming conductive paste, resistive paste, etc. on a substrate into the desired shape using the screen printing method, and then drying and baking. It is manufactured by

In addition, in recent years, National Technical Report Vol. 51, No. 5, October 1985 (National Tech
i-cal Report Wall 1', Na5
, Oat, 1985), as a technique to reduce variation in pattern width and to simplify pattern switching in place of the screen printing method, a technique for discharging paste through a nozzle and drawing directly on the substrate was introduced [New Circuit Formation]. The technology "Resistance drawing technology" has been reported.

In addition, 1% Publication No. 127788/1988, Japanese Patent Application Publication No. 1983
JP-A-132385 and JP-A-60-220988 disclose techniques for reducing variations in resistance by using various dimensions of the tip of the nozzle and the substrate to make them constant.

[Problem that the invention seeks to solve]

However, as described above, the conventional technique of applying paste directly onto a substrate from a nozzle has the following problems.

For example, resistive paste used in thick film circuits.

Generally, ruthenium oxide based resistance materials, glass frit,
It has a very high viscosity and is composed of a resin binder, a solvent, etc. This viscosity is influenced by temperature changes, volatilization of the Jl agent, etc., and changes.

In conventional thick film circuit drawing apparatuses, paste is discharged by filling a syringe with a nozzle with the paste, applying precisely controlled air pressure, and moving the nozzle. In order to dispense the paste with even greater precision, efforts have been made to keep the syringe containing the paste at a constant temperature. When drawing with such a drawing device, the conditions of the drawing device must first be adjusted according to the paste. In other words, even if the resistor paste has the same model number, if it was manufactured at a different time,
Because the viscosity inevitably varies, it is necessary to make delicate adjustments to the drawing device's syringe temperature, air pressure, nozzle height, nozzle feed speed, etc., which are related to drawing accuracy, each time the paste is replaced. Further, even if the paste is the same, the solvent evaporates and the viscosity changes over time, so it is necessary to adjust the drawing device before drawing. Sara K also,
When used for a long time, even if the temperature of the atmosphere changes during use, the viscosity of the paste changes at the tip of the nozzle, causing variations in paste application.

In conventional drawing devices, the viscosity of the paste is controlled by open-loose.

If the atmosphere or the like changes, the effect cannot be corrected, so there is a problem in that the drawn line width varies.

The object of the present invention is to eliminate the problems of the prior art.

It is an object of the present invention to provide a thick film circuit drawing device with good precision and even higher reliability.

[Means for solving problems]

The object is to provide a syringe having a nozzle, a pressurizing means for controlling the pressure inside the syringe, a moving means for moving the syringe vertically and horizontally, and a temperature adjusting means for keeping the temperature inside the syringe constant. a visual sensor and an image processing device for measuring the drawing line width of the paste discharged from the tip of the nozzle, inputting a measured value of the drawing line width of the paste from the image processing device, and measuring the drawing line width; The value is compared with the target line width, and if there is a difference between these values, the viscosity of the paste is determined from the data in the built-in database and the parameters of the initial conditions of the drawing device, and the viscosity of the paste is determined based on the viscosity of this paste. and a control device that reads data for adjusting the drawing line width to a constant value from the database and controls each part of the drawing device.
achieved.

[Effect]

In the present invention, a visual sensor images the paste discharged from the tip of the nozzle, and the image is sent to an image processing device. This image processing device processes one image, measures the drawing line width of the paste, and sends the measured value to the control device.

The control device compares the measured value of the drawing line width sent from the image processing device with a target line width set in the control device. If there is a difference between the two values, the control device determines the viscosity of the paste based on the data in the built-in database and the parameters of the initial conditions of the drawing device. Then,
The control device reads data for adjusting the drawing line width to a constant level from the database based on the determined viscosity of the paste, and controls each part of the drawing device.

As mentioned above, highly accurate and stable drawing is achieved by measuring the drawing line width of the paste actually discharged from the nozzle and feeding back the signal of the drawing line width to control each part of the drawing device. be able to.

〔Example〕

Embodiments of the present invention will be described below with reference to the drawings.

FIG. 1 is a perspective view showing an embodiment of the present invention.

In the thick film circuit drawing apparatus of the embodiment shown in FIG. 1, a heat insulator 2 is fixed to the syringe 1 so as to surround the syringe 1 to keep the temperature constant.

A nozzle 3 is attached to the tip of the syringe 1. Further, the syringe 1 has a syringe bracket 4
The syringe bracket 4 is fixed to the upper and lower sliders 5. This vertical slider 5 is held so as to be vertically movable using a vertical guide 6 as a guide. The vertical guide 6 is fixed to the vertical bracket 7. A pulse motor 8 is fixed to the upper and lower brackets 7 via a motor bracket 9.

A ball screw 10 is fixed to the pulse motor 8. A nut 10' is screwed onto this ball screw 10, and this nut 10 is fixed to the vertical slider 5. Therefore, by driving the pulse motor 8, the syringe 1 is moved in the vertical direction.

Furthermore, left and right sliders 11 are fixed to the upper and lower brackets 7, and these left and right sliders 11 are attached to left and right guides 12.
is held so as to be movable in the left-right direction (arrow X direction) K using as a guide. The left and right guides 12 are fixed to a base 13, and a pulse motor 14 is mounted on the base 13.
is fixed.

A ball screw 15 is attached to the motor shaft of this pulse motor 14.
is fixed, and a nut 15 is attached to this ball screw 15.
are screwed together. This nut 15 is fixed to the upper and lower brackets 7. As a result, by driving the pulse motor 14, the syringe 1 can be moved from side to side in a horizontal plane.

A sensor bracket 16 is fixed to the vertical slider 5, and a visual sensor 17 such as a TV left camera or a one-dimensional image sensor is fixed to this sensor bracket 16. The visual sensor 17 is positioned so as to focus on the paste 19 discharged from the nozzle 3 onto the substrate 18 . Further, the visual sensor 17 is a highly accurate one with a resolution of several microns. The visual sensor 17 is configured to output the captured image to the LLI image processing device 20.

The image processing device 20 is configured to process the image input from the visual sensor 17, measure the drawing line width ejected from the nozzle 3, and output the measured value to the control device 21.

The control device 21 compares the measured value of the drawing line width inputted from the image processing device 20 with the target line width stored in advance in the control device 21, and if there is a difference between these values, the built-in The data in the database 22 that is currently being read is read out. The database 22 contains paste 1
9 and parameters including the height of the nozzle 6, the viscosity of the paste 19, the moving speed of the nozzle 3, and the temperature and pressure inside the syringe 1 are stored. There is. Therefore, when the difference between the actual drawn line width and the target line width is out of the allowable range, the control device 21 determines the viscosity of the paste 19 based on the data in the database 22 and the parameters of the initial conditions of the drawing device. do. Then, the control device 21 reads data from the database 22 that allows the drawn line width to be adjusted to a constant value based on the determined viscosity of the paste 19. Then, based on this data,
A control signal is sent to the controller 26 of the pulse motor 14 that controls the horizontal movement of the nozzle 3, the pressure controller 24 that controls the pressurizing force inside the syringe 1, etc., and the drawing line width of the paste 19 matches the target line width. It is configured to be controlled as follows. Further, the control device 21 is configured to also control a temperature controller 23 and a controller 25.

One of the controllers 25 and 26 controls the pulse motor 8 that moves the nozzle 3 in the vertical direction through the driver z7.

The other controller 26 controls the moving speed of the nozzle 3 by controlling the pulse motor 14 that moves the nozzle 3 in the left-right direction through a driver 28.

The thick film circuit drawing apparatus of the above embodiment is operated and operated as follows.

First, when the target line width to be drawn on the substrate 18 with the paste 19 is input to the control device 21, the height of the nozzle 3, the syringe 1
Temperature inside, pressure inside syringe 1.

The moving speed of the nozzle 3 is set to a certain initial condition. In this condition, the paste 19 is applied to the substrate 1 from the nozzle 3.
8 and apply.

Simultaneously with the start of discharging the paste 19 onto the substrate 18,
The visual sensor 17 images the drawing line width of the paste 19 and outputs the image to the image processing device 20 .

The image processing device 20 inputs an image of the actual drawn line width from the visual sensor 17, processes this, measures the drawn line width, and outputs the measured value to the control device 21.

The control device 21 compares the drawing width a inputted from the image processing device 20 with the target line width. As a result of the comparison, if the difference between the measured drawing line width and the target line width is within the allowable range, the paste 19 is discharged under the same conditions to draw on the substrate 18. As a result of the comparison, if the difference between the measured drawing line width and the target line width is outside the allowable range, control is performed as follows.

That is, from the initial conditions of the drawing device, the height of the nozzle 3, the moving speed of the nozzle 3, and the temperature inside the syringe 1.

The pressure inside the syringe 1 is known, and the paste 19
The viscosity of the paste 19 is uniquely determined by the measured value of the drawn line width. So, this viscosity.

In order to match the drawn line width of paste 19 with the target line width,
Data regarding the moving speed of the nozzle 3 and the pressurizing force inside the syringe 1 are read from the database 22 built in the control device 21, and based on the data, the control device 21 executes the following steps:
It controls the pressure controller 24 and the controller 26 of the pulse motor 14 that moves the nozzle 3 in the left-right direction.

As a result, it becomes possible to adjust the drawing line width drawn on the substrate 18 by the paste 19 discharged from the nozzle 3 to a constant value.

In addition, in this embodiment, the viscosity of the paste 19 gradually decreases due to rounding, which constantly feeds back the drawing line width signal of the paste 19 to the control device 21, and due to the temperature of the atmosphere or the volatilization of the solvent of the paste 19 due to long-time application. Even if the width of the drawing line of the paste 19 changes, each part of the drawing device is controlled accordingly so that the drawing line width of the paste 19 is constant.
It is possible to draw with high precision and a stable drawing line width.

Note that in the embodiment shown in one drawing, drawing is performed only in one direction within a plane, but by mounting the upper and lower brackets 7 of the syringe 1 on an XY table, for example, it is also possible to draw freely on a plane. It is possible.

〔Effect of the invention〕

According to the present invention described above, a syringe having a nozzle, a pressurizing means for controlling the pressure inside the syringe,
A moving means for moving the syringe vertically and horizontally, a temperature adjusting means for keeping the temperature inside the syringe constant, and a visual sensor and image sensor for measuring the width of the drawn line of the paste discharged from the tip of the nozzle. The processing device inputs the measured value of the drawn line width of the paste from the image processing device, compares the measured value of the drawn line width with the target line width, and if there is a difference between these values, the built-in The viscosity of the paste is determined from the data in the database and the parameters of the initial conditions of the drawing device, and based on the viscosity of the paste, data for adjusting the drawing line width to a constant level is read from the database, and each part of the drawing device is controlled. It is equipped with a control device to

When drawing thick film circuits, the signal of the actual drawing line width is constantly fed back and the drawing line width can be controlled to always be constant, making it possible to achieve highly accurate, powerful and reliable drawing. be.

[Brief explanation of drawings]

FIG. 1 is a perspective view showing an embodiment of the present invention. 1...Syringe 3...Nozzle 8.14...Pulse motor 17...Visual sensor 18...Substrate 19...Paste 20...Image processing device 21...Control device 22...・Database 23.24...Temperature, pressure controller 25.26・
...Pulse motor controller.

Claims (1)

[Claims] 1. A thick film circuit drawing device that discharges paste from the tip of a nozzle to draw a thick film circuit on a substrate, which includes a syringe having the nozzle, a pressure means for controlling the pressure inside the syringe, and a syringe that is moved vertically. a moving means for moving the paste in the horizontal direction; a temperature adjusting means for keeping the temperature inside the syringe constant; a visual sensor and an image processing device for measuring the width of the drawn line of the paste discharged from the tip of the nozzle; Input the measured value of the drawn line width of the paste from the image processing device, compare the measured value of the drawn line width with the target line width, and if there is a difference between these values, the data will be stored in the built-in database. a control device that determines the viscosity of the paste from the data and parameters of the initial conditions of the drawing device, reads data for adjusting the drawing line width to a constant from the database based on the viscosity of the paste, and controls each part of the drawing device; A thick film circuit drawing device comprising: