JPH06270444A - Method and device for trimming thermal head - Google Patents

Abstract

PURPOSE:To provide a trimming method and trimming device which does not increase a number of trimming processes, fulfills short time processing of trimming and realizes high speed manufacture of a thermal head. CONSTITUTION:A relay R8 is changed over to a relay R1 of a switch board 50 by a computor 10 so that in relation to a plurality of multiplexor relays 41, 42, 43, 44 selecting several bits of a heating resistor of a thermal head at the same time, respective relays are joined to the first high electric field pulse generating apparatus 21, the second high electric field pulse generating apparatus 22, an annealing pulse generating apparatus 25 and a resistance measuring apparatus 30 and the plurality of the bits are trimming-processed at the same time by one trimming device. The rate of working efficiency of each apparatus of trimming devices are improved, trimming processes are not increased, trimming processing time is reduced and speeding-up in manufacture of thermal head can be performed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for trimming a thick film type thermal recording head suitable for a high image quality printer such as a full color printer and a trimming device for performing the trimming.

[0002]

2. Description of the Related Art The outline of a thermal head (alternate lead type) will be described with reference to FIG. The thermal head is an insulating substrate 2
An individual electrode 4 made of a conductive material and a common electrode 3 are connected to each other by a heating resistor 5, and a constant voltage is applied for a certain time between the individual electrode 4 made of a conductive material and the common electrode 3. Then, Joule heat is generated in the selected bit 5a of the heating resistor 5, and the heat causes the heat-sensitive recording paper arranged in contact with the heating resistor 5 to develop color.
In these thermal heads, for example, 1728 heating resistor elements are formed per A4 size head, but not all the resistor elements have the same resistance value, and variations occur. However, if the resistance value of the heating resistor is not uniform, there will be a difference in temperature of the heating resistor when heat is generated, and when printing on thermal transfer paper, etc., uneven density will occur in the printed characters or figures. There was an inconvenience to do.

In order to prevent such uneven density, a process for equalizing the resistance value of each heating resistor is performed.
BACKGROUND ART Conventionally, pulse trimming is known as a resistance value adjusting (trimming) method for equalizing variations in resistance values of heating resistors of a thermal head. This pulse trimming utilizes the property that the resistance value of the heating resistor decreases according to the strength of the electric field when a predetermined electric field is applied within a range that does not cause resistance breakdown to the heating resistor. The value is made uniform (see, for example, Japanese Patent Laid-Open No. 61-83053), and the heating current of the resistance element is made uniform by passing a recording current through the heating resistor having a uniform resistance value. This prevents the occurrence of uneven density due to the difference in the amount of heat generated by body elements.

The structure of a conventional trimming device will be described with reference to the block diagram shown in FIG. The prober 16 is a probe 16a, 16b which contacts the pad of the electrode 4 through the connection terminal,
16c ... The multiplexer relay 14 is connected to the prober 16, and the prober 16 and the multiplexer relay 14 are controlled by the computer 11 so that the probe needles 16 a, 16 of the prober 16 are connected.
b, 16c ..., The heating resistor 5 via the individual electrode 4
Is configured to select one bit 5a of The multiplexer relay 14 is connected to the pulse generator 12 via a changeover switch 15 controlled by the computer 11.
Of the resistance measuring instrument 13 or the input terminal of the resistance measuring device 13. Then, this trimming device controls the pulse applied to the heating resistor 5 while measuring the resistance value of each resistor element by the computer 11, and lowers the resistance value to make it equal to a desired resistance value.

Next, the operation of the trimming device will be described with reference to the flowchart shown in FIG. Starting at step S ₀ , the channel is set by the multiplexer relay 14 at step S ₁ . In step S ₂ , the resistance value of the heating resistor is measured, and in step S ₃ , it is determined whether the measured value is the resistance value in the target area. If NO, the process proceeds to step S ₄ to set an applied voltage according to the resistance value by voltage calculation, and a high electric field pulse having a pulse width of 1 μsec or less is applied in step S ₅ . In step S ₆ , an annealing pulse having a pulse width of about 1 μsec is applied to stabilize the resistance value. Then, returning to step S ₂ , the resistance value of the heating resistor is measured, and in step S ₃ , it is determined whether or not the measured value is the resistance value in the target area. Proceed to step ₄ and repeat the pulse application to align the target resistance value bit by bit. If it is determined that the resistance value of the target area at step S ₃ proceeds to step S _7, and determines whether it has completed all the bits in the case of NO to the next channel set in step S _1. Then, the total bit adjustment to terminate the trimming operation in step S ₈ when it is determined to have ended.

[0006]

The above-described trimming method and trimming apparatus have a structure and flow in which each trimming process is sequentially performed. However, in the series of trimming operations, the resistance measuring device does not operate during processes other than the resistance measuring process, and similarly, the pulse generator 12 does not operate except for the pulse applying operation. Therefore, the operating rate of each device of the apparatus itself was very low, being 1/4 or less. In addition, applying an annealing pulse to improve the image quality of the thermal head and half-dot trimming are very excellent methods to reduce the variation in the resistance value of the heating resistor, but this increases the number of steps and increases the cost. There was a problem that became. Therefore, in order to simplify the man-hour,
Trimming (see Japanese Patent Laid-Open No. 1-51958) for determining an applied power value based on a calibration curve and a measured resistance value created in advance for each process or for each head, or by measuring the resistance value of the heating resistor, Trimming (Japanese Patent Application Laid-Open No. 63-59548) for determining the applied voltage by using the created resistance vs. applied voltage table has been proposed.

The present invention has been made in view of such a situation, and provides a trimming method and a device capable of performing high-speed pulse trimming by increasing the operating rate of the device without increasing the number of trimming steps. To do.

[0008]

A method of trimming a thermal head according to the present invention comprises a resistance value measuring step of simultaneously selecting several bits of a heating resistor and measuring the resistance value of each bit.
From the voltage setting step of setting the voltage applied to the heating resistor from the difference between the measured resistance value and the target resistance value, the pulse applying step of applying the pulse application of the set voltage to the resistor, and the annealing pulse applying step. It is provided with a configuration in which different trimming steps are sequentially progressed bit by bit in parallel.

The thermal head trimming device of the present invention is provided with a plurality of multiplexers / relays for selecting one bit from a plurality of heating resistors, selects a plurality of bits at the same time, and has a resistance value for the selected bit. , A pulse generator that applies a high electric field pulse to a heating resistor, an annealing pulse generator that generates an annealing pulse, a bit selected by a multiplexer / relay, and a resistance meter / pulse generator Of the matrix relay board that switches the connection between the anneal pulse generator and the anneal pulse generator, and switching of the relay of the matrix relay board so that the resistance measuring instrument, pulse generator, and anneal pulse generator are connected to different multiplexer relays in synchronization And a control device for controlling the.

[0010]

Since a plurality of bits simultaneously perform the trimming process, the time required for trimming the entire heating resistor is shortened. In addition, the thermal head can be produced at high speed by improving the operating rates of the resistance value measuring device and the pulse generator of the trimming device.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS A trimming apparatus embodying the present invention will be described with reference to the block diagram of FIG. The pulse trimming device has the probes 61, 62, 63 ... Which come into contact with the electrode pads of the heating resistor of the thermal head 70 whose resistance value is to be adjusted.
And a prober (brobing device) 60 controlled by the computer 10. A multiplexer / relay for selecting one bit of the thermal head is connected to the prober 60. The multiplexer relay in this embodiment is divided into four, and four multiplexers of a first multiplexer relay 41, a second multiplexer relay 42, a third multiplexer relay 43, and a fourth multiplexer relay 44 are provided.・ By installing a relay, 4 bits of the thermal head (bit 1, bit 2,
Bit 3 and bit 4) are formed so that they can be selected at the same time. Each multiplexer / relay has a resistance measuring device 30 for measuring a resistance value via a switch (relay) board 50 and two high electric field pulse generators 2 arranged.
It can be connected to any one of 1, 2 and the annealing pulse generator 25. The high electric field pulse generator includes a first high electric field pulse generator 21 and a second high electric field pulse generator 22.
The first high electric field pulse generator 21 is connectable to the first multiplexer relay 41 and the third multiplexer relay 43, and the second high electric field pulse generator 2
2 can be connected to the second multiplexer relay 42 and the fourth multiplexer relay 44. Then, the computer 10 controls the pulse applied to the heating resistor while measuring the resistance value of each bit,
By decreasing the resistance value, the desired resistance value is obtained.
That is, the resistance value is measured by the resistance measuring device 30, the high electric field pulse is applied by the high electric field pulse generators 21 and 22, and the annealing pulse is applied by the annealing pulse generator 25 in order of bits 1, 2, 3, and 4. It will be executed.
In the normal trimming process, the process of applying the high electric field pulse takes the longest time, and the takt time is about twice as long as the time required for the process of measuring the resistance value and applying the annealing pulse. Therefore, this device is provided with two high electric field pulse generators, and the first high electric field pulse generator 21 is
The second high electric field pulse generator 22 executes the pulse application of the bit selected by the multiplexer relays 41 and 43 of the above, and the second high electric field pulse generator 22 performs the pulse application of the bit selected by the second and fourth multiplexer relays 42 and 44.

For example, the first multiplexer relay 4
The bit selected by 1 is the relay R of the switch board 20.
When the pulse is applied by the first high electric field pulse generator 21 with 1 connected to the contact a, the bit selected by the second multiplexer relay 42 is the relay R3.
Is connected to the contact a and is connected to the second high electric field pulse generator 22, and the pulse application operation is executed. The bit selected by the third multiplexer relay 43 connects the relay R2 to the contact b and the relay R6 to the contact a, and the pulse applying operation by the annealing pulse generator 25 is executed. The bit selected by the fourth multiplexer relay 44 connects the relay R4 to the contact b and the relay R8 to the contact b, and the resistance value is measured by the resistance measuring device 30. Thus, in the trimming operation by the trimming device of the present invention, the computer 10 controls switching of the relays of the switch board 50 and connects the four bits selected by the multiplexer relays 41, 42, 43, 44 to the respective devices. At the same time, the trimming process is allowed to proceed in parallel with each other.

Next, the trimming operation of the trimming apparatus of the present invention will be described with reference to the trimming flow of FIG. The multiplexer / relays 41, 42, 43, 44 are respectively step S100, step S200, step S300,
The channel is set in step S400. The resistance value is measured in step S110, step S220, step S330, and step S450, and step S120,
Step S230, Step S340, Step S41
At 0, it is determined whether the resistance value is in the target area. Step S
In 130, step S240, step S350, and step S420, a voltage is set based on the applied voltage calculation according to the resistance value, and in step S140, step S250, step S310, and step S430, a high electric field pulse having a pulse width of 1 μsec or less is applied. In step S150, step S210, step S320, and step S440, an annealing pulse having a constant voltage and a pulse width of about 1 msec is applied to stabilize the resistance value. Then, in step S110, step S220, step S330, and step S450, it is determined whether all the bits set in the channel have the target resistance value by proceeding to the resistance value measurement and repeating the pulse application to determine whether the resistance value is the target resistance value.
If it is determined in 260, step S360, and step S460 that the target resistance value is reached, new channel setting is performed in step S100, step S200, step S300, and step S400, and the newly selected bit is set. By repeating the resistance value measurement, pulse application, and annealing pulse application, all the bits of the heating resistor are aligned with the target resistance value. Then, it is confirmed in step S500 that all the bits of the heating resistor have been completed.
When the judgment is made in step 3, the trimming work is completed.

In order to operate the trimming device according to such a control flow, there is a difference in the processing time in the trimming process. Therefore, if each device is operated in parallel, a high charge pulse application with a long processing time is applied. Parallel operation is deviated in the process. Therefore, the trimming apparatus of the present invention divides the operation of each device so that the operation time of each divided operation step is constant.

The operation steps of each device will be described with reference to the block diagram of FIG. Operation step: an operation step of resistance measurement of the resistance measuring device 30, which is a matrix of the switch board 50.
The relay is switched to the resistance measuring device 30, and after waiting for the relay operating time, the resistance value is measured and the value is read. Operation step: An operation step of judgment, voltage calculation, and pulse application. The program judges whether the resistance value is within the target value range. If it is not, voltage calculation is performed and the applied pulse Voltage is set, and after the power supply is stabilized, a high voltage pulse is applied by the first pulse generator 21 or the second pulse generator 22.
However, since the pulse application required processing time is long, the steps are divided into the first half and the second half so that the takt time becomes equal. Operation step-1 …… From relay switching to voltage setting Operation step-2 …… From voltage stabilization waiting to pulse application Operation step …… Annealing pulse application operation step, annealing pulse generation for matrix relay Switch to the device 25, wait for the relay operating time, and then apply the pulse. This trimming device is controlled by the computer 10 so that the matrix relays R1, R2 ...
The resistance value of the heating resistor is adjusted by switching R8 and executing operation steps.

This operation step is shown in FIG. 2 in parallel with 4 bits selected by the first multiplexer relay 41, the second multiplexer relay 42, the third multiplexer relay 43, and the fourth multiplexer relay 44. The operation of the trimming device according to the time step when the trimming flow shown is executed will be described (see FIG. 4). Step A ... Relay R1 is contact b, relay R2 is contact a, relay R5 is contact b, relay 3 is contact b, relay R
4 is switched to contact a and relay R7 is switched to contact a. The first multiplexer / relay 41 is connected to the resistance measuring instrument 30 to execute the operation of the above operation steps. The second multiplexer relay 42 is the annealing pulse generator 25.
Connect to and execute the operation of the operation step. The third multiplexer relay 43 is the first high electric field pulse generator 2
1 to execute the operation of operation step-2. The fourth multiplexer relay 44 is connected to the second high electric field pulse generator 22 to perform the operation of operation step-1.

Step B ... Switching the relay R1 to the contact a, the relay R2 to the contact b, the relay R5 to the contact a, the relay 3 to the contact b, the relay R4 to the contact a, and the relay R7 to the contact b. The first multiplexer / relay 41 is connected to the first high electric field pulse generator 21 to execute the operation of operation step-1. The second multiplexer relay 42 is connected to the resistance measuring instrument 30 to execute the operation of the above operation step. The third multiplexer relay 43 is connected to the annealing pulse generator 25 and executes the operation of the operation step. The fourth multiplexer / relay 44 is connected to the second high electric field pulse generator 22 to operate step-2.
Perform the operation of.

Step C ... Switching the relay R1 to the contact a, the relay R2 to the contact b, the relay R6 to the contact b, the relay 3 to the contact a, the relay R4 to the contact b, and the relay R8 to the contact a. The first multiplexer relay 41 is connected to the first high electric field pulse generator 21 to perform the operation of operation step-2. The second multiplexer relay 42 is connected to the second high electric field pulse generator 22 to perform the operation of operation step-1. The third multiplexer relay 43 is connected to the resistance measuring instrument 30 and executes the operation of the above operation step. Fourth multiplexer / relay 44
Is connected to the annealing pulse generator 25 to execute the operation of the operation step.

Step D ... Switching the relay R1 to the contact b, the relay R2 to the contact a, the relay R5 to the contact a, the relay 3 to the contact a, the relay R4 to the contact b, and the relay R8 to the contact b. The first multiplexer relay 41 is annealed
It connects to the pulse generator 25 and executes the operation of the operation step. The second multiplexer relay 42 is connected to the second high electric field pulse generator 22 to perform the operation of Operation Step-2. The third multiplexer relay 43 is connected to the first high electric field pulse generator 21 to perform the operation of operation step-1. The fourth multiplexer / relay 44 is connected to the resistance measuring instrument 30 to execute the operation of the above operation steps. And multiplexer relay 1
For the resistor bit specified by ~ 4, the computer 1
While switching the relay at 0, step A to step D of the operation are repeated according to the temporal flow.

Then, the case where the 1-bit trimming operation selected by the multiplexer / relay is completed and the operation is shifted to the next channel will be described. This embodiment shows the case where the bit selected by the second multiplexer relay 42 has completed the trimming operation (see FIG. 5). The end of trimming is judged by the judgment routine of operation step-1 in step C ', and the channel setting is changed in operation step-2 in step D'. Then, in step A ′, the relays are switched so that the relay R2 is connected to the contact a, the relay R5 is connected to the contact b, and the second multiplexer relay 42 is connected to the annealing pulse device. However, pulse application is not executed. This operation step is called an operation step *. Then, the operation returns to the operation of measuring the resistance value in the operation step of step B ′. Each bit selected by the multiplexer relays 1, 3 and 4 ends the trimming operation one after another, but the channel setting is performed in the operation step-2 in the order in which the end determination is performed in the determination routine of the operation step-1. The operation step * is changed, and the pulse application is not executed, and the operation proceeds to the resistance value measurement operation in the operation step.

As shown in this embodiment, the trimming operation is carried out in parallel with the trimming device having two high electric field pulse generators for the four bits selected by the four multiplexers / relays at the same time. Therefore, it is about 1/3 compared to the conventional trimming time.
All bits can be trimmed in the required time.

[0022]

As described above, according to the trimming method of the present invention, the trimming process time is significantly shortened by advancing the existing trimming processes simultaneously in parallel for several bits without increasing the trimming process. It has the effect of being able to. Further, the trimming device according to the present invention does not need to prepare as many devices as the number of bits for the trimming processes which are simultaneously performed.
Since the relay board is used to increase the operating efficiency of the device, it is possible to provide an economical trimming device with a small capital investment, and it is also possible to manufacture a thermal head at high speed without variation in resistance value.

[Brief description of drawings]

FIG. 1 is a block diagram of a trimming device of the present invention.

FIG. 2 is a flowchart of trimming according to the present invention.

FIG. 3 is an operation decomposition block diagram of a trimming flowchart.

FIG. 4 is a parallel operation table of trimming for each step.

FIG. 5 is a parallel operation table of trimming for each step.

FIG. 6 is a block diagram of a conventional trimming device.

FIG. 7 is a flowchart of conventional trimming.

FIG. 8 is a perspective view of a thermal head.

[Explanation of symbols]

10 computer, 21 1st high electric field pulse generator, 22 2nd high electric field pulse generator, 25 annealing pulse generator, 30 resistance measuring device, 41 1st multiplexer relay, 42 2nd multiplexer relay, 43 third multiplexer relay, 44 fourth
Multiplexer relays, 50 switchboards, 6
0 prober, 70 thermal head.

Claims (3)

[Claims] 1. For one bit selected by the heating resistor,
A resistance value measuring step of measuring the resistance value, a voltage setting step of setting a voltage applied to the heating resistor from the difference between the measured resistance value and the target resistance value, and pulse application of the set voltage to the resistor This is a thermal head trimming method in which the pulse applying step and the annealing pulse applying step are performed in this order, and the resistance values of the heating resistors are made uniform. Several bits of the heating resistors are selected at the same time, and each bit is trimmed differently. A method of trimming a thermal head, characterized in that the above steps are sequentially progressed in parallel. 2. A trimming device for a thermal head, which applies a voltage pulse to a plurality of heating resistors to make the resistance values of the plurality of heating resistors uniform, wherein the multiplexer / relay selects one bit from the plurality of heating resistors. Select with a resistance measuring device that measures the resistance value of the selected bit, a pulse generator that applies a high electric field pulse to the heating resistor, an annealing pulse generator that generates an annealing pulse, and a multiplexer relay The trimming device is provided with the multiplexer, the matrix relay board that switches the connection between the resistance measuring device, the pulse generator, and the annealing pulse generator, and the control device that controls the switching of the relay of the matrix relay board. Multiple relays are installed to select multiple bits at the same time, and the control unit synchronizes the resistance. Joki,
A trimming device for a thermal head, which controls switching of relays of a matrix relay board so that a pulse generator and an annealing pulse generator are connected to different multiplexer relays respectively. 3. A plurality of pulse generators are provided, and
3. The thermal head trimming device according to claim 2, wherein each pulse generator is configured to be connectable to a plurality of different multiplexer relays.