KR100227476B1 - Printing apparatus - Google Patents

Abstract

The thermal head 9 is always preheated with an appropriate preheat pulse width, eliminating spots in print density, and obtaining a high quality printed image.

After the printing is performed by the thermal head 9 at a predetermined printing pulse width based on the image data, the thermal head 9 is preheated and controlled by a predetermined preheating width until the next printing time. In the ROM 2, table data Td1, which is set to the print pulse width to be applied to the thermal head 9, and table data Td2, which is set to the preheat pulse width, are respectively stored in response to the temperature of the thermal head 9. do. The value of the preheat pulse width set in the table data is larger in proportion to the value of the print pulse width set in the same table data as the temperature of the thermal head 9 is lower, and the temperature of the thermal head 9 is higher. It is set to become smaller.

Description

Printing equipment

1 is a block circuit diagram showing an embodiment in which the present invention is embodied in a facsimile apparatus.

2 is a flowchart showing an operation when receiving one page of image data executed by a CPU, and (b) is a flowchart showing a time division routine executed based on the input of a time division signal.

FIG. 3 is an explanatory diagram showing table data in which a printing pulse width to be applied to the thermal head is set corresponding to the temperature of the thermal head.

FIG. 4 is an explanatory diagram showing table data in which the preheat pulse width to be applied to the thermal head is set corresponding to the temperature of the thermal head.

FIG. 5 is an explanatory diagram showing the values of the printing pulse width corresponding to the temperature in the thermal head, the value of the preheat pulse width in the present embodiment and the value of the preheat pulse width in the prior art, respectively.

6 is a timing difference art showing an operation at the time of reception.

* Explanation of symbols for main parts of the drawings

1: CPU 2: ROM

3: RAM 8: Head drive circuit

9: thermal head 10: temperature sensor

13: Time Division Timer Td1: Table Data

Td2: Table Data

The present invention relates to, for example, a printing apparatus in a facsimile apparatus and the like, and more particularly, to a printing apparatus which prints using a thermal head.

In general, in a facsimile apparatus, image data is transmitted in a coded state, but the coded data is a different amount of information for each line. For this reason, in the transmission of image data, the transmission time for each line changes, and the time required for the encoding and decoding processing for each line also changes. Therefore, when receiving such image data and printing on a recording sheet, the time between printing one line and starting printing of the next line changes with the transmission and processing time change for each line. do.

By the way, in the printing apparatus using the thermal head, if the length of time between the printing of one line and the start of the next line is started, the thermal head is not heat-controlled during that time, so that the temperature of the thermal head is lowered. Make. Therefore, even if the thermal head is heat-controlled in the printing of the next line, the temperature of the thermal head is not sufficiently raised, and the print density is thinned.

Therefore, in the printing apparatus using such a thermal head, when the period between printing one line and starting printing of the next line becomes long, the thermal head is preheated so that the temperature of the thermal head is not lowered. It is conventionally performed.

That is, in this conventional apparatus, as shown by a solid line in FIG. 5, for example, table data in which the print pulse width to be applied to the thermal head is set corresponding to the temperature of the thermal head is provided. The thermal head is also equipped with a temperature sensor for detecting the temperature of the thermal head. When printing each line by the thermal head, the table data is referred to based on the detected temperature by the temperature sensor to set the optimum print pulse width to be applied to the thermal head, and the printing of the set time width on the thermal head. A pulse is applied. After the printing of the line, a pulse signal for preheating is applied to the thermal head, but the time width of the preheating pulse is equal to and (E.g. 50 It was set method such as). As a result, as indicated by a dotted line in FIG. 5, conventionally, printing is performed at a predetermined print pulse width based on table data, and then a preheating pulse having a time width that is always a constant ratio with respect to the print pulse width is applied to the thermal head. It was.

By the way, when the preheat pulse width is always set at a constant ratio with respect to the printing pulse width as in the conventional art, the following problems arise. In other words, when the transmission and processing time for each line does not exceed a predetermined time width (for example, 10 ms), the recording paper is sent one line for each predetermined time width. For this reason, as shown by the solid line in FIG. 5, although the temperature of the thermal head is low and it is necessary to increase the printing pulse width, the maximum value of the printing pulse width is actually limited to the above-described time width, and larger than that. It cannot be set. Therefore, as indicated by the dotted line in FIG. 5, when the temperature of the thermal head is low, the preheat pulse width determined by the printing pulse width is also limited to the maximum value, and there is a problem that the thermal head cannot be sufficiently preheated.

On the contrary, even if the temperature of the thermal head is high and the print pulse width needs to be reduced, the preheat pulse width is set larger than necessary, and the thermal head has a problem of exceeding an appropriate preheat temperature. As a result, a problem arises such that unevenness occurs in the print density, and a high quality print image cannot be obtained.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object thereof is to provide a printing apparatus capable of always preheating the heat-sensitive head with an appropriate preheat pulse width, without causing spots on printing density, and obtaining a high quality print image. There is.

In order to achieve the above object, in the invention of claim 1, the printing is performed by the thermal head at a predetermined printing pulse width based on the image data, and then the heating is performed at a predetermined preheating pulse width until the next printing start. A printing apparatus provided with a control means for preheating control of a head, wherein the control means stores table data in which the printing pulse width to be applied to the thermal head corresponding to the temperature of the thermal head and table data in which the preheat pulse width is set. It is equipped.

In the invention of claim 2, the value of the preheat pulse width set in the table data is similar to the value of the print pulse width set in the table data. The lower the temperature of the thermal head is, the smaller the temperature of the thermal head is. It is set to lose.

In the invention of claim 3, the control means repeats the preheating control at a predetermined cycle until the next printing start.

Therefore, according to the invention of claim 1, since the table data which sets the print pulse width to be applied to the thermal head and the table data which set the preheat pulse width correspond to the temperature of the thermal head, the preheat pulse width is printed. Regardless of the pulse width, it can be set to an appropriate value.

According to the invention of claim 2, even when the temperature of the thermal head is low, the thermal head can be sufficiently preheated. In addition, even when the temperature of the thermal head is high, the preheat pulse width is not set larger than necessary, and the thermal head does not exceed the proper preheat temperature.

According to the invention of claim 3, even if the time between printing and the next printing starts is very long, the preheating temperature of the thermal head can be maintained at an appropriate temperature until the next printing start.

EMBODIMENT OF THE INVENTION Hereinafter, one Embodiment which embodies this invention in the facsimile apparatus is demonstrated based on drawing.

1 shows the circuit configuration of the facsimile apparatus of this embodiment. The CPU (central processing unit) 1 includes a read-only memory (ROM) 2 storing programs and the like for controlling the operation of the entire apparatus, and a random-access memory (RAM) 3 temporarily storing various information. ) Is connected. In the present embodiment, the control means is constituted by the CPU 1, the ROM 2, and the RAM 3. In the ROM 2, two table data Td1 and Td2 shown in Figs. 3 and 4 are stored in advance. The contents of these table data Td1 and Td2 will be described later. The network control unit (NCU) 4 controls the connection with the telephone line. The modem 5 modulates and demodulates the transmission and reception data.

The reading unit 6 reads an image on the original. The code and decoding circuit 7 encodes the read image data described above and decodes the received image data. The head drive circuit 8 generates printing pulses based on one line of image data (line data) sent from the CPU 1 and a predetermined printing pulse width signal described later. The head drive circuit 8 includes a line memory (not shown), and the input line data is temporarily stored in this line memory. Then, the head drive circuit 8 applies a printing pulse to the thermal head 9 when receiving a print request signal from the CPU 1. Then, based on the printing pulse, a plurality of heat generating resistors (not shown) provided in the thermal head 9 are selectively generated to print one line on the recording paper. Further, in this embodiment, as a printing apparatus having a thermal head 9, a thermal transfer printing apparatus that thermally transfers ink on an ink ribbon onto a recording sheet may be applied, or thermal recording for performing thermal recording on a thermal recording sheet. A printing apparatus of a type may be applied. The head drive circuit 8 sends a print display signal to the CPU 1 while the heat-sensitive head 9 is under heat generation control.

The time division timer 13 is started at the same time as the CPU 1 outputs a print request signal, and generates a time division signal after a predetermined time (10 ms in this embodiment) from the column. Then, the CPU 1 outputs a predetermined preheat pulse width signal, which will be described later, to the head drive circuit 8 based on the input of the time division signal, and outputs the print request signal again. The head drive circuit 8 then generates a preheat pulse based on the line data held in the line memory and the preheat pulse width signal, and applies the preheat pulse to the thermal head 9. As a result, the heat generating resistor of the thermal head 9 is selectively generated based on the preheating pulse. The heat generation also causes overprinting to be performed on the printing place on the recording sheet. The head drive circuit 8 also sends a print display signal to the CPU 1 while the thermal head 9 is preheated controlled.

The temperature sensor 10 consists of a thermistor etc., and is attached on the board | substrate which is not shown in figure which supports the heat generating resistor in the said heat sensitive head 9. As shown in FIG. Then, the temperature sensor 10 detects the temperature of the substrate of the thermal head 9 and outputs a temperature detection signal to the CPU 1 before each line of printing starts by the thermal head 9. Then, the CPU 1 recognizes the temperature of the substrate of the thermal head 9 (hereinafter simply referred to as the temperature of the thermal head 9) based on the input temperature detection signal.

The motor drive circuit 11 generates a drive signal based on the motor drive command sent from the CPU 1, and outputs the drive signal to the paper transfer motor 12. Then, the paper feed motor 12 is rotated by the drive signal so that the recording paper is sent line by line. In addition, the image data is different in transmission time or time required for decoding processing for each line. Here, when the transfer processing time for each line does not exceed a predetermined time width (10 ms in this embodiment), the CPU 1 outputs a motor drive command every 10 ms and sends a recording sheet every 10 ms. .

As shown in FIG. 3, in the above table data Td1, the time width (print pulse width) of the printing pulse to be applied to the thermal head 9 is set corresponding to the temperature of the thermal head 9. As shown in the same figure, the value of the printing pulse width is set so that the lower the temperature of the thermal head 9 is, the smaller the higher the temperature of the thermal head 9 is. However, in the range where the temperature of the thermal head 9 is equal to or less than the predetermined temperature, the value of the print pulse width is limited to a constant value of approximately 10 ms so as not to be larger than the time width 10 ms at the time of conveying the paper.

As shown in FIG. 4, in the above table data Td2, the time width (preheating pulse width) of the preheating pulse to be applied to the thermal head 9 is set corresponding to the temperature of the thermal head 9. As shown in the same figure, the value of this preheat pulse width is set so that the lower the temperature of the thermal head 9 is, the smaller the higher the temperature of the thermal head 9 is. Moreover, as is apparent from FIG. 5 in particular, the value of this preheat pulse width is such that the ratio of the print pulse width set in the table data Td1 of FIG. 3 above is low in the temperature of the thermal head 9. It is set so that it is so large that it becomes small, so that the temperature of the thermal head 9 is high.

Next, the operation at the time of receiving image data for one page executed by the CPU 1 will be described according to the flowcharts shown in FIGS. 2A and 2B. As shown in FIG. 2 (a), when the CPU 1 receives the image data, in step S1, the decoding of the code and the line data by the decoding circuit 7 is started. Transfer of the decoding data to the line memory of the head drive circuit 8 is started. Then, the CPU 1 waits for the end of the line data decryption in step S2. When the decryption ends, the CPU 1 proceeds to step S3 to determine whether the thermal head 9 is currently in heat generation control. This determination is made based on the presence or absence of a print display signal from the head drive circuit 8.

The CPU 1 waits for the thermal head 9 to finish the heat generation control when there is an input of a print display signal. If there is no input of the print display signal, the CPU 1 proceeds to step S4, and stops if the time division timer 13 is activated. Next, in step S5, the CPU 1 drives the paper transfer motor 12 by the motor drive circuit 11, and sends a recording sheet for one line. Next, in step S6, the CPU 1 recognizes the temperature of the thermal head 9 based on the temperature of the thermal head 9 based on the detection signal from the temperature sensor 10. Then, in step S7, the CPU 1 prints to be applied to the thermal head 9 with reference to the table data Td1 shown in FIG. 3 based on the temperature of the thermal head 9 recognized first. The pulse width is set and the printed pulse width signal is sent to the head drive circuit 8.

Then, the CPU 1 sends a print request signal to the head drive signal 8 in step S8. As a result, the heat-sensitive head 9 generates heat by controlling the printing pulse width set first, and the heat-sensitive head 9 prints on the recording paper. At the same time as the output of the print request signal, the CPU 1 starts the time division timer 13 again in step S9. Then, the time division timer 13 generates a time division signal 10 ms after the start and outputs it to the CPU 1.

Then, the CPU 1 executes the time division routine shown in FIG. 2 (b) based on the input of this time division signal. In addition, this time division routine is described with reference to the timing difference art shown in FIG. As shown in FIG. 2 (b), the CPU 1 refers to the table data Td2 shown in FIG. 4 based on the temperature of the thermal head 9 recognized first in step S11. Then, the preheat pulse width to be applied to the thermal head 9 is set, and the preheat pulse width signal is sent to the head drive circuit 8. Then, the CPU 1 sends a print request signal to the head drive circuit 8 in step S12. As a result, the thermal head 9 is preheated and controlled by the preheat pulse width set first, and overprinting is performed on the printing place on the recording paper. At the same time as the output of this print request signal, the CPU 1 starts the time division timer 13 again in step S13. Then, the time division timer 13 generates the time division signal again 10 ms after the start, so that the above time division routine is executed again, and as shown in FIG. 6, the preheating control for the thermal head 9 is performed every 10 ms. It is repeated.

Returning to Fig. 2 (a), the CPU 1 determines in step S10 whether the reception of one page has ended or not, and in the case of the reception termination, terminates the processing once, and does not end reception. In the case, the process returns to the step S1 to start the duplication of the next line data.

During the execution of the time division routine, when the decoding of the next line data is finished in step S2, it is determined whether or not the thermal head 9 is in preheating control in step S3. Here, if it is not during preheating control, the flow advances to step S4 and the time division timer 13 is immediately stopped, and after the kind of preheating control under preheating control, the process proceeds to step S4 and the time division timer 13 stops. do. As a result, the time division routine is terminated, and the printing operation of the next retarder is shifted.

As described above, in this embodiment, even when the time from the printing of one line to the start of the printing of the next line becomes long, the thermal head 9 is preheated and controlled, and thus the thermal head until the next printing start. The temperature of (9) decreases and does not dry. For this reason, in the printing of the next line, when the heat-sensitive head 9 is heat-controlled, the temperature of the heat-sensitive head 9 can be raised to a sufficient temperature, and the print density is not thinned.

In addition, in the present embodiment, the table data Td1 in which the printing pulse width to be applied to the thermal head 9 is set corresponding to the temperature of the thermal head 9, and the table data Td2 in which the preheating pulse width is set are: Each is provided. For this reason, unlike the prior art mentioned above, the preheating pulse width applied to the thermal head 9 can be set to an appropriate value irrespective of the printing pulse width. And, as shown in FIG. 5, the preheat pulse width value of this embodiment is larger in proportion to the value of the print pulse width as the temperature of the thermal head 9 is lower, and as the temperature of the thermal head 9 is higher. It is small. As a result, since the preheat pulse width can be set regardless of the printing pulse width, in the present embodiment, the value of the preheat pulse width is compared with that of the conventional preheat pulse width indicated by a dotted line in the same drawing. When the temperature is low, it can be made large, and when the temperature of the thermal head 9 is high, it can be made small.

As a result, in the present embodiment, even when the temperature of the thermal head 9 is low, the preheat pulse width can be set to a sufficiently large value without being limited to the printing pulse width, and the thermal head 9 can be sufficiently preheated. In addition, even when the temperature of the thermal head 9 is high, the preheat pulse width is not set larger than necessary, and the thermal head 9 does not exceed the appropriate preheat temperature. For this reason, in actual printing operation | movement, a stain does not arise in print density, and a high quality printed image can be obtained.

In addition, by storing the data of the preheat pulse width corresponding to the temperature of the thermal head 9 in the form of table data Td2, the preheat pulse to be applied to the thermal head 9 without performing complicated arithmetic processing or the like. The width can be set simply and quickly.

In this embodiment, the preheating control for the thermal head 9 is repeated at a predetermined cycle until the next printing start. For this reason, even when the time between printing and the next printing starts is very long, the preheating temperature of the thermal head 9 can be reliably maintained at an appropriate temperature until the next printing start.

In addition, this invention is not limited to the above-mentioned embodiment, For example, it can also be embodied in the following forms.

(1) Limit the number of repetitions of preheating control to a predetermined number. In this case, it is possible to prevent the print density from becoming too thick due to overprinting according to the preheating control.

(2) The temperature sensor 10 detects the temperature of the thermal head 9 each time the preheat pulse width is set. In this way, the temperature of the thermal head 9 before preheating control can be detected more accurately, and the preheating pulse width can be set to a more accurate value.

(3) The present invention is embodied in a printing apparatus other than a facsimile apparatus, such as a printer.

Technical thoughts other than the claims grasped from the above embodiments will be described next with the effects.

(1) The printing according to claims 1 to 3, wherein a temperature sensor for detecting the temperature of the thermal head is provided, and the control means is to be applied to the thermal head with reference to each table data based on the detected temperature by the temperature sensor. Printing apparatus for setting pulse width and preheat pulse width.

In this way, an appropriate printing pulse width and preheating pulse width can be set simply and quickly on the basis of the temperature of the thermal head detected by the temperature sensor.

As described above, according to the present invention, the following excellent effects can be obtained.

According to the invention of claim 1, the preheat pulse width can be set to an appropriate value regardless of the printing pulse width. For this reason, it is possible to always preheat a thermal head to an appropriate preheat pulse width, and to obtain a high quality printed image, without making a stain in print density.

According to the invention of claim 2, even when the temperature of the thermal head is low, the thermal head can be sufficiently preheated. In addition, even when the temperature of the thermal head is high, the preheat pulse width is not set larger than necessary, and the thermal head does not exceed the appropriate preheat temperature.

According to the invention of claim 3, even if the time between printing and the next printing starts is very long, the preheating temperature of the thermal head can be reliably maintained until the next printing start.

Claims (5)

Printing with control means for preheating control of the thermal head with a predetermined preheat pulse width until the printing is performed by the thermal head 9 at a predetermined printing pulse width based on the image data until the next printing start. An apparatus comprising: a memory in which control means stores table data Td1 for setting a print pulse width to be applied to the thermal head and a table data Td2 for setting a preheat pulse width respectively. Printing device. 2. The heat transfer head according to claim 1, wherein a ratio of the preheat pulse width set in the table data Td2 to a value of the print pulse width set in the table data Td1 is larger as the temperature of the heat head is lower. The printing apparatus is set to become smaller as the temperature of the gas becomes higher. The printing apparatus according to claim 1 or 2, wherein the control means repeats the preheating control at a predetermined cycle until the next printing start. Printing with control means for preheating control of the thermal head with a predetermined preheat pulse width until the printing is performed by the thermal head 9 at a predetermined printing pulse width based on the image data until the next printing start. An apparatus comprising: a memory in which table means Td1 for printing pulse width and table data Td2 for preheat pulse width are respectively stored by the control means to be applied to the thermal head in correspondence with the temperature of the thermal head. Printing device. The value of the preheating set in the table data Td1 is set so that the ratio with respect to the value of the printing pulse width is set so that the temperature of the thermal head is lower, and the temperature of the thermal head is smaller. Printing device.