KR100213765B1 - Temperature control device for facsimile - Google Patents

Abstract

According to the present invention, when the temperature of the thermal head (TPH) is lower than the set temperature in the facsimile, the TPH generates heat before recording, and when the set temperature is higher than the set temperature, the fan is driven to maintain the temperature of the TPH to increase the printing speed and improve image quality The present invention relates to a printer temperature control device, and an object of the present invention is to convert the analog signal output from the temperature detector (6) and the temperature detector (6) which detects its own temperature of the TPH (3) into a digital signal, thereby providing a CPU. Strobe signal for the self-don value of the fan control unit 8 and the TPH 3 controlling the fan by the A / D conversion unit 7 applied to (1) and the control signal output from the CPU 1 This is achieved by additionally configuring the RAM 10 in which values and data required for fan driving are stored.

Description

Facsimile Printer Temperature Controller

1 is a block diagram of a conventional printer driving system.

2 is a timing diagram of a conventional thermal head drive.

3 is a graph of the relationship between the conventional thermal head temperature and the printing time.

4 is a block diagram of a printer temperature control apparatus of the present invention.

5 is a thermal head driving timing diagram according to the present invention.

Figure 6 is a graph of the relationship between the thermal print head temperature and the printing time according to the present invention.

7 is a control flow diagram according to the operation of the present invention.

* Explanation of symbols for main parts of the drawings

6: temperature detection unit 7: A / D conversion unit

8: Fan control unit 10: RAM

The present invention relates to a facsimile printer temperature control device. More specifically, when the temperature of the thermal print head (hereinafter referred to as TPH) is lower than the set temperature, the TPH is generated before recording. The present invention relates to a printer temperature control device which maintains a constant temperature of the TPH to increase printing speed and improve image quality.

1 is a block diagram of a conventional printer driving system, and converts serial data output through a parallel bus of the CPU 100 and a central processing unit (hereinafter referred to as CPU 100) to control the overall operation of the system into serial data. And a thermal recording head (TPH: 102) for real recording the data output from the data conversion section 101 by applying the data output from the data conversion section 101 to a line memory. The TPH control unit 103 controls the recording operation of the TPH 102 by the signal output from the unit 100, and the timer 104 generates an interrupt signal at a time interval determined by the CPU 100.

Reference numeral 105 denotes an EPROM in which a program related to a printer device is recorded.

The operation of the conventional printer driving system configured as described above will be described in detail with reference to FIGS. 2 to 3 of the accompanying drawings. The central processing unit 100 transfers data to be recorded to the data conversion unit 101 via parallel buses as parallel data. Is authorized.

Accordingly, the data changing unit 101 converts the input parallel data into serial data and inputs the same into the line memory in the thermal recording head 102 in synchronization with the clock signal CLOCK shown in FIG.

At this time, the central processing unit 100 generates a control signal in the program order stored in the pyramid 105 according to the timing signal input from the timer 104 to drive the thermal recording head 102, thereby generating the TPH controller 103. Will be applied to.

When a latch signal (LaTch) as shown in FIG. 2C generated by the TPH control unit 103 is input to the TPH 102, data of one line (consisting of 1728 pixels when the recording paper is A4 size) is stored in the line memory (one line buffer). It is latched at one time.

The data of one latched line is composed of several blocks (in this case, composed of four blocks). Each block generates only the dot in which data is set by the pulse width of the STROB signal and is recorded on the thermal recording paper.

That is, the data of one latched line is completed when data of one latched line is completed when strobe signals such as FIG.

In Fig. 2, SC denoted by d-g means the time of one block T.P.H STROB signal.

FIG. 3 is a graph showing the relationship between the self temperature and the fritting time of the TPH 102 recorded as described above, where TS is an exothermic temperature for producing an optimal recording quality, and Td is a set TPH reference temperature. td denotes the initial TPH heating time, tc denotes the period of the pulse, and Cc denotes the thermal response characteristic curve.

However, such a conventional printer driving system has a low thermal head temperature as in the thermal response characteristic curve shown in FIG. Even though TPH temperature compensation is made due to the gradual increase in the temperature of the thermal head itself, there is a problem that communication quality is lost due to deterioration of recording quality or interruption of recording because natural temperature of one-line recording time does not prevent the temperature rise. There was a problem that the recording time is considerably high because the heat generation takes a lot of time when recording or rest of the initial page of the next page.

Therefore, the object of the present invention is to heat the TPH before recording if the temperature of the thermal head is lower than the set money, and to drive the cooling fan if the temperature is higher than the set temperature to maintain a constant temperature of the TPH so that the image quality can be improved and the printing speed can be increased accordingly. It is to provide a printer temperature control device.

The object of the present invention is a temperature detection unit for detecting the temperature of the TPH, an A / D conversion unit for converting the analog signal output from the temperature detection unit into a digital signal, a fan control unit for controlling the heating of TPH above the reference value and The present invention is achieved by additionally configuring a RAM in which a STROB signal value and a data for driving a fan are stored.

4 is a block diagram of a printer temperature control device of the present invention, a central processing unit (hereinafter referred to as CPU 1) for controlling the overall operation of the printer system, and parallel reception output through a parallel bus of the CPU 1; A data converting unit 2 for converting data into serial data and outputting the data; and a thermal print head for receiving the data output from the data changing unit 2 into a line memory and actually recording the data. ), A TPH controller 4 for controlling the recording operation of the TPH 3 by the signal output from the CPU 1, and a timer 5 for generating an interrupt signal at a time interval determined by the CPU 1; And a temperature detector 6 for detecting its own temperature of the TPH 3, and an A / D changer for converting an analog signal output from the temperature detector 6 into a digital signal and applying it to the CPU 1; 7) and the fan is removed by the control signal output from the CPU (1). It was composed of a fan control unit (8) for.

Reference numeral 9 denotes an EPROM in which a program related to a printer device is recorded, and 10 denotes a RAM in which a strobe signal value for the TPH self temperature value and data necessary for fan driving are stored.

The operation and effects of the printer temperature control apparatus of the present invention configured as described above will be described in detail with reference to FIGS. 5 to 7.

As shown in FIG. 4, in order to record, the CPU 1 applies the recorded data to the data converter 2 via a parallel bus.

The data changing unit 2 converts the input parallel data into serial data and inputs the same to the line memory in the TPH 3 in synchronization with the clock signal CLOCK shown in FIG.

At this time, the CPU 1 generates a control signal in the program order stored in the EPROM 9 and applies it to the TPH controller 4 according to the timing signal input from the timer 5 to drive the TPH 3. .

The TPH controller 4 inputs a latch signal as shown in FIG. 5C to the TPH 3 and accordingly, 1728 pixels in the line memory (one line buffer) of the TPH 3 (based on the recording paper A4 size basis). Data is latched at a time.

The latched one-line data consists of several blocks (in this case, composed of four blocks, STROB1-STROB4). Each block generates only the dot in which data is set by the input of the STROB signal and records the data on the thermal recording paper.

At this time, the STROB pulse width can be adjusted by detecting the self temperature Ta of the T.P.H (3) from the temperature detector 6.

In other words, the analog temperature value detected from the temperature detector 6 is converted into a digital temperature value through the A / D converter 7 and is applied to the CPU 1.

In contrast, if the detected temperature value Ta is less than the reference value Td, the strobe width SN may be reduced as shown in FIG. 5d-g by increasing the TPH 3 to the reference temperature.

In addition, if the detected temperature value Ta is equal to or greater than the reference value Td, the CPU 1 obtains the corresponding value from the RAM 10 according to the rising width, and controls the fan control unit 8 and the TPH control unit 4 to control the TPH (3). By controlling the and driving the fan will be able to adjust the temperature of the TPH (3) to the same as the reference value.

As described in detail above, according to the present invention, as the TPH 3 starts to generate heat at the set reference temperature Td as shown in FIG. 6, the present invention reaches an exothermic temperature for producing an optimum recording quality. It takes less time, so the reception speed is faster and the communication speed is faster, and the heat generation temperature can be kept constant like Ts, so the recording quality of the factor is good and the communication termination due to TPH overheating is eliminated. Will be effective.

Claims (1)

CPU 1 for controlling the whole system operation, data conversion unit 2 for converting parallel data output from the CPU 1 into serial data and outputting to TPH 3 in synchronization with a clock signal CLOCK; A TPH controller 4 for controlling the recording operation of the TPH 3 by the signal output from the CPU 1, a temperature detector 6 for detecting its own temperature of the TPH 3, and the temperature detector An A / D conversion unit 7 for converting the analog signal outputted from (6) into a digital signal and applying it to the CPU 1, and a fan control unit for controlling the fan by the control signal output from the CPU 1 ( 8) and a RAM (10) storing strobe signal values for the TPH (3) 's own temperature values and data necessary for driving the fan.