JP2721150B2 - Thermal recording device - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a thermal recording apparatus. FIG. 3 is a main part electric circuit diagram for explaining an example of a conventional thermal recording apparatus, and FIG. 4 is a time chart for explaining the operation of the circuit of FIG. Heating resistor, 2
Is a driver, 3 is a latch circuit, and 4 is a shift register. Image information is serially input to the shift register 4, and after one line has been input, it is input to the latch circuit 3 in parallel. According to the image information, the driver 2 is turned on and off to supply a current to the heating resistor 1 to cause the heating resistor 1 to generate heat and record it on the thermal paper. Thermal paper develops color due to the energy of the heating element. That is, it depends on the voltage applied to the resistor and the time. Attempting to print one line at a time consumes very large power if one line is all black. For this reason,
Divide into several blocks as shown in the figure, EN1, EN2,
EN3, ... are recorded sequentially. In this case, the maximum power consumption is determined by the number of bits in the block, and large power is not required. However, the reading speed decreases.
Also, the inside of the block may not be all black, which is inefficient. For this reason, as shown in JP-A-54-8415,
If none of the image signals in the block is to be recorded, the supply of the selection signal to the recording element block whose selection order has been reached is prohibited, so that the recording method is designed to reduce power consumption and heat generation. Kaisho 56-106880
As shown in the publication, a shift register for serially / parallel conversion of a recording signal is divided into a plurality of groups, and an output control terminal for controlling on / off of the output for each group is provided. A recording method has been considered in which a control signal supply pattern to an output control terminal is determined so that the total value of current flowing through the heating resistor does not exceed the current capacity of the power supply in accordance with the pattern of the recording signal. However, this is inefficient because not all of the bits in the block are controlled. As described above, the thermal recording method used as a recording device such as a facsimile has a large correlation between the recording speed and the power consumption, and if the recording speed is to be increased, the power consumption becomes large, and the power consumption becomes large. If you try to make it smaller, the recording speed will be slower. SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and has been made to provide a thermal recording apparatus capable of efficiently increasing a recording speed without increasing power consumption. . Configuration In order to achieve the above object, the present invention provides a thermal recording apparatus having heating resistors arranged in a row and driving elements connected to the heating resistors, wherein one of the driving elements is turned on and off. It is characterized by having a shift register that controls every bit or more, and a clock selection circuit that selects a clock signal of the shift register according to an image signal. Hereinafter, a description will be given based on examples of the present invention. FIG. 1 is an electric circuit diagram for explaining an embodiment of a thermal recording apparatus according to the present invention, and FIG. 2 is a time chart for explaining the operation thereof.
Is a driver, 13 is an enable circuit, 14 is a clock selection circuit, 15 is a latch circuit, and 16 is a data shift register. The configurations of the heating resistor 11 and the driver 12 are the same as those conventionally known. Thus, the conventional enable circuit is divided into blocks and externally controlled, but in the present invention, a drive signal transmission register is provided for each bit, and the parallel output of the drive signal transfer register is used as an enable signal. The clock signal of the drive signal transfer register is independently controlled for each bit, and has a clock signal selection circuit. This is a circuit for selecting a clock signal according to image information. When an image signal is printed as black, H (high level) is output to the Q terminal of the latch circuit and L (low level) is output to the terminal. Is done. As a result, CK1 is selected as the clock signal. When the image information is white and not printed, the Q terminal of the latch circuit becomes L and the terminal becomes H, and CK2 is selected. The latch circuit 15 and the data shift register circuit 16 are the same as those conventionally known. Next, the operation of the above circuit will be described with reference to the time chart of FIG. Note that the recording method can be set according to each condition, but here, for the sake of simplicity, the following settings are made. Heat storage period: t ₁ Simultaneous recording bits: 3 bit clock period ratio: CK1: CK2 = 4: 1 data data into the shift register 16 is input, data is transferred to the latch circuits 15. As is well known, each latch circuit stores white and black image information. Period of CK1 is set to t _1/3 under the above conditions. Next, enable circuit 13
Inputting a d enable data (Enable Data) to, but this error enable data and rise of CK1 at a pulse width of t ₁ C
Make sure to rise between the rises of K2. When the image information of the first bit is not printed in white, it becomes H in synchronization with the rise of CK2. That is, the first bit is enabled. However, since the output from the latch is L, no current flows through the heating resistor R1 and no printing is performed. The enable signal E1 of the first bit is connected to the D input of the drive signal transfer register of the next stage, and if the second bit is white, it is shifted at a high speed by CK2. If the third bit is black, it is shifted at a low speed by CK1. Since the output from the latch is H, a current flows through the heating resistor R3 and printing is performed. As described above, when printing is not performed according to the image information, the bits are shifted at high speed and the number of enabled bits increases. However, when printing, the enable data is not shifted until the next rise of CK1. Therefore, the number of bits to be printed is always 3 bits. The print end signal for one line is obtained by detecting the enable signal at the last stage, thereby enabling the next print. CK1 and CK2 for this example
Is set to 4: 1. By increasing this ratio, higher speed driving becomes possible. That is, assuming that the number of pixels for one line is this ratio, scanning is completed in one clock of CK1 even in the case of all white. Also, the heat storage period and the number of simultaneous recording bits can be freely set with the same configuration. In the illustrated embodiment, a clock selection circuit is provided for each bit, but one circuit may be provided for two or more bits. Effects As is clear from the above description, according to the present invention, (a) since scanning is performed while always printing the set number of bits, the efficiency is high with respect to the power supply capacity. (B) When the number of printing bits is small, high-speed recording is possible. (C) The heat storage time and the number of simultaneous recording bits can be freely set with the same configuration, and the control circuit can be easily configured. (D) High-speed recording is possible with a small power supply, and the control circuit is simplified. There are advantages such as.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an electric circuit diagram for explaining an embodiment of a thermal recording apparatus according to the present invention, and FIG. 2 is a diagram for explaining the operation of the circuit shown in FIG. 3 is a time chart, FIG. 3 is an electric circuit diagram for explaining an example of a conventional thermal recording apparatus,
FIG. 4 is a time chart for explaining the operation of the circuit of FIG. 11 ... heating resistor, 12 ... driver, 13 ... enable circuit, 14 ... clock selection circuit, 15 ... latch circuit, 16 ...
... Data shift register.

Claims (1)

(57) [Claims] In an image recording apparatus having a recording element arranged in a row and a driving element connected to each of the recording elements, and applying a predetermined driving signal to the driving element to record image information, A drive signal transfer unit that sequentially supplies a predetermined drive signal to the drive element at a transfer speed based on a clock signal; and a clock selection unit that selects a clock signal according to image information and outputs the clock signal to the drive signal transfer unit. And a transfer device for changing a transfer speed of a drive signal according to image information to be recorded. 2. The clock signal input to the drive signal transfer unit is
The thermal recording apparatus according to claim 1, wherein clock signals having different frequencies can be selected and input. 3. The thermal recording apparatus according to claim 1, wherein the enable signal input to the drive signal transfer unit is one clock or more. 4. 2. The thermal recording apparatus according to claim 1, wherein a signal at the last stage of the drive signal transfer unit is a write end signal for one line. 5. 2. The heat-sensing device according to claim 1, wherein the clock for driving bits to be recorded in the drive signal transfer unit has a lower frequency, and the clock for driving non-recording bits has a higher frequency. Recording device.