JPS6335433B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Technical Field of the Invention] The present invention relates to a thermal printer with improved thermal responsiveness.

[Technical background of the invention and its problems]

Arranging a plurality of heating resistance elements in one example or in multiple rows,
In thermal printers, which print and record by passing current through each element in accordance with recording information signals to generate a thermal pattern on thermal paper or transfer ribbon, the thermal response of the heating resistive element is is known to be a problem.

That is, if the heating resistor element is simply turned on or off depending on whether the input recording information signal is a mark signal or a space signal, the first pixel when the space signal transitions to the mark signal will be:
Since the element does not reach a sufficient temperature, the recording density drops extremely, resulting in so-called white spots. In order to avoid this, if the current energy applied during the mark signal is increased, the element will become too hot when the mark signal is continuous, and the first pixel when the next space transition will be recorded. A snoring phenomenon occurs.

As a way to solve this problem,
There is No. 48631 "Dot printing method". this is,
When the previous signal to the same printing element is a space signal and the next signal is a mark signal, a control signal to perform additional printing is supplied, and when mark signals continue, regular printing is performed. An extra current is passed only when the signal changes to a mark signal to speed up the response, and no extra current is passed when the mark signal continues to prevent the element from becoming excessively hot.

However, this method has the following problems. First, a means for detecting the transition of the recorded information signal from the space signal to the mark signal is required, which makes the apparatus complicated and expensive. In other words, in order to detect the transition from a space signal to a mark signal for each element, it is necessary to compare corresponding pixel components of adjacent scanning lines, which requires a large-capacity memory element. Second, since the heating resistor element is energized only when the recording information signal is a mark signal, the ambient temperature of the heating resistor element varies depending on the pattern of the recording information signal, causing global density unevenness.

As a conventional technique known as a countermeasure against this problem, there is a method of controlling the pulse width of a drive pulse applied to a thermal head according to the density of the drive pulse, as shown in JP-A-51-16935 "Thermal Printer". A method of controlling the energization pulse width (controlling energization during printing) using a signal from a temperature detection element attached to a thermal head, disclosed in No. 1972-29648 "Print density control device for thermal printing", JP Akira
No. 52-9442 "Thermal head printing density control method"
The print pulse width,
There are methods of digitally controlling the amplitude. However, these methods are effective only after all actual printing has been done to some extent, and uneven density still occurs when the apparatus is started up or restarted after being stopped. In order to solve this problem, it is necessary to actively control the temperature around the head without depending on the recording information signal.

[Purpose of the invention]

The purpose of the present invention is to improve the recording speed by substantially speeding up the thermal response without detecting changes in the recorded information signal pattern, and further to alleviate the occurrence of global density unevenness that depends on the recorded information signal pattern. We are here to provide you with a thermal printer that can.

[Summary of the invention]

The present invention starts at the start point of one pixel recording period and
Means for generating a first pulse that ends within a pixel recording period and a second pulse that starts within one pixel recording period and ends at the end point of one pixel recording period is provided, and the recording information signal is a mark signal. By selecting the first pulse as the energizing pulse for the heating resistor element, the period of the first pulse (first period)
For the heating resistor element whose recorded information signal is a space signal, the second pulse is selected as the energization pulse, and the energization is performed during the period of the second pulse (second period). This is how it was done.

In other words, the heat generating resistive element corresponding to the pixel of the space signal is also energized, but energy is given to an extent that does not result in recording. Therefore, when the space signal is continuous, heat is generated but the state is maintained in which no recording occurs. . When transitioning from a space signal to a mark signal, the remaining heat due to the energized power in the second period, which is after the one pixel recording period of the previous space signal, and the mark signal, which is earlier than the one pixel recording period. Recording is performed by superimposing the heat generated by the applied electric power during the first period.

〔Effect of the invention〕

According to the present invention, when the recorded information signal transitions from a space signal to a mark signal, the thermal response is substantially reduced due to the superposition of residual heat caused by the energized power during the second period of the previous one-pixel recording period. Since the recording speed is increased, white spots will not occur even if the recording speed is increased, and since there is no such heat superimposition effect when mark signals are continuous, it is possible to avoid the tailing phenomenon due to overheating. Therefore, not only high-speed recording is possible, but also a constant recording density can be obtained regardless of the pattern of the recording information signal. In this case, changes in the recorded information signal pattern. In other words, there is no need to detect the change from a space signal to a mark signal, and it is sufficient to simply control the energization period depending on whether the recording information signal of the scanning line to be recorded is a space signal or a mark signal. can be realized with a simple and inexpensive configuration that does not include a large-capacity memory element or the like.

In addition, since electricity is applied even during space signals, global density unevenness due to the recording information signal pattern can be reduced compared to a case where electricity is applied only during mark signals. This concentration unevenness can also be actively compensated by using the second period) and controlling the length of this period according to the ambient temperature of the heating resistor element.

[Embodiments of the invention]

FIG. 1 is a configuration diagram of a drive circuit section of a thermal printer according to an embodiment of the present invention, and FIG. 2 is a time chart for explaining its operation. In the figure, recording information signals corresponding to pixels corresponding to each of the heat generating resistive elements 8 arranged in an example are given to the recording information signal input terminal 1 in parallel, for example, and these recording information signals are applied to the clock signal input terminal 2. It is stored in latch 3 by the applied clock signal.
Each output of the latch 3 is input to a drive circuit 4, respectively.

The drive circuit 4 is configured as follows. That is, the output of latch 3 is the 3-input AND gate 1.
2 and 13 directly and via the inverter 11. and gate 12,1
The energization control signal given to the control signal input terminal 5 is commonly inputted to the second input terminal of 3, and the first and second pulse generators 6 and 7 are inputted to the third input terminal.
output pulses are respectively input.

Now, assuming that the recording information signal appearing at one output of the latch 3 is shown in FIG. 2a, the first and second pulse generators 6 and 7 are driven by the clock signal CK.
As shown in FIGS. 2b and 2c, in the earlier period T ₁ and the later period T ₂ of the one pixel recording period T, respectively,
A first pulse that starts at the start point of one pixel recording period T and ends within one pixel recording period T, and a second pulse that starts within one pixel recording period T and ends at the end point of one pixel recording period T. occurs. Here, as shown in the figure, the time length of the second period _T2 is shorter than the time length of the first period _T1 . Therefore, if the energization control signal input to the terminal 5 is always at the "1" level, the output of the OR gate 14 that combines the outputs of the AND gates 12 and 13 will contain the recording information signal shown in FIG. Corresponding to the "1" level (mark signal) and "0" level (space signal), the signal has a pattern as shown in FIG. A signal is obtained that is at the "1" level only during the period _T1 , and when it is a space signal, is at the "1" level only during the period _T2 . That is, for a heating resistor element whose recording information signal is a mark signal, the first pulse, which is the output pulse of the first pulse generator 6, is selected as the energization pulse, and the recording information signal is a space signal. For the resistive element, the second pulse, which is the output pulse of the second pulse generator 7, is selected as the energizing pulse. And or gate 1
The energizing pulse output from 4 is the drive element 15.
The voltage is applied to each end of the heating resistor element 8 via.
The other ends of the heat generating resistor elements 8 are commonly connected to a drive power supply terminal 9.

In this way, the heating resistor element 8 is energized while the output of the corresponding OR gate 14 is at the "1" level, and its thermal response waveform becomes as shown in FIG. 2e. The level indicated by the dotted line in Fig. 2e is the temperature threshold at which recording is performed or not, and as can be seen from the figure, the recording information signal in Fig. 2a is followed by a space signal, and in Fig. 2c When an isolated waveform appears at the output of the OR gate 14 in FIG. Due to the superposition of the residual vapor caused by the mark signal and the temperature rise caused by the pulse corresponding to the mark signal, the temperature exceeds the threshold value and recording is performed. When the mark signals are continuous, only the pulses shown in FIG. It will never be.

In the above explanation, the output pulse width of the second pulse generator 7 was explained as constant, but if it is made variable and controlled according to the ambient temperature of the heating resistor element 8, the recording density can be made even more uniform. effective.
That is, for example, a mono-multivibrator whose pulse width can be changed by an external control signal is used as the second pulse generator 7, and the heating resistor element 8 is used as the second pulse generator 7.
By giving the output of the temperature sensor 10 installed near the temperature sensor 10 as a control signal to the second pulse generator 7, the output pulse width becomes narrower as the surrounding temperature of the heating resistor element 8 becomes higher, and as the surrounding temperature becomes lower. For example, control is performed so that the output pulse width becomes wider. Considering the fact that most of the output images of printers are occupied by space, performing this type of control is essentially effective in controlling the ambient temperature of the heating resistor element 8 observed by the temperature sensor 10, regardless of the pattern of the recorded information signal. It has the effect of keeping constant. As a result, the residual heat during the transition from the space signal to the mark signal can be kept almost constant, and recording can be performed at a constant density regardless of the environmental temperature or the pattern of the recording information signal.

FIG. 3 shows an example of the configuration of a control circuit section attached to the drive circuit section of FIG. 1 in the case of a character printer. The code memory 31 stores a code string corresponding to a character string to be printed.
A clock signal is generated from the clock generator 32 at a period corresponding to one pixel row of a character, and the counter 33 counts the number of pixel rows for one character.
Character codes are output at intervals corresponding to the count. This character output is decoded by a decoder 34, and one output of the decoder 34 is supplied to a character pattern memory 35 as an address signal. Another output of the decoder is a signal indicating that the character code is not a space signal, and is a signal at terminal 5 in Figure 1.
is supplied as an energization control signal. The clock signal output from the clock generator 32 drives the character pattern memory 35 to output a pattern according to the address signal for each pixel column as shown at 41 in FIG. The output of this character pattern memory 35 is inputted to terminal 1 in FIG. 1 as a recording information signal. On the other hand, the output of the clock generator 32 is also supplied to the terminal 2 in FIG.

In this way, the terminal 5 in FIG. 1 is sent to the "0" level and "1" level, respectively, for each character period as shown by 42 in FIG. An energization control signal indicated as a level is supplied, which causes AND gates 12,1
If the entire area of one character is a space, the output of 3 becomes a "0" level, and the current of the heating resistor element 8 is completely cut off. In this way, unnecessary energization during the space signal period when one character period is all spaces can be eliminated, and wasteful power consumption can be suppressed.

As described above, according to the present invention, the change from a space signal to a mark signal in a recorded information signal can be substantially detected by using a simple circuit configuration including only a gate circuit, which does not require any particular detection of a change in a recording information signal from a space signal to a mark signal. It is possible to avoid white spots at times and tailing phenomena when changing from a mark signal to a space signal, thereby making it possible to improve the recording speed and make the recording density uniform. Furthermore, the temperature around the heating resistor element can be actively maintained at a constant temperature by actively utilizing the energization during the space signal. On the other hand, if power consumption during space signals is a problem, energization during space signals can be interrupted by a simple means of adding an energization control signal commonly applied to a plurality of heating resistive elements.

The present invention is not limited to the embodiments described above, and various modifications can be made. For example, in the embodiment, a single pulse is used to energize both the space signal and the mark signal period. Of course, even if energization is added at a later period of the one pixel recording period during the mark signal, it is possible to achieve the same effect in terms of thermal response as in the embodiment. It is.

In addition, as a control to suppress excessive power consumption, an example was shown in which the energization is cut off by the energization control signal during both the space signal and the mark signal.
The energization may be cut off only during the space signal. Furthermore, although the example of a character printer has been illustrated as an energization control signal, it is obvious that in a facsimile or the like, for example, if there is layout information of a print recording area, it can be used as an energization control signal. In short, energization may be controlled by a global energization control signal that corresponds to the entire heat generating resistor element array or to each of a plurality of blocks, without directly responding to changes in the recording information signal pixel by pixel.

[Brief explanation of drawings]

FIG. 1 is a configuration diagram of a drive circuit section of a thermal printer according to an embodiment of the present invention, FIG. 2 is a time chart for explaining its operation, and FIG. 3 is a configuration diagram of a control circuit section of the thermal printer. , FIG. 4 is a diagram showing a recording pattern for explaining the operation. 1... Recording information signal input terminal, 2... Clock signal input terminal, 3... Latch, 4... Drive circuit,
5... Energization control signal input terminal, 6, 7... Pulse generator, 8... Heat generating resistor element, 9... Drive power supply terminal, 10... Temperature sensor.

Claims (1)

[Scope of Claims] 1. A thermal printer comprising a plurality of arrayed heat generating resistive elements and a driving means for energizing and driving these heat generating resistive elements in accordance with a recording information signal consisting of a mark signal and a space signal, The driving means includes means for generating a first pulse that starts at the start point of one pixel recording period and ends within one pixel recording period, and means that starts within one pixel recording period and ends at the end point of one pixel recording period. means for generating a second pulse to generate a second pulse, and selecting the first pulse as an energization pulse for a heating resistor element whose recording information signal is a mark signal, and selecting the first pulse as an energization pulse for a heating resistor element whose recording information signal is a space signal; A thermal printer comprising: means for selecting the second pulse as the energizing pulse; and means for energizing the heating resistor in accordance with the energizing pulse selected by the means. 2. The thermal printer according to claim 1, wherein the pulse width of the second pulse is shorter than the pulse width of the first pulse. 3. The thermal printer according to claim 1, wherein the pulse width of the second pulse is controlled according to the ambient temperature of the heating resistor element. 4. The driving means is controlled so as not to energize the heating resistor element when one character period of the recorded information signal is entirely a space signal. thermal printer.