JP2006335026A - Thermal recording device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a thermal recording device having a thermal head, which can suppress a density unevenness generates by a temperature dispersion due to the position in a thermal head, and can record a thermal image of high definition and high quality. <P>SOLUTION: The thermal recording device is used to record an image on a thermal recording material and includes a control means which controls the recording density to thermal recording material based on the measuring result of the recording density of a recording area (density patch) which is provided in the rear end of a thermal recording material to be recorded and records the density defined beforehand. This control means is preferably used such that the temperature in the width direction of the thermal head 66 is controlled individually at each of the positions properly divided in response to the printing width (size) of the thermal recording material. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a thermal recording apparatus using a thermal head. More specifically, when the temperature of each part of the thermal head becomes non-uniform depending on the usage conditions, etc., the occurrence of density unevenness due to this, etc. The present invention relates to a thermal recording apparatus having a function for preventing the above-described problem.

Image recording (hereinafter also referred to as thermal image recording) using a thermal recording material in which a thermal recording layer is formed on a film or the like as a support is used for recording an ultrasonic diagnostic image or the like.
Since this thermal image recording has advantages such as no need for wet development and easy handling, in recent years, not only small-sized image recording such as ultrasonic diagnosis, but also CT diagnosis and MRI diagnosis. In applications where large and high-quality images are required, such as X-ray diagnosis, the use for image recording for medical diagnosis is progressing.

As is well known, thermal image recording is a thermal head having a glaze (heating element) in which heating resistors constituting a heating element are arranged in one direction for recording an image by heating a thermal recording layer of a thermal material. With the glaze pressed slightly against the heat-sensitive recording material (heat-sensitive recording layer), the energy was applied to each heating element of the glaze while relatively moving both in the direction perpendicular to the extending direction of the glaze. Then, by heating according to the recorded image, the heat-sensitive recording layer of the heat-sensitive recording material is heated imagewise to perform image recording.
Particularly in recent years, in applications requiring high image quality such as medical use, the energy applied to each glaze heating element is controlled by modulating the application time under a constant applied voltage. Often done by pulse width modulation.

  By the way, when performing thermal recording on a thermal recording material (thermal recording layer) by applying a voltage to the thermal head, the thermal head generates heat to the extent that cooling is required. Normally, a cooling fan (exhaust fan) is arranged in the vicinity of the thermal head so that the temperature of the thermal head does not exceed a predetermined temperature, and heat generated from the thermal head is removed (for example, Patent Documents). 1).

Japanese Patent Laid-Open No. 10-230635

  By the way, in recent years, in a thermal image recording apparatus for medical use, as the application expands, images of different sizes are often performed by one thermal image recording apparatus (so-called multi-size recording). The problem in this case is that the thermal head to be energized becomes partial due to the change in size, and accordingly, a large temperature distribution is generated in the thermal head.

  When such a temperature distribution occurs in the thermal head, the density of the image recorded on the thermal recording material varies depending on the location, and as a result, density unevenness occurs. Such a variation in the density of recorded images is required when high-quality image recording is required as in medical use, particularly in the case of recording high-definition halftone images. Since an image is required, it has been a serious problem that hinders image observation and leads to a diagnosis error.

  The present invention has been made in view of the above circumstances, and an object of the present invention is to solve the above-described problems of the prior art, and in a thermal recording apparatus using a thermal head, a temperature difference depending on the position occurs in the thermal head. Accordingly, it is an object of the present invention to provide a thermal recording apparatus capable of preventing a density variation from occurring and stably recording a high-quality and high-quality thermal image.

  In order to achieve the above object, a thermal recording apparatus according to the present invention is a thermal recording apparatus that records an image on a thermal recording material by applying a voltage to a thermal head in accordance with image data, and is to be recorded. Control having a function of controlling the recording density on the thermal recording material based on the measurement result of the recording density of a recording area (density patch) for recording a predetermined density provided at the rear end of the thermal recording material Means are provided (claim 1).

Here, it is preferable that the control means individually controls the temperature along the width direction of the thermal head for each divided position according to the print width (size) of the thermal recording material. (Claim 2).
Further, it is preferable that the control means controls the temperature along the width direction of the thermal head based on the measurement result of the recording density of the recording area (density patch) for recording the predetermined density. (Claim 3).

The control means controls the temperature along the width direction of the thermal head based on the outside temperature and / or the ambient temperature of the thermal head, in addition to the measurement result of the recording density of the recording area (density patch). It is preferable that the temperature of the thermal head used by the control means is the temperature of the heat sink of the thermal head (Claim 5).
For the temperature control by the control means, a method of individually controlling a plurality of cooling fans arranged in the width direction of the heat-sensitive recording material can be suitably used.

  According to the present invention, a thermal recording capable of stably recording a high-quality and high-quality thermal image by preventing a temperature difference depending on a position in the thermal head and thereby preventing a density variation due to the temperature difference. There is a remarkable effect that the device can be realized.

  Hereinafter, the present invention will be described in detail based on preferred embodiments shown in the drawings.

FIG. 1 shows a schematic cross-sectional schematic diagram of a thermal recording apparatus according to an embodiment of the present invention.
A thermal recording apparatus (hereinafter simply referred to as a recording apparatus) 10 shown in FIG. 1 performs thermal image recording on a thermal recording material (hereinafter simply referred to as a thermal material) A which is a cut sheet of a predetermined size such as B4 size. There are a loading unit 14 in which a magazine 24 in which the thermal material A is accommodated is loaded, a supply transport unit 16, a recording unit 20 that records a thermal image on the thermal material A by a thermal head 66, and a discharge unit 22.

  As will be described later (see FIG. 3), the thermal head 66 of the recording unit 20 is connected to the recording control unit 84 and the fan control unit 74 via the overall control unit 78, the image processing unit 80, and the image memory 82. Further, a data storage unit 86 is connected to the image processing unit 80. Further, the discharge unit 22 is provided with a concentration measurement unit 18 that measures the concentration of the concentration patch recorded on the heat-sensitive material A.

  In such a recording apparatus 10, the thermal material A is conveyed to the recording unit 20 by the supply conveyance unit 16 and the thermal head 66 is pressed against the thermal material A while the longitudinal direction of the glaze 66a (in FIGS. 1 and 2). A thermal image is recorded on the thermal material A by conveying the thermal material A in a direction orthogonal to the direction perpendicular to the paper surface and heating each heating element in accordance with the recorded image.

The heat-sensitive material A is formed by forming a heat-sensitive recording layer on one surface of a transparent polyethylene terephthalate (PET) film or the like as a support or paper.
Such a heat-sensitive material A is usually a laminated body (bundle) of a predetermined unit such as 100 sheets and is packaged by a bag or a belt. In the illustrated example, the heat-sensitive recording layer remains in a bundle of a predetermined unit. Are stored in the magazine 24 of the recording apparatus 10 with the bottom surface being taken out from the magazine 24 one by one and used for thermal image recording.

The magazine 24 is a housing having a lid 26 that can be freely opened and closed. The magazine 24 stores the heat-sensitive material A and is loaded into the loading unit 14 of the recording apparatus 10.
The loading unit 14 includes an insertion port 30 formed in the housing 28 of the recording apparatus 10, a guide plate 32, guide rolls 34 and 34, and a stop member 36. The magazine 24 has the lid 26 side first. The recording device 10 is inserted into the recording device 10 through the insertion port 30, and is guided to the stop plate 36 while being guided by the guide plate 32 and the guide roll 34, so that the recording device 10 is loaded at a predetermined position.

  The supply / conveyance means 16 takes out the heat-sensitive material A from the magazine 24 loaded in the loading section 14 and conveys it to the recording section 20, and is a single-wafer mechanism that uses a suction cup 40 that adsorbs the heat-sensitive material A by suction. A means 42, a conveyance guide 44, and a regulating roller pair 52 positioned at the exit of the conveyance guide 44 are included.

  The conveying means 42 includes a conveying roller 46, a pulley 47 a coaxial with the conveying roller 46, a pulley 47 b and a tension pulley 47 c connected to a rotational drive source, an endless belt 48 stretched around these three pulleys, The nip roller 50 is pressed against the roller 46, and the tip of the heat-sensitive material A sheeted by the suction cup 40 is sandwiched between the conveyance roller 46 and the nip roller 50 to convey the heat-sensitive material A.

  When an instruction to start recording is issued in the recording apparatus 10, the lid body 26 is opened by an unillustrated opening / closing mechanism, and a single-wafer mechanism using the suction cup 40 takes out one thermal material A from the magazine 24, and the leading end of the thermal material A Is supplied to the conveying means 42 (conveying roller 46 and nip roller 50). When the heat-sensitive material A is sandwiched between the conveying roller 46 and the nip roller 50, the suction by the suction cup 40 is released, and the supplied heat-sensitive material A is guided to the regulating roller pair 52 by the conveying means 42 while being guided by the conveying guide 44. Be transported. Note that when the heat-sensitive material A used for recording is completely discharged from the magazine 24, the lid 26 is closed by the opening / closing mechanism.

The distance from the conveying means 42 to the regulating roller pair 52 defined by the conveying guide 44 is set slightly shorter than the length in the conveying direction of the thermal material A, and the tip of the thermal material A is moved by the conveying means 42. Although the control roller pair 52 is reached, the control roller pair 52 is initially stopped, and the tip of the heat-sensitive material A is stopped and positioned here.
When the tip of the heat sensitive material A reaches the regulating roller pair 52, the temperature of the thermal head 66 (glaze 66a) is confirmed. If the temperature of the thermal head 66 is a predetermined temperature, the heat sensitive by the regulating roller pair 52 is detected. The conveyance of the material A is started, and the heat sensitive material A is conveyed to the recording unit 20.

FIG. 2 shows a schematic diagram of the recording unit 20. The recording unit 20 includes a thermal head 66, a platen roller 60, a cleaning roller pair 56, a guide 58, a cooling fan 76 (see FIG. 1) for cooling the thermal head 66, and a guide 62.
The thermal head 66 performs, for example, thermal image recording with a recording (pixel) density of about 300 dpi capable of image recording up to a maximum B4 size, and serves as a heating element that performs thermal recording on the thermal material A. Heat resistance of alumina ceramics or the like formed with glaze 66a in which many heating resistors 90 (see FIGS. 4A and 4B) are arranged in one direction (longitudinal direction perpendicular to the paper surface in FIGS. 1 and 2). Ceramic substrate 66b made of an electrically insulating material having excellent properties, a base 66d made of a metal plate such as aluminum laminated on the surface of ceramic substrate 66b opposite to glaze 66a, and the other surface of base 66d And a heat sink 66c made of metal such as aluminum having a large number of radiating fins (see FIG. 3). The thermal head 66 is supported by a support member 68 that is rotatable about a fulcrum 68a in the direction of arrow a and in the opposite direction.

Next, the platen roller 60 rotates at a predetermined image recording speed while holding the heat-sensitive material A in a predetermined position, and conveys the heat-sensitive material A in a direction orthogonal to the main scanning direction (the direction of arrow b in FIG. 2). .
The cleaning roller pair 56 is a roller pair composed of an adhesive rubber roller 56a, which is an elastic body, and a normal roller 56b. The adhesive rubber roller 56a removes dust and the like adhering to the heat-sensitive recording layer of the heat-sensitive material A, and glaze 66a. This prevents dust from adhering to the image and from adversely affecting image recording.

In the illustrated recording apparatus 10, before the heat-sensitive material A is conveyed, the support member 68 is rotated upward (in the direction opposite to the arrow a direction), and the thermal head 66 (glaze 66 a) and the platen roller 60. There is no contact.
When the conveyance by the regulating roller pair 52 is started, the heat sensitive material A is then sandwiched between the cleaning roller pair 56 and further conveyed while being guided by the guide 58. When the leading end of the heat sensitive material A is conveyed to the recording start position (position corresponding to the glaze 66a), the support member 68 rotates in the direction of arrow a, and the heat sensitive material A becomes the glaze 66a of the thermal head 66 and the platen roller 60. And the glaze 66a is pressed against the recording layer, and the heat-sensitive material A is held at a predetermined position by the platen roller 60, while the platen roller 60, the regulating roller pair 52, and the conveying roller pair 63 are in the direction of arrow b. It is conveyed to.
Along with this conveyance, the thermal image recording is performed on the thermal material A by heating each heating resistor 90 of the glaze 66a in accordance with the recorded image.

FIG. 3 is a schematic perspective view of the thermal head 66 and its control block diagram, and FIGS. 4A and 4B are a partial sectional schematic view and a partial top schematic view showing details of the glaze 66a portion of the thermal head 66, respectively. Indicates.
As shown in FIG. 3, the thermal head 66 has the glaze 66a, the ceramic substrate 66b, the heat sink 66c, and the base 66d as described above. Further, as described above, the thermal head 66 is connected to the image processing unit 80, the image memory 82, and the recording control unit 84 via the overall control unit 78, and the data processing unit 80 is connected to the image processing unit 80. Has been.

  In the recording apparatus 10 according to the present embodiment, for example, before starting the actual recording of the thermal recording, recording is performed on the thermal material A that should be called a dummy, and at the rear end portion of the thermal material A, as shown in FIG. Dummy printing for detecting the temperature of the thermal head 66 is performed. The areas 96a, 96b,... Where the dummy printing is performed are hereinafter referred to as defined density patches. It should be noted that the patch (region) having a specified density referred to here is precisely an “area to which energy necessary for recording at a specified density is given”.

  As described in detail later, the specified density patches 96a, 96b,... Described above are density measuring units 18 each including a light emitter 18a and a light receiver 18b provided in the discharge unit 22 of the recording apparatus 10. The density during the recording is measured, and the temperature at the time of recording (that is, the temperature of the thermal head 66) is estimated by referring to a conversion table or the like obtained in advance.

  Then, the temperature of the thermal head 66 converted from the density measurement values by these density measurement units 18 (more specifically, the heating resistor 90 (see FIGS. 4A and 4B) of each notch portion). Temperature) is detected, and the detection result is transmitted to the overall controller 78 as shown in FIG. The overall control unit 78 receives the detection result and controls the cooling fan 76 corresponding to each density patch patch 96a, 96b,... As described later.

As shown in FIG. 4A, the glaze 66a of the thermal head 66 is a heat storage section that is formed on the ceramic substrate 66b and stores heat generated by the heating resistor 90, and has a height (glaze height) H. , Made of glass or polyimide resin in a bowl shape (semicircle or semi-elliptical shape) having a width (glaze width) W. A heating resistor 90 is laminated on the glaze 66a. As shown in FIG. 4B, the heating resistor 90 extends on the ceramic substrate 66b on both sides of the glaze 66a, and is made of a strip-shaped tantalum nitride (Ta ₂ N) having a width (heater width) s. For each pixel, for example, when the recording pixel density is 300 dpi, the pixels are arranged as many as necessary for one line at intervals of 84.7 μm.

On the heating resistor 90, a pair of electrodes 92a and 92b made of aluminum, copper or the like and having substantially the same width are laminated except the central portion. Between the electrode 92a and the electrode 92b, the heating resistor 90 is not covered over the length (heater length) L, and the heating resistor 90 is exposed, and this exposed portion corresponds to the glaze 66a. It corresponds to a dot of one pixel which is on the top and applies heat generated by the heating resistor 90 through the protective film 94 to cause the thermal material A to develop color. On the entire surface of the pair of electrodes 92a and 92b, the exposed heating resistor 90, the glaze 66a and the ceramic substrate 66b, silicon carbide (SiC), silicon nitride (SiN), tantalum pentoxide (Ta ₂ O ₅ ), SiAlON ( A protective film 94 having a film thickness (protective film thickness) d made of a material having excellent wear resistance such as nitrogen-containing glass such as commonly known sialon) or LaSiON (commonly known as Lacion) is laminated. The portion of the glaze 66a of the thermal head 66 is manufactured by a manufacturing technique such as a semiconductor device, for example, CVD, PVD, sputtering, vapor deposition, photolithography or the like. Therefore, since the protective film 94 is deposited on the electrodes 92a and 92b formed by etching or the like, a similar concave portion is formed on the top of the protective film 94 by the concave portion between the electrodes 92a and 92b. The thermal head 66, particularly the glaze 66a, is basically configured as described above.

  As described above (see FIG. 3), the recording control system of the thermal head 66 is configured around the overall control unit 78, and performs image processing such as sharpness on the image data supplied from the image data source. The image processing unit 80 and the fan control unit 74 are configured. The image processing unit 80 includes an image memory 82 that stores image processed image data and the like, a recording control unit 84 that controls thermal recording by the thermal head 66 based on the image data, and an image processing unit 80. A data storage unit 86 for storing correction data for various image processing is connected.

Hereinafter, an outline of the operation of the recording apparatus 10 according to the present embodiment will be described.
First, image data from an image data source such as CT or MRI is sent to the image processing unit 80 as 10-bit (0 to 1023) digital data, for example.

  The image processing unit 80 is a combination of various image processing circuits and memories, receives image data from an image data source, and sharpness correction processing for emphasizing the contour of a thermal recording image on the image data. (Sharpness enhancement processing) and other adjustments to adjust the heat generation energy according to the γ value of the heat-sensitive material and the gradation correction for obtaining an appropriate image corresponding to the recording device, especially the thermal head, and the temperature of the heating element of the thermal head Temperature correction, shading correction that corrects density unevenness caused by variations in the longitudinal direction of the glaze of the thermal head, resistance value correction that corrects the difference in resistance value of each heating element, and thermal head power supply voltage drop due to changes in the recording pattern Regardless of the change, the image data corresponding to the same density is subjected to predetermined image processing such as black ratio correction for color development at the same density. Further formatted as necessary (scaling, frame allocation) performed, and outputs the image memory 82 as a heat-sensitive recording image data corresponding to the thermal recording with a thermal head 66.

In this way, image processing such as sharpness correction, gradation correction, temperature correction, shading correction, resistance value correction, and black ratio correction is supplied from the image data source R such as CT or MRI and is performed in the image processing unit 80. In addition, the thermal recording data corresponding to the thermal recording by the thermal head 66, which is formatted as necessary, is stored in the image memory 82.
The recording control unit 84 sequentially reads out thermal recording image data line by line in the longitudinal direction of the glaze 66a of the thermal head 66 from the image memory 82, and records signals corresponding to the read thermal recording image data (in the case of pulse width modulation, the image is converted into an image). A corresponding voltage application time) is output to the thermal head 66.

The heating resistor 90 provided for each pixel of the thermal head 66 generates heat according to the recording signal, and as described above, the thermal material A is conveyed in the direction of the arrow b by the platen roller 60 and the like, and thermal image recording is performed. Is done.
The thermal image recording performed here is performed by pulse width modulation, in which thermal recording is performed in an image-like manner by modulating the voltage application time according to the density under a constant voltage.
Note that the recording method to which the present invention can be applied is not limited to pulse width modulation, and may be intensity modulation in which a voltage is modulated according to the concentration under a certain application time.

  The thermal material A for which thermal image recording has been completed is transported to the platen roller 60 and the transport roller pair 63 while being guided by the guide 62 and discharged to the tray 72 of the discharge unit 22. The tray 72 is disposed outside the recording apparatus 10 from a discharge port (conveying roller pair 63 outlet side) formed in the housing 28, and the heat-sensitive material A on which the image is recorded is discharged to the outside through this discharge port. And taken out.

  The above description is a general operation description of the recording apparatus 10. In the range described so far, when multi-size recording or the like is performed, the heating history at the time of recording with each heating element of the thermal head 66 is described. As described above, there is a partial variation in the density of the thermal recording image obtained by this recording apparatus.

  For this reason, the present inventor corresponds to the temperature estimated from the concentration measurement results by the plurality of concentration measuring units 18 (here, five as an example) in the overall control unit 78 as shown in FIG. By controlling the five cooling fans 76a to 76e individually, the temperature at the time of recording of each heating element of the thermal head 66 is made substantially uniform, so that the density unevenness of the above-mentioned thermal recording image is reduced. I try to lose it.

  That is, the thermal head estimated based on the density measurement results of the five density patches 96a, 96b,... Recorded at the rear end of the heat-sensitive material A that has been recorded by the density measurement unit 18 described above. The cooling fans 76a to 76e disposed at the measurement positions are controlled independently according to the recording temperature of each heating element 66. In this control, on / off control of operation, control by changing the rotational speed (in this case, stepwise change and stepless change are possible) and the like are performed.

  In addition, with regard to how to respond to the temperature measurement result, it is possible to add a condition such as how to respond depending on whether or not a predetermined temperature is exceeded and whether or not the state has continued for a predetermined time or more. Various correspondence methods such as a method of dividing the temperature range into a plurality of stages and changing the correspondence depending on where the temperature range falls can be adopted.

An example of a specific operation flowchart of this control is shown in FIG.
In this example, a table (a plurality of intermediate tables) is first set that defines how to determine the temperature measurement result and the pattern of the cooling fan drive method (on-off control, rotation speed change, etc.). It is also possible to select from the above, and the corresponding operation (for example, the operation shown in this flowchart) is started.

  In this operation flowchart, first, the density of the specified density patches 96a, 96b,... Recorded at the rear end of the heat sensitive material A is individually measured by the density measuring unit 18, and this measurement is performed. From the result, the temperature at the time of recording of each heating element of the thermal head 66 is estimated (step 102), the timing for starting the cooling fan is obtained (step 104), and after the cooling fan is started, A check step (steps 106 to 118) for determining whether or not to continue driving (in other words, whether or not to stop) is appropriately performed, but this is an example, and various modifications are possible. It is.

  According to the recording apparatus (thermosensitive recording apparatus) shown in the above embodiment, a temperature difference due to the position in the thermal head is generated, thereby preventing density variation, and high image quality and high quality thermal sensitivity. An effect of realizing a recording apparatus capable of stably recording an image can be obtained.

  In other words, if there is no temperature difference due to the position as described above in the thermal head, the patches 96a, 96b,... With the specified density are originally recorded at a substantially uniform density. However, when there is a temperature difference depending on the position in the thermal head, the patches 96a, 96b,... Vary in density, and this is detected by the density difference.

  Here, the concentration measuring unit 18 has a transmissive configuration composed of a light emitter 18a and a light receiver 18b, but is not limited to this, and other configurations (for example, light emission) Needless to say, the reflector 18a and the light receiver 18b may be of a reflective type.

  According to the recording apparatus 10 according to the present embodiment, a table or the like that summarizes the correspondence between the density values of the patches measured by the five density measuring units 18 and the temperature of the thermal head from which the density is obtained. By converting the density value of the patch to the temperature of the thermal head using the conversion means, drive control of the cooling fan 76 (76a to 76e) is performed corresponding to this temperature. As the drive control method used here, various methods as described above can be used.

  According to the recording apparatus (thermosensitive recording apparatus) shown in the above embodiment, a temperature difference due to the position in the thermal head is generated, thereby preventing density variation, and high image quality and high quality thermal sensitivity. An effect of realizing a recording apparatus capable of stably recording an image can be obtained.

  The above embodiment shows an example of the present invention, and the present invention is not limited to the above embodiment, and various modifications and improvements are made without departing from the spirit of the present invention. Needless to say, it may be.

  For example, in the above embodiment, the temperature difference depending on the position in the thermal head thermal head is eliminated by a method of controlling the driving of a plurality of cooling fans 76 (76a to 76e). It goes without saying that the method may be used. Moreover, although the example which has arrange | positioned five measuring means for obtaining temperature information, such as a density | concentration measurement part with respect to the width direction of the heat sensitive material A was shown, this arrangement | positioning number is not limited to five pieces. Needless to say, an appropriate number may be arranged.

1 is a schematic configuration diagram of a thermal recording apparatus according to an embodiment of the present invention. FIG. 2 is a partial enlarged cross-sectional schematic diagram of a recording unit of the thermal recording apparatus shown in FIG. 1. FIG. 3 is a partially cutaway schematic perspective view of a thermal head including a control system block diagram used in the recording unit shown in FIG. 2. (A) And (b) is the partial expanded sectional schematic diagram and the partial upper surface schematic diagram which respectively show the structure of the thermal head shown in FIG. It is a figure which shows the recording condition of the recording material which concerns on other embodiment of this invention. It is a flowchart of the cooling fan operation control of the thermal recording apparatus which concerns on one Embodiment.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 (Thermal image) Recording apparatus 14 Loading part 16 Supply conveyance means 18 Density measurement part 18a Light emitter 18b Light receiver 20 Recording part 22 Discharge part 24 Magazine 26 Lid 28 Housing 30 Insertion port 32 Guide plate 34 Guide roll 36 Stop member 40 Suction cup 42 Conveying means 44 Conveying guide 48 Endless belt 50 Nip roller 52 Regulating roller pair 56 Cleaning roller pair 58, 62 Guide 60 Platen roller 63 Conveying roller pair 66 Thermal head 66a Glaze 66b Ceramic substrate 66c Heat sink 66d Base 68 Support member 72 Tray 74 Fan Control unit 76, 76a to 76e Cooling fan 78 Overall control unit 80 Image processing unit 82 Image memory 84 Recording control unit 86 Data storage unit 90 Heating resistor 92a, 92b Electrode 94 Protective film 96a, 96b,... Patch 102-120 Operation step A Heat sensitive (recording) material d Protective film thickness H Glaze height L Heater length p Pixel pitch s Heater width W Glaze width

Claims (6)

A thermal recording apparatus that records an image on a thermal recording material by applying a voltage to a thermal head according to image data,
The recording density on the thermal recording material is controlled based on the measurement result of the recording density of the recording area (density patch) for recording the predetermined density provided at the rear end of the thermal recording material to be recorded. A thermal recording apparatus comprising a control means having a function. The control means includes
The thermal recording apparatus according to claim 1, wherein the temperature along the width direction of the thermal head is individually controlled for each divided position according to the print width (size) of the thermal recording material. The control means includes
2. The thermal recording apparatus according to claim 1, wherein a temperature along the width direction of the thermal head is controlled based on a measurement result of a recording density of a recording area (density patch) for recording the predetermined density. The control means includes
The temperature along the width direction of the thermal head is controlled based on the outside air temperature and / or the ambient temperature of the thermal head in addition to the measurement result of the recording density of the recording area (density patch). 3. The thermal recording apparatus according to 3.   The thermal recording apparatus according to claim 4, wherein an ambient temperature of the thermal head used by the control unit is a temperature of a heat sink of the thermal head.   The thermal recording apparatus according to claim 2, wherein the temperature control by the control unit individually controls a plurality of cooling fans arranged in a width direction of the thermal recording material.

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