JPH11334125A - Thermal head device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance durability of a heating resistor without changing the size of a thermal head. SOLUTION: This thermal head device comprises a plurality of heating resistor arrays 2, 3 each consisting of a plurality of heating resistor units 2a, 3a provided on an insulation plate 1 in an identical line at equal intervals and a heating resistor drive controlling section 10 that controls recording of a predetermined image information by selectively switching on or off the heating resistor units 2a, 3a. A power source line 4 for individually connecting each of the heating resistor units 2a, 3a in the respective heating resistor arrays 2, 3 to a single power source 5 in parallel is provided. A switch 6 for selecting one of the heating resistor arrays 2, 3 is provided to the heating resistor arrays 2, 3. The switch 6 and power source line 4 are provided on the insulation plate 1.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a thermal head device, and more particularly to a thermal head device having a plurality of rows of heating resistors and used in a printer or a facsimile machine.

[0002]

2. Description of the Related Art Thermal heads, which are often used in printers and facsimile machines, record the image information by means of thermal energy selectively supplied in accordance with the image information, and have been used more frequently than before. JP-A-61-114
No. 863 shows an example.

As disclosed in Japanese Patent Application Laid-Open No. 61-114683, in a conventional thermal head, a plurality of rows of heating resistors are arranged on an insulating substrate. The power line P11 is selected to cause the first heating resistor row to generate heat, and the power line P12 is selected to cause the second heating resistor to generate heat.

Further, Nikkei Mechanical, May 30, 1994
As a well-known example described in FIG. 10 of P31 of the Japanese era, there are a plurality of inputting data corresponding to the common power supply line P1 and the image information to the first and second heating resistors formed every specific section. The data lines D1, D2, D3,.
Some of the above-described heating resistor arrays are alternately connected. When the common power supply line P1 is energized, the heat generated at a predetermined timing depends on the presence or absence of the image information data input from the data lines D1, D2, D3,. By heating the resistor, recording for one dot line is performed.

[0005]

However, in the thermal head of the above-mentioned conventional example, when a plurality of heating resistor rows are formed on the insulating substrate, the insulating substrate of the thermal head must be large in order to secure a power supply line. In addition, it is necessary to prepare the power supply for a plurality of columns, and it is difficult to reduce the size.

[0006] In addition, in the case where a dot break occurs in the heating resistor in the first and second heating resistor rows formed in every specific section, the quality of printing deteriorates, so that a thermal head situation may occur. There was a need for replacement, and there was a problem in durability.

[0007]

SUMMARY OF THE INVENTION It is an object of the present invention to provide a thermal head device capable of increasing the durability of a heating resistor without changing the size of the thermal head.

[0008]

In order to achieve the above object, according to the first aspect of the present invention, there is provided a heating resistor array having a plurality of unit heating elements provided at equal intervals on the same line on an insulating plate. In a thermal head device including a heating element drive control unit for selectively turning on and off each of the heating element rows to control ON / OFF of recording of predetermined pixel information, a plurality of heating element rows are arranged in parallel. In addition, a power supply line for individually connecting each of the unit heating elements of the plurality of heating resistor rows to one power supply unit in parallel is provided. Further, a changeover switch for selecting any one of the respective heating resistor arrays is provided in each heating resistor array. The changeover switch and the power supply line are provided on the above-mentioned insulating plate.

Therefore, according to the present invention,
When the thermal head is operated, for example, one of the heating resistor rows is selected by a changeover switch based on a command from a higher-level device, and each unit heating element of the heating resistor row is set in a state where it can be energized. Then, when given image information is given from the host device, each unit heating element of the heating resistor row is individually operated, and the recording operation of the image information is started.

Next, if at least one of the heating elements in one of the heating element arrays is broken, a changeover switch is activated based on a switching command from a host device, and the heating element array is operated. Can be switched from one heating resistor row to the other heating resistor row. Thereby, the recording operation of the image information sent from the host device is continued by the other heating resistor array.

As described above, even when two heating resistor arrays are provided, for example, the thermal head can be formed without increasing the number of power lines and changing the size of the insulating substrate by making the power lines common. By arbitrarily switching and selecting the heating resistor array, the life of the heating element can be extended at least twice, and the maintainability of the device is improved.

According to the second aspect of the present invention, there is provided a heating resistor array comprising a plurality of unit heating elements provided at equal intervals on the same line on an insulating plate, and each of the heating resistor arrays is selectively driven to conduct. In a thermal head device having a heating element drive control unit for controlling ON / OFF of recording of predetermined pixel information, a plurality of heating resistor rows are provided in parallel, and each unit of the plurality of heating resistor rows is provided. A power supply line is provided for individually connecting the heating elements to one power supply unit in parallel. Further, a changeover switch for selecting any one of the respective heating resistor arrays is provided in each of the heating resistor arrays described above.

The changeover switch and the power supply line described above are provided on an insulating plate. Further, the above-described heating element drive control section operates based on a command from a higher-level device, drives the above-described changeover switch, selects one of the above-described plurality of heating resistor rows, and enters an operating state. A configuration is provided in which a heating element row selection control function to be set is provided.

Therefore, according to the second aspect of the present invention,
In addition to functioning in the same manner as the first aspect of the present invention, the heating element drive control section is further operated to detect a disconnection accident of the unit heating element and to smoothly and quickly switch to another heating resistor array. Be executed.

According to a third aspect of the present invention, in the thermal head device according to the first or second aspect, a power supply line is provided between the respective heating resistor arrays. For this reason, the invention according to claim 3 functions in the same manner as the invention described in claim 1 or 2, and furthermore, the power supply line portion of the power supply line has the same length with respect to each unit heating element. In addition, it can be set short, which is convenient.

According to a fourth aspect of the present invention, in the thermal head device according to the first, second, or third aspect, the heating element drive control unit determines that a specific unit heating element of one of the heating element rows selected in advance is selected. A configuration is provided in which a heating element failure detection function is provided for detecting this when it has not been activated and transmitting it to the host device. Therefore, according to the fourth aspect of the invention, in addition to functioning equivalently to the above-described first, second, or third aspect, it is also possible to detect a failure of the operating heating resistor array in real time. There are advantages.

According to a fifth aspect of the present invention, in the thermal head device according to the first, second, or third aspect, the heating element drive control section controls the specific unit heat generation of one of the heating element rows selected in advance. A heating element failure detection function for detecting and transmitting the failure to the host device when the body does not operate; and immediately operating when the heating element failure detection function is activated, and replacing the heating resistor row with one of the heating resistor rows. And a failure switching control function for switching and controlling the other heating resistor array. Therefore, according to the fifth aspect of the present invention, in addition to functioning in the same manner as the first, second, or third aspect of the present invention, it is possible to detect a failure of the operating heating resistor array in real time, Further, there is an advantage that the switching can be smoothly performed.

[0018]

DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of the present invention will be described below with reference to FIG. In FIG. 1, reference numeral 1 denotes an insulating substrate. On the insulating substrate 1, a heating resistor array 2 including a plurality of unit heating elements (for one dot) 2a provided at equal intervals on the same line is provided.

The heating resistor array 2 is provided with another heating resistor array 3 having the same structure at a predetermined interval. Reference numeral 3a indicates a plurality of unit heating elements 3a provided in another heating resistor array 3.

Further, reference numeral 10 denotes a heating element drive control unit. The heating element drive control section 10 has a function of selectively conducting and driving each of the unit heating elements of the heating resistor array 2 or 3 to control ON / OFF of recording of predetermined pixel information.

In the present embodiment, the above-described heating resistor rows 2 and 3 are provided with two rows at predetermined intervals, but three or more rows may be provided. Reference numeral 4 denotes a power supply line for individually connecting the unit heating elements 2a and 3a of the plurality of heating resistor arrays 2 and 3 to one power supply unit 5 in parallel. The power supply line 4 is provided with power supply line portions 4A ₁ , 4A for the unit heating elements 2a, 3a of the heating resistor rows 2, 3.
A ₂ , 4A ₃ ,..., 4A _n , 4B ₁ , 4B ₂ , 4
B _3, ......, 4B _n portions are disposed therebetween of the heating resistor string 2.

Further, each of the feeder line portions 4A ₁ , 4A ₂ ,
4A ₃ ,..., 4A _n , 4B ₁ , 4B ₂ , 4B ₃ ,.
..., 4B _n is configured with a two feeder lines respectively one unit the heating element 2a, 3a. For example the feed line portion 4A ₁ is provided is divided into two hands at the feed side of the unit the heating element 2a (power input). by this,
Even if one of them is cut off, the other can be energized, and at this point the durability is increased.

A changeover switch 6 for selecting and heating one of the heating resistors 2 or 3 in the actual printing output is provided alongside the heating resistor arrays 2 and 3 described above. Have been. Symbols 6A ₁ , 6A ₂ , 6A ₃ , ...
..., 6A _n , 6B ₁ , 6B ₂ , 6B ₃ , ..., 6B
_n is a changeover switch 6 and the above-described heating resistor arrays 2 and 3
And a power supply control line connecting the unit heating elements 2a and 3a. The changeover switch 6 and the above-described power supply line 4 are provided on the insulating plate 1.

Further, the heating element drive control unit 10 described above
A heating element row selection control function that operates based on a command from the host device 7 and drives the above-described changeover switch 6 to select one of the plurality of heating resistors 2 and 3 and set the operating state. It has.

The heating element drive control section 10 immediately detects when a specific unit heating element of one of the heating element rows selected in advance does not operate, and transmits it to the host device. It has a detection function. In this case, the host device immediately instructs the above-described heating element drive control unit 10 to switch the heating resistor array, and upon receiving the command, the heating element drive control unit 10 immediately operates to change the heating resistor array to one side. The heating resistor array 2 is switched to the other heating resistor array 3. This operation is performed via the above-described changeover switch 6.

Here, the heating element drive control section 10 controls the specific unit heating element 2a of one of the heating element rows selected in advance.
In the above example, the heating element failure detection function is activated and the information is transmitted to the higher-level device when the upper-level device does not operate. You may comprise so that a body row may be switched.

That is, when the above-described heating element failure detection function is activated, the failure switching control function is immediately activated to switch and control the above-described heating resistor row from one heating resistor row 2 to the other heating resistor row 3. May be provided in the heating element drive control unit 10 described above. in this case,
The control content is always transmitted from the heating element drive control unit 10 to the host device.

Next, the operation of the above embodiment will be described.

In FIG. 1, when the thermal head is operated, the heating element drive control section 10 operates based on a command from a host device, and selects, for example, the heating resistor array 2 via the changeover switch 6 and selects the heating resistor. Each of the unit heating elements 2a of the body row 2 is set to a state in which the power can be supplied. Then, when predetermined image information is given from a higher-level device (not shown), each unit heating element 2a of the heating resistor array 2a operates individually, and the recording operation of the image information starts.

Next, when at least one of the unit heating elements 2a formed in the heating resistor array 2 is broken, the heating element failure detection function of the heating element drive control unit 10 is activated. Then, it is detected that the specific unit heating element 2a is not energized with respect to the energization information, and the information is communicated to the above-described upper device. Then, as described above, it operates immediately based on the switching command from the host device, and switches the heating resistor array from one heating resistor array 2 to the other heating resistor array 3 via the changeover switch 6. Thereby, the recording operation of the image information sent from the host device is continued by the other heating resistor array 3.

As described above, even if two heating resistor arrays are provided, for example, the thermal head can be formed without increasing the number of power lines and changing the size of the insulating substrate by making the power lines common. It is possible to extend the life of the heating element at least twice by switching and selecting the heating resistor row arbitrarily, thereby improving the maintainability of the apparatus.

[0032]

Since the present invention is constructed and functions as described above, according to this, a plurality of heating resistor arrays are provided, a power supply line is shared, and each heating resistor array is selectively used by switching. With this configuration, it is possible to form a thermal head without increasing the number of power supply lines and without changing the size of the insulating substrate, and to ensure quality reduction such as missing dots due to partial failure of the heating resistor array. It is possible to provide an unprecedented excellent thermal head device that not only can avoid the problem but also can improve the durability of the entire device and at the same time can improve the maintainability.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing an embodiment of the present invention.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Insulating board 2 One heating resistor row 2a, 3a Unit heating element 3 The other heating resistor row 4 Power supply line 5 Power supply unit 6 Changeover switch 10 Heating element drive control unit

Claims (5)

[Claims] 1. A heating resistor array comprising a plurality of unit heating elements provided at equal intervals on the same line on an insulating plate, and each of the heating resistor arrays is selectively driven to conduct predetermined pixel information. In a thermal head device comprising a heating element drive control unit for controlling the recording on / off, a plurality of heating resistor rows are provided in parallel, and each unit heating element of each of the plurality of heating resistor rows is connected to one. A power supply line that is individually connected in parallel to the power supply unit; and a changeover switch that selects any one of the heat generation resistor rows is provided in the heat generation resistor row, and the changeover switch and the power supply line are provided. Is provided on the insulating plate. 2. A heating resistor array comprising a plurality of unit heating elements provided at equal intervals on the same line on an insulating plate, and selectively driving each of the heating resistor arrays to conduct predetermined pixel information. In a thermal head device comprising a heating element drive control unit for controlling the recording on / off, a plurality of heating resistor rows are provided in parallel, and each unit heating element of each of the plurality of heating resistor rows is connected to one. A power supply line that is individually connected in parallel to the power supply section; a switch that selects any one of the heat-generating resistor rows is provided in each of the heat-generating resistor rows; A line is provided on the insulating plate, and the heating element drive control unit operates based on a command from a higher-level device to drive the changeover switch to drive any one of the plurality of heating resistor arrays. Select and set to active Thermal head apparatus characterized by comprising a heat element row selection control function. 3. The thermal head device according to claim 1, wherein the power supply line is provided between the respective heating resistor arrays. 4. The heating element drive control section has a heating element failure detection function for detecting when a specific unit heating element of one of the preselected heating element arrays does not operate and transmitting it to a host device. 4. The thermal head device according to claim 1, wherein the thermal head device is provided. 5. A heating element drive control section for detecting when a specific unit heating element of one of the heating resistor rows selected in advance does not operate, and transmitting it to a higher-level device; A failure switching control function that is activated immediately when the heating element failure detection function is activated and switches and controls the heating resistor row from one heating resistor row to the other heating resistor row. The thermal head device according to claim 1, 2 or 3, wherein: