JP2005271525A - Business form sheet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a form sheet which is printed with character information and a bar code read by an optical reader by heating, which facilitates the optical reading of the character information, and which enables the bar code to be printed by heating with a high degree of accuracy. <P>SOLUTION: A tailing color-development preventing layer 6 with a thickness of 0.5-3.0 μm, which is constituted by being coated with ink containing no pigment, is provided on the surface of a bar code printing area 5a. The ink is equipped with the characteristics of setting a tack value to be in the range of 1.0-3.0, and setting a coefficient of thermal conductivity after curing to be in the range of 0.13-0.30 W/K×m. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a form paper suitable for high-precision barcode printing by a thermal printer.

  For meter reading work such as gas, electricity, water, etc., it is possible to create meter reading slips on the spot, and handy terminals with excellent portability and convenience are widely used. By using the thermal printer, the thermal coloring layer of the form paper made of thermal recording paper is colored and printed, so that a fee payment slip with the required information displayed as a barcode is created along with the meter reading slip ( For example, see Patent Document 1).

  At the time of meter reading, a bill payment slip that displays the customer number, payment amount, payment deadline, billing date, receiving financial institution code, billing company code, and other required information in bar code is created on the handy terminal. A payment method that allows a customer to read the bar code displayed on the store side with an optical reader and make payment by bringing the fee payment slip to a convenience store where the POS terminal is installed. It is.

By the way, a bar code expresses required information consisting of numbers, alphabets, symbols, etc. by alternately arranging a plurality of types of black bars and white spaces having different widths in a predetermined combination pattern. Are classified into a binary level (binarization level) and a multi-level according to the types of black bars and white spaces which are the minimum units constituting the. As shown in FIG. 4 (a), the binary-level bar code includes a narrow black bar (NB: narrow bar), a thick black bar (WB: wide bar), a thin white space (NS: narrow space), and a thick white space (WS). : Wide bar), two types of black bars and white spaces with different widths are used. These fine black bars (NB) and white spaces (NS), thick black bars (WB) and white spaces (WS). The width ratio is NB: WB = NS: WS = 1: 2-3
It is stipulated. That is, when the width ratio of the fine black bar (NB) and the fine white space (NS) is 1, the width ratio of the thick black bar (WB) and the thick white space (WS) may be in the range of 2-3. The width ratio has a wide allowable range. CODE39, NW-7, ITF, etc. are known as such binary level barcodes.

On the other hand, as shown in FIG. 4B, the multi-level bar code has four types of black bars (B ₁ , B ₂ , B ₃ , B ₄ ) and white spaces (S ₁ , S ₂ ) having different widths. , S ₃ , S ₄ ) and the width ratio of each black bar and white space is
B ₁ : B ₂ : B ₃ : B ₄ = S ₁ : S ₂ : S ₃ : S ₄ = 1: 2: 3: 4
It is stipulated. This multi-level barcode has the advantage that more information can be displayed as long as the overall length of the barcode is the same as that of the binary level, but there is an allowable range of width ratio. When there is almost no printing accuracy, it becomes difficult to distinguish the width of each black bar and white space, and the occurrence rate of reading errors by the optical reading device increases. EAN-128 is known as such a multi-level barcode.
JP 2003-11433 A

  By the way, when creating a fee payment slip as described above, if the barcode is heated and printed by a thermal printer built in the handy terminal, the printing speed, the amount of heat applied by the thermal head (printing energy), or the thermal coloring layer of the form paper Depending on factors such as the color sensitivity that has been set, tail color development may occur in which the rear side of the paper feed direction exceeds the proper print range. That is, when the amount of heat applied to the head is higher than the color development sensitivity of the thermosensitive color development layer or when the printing speed is high, as shown in FIG. 5, the thin black bar (NB) and the thick black bar (WB) are displayed. The tail color development that spreads to the rear side in the paper feed direction F by α from the set basic width is likely to occur, and the width of the adjacent fine white space (NS) and thick white space (WS) on the rear side accordingly. Becomes narrower.

  Here, if the barcode to be printed is a binary-level barcode such as CODE39, as described above, the allowable range of the width ratio between the black bar and the white space is relatively wide, so that it spreads with tailing coloring. If the total width of the black bar is within the allowable range of the width ratio, reading by the optical reading device is possible. However, since a binary-level barcode has a small amount of information display, for example, if the barcode of required information displayed on the fee payment slip is formed using the CODE 39, three to four barcodes are required. . However, the form paper used for the handy terminal has a narrow paper width and cannot be made too long in the form of a fee payment form. For this reason, it is impossible to print a plurality of barcodes together with necessary character information.

  Therefore, in order to display all necessary information necessary for such a limited space with one barcode, it is preferable to use a multi-level barcode (EAN-128) having a high information density. In this multi-level bar code, as described above, since there is almost no allowable range of the width ratio between the black bar and the white space, if the width ratio changes due to the tail coloring, the reading by the optical reader is performed. There was a problem that could not be.

  An object of the present invention is to provide a form paper that solves such problems and enables high-precision barcode printing by a thermal printer.

  According to the present invention, a printing surface composed of a thermosensitive coloring layer is formed on a paper substrate, and a black surface of a barcode formed by arranging a plurality of types of black bars and white spaces read in parallel by an optical reading device on the printing surface. In a form paper provided with a bar code printing area that is heated and printed by a thermal printer so that the bar is orthogonal to the paper feed direction, and a character information printing area that is heated and printed by character information read by an optical reader, Thickness obtained by applying a pigment-free ink having a tack value of 1.0 to 3.0 (no unit) and a thermal conductivity of 0.13 to 0.30 W / Km after curing to the surface of the barcode printing area The form paper is characterized in that a tail coloring prevention layer having a thickness of 0.5 to 3.0 μm is provided.

  Here, the barcode printing area and the character information printing area are provided at different positions on the printing surface, and the tailing coloring prevention layer is provided only on the surface of the barcode printing area or a barcode other than the character information printing area. Provided on the print surface including the print area. Further, a barcode with a bar pattern based on the EAN-128 standard having a high information density is applied to the barcode printed on the barcode printing area.

  In addition, by using an ink to be applied containing 1 to 3% of silicon, a structure in which 1 to 3% of silicon is contained in the tailing coloring prevention layer is proposed.

  As described above, according to the present invention, a printing surface composed of a thermosensitive coloring layer is formed on a paper substrate, and a plurality of types of black bars and white spaces that are read by an optical reading device are arranged on the printing surface in parallel. A bar code printing area where the black bar of the code is heated and printed by a thermal printer so that the black bar is orthogonal to the paper feed direction, and a character information printing area where character information read by the optical reader is heated and printed are provided. In the form paper, the surface of the bar code printing region is coated with a pigment-free ink having a tack value of 1.0 to 3.0 and a thermal conductivity after curing of 0.13 to 0.30 W / Km. Since it is a form paper with a tail coloring prevention layer with a thickness of 0.5 to 3.0 μm, a slightly excessive amount of applied heat (printing energy) suitable for thermal printing of character information by the thermal head of a thermal printer. ), The printed bar code to the bar code printing area, and when printing the character information in the character information printing area, text information printed on the character information printing area is advantageous in optical reading becomes thicker. On the other hand, the surface of the barcode printing area is provided with a tailing coloring prevention layer having a thickness of 0.5 to 3.0 μm and a thermal conductivity of 0.13 to 0.30 W / Km. Excessive heat conduction is suppressed to an appropriate amount of heat applied, and a bar code having an appropriate width ratio between the black bar and the white space can be printed without causing tail coloring. In addition, since the ink used for printing the tail coloring prevention layer has a low viscosity with a tack value of 1.0 to 3.0, the ink surface is leveled during printing, and the smoothness of the surface of the tail coloring prevention layer is increased. Further, since the ink does not contain a pigment, wear of the thermal head is prevented. This improves the bar code printing quality in combination with the tail-coloring prevention function, and provides a bar pattern bar code based on the EAN-128 standard that has almost no tolerance for the width ratio between black bars and white spaces. Can be printed with high accuracy.

  In addition, the structure in which the tail color development preventing layer contains 1 to 3% of silicon improves the slipperiness of the surface of the tail color development preventing layer, and the ink fountain caused by contact with the thermal head is improved. Occurrence is prevented and the ink fountain does not adhere to the thermal head, so that the printing quality can also be improved.

Below, one Example of this invention is described based on FIGS. 1-3.
As shown in FIG. 1, the form paper 1 according to the present invention has a heat-sensitive coloring layer 3 formed on the surface of a paper substrate 2, and the upper surface of the heat-sensitive coloring layer 3 is a printing surface 4. As shown in FIG. 2, the printing surface 4 is provided with a barcode printing area 5a and a character information printing area 5b, and a tail color development preventing layer 6 is formed on the surface of the barcode printing area 5a. Has been. Here, the tail color-development preventing layer 6 does not include a pigment having such a characteristic that the tack value indicating the stickiness is 1.0 to 3.0 (no unit), and the thermal conductivity after curing is 0.13 to 0.30 W / Km. The ink is provided with a thickness of 0.5 to 3.0 μm (thickness after ink curing) by applying solid printing using a printing means such as offset printing. The ink to be applied may contain 1 to 3% of silicon in the tailing color-preventing layer 6 by using the ink containing 1 to 3% of silicon.

  The thickness of the tail coloring prevention layer 6 should be controlled with a gloss meter (eg, Murakami Color Research Laboratory; gloss meter GMX-202 type) as an index of the amount of ink applied. The specular glossiness is measured with the gloss meter, and the difference between the ink application part and the non-application part is set to 2 to 9.

  As the ink constituting the tail color-development preventing layer 6, an ink obtained by adding an auxiliary agent (kishikiri agent, reducer, etc.) to UV NVR varnish manufactured by T & K TOKA Co., Ltd. can be suitably used. In addition, 1 to 3% of silicon may be added to this ink.

  The form sheet 1 is formed in a long continuous shape, and is wound in a roll shape so as to be suitable for use in a handy terminal. FIG. 2 is a schematic diagram showing a state in which the required display information of the meter reading slip 8 and the fee payment slip 9 is printed on the form paper 1 using the handy terminal 7 incorporating the thermal printer. In the barcode printing area 5a provided on the printing surface 4 in advance, a barcode 10 in which a plurality of types of black bars and white spaces are arranged in parallel so that the black bars are orthogonal to the paper feed direction F is heated and printed. Is done. The bar code 10 is a 44-digit bar code based on the EAN-128 standard. A single bar code 10 is used to store a customer number, a payment amount, a due date, a billing date, The receiving financial institution code, billing company code, and other required information will be displayed. In addition, character information 11 having a predetermined content that is read by the optical reading device is heated and printed in the character information printing area 5b. The character information 11 displays an account number, a monetary amount, etc. with numbers, specific English letters and symbols, and is read by an optical reader when paying a fee at a post office or a bank. To be served. Although not shown in the drawing, the print surface 4 other than the barcode print area 5a and the character information print area 5b is heated and printed with predetermined visual information to constitute a meter reading slip 8 and a fee payment slip 9. It becomes.

  Here, in order to confirm the action of the tail coloring prevention layer 6, a sample was prepared in which the tail coloring prevention layer 6 having the above structure was provided on one side of the thermosensitive coloring layer 3 formed on the paper substrate 2. In this sample, the printing energy of the thermal head is changed stepwise on the portion with and without the tail coloring prevention layer 6 to print EAN-128 standard barcodes, and this barcode is optically read. The test which reads with an apparatus (scanner) was done. Bar code is printed using a B-458 type thermal printer manufactured by Tec Co., Ltd. at two printing speeds of 50 mm / sec and 100 mm / sec (printing and paper feeding speed). For reading the barcode, a handy scanner of RHT-100-01 type manufactured by Welcat Corporation was used. Also, a bar code of 44-digit EAN-128 standard was created using commercially available bar code creation software, and this bar code was printed with its black bar orthogonal to the paper feed direction.

  The result of the reading test is shown in FIG. Here, “A” indicates a portion without the trailing color development preventing layer 6, and “B” indicates a portion with the tail coloring prevention layer 6. The barcode printed on these “A” and “B” is displayed once. The symbol “○” indicates that the data can be reliably read by the scan of “1”, “△” indicates that the image can be read almost once, but can be read by rescanning when it cannot be read, and the symbol “×” indicates that the image cannot be read. It is attached and evaluated. In this chart, when the printing speed is 50 mm / sec, the barcode “A” with no trailing color-development prevention layer 6 can read barcodes printed within a printing energy range of 0.35 to 0.40 mJ / dot. Among them, “○” is evaluated only when the printing energy is 0.37 mJ / dot. On the other hand, in the portion “B” where the tail coloring prevention layer 6 is present, it is possible to read a bar code printed within a printing energy range of 0.37 to 0.42 mJ / dot, of which the printing energy is 0.37 mJ. In the case of / dot and 0.40mJ / dot, it is rated as “○”. From this result, by providing the tailing color-development preventing layer 6, the heat conduction of the excessive amount of heat applied to the heat-sensitive color-developing layer is suppressed to an appropriate amount of heat application. It is understood that a high-precision bar code with an appropriate width ratio was printed. In addition, since the setting range of the printing energy that can be evaluated as “◯” is expanded and the settable printing energy is shifted to the higher one, the character information printing area 5b (without the trailing coloring prevention layer 6) ( The character information 11 printed in FIG. 2) can be thickened by printing with a slightly excessive amount of applied heat, making it easy to optically read the character information 11 and easily seeing other visual information. It becomes.

  In addition, when the printing speed is 100 mm / second, the evaluation of “◯” is not obtained regardless of whether the portion “A” without the tail coloring prevention layer 6 or the portion “B” is present. It can be seen that the provision of the coloring prevention layer 6 increases the setting range of the printing energy for printing the bar code with the evaluation “Δ” up to 0.37 mJ / dot. Further, by expanding the settable print energy range to the higher one, the character information 11 printed in the character information print region 5b (see FIG. 2) without the trailing color-development preventing layer 6 as described above, It can be printed and thickened with a slightly excessive amount of applied heat, and the optical reading of the character information 11 is facilitated, and other visual information is easily visible.

  As described above, in the present invention, the printing surface 4 composed of the thermosensitive coloring layer 3 is formed on the paper substrate 2, and a plurality of types of black bars and white spaces that are read by the optical reading device are arranged in parallel on the printing surface 4. A barcode printing area 5a that is heated and printed by a thermal printer so that the black bar of the barcode 10 is orthogonal to the paper feed direction F, and character information 11 that is read by an optical reader is heated and printed. In the form 1 provided with the character information printing area 5b, the surface of the bar code printing area 5a has a tack value of 1.0 to 3.0 and a thermal conductivity after curing of 0.13 to 0.30 W / Km. Since the tail color development preventing layer 6 having a thickness of 0.5 to 3.0 μm formed by applying an ink containing no pigment is provided, the thermal head of the thermal printer uses a slightly excessive mark suitable for heating printing of the character information 11. When the barcode 10 is printed in the barcode printing area 5a and the character information 11 is printed in the character information printing area 5b by the amount of heat (printing energy), the character information 11 printed in the character information printing area 5b becomes thick. While it is advantageous for optical reading, the trailing color development preventing layer 6 suppresses heat conduction of an excessive amount of applied heat to the thermal color forming layer 3 in the bar code printing area 5a, thereby providing an appropriate amount of applied heat and causing tailing color development. In addition, the barcode 10 having an appropriate width ratio between the black bar and the white space can be printed in the barcode printing area 5a. Further, since the ink used for printing the tail coloring prevention layer 6 has a low viscosity with a tack value of 1.0 to 3.0, the ink surface is leveled during printing, and the smoothness of the surface of the tail coloring prevention layer 6 is increased. It is done. Further, since the ink does not contain a pigment, wear of the thermal head is prevented. This improves the printing quality of the bar code 10 coupled with the tail coloring prevention function, and the bar pattern bar code based on the EAN-128 standard, which has almost no allowable range of the width ratio between the black bar and the white space. 10 can be printed with high accuracy.

  Further, when 1 to 3% of silicon is contained in the tail coloring prevention layer 6, the surface lubricity of the tail coloring prevention layer 6 is improved, and ink fountain is generated due to contact with the thermal head. This prevents the ink fountain from adhering to the thermal head, which can also improve the printing quality.

2 is a longitudinal sectional view of a form sheet 1. FIG. It is a schematic plan view which shows the preparation state of the fee payment slip 9 by the handy terminal 7. FIG. It is a chart which shows the result of a bar code reading test. (A) is a schematic diagram of a binary-level barcode, and (b) is a schematic diagram of a multi-level barcode. It is explanatory drawing which shows the state which the tailing color development produced in the barcode.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Form paper 2 Paper base material 3 Thermosensitive coloring layer 4 Printing surface 5a Bar code printing area 5b Character information printing area 6 Trailing coloring prevention layer 10 Bar code 11 Character information F Paper feed direction

Claims (2)

A printing surface composed of a thermosensitive coloring layer is formed on a paper substrate, and the black bar of a bar code formed by paralleling a plurality of types of black bars and white spaces to be read by an optical reader is fed to the printing surface. In a form paper provided with a barcode printing area that is heated and printed by a thermal printer so as to be orthogonal to the direction, and a character information printing area that is heated and printed by character information read by an optical reader,
A thickness of 0.5 to 3.0 obtained by applying a pigment-free ink having a tack value of 1.0 to 3.0 and a thermal conductivity after curing of 0.13 to 0.30 W / Km on the surface of the barcode printing region. A form paper characterized by being provided with a μm tail coloring prevention layer. The form paper according to claim 1, wherein the tail color-development preventing layer contains 1-3% of silicon.

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