JP2011225233A - Coil binding hoop with bar code printed thereon - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coil binding hoop with a bar code having exact recognizability printed thereon, which prevents deterioration in recognizability of the bar code print on the hoop surface binding a coil-like object due to curving of the hoop, in the binding metallic band (hoop) of thin steel sheet coil.SOLUTION: The actual curvature of the bar code is increased by obliquely printing the bar code relative to the longitudinal direction of the hoop. In the coil binding hoop, the coil radius, bar code length, and an angle formed by the bar code and hoop are changed for printing, and the relationship between the bar code length (L) and the coil radius (R) satisfies the following expression: L≤(0.2×R-40)/cosθ, where L is bar code length (mm) and R is a coil radius (mm).

Description

  The present invention relates to a metal band (hoop) for bundling a coil of a steel thin steel sheet or the like wound up in a coil shape.

When a belt-like object such as a steel thin steel sheet is wound into a coil shape, the belt-like material is generally bound by a bundling metal band (hoop) in order to fix the belt-like object in a coil shape. This is because bundling with the hoop facilitates the transportation and storage of the coil-like material.
Nowadays, data management has been carried out for such coiled items for reasons of logistics and production management. In such data management, a unique identification number is assigned to each item of the coiled item for management. Conventionally, a staff with a printed identification number is attached to a coiled object, but recently, an identification number is given by a bar code or an IC tag.

In the case of a steel sheet coil, a unique identification number is similarly assigned to the coil. In the case of a steel sheet coil, the identification number is often bar-coded and printed on a binding hoop for use.
For example, Patent Document 1 (Japanese Patent Laid-Open No. 2006-293844) discloses a product management system in which product management data such as a barcode is printed on the surface of a coil binding hoop and is transported using the product management data.
Patent Document 2 (Japanese Patent Laid-Open No. 2005-231658) discloses a bundling device that detects and controls a printing position when performing laser printing on a bundling hoop of a thin coil.
Further, Patent Document 3 (Japanese Patent Laid-Open No. 2003-12020) discloses an IC tag in which flat small piece IC tags are attached to one side of a bundling hoop for packing at predetermined intervals along the longitudinal direction. A binding band is disclosed.

JP 2006-293844 A JP 2005-231658 A JP 2003-12020 A

In the product management by the IC tag described in Patent Document 3, the recognition rate is still lowered due to the influence of the back metal for the metal material which is a conductor such as steel, so that the product management by the barcode is general.
However, the hoop for binding a thin steel coil is usually wound around the outer peripheral surface of the coil (the circumferential direction of the coil). At this time, since the hoop is curved along the outer periphery of the coil, the barcode printed on the hoop surface is also read in a curved state. For this reason, depending on the coil diameter (curved diameter), the barcode reader may not be able to recognize and read. In that case, it depends on visual recognition by the operator, and the work is temporarily stopped, so that productivity and workability are remarkably deteriorated.
In order to avoid the curve of the hoop, an attempt was made to print a barcode in the width direction of the hoop. However, the normal hoop width is narrow (standard width of steel binding hoop is 32 mm), and the barcode cannot be accurately recognized. It's real.

  In view of this, the present invention has an object of improving the barcode recognizability on a curved hoop so as to solve such a problem. An object of the present invention is to propose a coil bundling hoop on which a barcode printing with accurate recognizability has been made, taking as an example a metal band (hoop) for bundling current steel sheet coils.

In order to solve the above-mentioned problems, the present inventors have conducted intensive studies, and as a result, the bar code is printed so that the lateral direction of the bar code is oblique with respect to the longitudinal direction of the hoop. The present inventors have found that bar code is printed and that bar code information can be recognized accurately, and have made the present invention.
The gist of the present invention is as follows.

  (1) A coil binding hoop printed with a bar code, wherein the bar code is printed so as to be orthogonal or oblique to the longitudinal direction of the hoop.

(2) The coil binding hoop according to (1), wherein a plurality of the barcodes are printed in parallel.

  (3) The coil binding hoop according to (1) or (2), wherein the coil binding hoop is made of steel, and the surface of the printed barcode is coated with a transparent resin.

Here, a coil means what wound the strip | belt-shaped object in the coil shape. For example, a thin steel coil of steel or a roll of paper is applicable.
A hoop is a thin band for binding coils. Steel hoops are generally used for steel sheet coils.
A bar code is an identifier that represents a numerical value or a character by the thickness of a striped line generally used for article management in retail, physical distribution, production management, and the like. Although there are many types of standards, in the present invention, the barcode standard is not required. A two-dimensional code such as a QR code is also equivalent to a barcode, and is included in the technical scope of the present invention.

  According to the present invention, even if the bar code is printed on the coil binding hoop, the bar code information can be accurately recognized regardless of the outer diameter of the coil. As a result, since the unrecognizable barcode is not confirmed, the continuous production flow is not interrupted, so that productivity and workability are remarkably improved.

The conceptual diagram which shows the product management process of a metal coil. The conceptual diagram which shows the binding state by the coil of metal material, and the hoop for binding. (A) is a conceptual diagram which shows the place which attached the binding hoop to the coil. (B) is a conceptual diagram showing an example of a barcode printed on a hoop. (C) is a conceptual diagram showing an example in which a plurality of barcodes are printed in parallel. The figure which shows the example of the laser dot printed on the hoop for binding. The figure which shows the example of the barcode printed on the steel hoop. The figure which shows the experimental result of the barcode recognizability by the difference in bar code length (L), the radius (R) of a metal coil, and the angle ((theta)) which a bar code and the hoop longitudinal direction make ((theta) = 0 degree). The figure which shows the experimental result of the recognition property of barcode by the difference in barcode length (L), the radius (R) of a metal coil, and the angle ((theta)) which a barcode and a hoop longitudinal direction make. (A) shows θ = 15 °. (B) shows θ = 30 °. (C) shows θ = 45 °. The figure which shows the example of the red rust which generate | occur | produced in steel hoops.

  Hereinafter, the present invention will be described using a thin coil made of steel as an example. Needless to say, the present invention is not limited to a thin steel coil, but can be applied to any hoop that binds a coiled coil. In particular, when applied to a bundling metal band (hoop) used for bundling metal materials such as steel, the effect is further increased.

  FIG. 1 shows a product management process for a thin coil of general steel. For example, a hot-rolled steel sheet hot-rolled in a hot-rolling factory is wound up as a steel sheet coil 1, and the steel sheet coil 1 is divided into products according to the demands of the customer. Issue is made. After the coil is paid out, the label and the service card are attached to the coil and conveyed to the coil packing process which is the next process. In the coil packing process, the bar code of the label and the service card are collated, and are transported to a designated place and stored by an instruction from a computer.

A label or a service card is a sticker (made of paper) on which a barcode is printed. The label or service card is often damaged or soiled during conveyance or storage, and the barcode recognition may deteriorate. In addition, since reading with a bar code relies on the operator, the workability is poor, and it is an impediment to productivity improvement.
Therefore, as shown in FIG. 2, it is considered to print a barcode directly on the coil binding hoop. The coil binding hoop is wound and bound along the outer periphery of the coil so as not to unwind the coil.

  In general, steel hoops have a hardened steel surface coated with wax (transparent resin). The surface is dark blue due to quenching. The standard hoop width in steel is 32 mm, and a width of about 13 to 32 mm is used as necessary.

  Bar code can be printed on the hoop by laser dot printing (Fig. 3). By properly arranging the laser dots, it can be printed as a barcode (FIG. 4). As described above, the surface of the steel hoop usually has a dark blue color of black rust (color by quenching, so-called bluing). When laser printing is performed there, iron oxide on the surface layer is removed, and the printed portion becomes a steel color (gray white), and the barcode can be recognized with this contrast. With this contrast, barcode information can be recognized by a barcode reader (not shown).

  In general, a barcode reader scans and reads a barcode portion with a straight line. Even if the straight line to be scanned is oblique to the barcode, there is no particular problem. This is because reading is performed with a relative bar width by using the first, last, and center (left end, right end, and center portion of the barcode) of the barcode scan as a reference.

However, as shown in FIG. 2, since the hoop is along the outer periphery of the coil, the hoop itself is curved, and as a result, the barcode printed on the hoop is also curved. Then, since the barcode reader is curved in the depth direction, the barcode recognizability is extremely deteriorated.
In other words, there is a barcode reading limit due to the curvature of the hoop. Therefore, by making the horizontal direction of the barcode oblique to the longitudinal direction of the binding hoop (FIG. 2), the substantial curvature radius of the barcode portion can be increased, and the barcode information can be recognized. Can be improved. For example, if the angle between the horizontal direction of the barcode and the longitudinal direction of the hoop is θ, the radius of curvature is roughly increased by 1 / cos θ. Therefore, when θ is small, the effect is small, but when θ is large, the effect becomes large.
That is, the barcode is printed obliquely with respect to the longitudinal direction of the hoop according to the actual bending radius (that is, the same as the coil radius), and the barcode length (the lateral length of the barcode, that is, the bars are arranged) By changing the direction length), the barcode information can be recognized accurately.

  Next, an experiment was conducted to see how barcode recognition changes. As the steel hoop used in the experiment, a binding hoop of a thin coil having a width of 32 mm that was actually used was used. The height of the barcode was 25 mm, and the corresponding numbers were printed along with the barcode (FIG. 3). The depth of the laser dot was about 20 μm (the depth of a normal laser dot is about 5 to 50 μm. In the present invention, the depth of the laser dot is not particularly limited. The BT series manufactured by Keyence Corporation was used under the same fluorescent lamp as the actual on-site environment, and the bar code recognition when θ = 0 ° is shown in Fig. 5. Three trials In the three cases, ◯ indicates that the barcode information was correctly recognized, △ indicates that the barcode information was not recognized once, and △ indicates that the barcode information was not recognized twice.

  Next, the results of testing the barcode recognition when the barcode is printed obliquely with respect to the hoop under the same conditions are shown in FIGS. 6 (a), 6 (b) and 6 (c). 6A shows the results when θ = 15 °, FIG. 6B shows the results when θ = 30 °, and FIG. 6B shows the results when θ = 45 °. In FIG. 6, when reading was attempted three times, the bar code information was recognized correctly three times. A solid line indicates a line L = (0.2 × R−40) / cos θ, and a broken line indicates a line indicating a recognition limit when θ = 0 ° (that is, L = 0.2 × R−40).

As can be seen from this result, it is understood that the barcode recognizability strongly depends on the barcode length (L), the coil radius (R), and the barcode and the hoop longitudinal angle (θ). It was. In order to recognize correctly, it turned out that the following formulas must be satisfied.
L ≦ (0.2 × R−40) / cos θ
L: Bar code length (mm)
R: Coil radius (mm)

The lower limit of the barcode length (L) varies depending on the amount of information included in the barcode, but in the case of a standard 13-digit code, about 35 mm is considered the limit that can be accurately recognized. The upper limit of the barcode length (L) is not particularly set, but a length that can be recognized within a common sense range may be set. For example, there is no problem even if the upper limit is 100 mm.
Also, if the angle (θ) between the barcode and the hoop longitudinal direction is small, the effect is small, and if it is large, the height of the barcode (corresponding to the length of one bar) and the barcode length are related to the hoop width. Is limited. The upper limit may be determined from the viewpoint of recognition and operability. Of course, bar code may be printed so that θ = 90 °, that is, orthogonal to the longitudinal direction of the hoop. From the result of FIG. 6 above, it can be seen that θ is preferably 15 ° or more and 60 ° or less in actual use with the standard width of the hoop of 32 mm, and that the effect is sufficiently obtained even when the angle is 15 ° or more and 45 ° or less.
A plurality of barcodes may be arranged in parallel (FIG. 2 (c)). For example, one barcode information may be divided into a plurality of pieces and printed in parallel and orthogonally or obliquely to the hoop. By dividing long bar code information, it is possible to print on the hoop with good recognizability.

Next, a description will be given of the deterioration of recognition due to red rust after laser printing.
FIG. 7 shows the appearance when a bar code printed on a steel hoop is left in a humid environment for 24 hours, as in FIG. It can be seen that red rust occurs in some places on the bar code, which significantly deteriorates the bar code recognition.

  Since the active surface of steel is exposed in the portion dug by the laser dots, iron oxidation proceeds due to moisture in the air, and red rust appears. If the occurrence of partial red rust, it is not completely unrecognizable, but over time, the occurrence of red rust increased and it was confirmed that the recognition performance deteriorated at an accelerated rate.

Therefore, as a measure against red rust, a transparent wax (resin) was coated to cover the entire barcode within 10 minutes after laser printing. Here, the term “transparency” refers to transparency that allows light to pass through and allows the barcode to be recognized by the contrast between the original surface color of the hoop and the barcode. As long as it is transparent and does not allow moisture to penetrate, the components and composition of the resin are not limited. This transparent wax (resin) coating confirmed that red rust was not generated even when left in a similar wet environment for 7 days. It was also confirmed that coating with transparent wax had no effect on barcode reading and recognition.
The coating of the transparent resin is desirably performed immediately after the barcode printing by the laser. For example, a transparent resin coating device may be disposed so as to be attached to the laser printing device described in Patent Document 2.

The present invention was implemented in an actual actual machine line in an actual thin coil bundling hoop.
Radius of thin coil: 400mm
Barcode length: 45mm and 60mm each printed on the same hoop
At this time, the angle formed by the barcode and the hoop longitudinal direction was 30 °.
Barcode reader: Keyence BT-500
As for the barcode reading result, a barcode with a length of 45 mm could be read accurately, but a barcode with a length of 60 mm could not be read at a portion near both ends.
In addition, a bar code having a length of 45 mm was applied to two coils, only one side was coated with a transparent resin (wax), and the other was left in the outdoor yard for 30 days with the bar code printed. As a result, the product coated with transparent resin had no red rust, and barcode information could be read accurately even after 30 days. However, the product without transparent resin coated had red rust, and three trials were underway. Bar code information could only be read once.
As described above in detail, the embodiment of the present invention described above is only an example, and it is needless to say that the present invention is not limited to these embodiments.

  The present invention can be used for a hoop for binding coiled objects. The present invention can be widely used not only for steel sheet coils used in the description but also for coil binding hoops made of metal materials.

DESCRIPTION OF SYMBOLS 1 Steel plate coil 2 Label 3 Service card 10 Binding hoop 11 Bar code

Claims (3)

A coil binding hoop having a bar code printed thereon, wherein the bar code is printed so that the horizontal direction of the bar code is oblique to the longitudinal direction of the hoop.
2. The bar code length (L), the coil radius (R), and the angle (θ) between the horizontal direction of the bar code and the longitudinal direction of the hoop are expressed by the following equations. The hoop for coil binding as described.
L ≦ (0.2 × R−40) / cos θ
L: Bar code length (mm)
R: Coil radius (mm)
θ: Angle at which the bar code horizontal direction and the hoop longitudinal direction intersect
  The coil binding hoop according to claim 1 or 2, wherein the coil binding hoop is made of steel, and the surface of the printed barcode is coated with a transparent resin.