JP2004223868A - Authenticity discriminating formed body - Google Patents
Authenticity discriminating formed body Download PDFInfo
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- JP2004223868A JP2004223868A JP2003014218A JP2003014218A JP2004223868A JP 2004223868 A JP2004223868 A JP 2004223868A JP 2003014218 A JP2003014218 A JP 2003014218A JP 2003014218 A JP2003014218 A JP 2003014218A JP 2004223868 A JP2004223868 A JP 2004223868A
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- 230000000149 penetrating effect Effects 0.000 claims abstract description 171
- 239000000463 material Substances 0.000 claims description 291
- 239000000758 substrate Substances 0.000 claims description 93
- 238000005553 drilling Methods 0.000 claims description 20
- 230000015572 biosynthetic process Effects 0.000 claims description 17
- 230000004888 barrier function Effects 0.000 claims description 5
- 239000011295 pitch Substances 0.000 claims description 3
- 230000002265 prevention Effects 0.000 abstract description 3
- 230000004075 alteration Effects 0.000 abstract 1
- 238000010586 diagram Methods 0.000 description 18
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- 238000010030 laminating Methods 0.000 description 2
- 238000000034 method Methods 0.000 description 2
- 230000002194 synthesizing effect Effects 0.000 description 2
- 239000000853 adhesive Substances 0.000 description 1
- 230000001070 adhesive effect Effects 0.000 description 1
- 230000007423 decrease Effects 0.000 description 1
- 230000002093 peripheral effect Effects 0.000 description 1
- 229920003023 plastic Polymers 0.000 description 1
- 239000004033 plastic Substances 0.000 description 1
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B42—BOOKBINDING; ALBUMS; FILES; SPECIAL PRINTED MATTER
- B42D—BOOKS; BOOK COVERS; LOOSE LEAVES; PRINTED MATTER CHARACTERISED BY IDENTIFICATION OR SECURITY FEATURES; PRINTED MATTER OF SPECIAL FORMAT OR STYLE NOT OTHERWISE PROVIDED FOR; DEVICES FOR USE THEREWITH AND NOT OTHERWISE PROVIDED FOR; MOVABLE-STRIP WRITING OR READING APPARATUS
- B42D25/00—Information-bearing cards or sheet-like structures characterised by identification or security features; Manufacture thereof
- B42D25/30—Identification or security features, e.g. for preventing forgery
- B42D25/346—Perforations
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- G—PHYSICS
- G07—CHECKING-DEVICES
- G07D—HANDLING OF COINS OR VALUABLE PAPERS, e.g. TESTING, SORTING BY DENOMINATIONS, COUNTING, DISPENSING, CHANGING OR DEPOSITING
- G07D7/00—Testing specially adapted to determine the identity or genuineness of valuable papers or for segregating those which are unacceptable, e.g. banknotes that are alien to a currency
- G07D7/003—Testing specially adapted to determine the identity or genuineness of valuable papers or for segregating those which are unacceptable, e.g. banknotes that are alien to a currency using security elements
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- G—PHYSICS
- G07—CHECKING-DEVICES
- G07D—HANDLING OF COINS OR VALUABLE PAPERS, e.g. TESTING, SORTING BY DENOMINATIONS, COUNTING, DISPENSING, CHANGING OR DEPOSITING
- G07D7/00—Testing specially adapted to determine the identity or genuineness of valuable papers or for segregating those which are unacceptable, e.g. banknotes that are alien to a currency
- G07D7/06—Testing specially adapted to determine the identity or genuineness of valuable papers or for segregating those which are unacceptable, e.g. banknotes that are alien to a currency using wave or particle radiation
- G07D7/12—Visible light, infrared or ultraviolet radiation
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- G—PHYSICS
- G07—CHECKING-DEVICES
- G07D—HANDLING OF COINS OR VALUABLE PAPERS, e.g. TESTING, SORTING BY DENOMINATIONS, COUNTING, DISPENSING, CHANGING OR DEPOSITING
- G07D7/00—Testing specially adapted to determine the identity or genuineness of valuable papers or for segregating those which are unacceptable, e.g. banknotes that are alien to a currency
- G07D7/181—Testing mechanical properties or condition, e.g. wear or tear
- G07D7/185—Detecting holes or pores
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- G—PHYSICS
- G07—CHECKING-DEVICES
- G07D—HANDLING OF COINS OR VALUABLE PAPERS, e.g. TESTING, SORTING BY DENOMINATIONS, COUNTING, DISPENSING, CHANGING OR DEPOSITING
- G07D7/00—Testing specially adapted to determine the identity or genuineness of valuable papers or for segregating those which are unacceptable, e.g. banknotes that are alien to a currency
- G07D7/20—Testing patterns thereon
- G07D7/202—Testing patterns thereon using pattern matching
- G07D7/206—Matching template patterns
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- Credit Cards Or The Like (AREA)
Abstract
Description
【0001】
【発明の属する技術分野】
本発明は、銀行券、パスポート、有価証券、カード、印紙類等の偽造防止、改竄防止が必要とされる貴重印刷物に適用する真偽判別形成体に関するものである。
【0002】
【従来の技術】
銀行券、パスポート、有価証券、カード、印紙類等の貴重印刷物は、その性質上、偽造、変造されにくいことが要求される。この防止策として、これらの貴重印刷物の基材に、複数の穿孔で数字等を形成することは知られている。また、複数の穿孔を有する基材を傾けて観察することにより潜像画像を視認できるようにして真偽判別を行う技術も知られている。
【0003】
前者は、スイスの銀行券に用いられており、数字を穿孔によって表現している。また、孔の直径は、反射状態においては裸眼でそれらのなすパターンが見えない点に特徴を有する、 安全マークが、透過状態においては見える文書面のパターンを形成する複数個の孔からなる、偽造を防止するための安全マークを備える安全保管文書が開示されている(例えば、特許文献1参照)。
【0004】
【特許文献1】
特表2000−501036号公報(第2頁、第1−2図)
【0005】
後者は、基材を有し、該基材に形成され、背景部と特定のパターンから成る情報部とを形成する目視しにくい多数の微細な穿孔を有する真偽判別形成体であって、上記背景部を形成する穿孔と上記情報部を形成する穿孔とは、穿孔の形状、寸法及び配列方向の少なくとも一つ以上が異なるように形成されていることを特徴とする真偽判別形成体が開示されている(例えば、特許文献2参照)。
【0006】
【特許文献2】
特開2000−233561号公報(第2頁、第1−2図)
【0007】
また、特定のパターンで配列されて情報を付与する多数の微細穿孔が形成されたカード基材を有する微細穿孔カードであって、上記微細穿孔は、レーザ加工機により、上記カード基材に対して特定の傾斜角度で貫通して形成された穿孔であり、上記微細穿孔カードの一面側から光を上記微細穿孔カードに対して上記特定の傾斜角度と同じ角度で投光して、上記微細な穿孔を透過させることにより、上記情報がチェックされる構成であることを特徴とする微細穿孔カードが開示されている(例えば、特許文献3参照)
【0008】
【特許文献3】
特開2002−160477号公報(第2頁、第1図)
【0009】
また、異なった角度で貫通した穿孔で画像を形成することによって両眼視差によって画像が立体的に視認されることが考えられる。
【0010】
【発明が解決しようとする課題】
上記の従来技術は総じて、基材に穿孔によって数字等を形成するものや、基材に一部の穿孔の形状を異ならせて、透過光で傾けて観察した場合に潜像画像が視認されるものであった。特表2000−501036号公報は、穿孔によって数字等を形成しているだけであって、偽造防止技術としては単純で改良の余地があった。また、特開2000−233561号公報は、情報部と背景部を組み合わせることで、穿孔群の中に情報部を隠し入れる構成であるため、基材を透過光で傾けて観察したときに傾ける角度を深めなければ潜像画像が明瞭に出現されない恐れがあり、複数の潜像画像を形成することは困難であった。また、特開2002−160477号公報は、基材に複数の穿孔からなる穿孔群を設け、穿孔群の一部の穿孔を基材に対して斜めに開けて潜像画像を構成し、基材を透過光で観察することにより潜像画像を視認できるものであり、レーザを垂直に照射し、且つ、基材を水平方向に自動搬送するような大量生産ラインを構成することは容易であるが、基材に斜め穿孔を形成することは、加工機の構成が複雑となり、作製上困難であった。また、異なった角度で貫通した穿孔で画像を形成することによって両眼視差によって画像が立体的に視認されることが考えられるが、異なった角度で貫通した穿孔だけの構成では、鮮明な立体画像を得ることができなかった。
【0011】
以上のことから、本発明は前述した問題点を解決することを目的としたもので、基材に貫通する穿孔群からなる画像と、これらの穿孔と基材を貫通しない穿孔群からなる潜像画像を形成し、画像を形成する基材を貫通する穿孔位置と、潜像画像を形成する基材を貫通しない穿孔位置を対応して配置することによって、透過光で観察した場合に明瞭な潜像画像の出現、多方向から異なる潜像画像の出現、鮮明な立体的な潜像画像の出現がされることを見出した。よって、本発明は真偽判別効果の高い、改ざん、複製防止効果のある真偽判別形成体を提案するものである。
【0012】
また、第1の基材に貫通する穿孔群からなる画像と、これらの穿孔と第2の基材を貫通する穿孔群からなる潜像画像を形成し、画像を形成する第1の基材を貫通する穿孔位置と、潜像画像を形成する第2の基材を貫通する穿孔位置を対応して配置して、第1の基材と第2の基材を積層することによって、透過光で観察した場合に明瞭な潜像画像の出現、多方向から異なる潜像画像の出現、鮮明な立体的な潜像画像の出現がされることを見出した。よって、本発明は真偽判別効果の高い、改ざん、複製防止効果のある真偽判別形成体を提案するものである。
【0013】
【課題を解決するための手段】
本発明は、基材に形成した2次元に配列された前記基材を貫通する穿孔により形成した穿孔群からなる画像と、基材に形成した2次元に配列された前記基材を貫通しない穿孔により形成した穿孔群からなる潜像画像を設け、前記潜像画像を形成する前記基材を貫通しない穿孔群の個々の穿孔位置は、前記画像を形成する前記基材を貫通する穿孔群の個々の穿孔位置に対応して配置されることを特徴とする真偽判別形成体である。
【0014】
また、本発明は、基材に形成した2次元に配列された前記基材を貫通する穿孔により形成した穿孔群からなる画像と、基材に形成した2次元に配列された前記基材を貫通しない穿孔により形成した穿孔群からなる潜像画像を設け、前記潜像画像を形成する前記基材を貫通しない穿孔群の個々の穿孔位置は、前記画像を形成する前記基材を貫通する穿孔群の個々の穿孔位置に対応して配置される真偽判別形成体であって、前記潜像画像を形成する前記基材を貫通しない穿孔群の個々の穿孔位置は、前記画像を形成する前記基材を貫通する穿孔群の個々の穿孔位置を基準とし、前記基準から特定方向に配置され、且つ、前記基材を貫通しない穿孔と前記基材を貫通する穿孔が一部重なるように配置されていることを特徴とする真偽判別形成体であって、前記真偽判別形成体を反射光または基材に対して垂直方向から透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像のみが視認でき、前記真偽判別形成体を基材に対して垂直方向から傾けて透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像内に前記基材を貫通しない穿孔により形成した穿孔群からなる潜像画像が視認されることを特徴とする真偽判別形成体である。
【0015】
また、本発明は、基材に形成した2次元に配列された前記基材を貫通する穿孔により形成した穿孔群からなる画像と、基材に形成した2次元に配列された前記基材を貫通しない穿孔により形成した穿孔群からなる少なくとも二つの潜像画像を設け、前記少なくとも二つの潜像画像を形成する前記基材を貫通しない穿孔群の個々の穿孔位置は、前記画像を形成する前記基材を貫通する穿孔群の個々の穿孔位置に対応して配置される真偽判別形成体であって、前記少なくとも二つの潜像画像を形成する前記基材を貫通しない穿孔群の個々の穿孔位置は、前記画像を形成する前記基材を貫通する穿孔群の個々の穿孔位置を基準とし、前記基準から特定方向に配置され、且つ、前記基材を貫通しない穿孔と前記基材を貫通する穿孔が一部重なるように配置され、更に、前記特定方向はそれぞれの潜像画像毎に異なる方向であることを特徴とする真偽判別形成体であって、前記真偽判別形成体を反射光または基材に対して垂直方向から透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像のみが視認でき、前記真偽判別形成体を基材に対して垂直方向から異なる方向に傾けて透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像内に前記基材を貫通しない穿孔により形成した穿孔群からなる少なくとも二つの潜像画像が視認されることを特徴とする真偽判別形成体である。
【0016】
また、本発明は、基材に形成した2次元に配列された前記基材を貫通する穿孔により形成した穿孔群からなる画像と、基材に形成した2次元に配列された前記基材を貫通しない穿孔により形成した一対の穿孔群からなる少なくとも一つの潜像画像を設け、前記少なくとも一つの潜像画像を形成する前記基材を貫通しない一対の穿孔群の個々の穿孔位置は、前記画像を形成する前記基材を貫通する穿孔群の個々の穿孔位置に対応して配置される真偽判別形成体であって、前記少なくとも一つの潜像画像を形成する前記基材を貫通しない前記一対の穿孔群の一方の穿孔群の個々の穿孔位置は、前記画像を形成する前記基材を貫通する穿孔群の個々の穿孔位置を基準として特定方向に前記基材を貫通する穿孔と一部重なるように配置され、且つ、前記一対の穿孔群の他方の穿孔群の個々の穿孔位置は、前記画像を形成する前記基材を貫通する穿孔群の個々の穿孔位置を基準として前記一方の穿孔群とは異なる方向で特定方向に前記基材を貫通する穿孔と一部重なるように配置され、更に、前記基材を貫通しない前記一対の穿孔群は、前記基材を貫通する穿孔群をパララックスバリアとする位置に配置されていることを特徴とする真偽判別形成体であって、前記真偽判別形成体を反射光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像のみが視認でき、前記真偽判別形成体を基材に対して垂直方向から透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像内に前記基材を貫通しない穿孔により形成した穿孔群からなる少なくとも一つの潜像画像が立体的に視認されることを特徴とする真偽判別形成体である。
【0017】
また、本発明は、第1の基材に形成した2次元に配列された前記第1の基材を貫通する穿孔により形成した穿孔群からなる画像と、第2の基材に形成した2次元に配列された前記第2の基材を貫通する穿孔により形成した穿孔群からなる潜像画像及び前記第2の基材を貫通する穿孔により形成した穿孔群からなる前記第1の基材に形成した画像と同一の画像を設け、前記潜像画像及び前記同一の画像を形成する前記第2の基材を貫通する穿孔群の個々の穿孔位置は、前記画像を形成する前記第1の基材を貫通する穿孔群の個々の穿孔位置に対応して配置される真偽判別形成体である。
【0018】
また、本発明は、第1の基材に形成した2次元に配列された前記第1の基材を貫通する穿孔により形成した穿孔群からなる画像と、第2の基材に形成した2次元に配列された前記第2の基材を貫通する穿孔により形成した穿孔群からなる潜像画像及び前記第2の基材を貫通する穿孔により形成した穿孔群からなる前記第1の基材に形成した画像と同一の画像を設け、前記潜像画像及び前記同一の画像を形成する前記第2の基材を貫通する穿孔群の個々の穿孔位置は、前記画像を形成する前記第1の基材を貫通する穿孔群の個々の穿孔位置に対応して配置される真偽判別形成体であって、前記第1の基材に形成された画像と前記第2の基材に形成された同一の画像が重なるように配置され、前記潜像画像を形成する前記第2の基材を貫通する穿孔群の個々の穿孔位置は、前記画像を形成する前記第1の基材を貫通する穿孔群の個々の穿孔位置を基準とし、前記基準から特定方向に配置され、且つ、前記同一の画像を形成する前記第2の基材を貫通する穿孔と前記潜像画像を形成する前記第2の基材を貫通する穿孔が一部重なるように配置され、前記第1の基材と前記第2の基材が積層されていることを特徴とする真偽判別形成体であって、前記真偽判別形成体を反射光または基材に対して垂直方向から透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像のみが視認でき、前記真偽判別形成体を基材に対して垂直方向から傾けて透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像内に前記基材を貫通する穿孔により形成した穿孔群からなる潜像画像が視認されることを特徴とする真偽判別形成体である。
【0019】
また、本発明は、第1の基材に形成した2次元に配列された前記第1の基材を貫通する穿孔により形成した穿孔群からなる画像と、第2の基材に形成した2次元に配列された前記第2の基材を貫通する穿孔により形成した穿孔群からなる少なくとも二つの潜像画像及び前記第2の基材を貫通する穿孔により形成した穿孔群からなる前記第1の基材に形成した画像と同一の画像を設け、前記少なくとも二つの潜像画像及び前記同一の画像を形成する前記第2の基材を貫通する穿孔群の個々の穿孔位置は、前記画像を形成する前記第1の基材を貫通する穿孔群の個々の穿孔位置に対応して配置される真偽判別形成体であって、前記第1の基材に形成された画像と前記第2の基材に形成された同一の画像が重なるように配置され、前記少なくとも二つの潜像画像を形成する前記第2の基材を貫通する穿孔群の個々の穿孔位置は、前記画像を形成する前記第1の基材を貫通する穿孔群の個々の穿孔位置を基準とし、前記基準からそれぞれの潜像画像毎に異なる特定方向に配置され、且つ、前記同一の画像を形成する前記第2の基材を貫通する穿孔と前記少なくとも二つの潜像画像を形成する前記第2の基材を貫通する穿孔が一部重なるように配置され、前記第1の基材と前記第2の基材が積層されていることを特徴とする真偽判別形成体であって、前記真偽判別形成体を反射光または基材に対して垂直方向から透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像のみが視認でき、前記真偽判別形成体を基材に対して垂直方向から異なる方向に傾けて透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像内に前記基材を貫通する穿孔により形成した穿孔群からなる少なくとも二つの潜像画像が視認されることを特徴とする真偽判別形成体である。
【0020】
また、本発明は、第1の基材に形成した2次元に配列された前記第1の基材を貫通する穿孔により形成した穿孔群からなる画像と、第2の基材に形成した2次元に配列された前記第2の基材を貫通する穿孔により形成した一対の穿孔群からなる少なくとも一つの潜像画像及び前記第2の基材を貫通する穿孔により形成した穿孔群からなる前記第1の基材に形成した画像と同一の画像を設け、前記少なくとも一つの潜像画像を形成する前記第2の基材を貫通する一対の穿孔群の個々の穿孔位置は、前記画像を形成する前記第2の基材を貫通する穿孔群の個々の穿孔位置に対応し、前記同一の画像を形成する前記第2の基材を貫通する穿孔群の個々の穿孔位置は、前記画像を形成する前記第1の基材を貫通する穿孔群の個々の穿孔位置に対応して配置される真偽判別形成体であって、前記第1の基材に形成された画像と前記第2の基材に形成された同一の画像が重なるように配置され、前記少なくとも一つの潜像画像を形成する前記第2の基材を貫通する前記一対の穿孔群の一方の穿孔群の個々の穿孔位置は、前記画像を形成する前記第1の基材を貫通する穿孔群の個々の穿孔位置を基準として特定方向に配置され、且つ、前記一対の穿孔群の他方の穿孔群の個々の穿孔位置は、前記画像を形成する前記第1の基材を貫通する穿孔群の個々の穿孔位置を基準として前記一方の穿孔群とは異なる方向で特定方向に配置され、且つ、前記同一の画像を形成する前記第2の基材を貫通する穿孔と前記少なくとも一つの潜像画像を形成する前記第2の基材を貫通する穿孔が一部重なるように配置され、前記第2の基材に形成された一対の穿孔群の個々の穿孔は、前記画像を形成する前記第1の基材を貫通する穿孔群をパララックスバリアとする位置に配置され積層されたことを特徴とする真偽判別形成体であって、前記真偽判別形成体を反射光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像のみが視認でき、前記真偽判別形成体を基材に対して垂直方向から透過光で観察した場合に、前記基材を貫通する穿孔により形成した穿孔群からなる画像内に前記基材を貫通する穿孔により形成した穿孔群からなる少なくとも一つの潜像画像が立体的に視認されることを特徴とする真偽判別形成体である。
【0021】
また、本発明は、前記画像を構成する穿孔及び前記潜像画像を構成する穿孔が基材に対して直角及び特定の角度で斜めの形状の少なくとも一つで形成されたことを特徴とする真偽判別形成体である。
【0022】
また、本発明は、前記画像を構成する穿孔及び前記潜像画像を構成する穿孔が、それぞれが等しいピッチで配置されたことを特徴とする真偽判別形成体である。
【0023】
また、本発明は、前記画像を構成する穿孔及び前記潜像画像を構成する穿孔の径が50μm〜1000μmであることを特徴とする真偽判別形成体である。
【0024】
また、本発明は、前記画像を構成する穿孔及び前記潜像画像を構成する穿孔の形状が円形状、多角形及び特殊な形状の少なくとも1つであることを特徴とする真偽判別形成体である。
【0025】
また、本発明は、前記画像を構成する穿孔及び前記潜像画像を構成する穿孔が、深さ方向に伴って、穿孔径が小さくなる形状で形成されることを特徴とする真偽判別形成体である。
【0026】
また、本発明は、前記画像及び前記潜像画像が、文字、数字、記号及び絵柄の少なくとも1つであることを特徴とする真偽判別形成体である。
【0027】
また、本発明は、前記基材を貫通しない穿孔により形成した穿孔群からなる潜像画像をカモフラージュするために前記基材を貫通しない穿孔により形成した穿孔群からなる潜像画像を形成した面に貫通しない穿孔を設けたことを特徴とする真偽判別形成体である。
【0028】
また、本発明は、前記第2の基材に形成した2次元に配列された前記第2の基材を貫通する穿孔により形成した穿孔群からなる潜像画像をカモフラージュするための穿孔を設けたことを特徴とする真偽判別形成体である。
【0029】
上記記載の特定方向についての説明図を図24に示す。ここで言う、特定方向とは穿孔(3a)に対して穿孔(3c)が形成される方向のことである。
【0030】
【発明の実施の形態】
本発明に係る真偽判別形成体の実施の形態を基づいて図面を参照して説明する。本発明の真偽判別形成体の特徴は基材に形成した2次元に配列された基材を貫通する穿孔により形成した穿孔群からなる画像と、基材に形成した2次元に配列された基材を貫通しない穿孔により形成した穿孔群からなる潜像画像を設け、潜像画像を形成する基材を貫通しない穿孔群の個々の穿孔位置は、画像を形成する基材を貫通する穿孔群の個々の穿孔位置に対応して配置されることによって、透過光で特定の観察方向から観察した場合に、基材を貫通しない穿孔により形成した潜像画像が観察可能とするものである。また、第1の基材に形成した2次元に配列された第1の基材を貫通する穿孔により形成した穿孔群からなる画像と、第2の基材に形成した2次元に配列された第2の基材を貫通する穿孔により形成した穿孔群からなる潜像画像及び第2の基材を貫通する穿孔により形成した穿孔群からなる第1の基材に形成した画像と同一の画像を設け、潜像画像及び同一の画像を形成する第2の基材を貫通する穿孔群の個々の穿孔位置は、画像を形成する第1の基材を貫通する穿孔群の個々の穿孔位置に対応して配置されることによって、透過光で特定の観察方向から観察した場合に、第2の記載に形成した潜像画像が観察可能とするものである。
【0031】
図1に基材(1a)に画像(2a)を穿孔(3a)により形成した図及びそのX−X’断面図を示す。図1に示すように穿孔(3a)は基材を貫通している必要がある。図2に基材(1a)に潜像画像(2c)のみを穿孔(3c)により形成した図及びそのX−X’断面図を示す。図2に示すように穿孔(3c)は基材を貫通することなく、一定の深さ又は複数に定められた深さに形成する必要がある。図1及び図2に示した穿孔(3a)により形成した画像(2a)及び穿孔(3c)により形成した潜像画像(2c)が施された真偽判別形成体(4a)及びそのX−X’断面図を図3に示す。図3に示すように基材(1a)を貫通しない穿孔(3c)が、基材(1a)を貫通する穿孔(3a)に一部が重なるようにして規則的に配置される必要がある。この場合は、基材(1a)を貫通しない穿孔(3c)は、基材(1a)を貫通する穿孔(3a)に対して、左部に規則的に配置されているが、右部、上部又は下部等、つまり、基材(1a)を貫通する穿孔(3a)の周辺領域に対して一部重なるように規則的に配置されていれば良い。
【0032】
図5(a)は、真偽判別形成体(4a)を反射光で観察した場合、図5(b)は、真偽判別形成体(4a)を基材に対して垂直方向から透過光で観察した場合の図を示す。図5(a)に示すように、潜像画像(2c)を形成する基材(1a)を貫通しない穿孔(3c)は、基材と同じ色であるため、反射光で観察した場合は、観察者は、基材(1a)を貫通する穿孔による画像(2a)だけを認識することになる。また、図5(b)に示すように、真偽判別形成体(4a)を基材に対して垂直方向から透過光で観察した場合は、観察者は、基材(1a)を貫通する穿孔(3a)を透過してくる光を強く感じるため、基材(1a)を貫通する穿孔(3a)による画像(2a)をだけを認識することになる。上記どちらの場合も、潜像画像(2c)を視認することができない。
【0033】
図6は、真偽判別形成体(4a)を、図4に示したX方向から透過光で観察した場合の図を示す。図6に示すように基材(1a)を貫通する穿孔(3a)による画像(2a)内に、基材(1a)を貫通しない穿孔(3c)による潜像画像(2c)をはっきりと視認することができる(この場合は数字の1である)。これは、基材(1a)に設けた潜像画像(2c)を構成する穿孔(3c)が、基材(1a)に設けた画像(2a)を構成する穿孔(3a)に一部重なるように規則的に配置されているため、図4に示すような透過光が観察できる方向から観察することによって、穿孔(3a)と穿孔(3c)が重なっているように視認される領域からは透過光量が強く、穿孔(3a)と穿孔(3c)が重なっていない領域からはほとんど透過光量が認識されないため、このコントラストの差によって、図6に示したように画像(2a)内に、潜像画像(2c)を視認することができる。
【0034】
観察可能な方向については、図7に示すように潜像画像(2c)を構成する基材(1a)を貫通しない穿孔(3c)と、画像(2a)を構成する基材(1a)を貫通する穿孔(3a)との配置規則に依存する。つまり、図7のX−X’断面図に示すように、画像(2a)を構成する基材(1a)を貫通する穿孔(3a)に対して、潜像画像(2c)を構成する基材(1a)を貫通しない穿孔(3c)がY1側に規則的に配置された場合は、X1方向に傾けて透過光で観察することが必要であり、Y2側に規則的に配置された場合は、X2方向に傾けて透過光で観察することが必要である。また、基材の表裏どちらの面からも上記記載の同一方向から観察可能である。
【0035】
次に、透過光で異なる4方向から、それぞれ異なる潜像画像が見える真偽判別形成体(4b)を基材を貫通しない穿孔が形成されていない面から見た場合について図9に示す。基材には図1に示した画像を穿孔によって形成した基材を用いる。透過光で異なる4方向から、それぞれ異なる画像が視認できるようにするためには、基材を貫通しない穿孔と基材を貫通する穿孔に規則性を持たせる必要がある。例えば、図8(a)乃至図8(d)に示すように潜像画像(2c1)、潜像画像(2c2)、潜像画像(2c3)、潜像画像(2c4)の4つの潜像画像を出現させたい場合に、これらの4つの画像を合成して、基材(1a)に潜像画像(2c)を形成する必要があり、基材(1a)に設ける潜像画像(2c)を構成した穿孔(3c)は、基材(1a)を穿孔する穿孔(3a)に一部重なって規則的に配置する必要がある。基材(1a)を貫通しない穿孔(3c)が、図9に示すように穿孔(3a)に対してY1位置に規則的に配置(この場合、潜像画像2c1)された場合は、X1方向に傾けて透過光で観察することが必要であり、Y2位置に規則的に配置(この場合、潜像画像2c2)された場合は、X2方向に傾けて透過光で観察することが必要であり、Y3位置に規則的に配置(この場合、潜像画像2c3)された場合は、X3方向に傾けて透過光で観察することが必要であり、Y4位置に規則的に配置(この場合、潜像画像2c4)された場合は、X4方向に傾けて透過光で観察することが必要である。また、基材の表裏どちらの面からも上記記載の同一方向から観察可能である。
【0036】
よって、このような基材(1a)を貫通しない穿孔によって潜像画像(2c)を設けた真偽判別形成体(4b)は、図10(a)に示すように、図9に示した基材を貫通しない穿孔が形成されていない面からX1方向に傾けて透過光で観察する場合はY1に規則的に配置された潜像画像(2c1)(この場合は数字の2)が視認され、図10(b)に示すように、図9に示したX2方向に傾けて透過光で観察する場合はY2に規則的に配置された潜像画像(2c2)(この場合は数字の3)が視認され、図10(c)に示すように、図9に示したX3方向に傾けて透過光で観察する場合はY3に規則的に配置された潜像画像(2c3)(この場合は数字の4)が視認され、図10(d)に示すように、図9に示したX4方向に傾けて透過光で観察する場合はY4に規則的に配置された潜像画像(2c4)(この場合は数字の5)が視認される。つまり、透過光で異なる4方向から傾けて異なる4つの画像が視認できることとなる。また、基材の表裏どちらの面からも上記記載の同一方向から観察可能である。
【0037】
上記の真偽判別形成体(4b)は、4つの画像を出現されているが、言うまでもなく、2つ、3つの画像を出現させることもできる。また、潜像画像(2c1)、潜像画像(2c2)、潜像画像(2c3)、潜像画像(2c4)の4つの潜像画像は、穿孔(3a)に対して上下左右に規則的に配置されているが、斜め方向に規則的に配置させてもよく、この場合、上下左右に規則的に配置された穿孔と斜めに規則的に配置させて穿孔を組み合わせて8つの潜像画像を出現させることも可能である。また、このような複数の潜像画像を用いて、動画的にそれぞれの潜像画像の一部を異ならせ、真偽判別形成体を作製することによって、透過光で傾けて真偽判別形成体を回転させて観察することによって潜像画像が動画像のように動いて観察することができる。また、潜像画像(2c1)、潜像画像(2c2)、潜像画像(2c3)、潜像画像(2c4)の4つの潜像画像は、すべて異なっている画像を用いているが、同一の画像を用いても、同一の画像と異なった画像を組み合わせても良い。
【0038】
以上、真偽判別形成体(4a)、(4b)をまとめると、基材を貫通しない穿孔による潜像画像が、n個の異なった潜像画像を合成した穿孔によって構成され、n1の潜像画像を構成する穿孔が、基材を貫通する穿孔による画像を構成する穿孔に対して、一部重なるように規則性をもって配置され、n2、n3、n4…の潜像画像を構成する穿孔が、基材を貫通する穿孔による画像を構成する穿孔に対して、n1の潜像画像を設けた領域以外で、基材を貫通する穿孔による画像を構成する穿孔に、一部重なるように規則性をもって配置される必要がある。
【0039】
次に、基材に対して垂直方向から透過光で観察した場合に立体的な画像が視認できる場合を示す。基材を貫通する穿孔による画像は図1に示したものを用いる。基材に対して垂直方向から透過光で観察した場合に立体的な像が視認できるようにするためには、基材を貫通しない穿孔の配置に規則性を持たせる必要がある。図11に示すように、基材を貫通しない穿孔(3c)による一対の潜像画像(2c1、2c2)は、基材を貫通する穿孔(3a)と、一部重なるように、基材を貫通する穿孔(3a)に対して規則性をもって左右、上下等の対称に設ける必要がある。さらに、基材を貫通しない穿孔(3c)による一対の潜像画像(2c1、2c2)を配置する位置は、両眼視差を考慮した位置に配置する必要がある(図11)。
【0040】
基材を貫通しない穿孔(3c)による一対の潜像画像(2c1、2c2)を、基材を貫通する穿孔(3a)と、一部重なるように、基材を貫通する穿孔(3a)に対して対称に設けて作製した真偽判別形成体(4c)は、図12に示すように基材に対して垂直方向から透過光で観察した場合に、観察者の左眼には、基材を貫通する穿孔(3a)の右側に設けた、基材を貫通しない穿孔(3c)による潜像画像(2c1)が視認され、観察者の右眼には、基材を貫通する穿孔(3a)の左側に設けた、基材を貫通しない穿孔(3c)による潜像画像(2c2)が視認されることによって、基材を貫通しない穿孔による潜像画像が立体的に視認される。つまり、基材を貫通しない穿孔による一対の潜像画像(2c1、2c2)は、基材を貫通する穿孔による画像(2a)をパララックスバリアとする位置に配置する必要がある。
【0041】
本発明の穿孔はレーザ穿孔装置等で付与でき、大きさは50〜1000ミクロンが好ましい。穿孔の大きさは基材の厚みと表現したい画像の解像度や数と関係がある。当然、特定の領域に高い解像度の画像を表現する場合にはできるだけ小さな径の穿孔が必要であるが、数十ミクロン以下であると穿孔を作成する上で困難となる。また、大きな径の穿孔を用いる場合は、表現できる画像が粗いものとなってしまう。
【0042】
本発明の画像を形成する穿孔と潜像画像を形成する穿孔の重なる度合いは、潜像画像を形成する穿孔の直径の0%〜70%が好ましい。潜像画像を形成する穿孔の直径は、設ける潜像画像の数と関係があり、画像を形成する穿孔の直径の50%〜100%が好ましい。
【0043】
本発明に用いる基材は、特に限定されることはなく、紙葉類、フィルム、プラスティック等を利用することができる。また、基材の厚さについても特に限定されることはないが、0.1mmから1.0mm程度が好ましい。
【0044】
本発明の穿孔の形状は、特に限定されることはなく、円形、多角形及び特殊な形状の穿孔の少なくとも一つで形成する必要がある。多角形又は特殊な形状の穿孔を用いることによって、複製されにくくなるため偽造防止効果が向上する。
【0045】
本発明の画像を構成する穿孔及び潜像画像を構成する穿孔が、基材に対して直角及び特定の角度で斜めの形状の少なくとも一つで形成することができる。特定の角度で斜めに形成した場合、複製されにくくなるため偽造防止効果が向上する。特定の角度で斜めの角度を深めると潜像が視認される観察角度も多少深くなる。
【0046】
本発明の穿孔が、深さ方向に伴って、穿孔の直径が同一及び穿孔の直径が小さくなる形状の少なくとも一つで形成することによって、複製されにくくなるため偽造防止効果が向上する。
【0047】
本発明の潜像画像が、文字、数字、記号及び絵柄の少なくとも1つであることにより、透過光で傾けて観察した場合に真偽判別効果が向上する。
【0048】
本発明の基材を貫通しない穿孔により形成した穿孔群からなる潜像画像をカモフラージュするために基材を貫通しない穿孔により形成した穿孔群からなる潜像画像を形成した面に貫通しない穿孔を設けることによって、裏面から潜像画像が視認されてしまうことを防ぐことができる。カモフラージュの穿孔については図23に示す。
【0049】
本発明の穿孔の粗密、大きさ及び配置の少なくとも一つで潜像画像又は/及び画像を形成することによって潜像画像又は/及び画像に階調を付与することができる。
【0050】
以上の構成中の画像と潜像画像の配置関係を概念的に簡単に整理すると、図19に示す通りである。本発明の画像と潜像画像を形成する穿孔が基材に対して特定の角度で斜めに形成した場合の図を図20に示す。穿孔の角度以外は真偽判別形成体(4a)と同様な構成を示す構成を図20(a)に示す。穿孔の角度以外は真偽判別形成体(4b)と同様な構成を示す構成を図20(b)に示す。穿孔の角度以外は真偽判別形成体(4c)と同様な構成を示す構成を図20(c)に示す。図20(a)、図20(b)の効果は、真偽判別形成体(4a、4b)とは異なり、垂直方向から透過光で観察した場合に画像は観察できないが、傾けて観察した場合に画像が観察され、更に傾けると潜像画像が観察される。図20(c)の効果は真偽判別形成体(4c)とは異なり、垂直方向から透過光で観察した場合に画像は観察できないが、傾けて観察した場合に潜像画像が立体的に観察される。本発明の穿孔が、深さ方向に伴って、穿孔の径が小さくなる形成する場合の図を図21に示す。図21は、切頭円錐の一例を示す。また、本発明の画像と基材を潜像画像を形成する穿孔の大きさが同一の場合でも、穿孔の配置位置によっては基材を斜めから観察した場合に階調ある潜像画像を視認することができる。
【0051】
上記記載の真偽判別形成体(4a、4b、4c)は1枚の基材に形成されているが、本発明はこれに限定されることなく、次の構成によっても本発明の効果を奏することができる。図22(a)乃至(c)に示すように第1の基材(11a)と第2の基材(11b)を設ける2層構造にしても良い。この場合、画像および潜像画像は基材を貫通する穿孔を用いる。図22(a)は真偽判別形成体(4a)と同様な効果を示し、第1の基材(11a)に画像(2a)を構成する基材を貫通する穿孔(3a)を設け、第2の基材(11b)に潜像画像(2c)及び第1の基材(11a)に設けた画像(2a)と同一の画像(2a’)を構成する基材を貫通する穿孔(3c)を設けた構成である。図22(b)は真偽判別形成体(4b)と同様な効果を示し、第1の基材(11a)に画像(2a)を構成する基材を貫通する穿孔(3a)を設け、第2の基材(11b)に潜像画像(2c)及び第1の基材(11a)に設けた画像(2a)と同一の画像(2a’)を構成する基材を貫通する穿孔(3c)を設けた構成である。図22(c)は真偽判別形成体(4c)と同様な効果を示し、第1の基材(11a)に画像(2a)を構成する基材を貫通する穿孔(3a)を設け、第2の基材(11b)に潜像画像(2c)及び第1の基材(11a)に設けた画像(2a)と同一の画像(2a’)を構成する基材を貫通する穿孔(3c)を設けた構成である。第1の基材(11a)と第2の基材(11b)は接着剤等で接着されても良い。ただし、真偽判別形成体(4a、4b、4c)を2層構造で形成した場合、第1の基材を貫通する穿孔で構成された画像と第2の基材を貫通する穿孔で構成された画像が同一であり、且つ、第1の基材を貫通する穿孔で構成された画像と第2の基材を貫通する穿孔で構成された画像が重なるように、第1の基材と第2の基材が積層されている必要がある。また、穿孔の形状、大きさ、ピッチ、カモフラージュ等は真偽判別形成体(4a、4b、4c)と同様な要素を用いることができる。
【0052】
【実施例】
以下、実施例を用いて本発明を更に詳細に説明するが、本発明の内容は、これらの実施例の範囲に限定されるものではない。
【0053】
(実施例1)
厚さ約0.15mmの紙を1枚用意し、この紙に、直径0.1mmの穿孔を0.8mmの一定間隔で格子状にレーザ加工機によって紙を貫通させて図柄(A)を施した(図13参照)。またこの紙に、直径0.1mmの穿孔を0.8mmの一定間隔で、レーザ加工機によって紙を貫通させることなく一定の深さで潜像図柄(B)を施した(図13参照)。このとき、紙に施した図柄(A)の穿孔と、紙に施した潜像図柄(B)を形成する穿孔が、図柄(A)の穿孔を基準として左側に規則的に配置し、真偽判別形成体(C1)を作成した(図13参照)。この真偽判別形成体(C1)を反射光で観察した場合には、図柄(A)のみが視認され、透過光で図13の矢印に示す方向から観察した場合には、図14に示すように、画像(A)内に潜像図柄(B)が視認することができた。また、基材の表裏どちらの面からも上記記載の同一方向から観察できた。
【0054】
(実施例2)
厚さ約0.15mmの紙を1枚用意し、この紙に、直径0.1mmの穿孔を0.8mmの一定間隔で格子状に、レーザ加工機によって紙を貫通させて図柄(A)を施した(図15参照)。またこの紙に、直径0.1mmの穿孔を0.8mmの一定間隔で、レーザ加工機によって紙を貫通させることなく一定の深さで異なる4つの潜像図柄(B1)、潜像図柄(B2)、潜像図柄(B3)、潜像図柄(B4)が形成されている潜像図柄(B)を施した(図15参照)。紙に施した図柄(A)の穿孔と、紙に施した潜像図柄(B)を形成する穿孔が、図柄(A)の穿孔を基準として、潜像図柄(B1)を形成している穿孔が右側(上側を0度とした場合、90度)に規則的に配置し、潜像図柄(B2)を形成している穿孔が左側(上側を0度とした場合、270度)に規則的に配置し、潜像図柄(B3)を形成している穿孔が下側(上側を0度とした場合、180度)に規則的に配置し、潜像図柄(B4)を形成している穿孔が上側(上側を0度とした場合、0度)に規則的に配置して真偽判別形成体(C2)を作成した(図15参照)。この真偽判別形成体(C2)を反射光で観察した場合には、図柄(A)のみが視認され、透過光で図15に示す基材を貫通しない穿孔が形成されていない面からX1方向から観察した場合には、図16(a)に示すように図柄(A)内に潜像図柄(B1)が視認でき、透過光で図15に示すX2方向から観察した場合には、図16(b)に示すように図柄(A)内に潜像図柄(B2)が視認でき、透過光で図15に示すX3方向から観察した場合には、図16(c)に示すように図柄(A)内に潜像図柄(B3)が視認でき、透過光で図15に示すX4方向から観察した場合には、図16(d)に示すように図柄(A)内に潜像図柄(B4)が視認できた。また、基材の表裏どちらの面からも上記記載の同一方向から観察できた。
【0055】
(実施例3)
厚さ約0.3mmの紙を1枚用意し、この紙に、直径0.08mmの穿孔を0.8mmの一定間隔で格子状にレーザ加工機によって紙を貫通させて図柄(A)を施した(図17参照)。またこの紙に、直径0.08mmの穿孔を0.8mmの一定間隔で、レーザ加工機によって紙を貫通させることなく深さ約0.15mmで一対の潜像図柄(B1、B2)を施した(図17参照)。このとき、紙に施した図柄(A)の穿孔と、紙に施した一対の潜像図柄(B1、B2)を形成する穿孔が、図柄(A)の穿孔の中心から左側および右側0.04mmずらして規則的に配置し、真偽判別形成体(C3)を作成した(図17参照)。この真偽判別形成体(C3)を反射光で観察した場合には、図柄(A)のみが視認され、図18に示すように、基材に対して垂直方向から透過光で、約300mm離れた距離から観察した場合には、左眼と右眼にそれぞれ潜像図柄(B1)と潜像図柄(B2)が見えることから、図柄(A)内に立体的な潜像画像が視認することができた。
【0056】
以上、本発明の実施例に基づいて説明したが、本発明はこの実施例に限定されるものではなく、特許請求の範囲記載における技術的思想の範囲内であれば、その他のいろいろな実施の形態が考えられる。
【0057】
【発明の効果】
基材に貫通する穿孔群からなる画像と、これらの穿孔と基材を貫通しない穿孔群からなる潜像画像を形成し、画像を形成する基材を貫通する穿孔位置と、潜像画像を形成する基材を貫通しない穿孔位置を対応して配置することによって、透過光で観察した場合に明瞭な潜像画像の出現、多方向から異なる潜像画像の出現、鮮明な立体的な潜像画像の出現がされるため、真偽判別効果の高い、改ざん、複製防止効果のある真偽判別形成体と成り得、銀行券、パスポート、有価証券、カード、印紙類等の偽造、複写、改ざんを防止する必要性のある貴重印刷物に適用することができる。
【0058】
また、第1の基材に貫通する穿孔群からなる画像と、これらの穿孔と第2の基材を貫通する穿孔群からなる潜像画像を形成し、画像を形成する第1の基材を貫通する穿孔位置と、潜像画像を形成する第2の基材を貫通する穿孔位置を対応して配置して、第1の基材と第2の基材を積層することによって、透過光で観察した場合に明瞭な潜像画像の出現、多方向から異なる潜像画像の出現、鮮明な立体的な潜像画像の出現がされるため、真偽判別効果の高い、改ざん、複製防止効果のある真偽判別形成体と成り得、銀行券、パスポート、有価証券、カード、印紙類等の偽造、複写、改ざんを防止する必要性のある貴重印刷物に適用することができる。
【0059】
デザイン上、異なる複数の観察方向により第2の画像を出現させることが可能であり、真偽判別装置等を用いることなく誰でもその場で真偽判別することができる。また、本デバイスを偽造、改竄しようとした場合、基材を貫通する穿孔と基材を貫通しない穿孔の位置関係、又は、第1の基材を貫通する穿孔と第2の基材を貫通する穿孔の位置関係を忠実に再現する必要があり、微細な穿孔自体の再現のみならず、それらの配置までも再現することは非常に困難となる。
【0060】
本発明の真偽判別形成体はレーザを垂直に照射し、且つ、基材を水平方向に自動搬送するような大量生産ラインを構成する装置でも作製でき、基材に斜め穿孔を形成しなくとも潜像画像を形成できるため、複雑な加工機を用いることなく作製できる。
【0061】
【図面の簡単な説明】
【図1】基材(1a)に画像(2a)を穿孔(3a)により形成した図及びそのX−X’断面図である。
【図2】基材(1a)に潜像画像(2c)を穿孔(3c)により形成した図及びそのX−X’断面図を示す図である。
【図3】真偽判別形成体(4a)及びそのX−X’断面図を示す図である。
【図4】真偽判別形成体(4a)の透過光の方向を示す図である。
【図5】真偽判別形成体(4a)を反射光で観察した場合又は垂直方向から透過光で観察した場合を示す図である。
【図6】真偽判別形成体(4a)に対して図4に示した透過光が見える方向から透過光で観察した場合の図を示す図である。
【図7】観察可能な方向についての説明図である。
【図8】潜像画像(2c1)、潜像画像(2c2)、潜像画像(2c3)、潜像画像(2c4)の4つの潜像画像を示す図である。
【図9】潜像画像(2c1)、潜像画像(2c2)、潜像画像(2c3)、潜像画像(2c4)の4つの潜像画像を合成して作成した潜像画像(2c)を示す図である。
【図10】真偽判別形成体(4b)を透過光でX1方向、X2方向、X3方向、X4方向に傾けた場合の図である。
【図11】一対の潜像画像(2c1、2c2)を有する真偽判別形成体(4c)及びそのX−X’断面図を示す図である。
【図12】真偽判別形成体(4c)の立体像が視認される原理を示す図である。
【図13】紙を貫通する穿孔により施した図柄(A)及び紙を貫通しない穿孔により施した潜像図柄(B)から成る真偽判別形成体(C1)を示す図である。
【図14】真偽判別形成体(C1)を図11に示した方向から透過光で観察した場合を示す図である。
【図15】紙を貫通する穿孔により施した図柄(A)及び紙を貫通しない穿孔により施した潜像図柄(B1)、潜像図柄(B2)、潜像図柄(B3)、潜像図柄(B4)が合成された潜像図柄(B)から成る真偽判別形成体(C2)を示す図である。
【図16】真偽判別形成体(C2)を透過光でX1方向、X2方向、X3方向、X4方向に傾けて透過光で観察した場合を示す図である。
【図17】紙を貫通する穿孔により施した図柄(A)及び紙を貫通しない穿孔により施した一対の潜像図柄(B1、B2)から成る真偽判別形成体(C3)を示す図である。
【図18】真偽判別形成体(C3)で立体像が視認される観察方向を示す図である。
【図19】基材を貫通する穿孔で形成する画像と基材を貫通しない穿孔で形成する潜像画像の配置関係を概念的に簡単に示す図である。
【図20】基材に対して特定の角度で斜めに形成した場合の図である。
【図21】本発明の穿孔が、深さ方向に伴って、穿孔の直径が小さくなる場合の図である。
【図22】第1の基材(11a)と第2の基材(11b)を設ける2層構造を示す図である。
【図23】本発明のカモフラージュの穿孔の説明図である。
【図24】本発明で言う特定方向についての説明図である。
【符号の説明】
1a 基材
2a 画像
2a’ 同一の画像
2c、2c1、2c2、2c3、2c4 潜像画像
3a 基材を貫通する穿孔
3c、3c1、3c2、3c3、3c4 基材を貫通しない穿孔
4a、4b、4c 真偽判別形成体
11a 第1の基材
11b 第2の基材
A 図柄
B、B1、B2、B3、B4 潜像図柄
C1、C2、C3 真偽判別形成体
S カモフラージュ穿孔[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a true / false discrimination forming body applied to valuable printed matter that needs to be prevented from forgery and tampering such as banknotes, passports, securities, cards, and stamps.
[0002]
[Prior art]
Due to the nature of precious printed matter such as banknotes, passports, securities, cards, and stamps, they are required to be difficult to forge or alter. As a preventive measure, it is known to form numbers or the like on a substrate of these valuable printed materials by a plurality of perforations. There is also known a technique for performing authenticity determination by allowing a latent image to be visually recognized by tilting and observing a substrate having a plurality of perforations.
[0003]
The former is used for Swiss banknotes, and the numbers are expressed by perforations. In addition, the hole diameter is characterized in that the pattern formed by the naked eye cannot be seen in the reflective state, and the safety mark is composed of a plurality of holes that form a pattern on the document surface that is visible in the transparent state. A safekeeping document provided with a safety mark for preventing this is disclosed (for example, see Patent Document 1).
[0004]
[Patent Document 1]
JP 2000-501036 A (2nd page, Fig. 1-2)
[0005]
The latter is a true / false discriminating body having a base material and having a large number of fine perforations that are formed on the base material and form a background portion and an information portion consisting of a specific pattern that are difficult to see. A true / false discrimination formed body characterized in that the perforations forming the background portion and the perforations forming the information portion are formed so that at least one of the shape, size and arrangement direction of the perforations is different. (For example, refer to Patent Document 2).
[0006]
[Patent Document 2]
JP 2000-233561 (2nd page, Fig. 1-2)
[0007]
Also, a micro-perforated card having a card base with a large number of micro-perforations formed in a specific pattern to give information, the micro-perforations being applied to the card base by a laser processing machine A perforation formed by penetrating at a specific inclination angle, and projecting light from one side of the fine perforation card to the fine perforation card at the same angle as the specific inclination angle, thereby forming the fine perforation. A micro-perforated card is disclosed in which the above information is checked by transmitting the card (for example, see Patent Document 3).
[0008]
[Patent Document 3]
JP 2002-160477 (second page, FIG. 1)
[0009]
In addition, it is conceivable that an image is viewed three-dimensionally by binocular parallax by forming an image with perforations penetrating at different angles.
[0010]
[Problems to be solved by the invention]
In general, the above-described prior art generally recognizes a latent image when a numeral is formed on a base material by perforation, or when a part of the perforation is formed on the base material and tilted with transmitted light. It was a thing. The Japanese translation of PCT publication No. 2000-501036 only forms numbers and the like by perforation, and it is simple and has room for improvement as a forgery prevention technique. Japanese Patent Laid-Open No. 2000-233561 has a configuration in which the information part is concealed in the perforation group by combining the information part and the background part. If the depth is not deepened, the latent image may not appear clearly, and it is difficult to form a plurality of latent images. Japanese Patent Laid-Open No. 2002-160477 discloses a base image in which a perforation group including a plurality of perforations is provided on a base material, and a partial image of the perforation group is opened obliquely with respect to the base material to form a latent image. It is easy to construct a mass production line that can irradiate a laser beam vertically and automatically convey the substrate in the horizontal direction. Forming oblique perforations in the base material has a complicated processing machine configuration and is difficult to manufacture. In addition, it is conceivable that the image is viewed three-dimensionally by binocular parallax by forming an image with perforations penetrating at different angles. Could not get.
[0011]
In view of the above, the present invention is intended to solve the above-described problems. An image composed of a group of perforations penetrating the base material and a latent image composed of these perforations and a group of perforations that do not penetrate the base material. By arranging a perforation position that forms an image and penetrates the substrate on which the image is formed and a perforation position that does not penetrate the substrate on which the latent image is formed, a clear latent image can be obtained when observed with transmitted light. It has been found that the appearance of image images, the appearance of different latent image images from multiple directions, and the appearance of clear three-dimensional latent image images. Therefore, the present invention proposes a true / false discrimination forming body having a high authenticity discrimination effect and an effect of preventing falsification and duplication.
[0012]
In addition, an image composed of a perforation group penetrating the first base material and a latent image formed of the perforation group penetrating these perforations and the second base material are formed, and the first base material for forming the image is formed. By arranging the perforation position to penetrate and the perforation position to penetrate the second base material forming the latent image, and laminating the first base material and the second base material, When observed, it has been found that a clear latent image appears, a different latent image appears from multiple directions, and a clear three-dimensional latent image appears. Therefore, the present invention proposes a true / false discrimination forming body having a high authenticity discrimination effect and an effect of preventing falsification and duplication.
[0013]
[Means for Solving the Problems]
The present invention relates to an image comprising a group of perforations formed by perforations penetrating the two-dimensionally arranged base material formed on the base material, and perforations not penetrating the two-dimensionally arranged base material formed on the base material. Providing a latent image formed of the perforated group formed by the above, and each perforation position of the perforated group not penetrating the base material forming the latent image is defined by each of the perforated group penetrating the base material forming the image. It is a true / false discriminating body characterized by being arranged corresponding to the perforation position.
[0014]
The present invention also includes an image comprising a group of perforations formed by drilling through the two-dimensionally arranged base material formed on the base material, and the two-dimensionally arranged base material formed on the base material. Provided is a latent image formed by a perforation group formed by not perforating, and each perforation position of the perforation group not penetrating the base material forming the latent image is formed by a perforation group penetrating the base material forming the image Each of the perforation positions of the perforation group that does not penetrate the base material that forms the latent image is defined by the base that forms the image. With respect to the individual drilling positions of the drilling group that penetrates the material, the holes are arranged in a specific direction from the reference, and the holes that do not penetrate the base material and the holes that penetrate the base material are partially overlapped. It is a true / false discrimination formation characterized by Thus, when the authenticity determination formed body is observed with reflected light or transmitted light from a direction perpendicular to the base material, only an image including a group of perforations formed by perforations penetrating the base material can be visually recognized. When the false discrimination formed body is tilted from the vertical direction with respect to the base material and observed with transmitted light, it is formed by perforation not penetrating the base material in an image composed of a perforation group formed by perforation penetrating the base material. The authenticity determination formed body is characterized in that a latent image formed of a perforation group is visually recognized.
[0015]
The present invention also includes an image comprising a group of perforations formed by drilling through the two-dimensionally arranged base material formed on the base material, and the two-dimensionally arranged base material formed on the base material. Providing at least two latent image images formed by perforation groups formed by non-perforation, and each perforation position of the perforation group not penetrating the base material forming the at least two latent image images is defined by the base forming the image. An authenticity-determining forming body arranged corresponding to each perforation position of the perforation group that penetrates the material, and each perforation position of the perforation group that does not penetrate the base material that forms the at least two latent image images Is based on the individual perforation positions of the perforation group that penetrates the base material forming the image, and is arranged in a specific direction from the reference, and the perforation that does not penetrate the base material and the perforation that penetrates the base material So that some overlap And the specific direction is a direction different for each latent image, wherein the authenticity determination forming body is perpendicular to the reflected light or the substrate. When observed with transmitted light from a direction, only an image consisting of a group of perforations formed by perforations penetrating the substrate can be visually recognized, and the authenticity determination formed body is tilted in a different direction from a vertical direction with respect to the substrate. When observed with transmitted light, at least two latent image images consisting of perforations formed by perforations not penetrating the base material are visible in an image consisting of perforations formed by perforations penetrating the base material. Is a true / false discrimination formation characterized by
[0016]
The present invention also includes an image comprising a group of perforations formed by drilling through the two-dimensionally arranged base material formed on the base material, and the two-dimensionally arranged base material formed on the base material. Providing at least one latent image composed of a pair of perforation groups formed by not perforating, and each of the perforation positions of the pair of perforation groups not penetrating the base material forming the at least one latent image is A pair of true / false discriminating members arranged corresponding to the respective perforation positions of the perforation group penetrating the base material to be formed, the pair of pairs not penetrating the base material forming the at least one latent image An individual perforation position of one perforation group of the perforation group is partially overlapped with a perforation penetrating the base material in a specific direction with reference to the individual perforation position of the perforation group penetrating the base material forming the image. Placed in front and An individual perforation position of the other perforation group of the pair of perforation groups is different from the one perforation group in a specific direction with reference to an individual perforation position of the perforation group penetrating the base material forming the image. The pair of perforations that are arranged so as to partially overlap with the perforations that penetrate the base material, and that the pair of perforations that do not penetrate the base material are disposed at positions where the perforation group that penetrates the base material is a parallax barrier. A true / false discrimination formed body characterized in that, when the true / false discrimination formed body is observed with reflected light, only an image composed of a perforation group formed by perforations penetrating the base material can be visually recognized, When the authenticity determination formed body is observed with transmitted light from a direction perpendicular to the base material, it is formed by perforation not penetrating the base material in an image formed of a perforation group formed by perforation penetrating the base material. At least consisting of perforations One latent image is authenticity discrimination formed body characterized by being stereoscopically view.
[0017]
Further, the present invention provides an image comprising a group of perforations formed by perforations penetrating the first base material arranged in a two-dimensional manner formed on the first base material, and a two-dimensional shape formed on the second base material. A latent image formed by a perforation group formed by perforations penetrating the second base material arranged on the first base material and formed on the first base material composed of perforation groups formed by perforations penetrating the second base material The first base material that forms the image is provided with the same image as the processed image, and the individual perforation positions of the perforation group that penetrates the latent image and the second base material that forms the same image. Is a true / false discrimination formed body arranged corresponding to each perforation position of the perforation group penetrating through the.
[0018]
Further, the present invention provides an image comprising a group of perforations formed by perforations penetrating the first base material arranged in a two-dimensional manner formed on the first base material, and a two-dimensional shape formed on the second base material. A latent image formed by a perforation group formed by perforations penetrating the second base material arranged on the first base material and formed on the first base material composed of perforation groups formed by perforations penetrating the second base material The first base material that forms the image is provided with the same image as the processed image, and the individual perforation positions of the perforation group that penetrates the latent image and the second base material that forms the same image. A true / false discriminating body arranged corresponding to each perforation position of a perforation group penetrating through the image, the image formed on the first base material and the same formed on the second base material The images are arranged so that the images overlap each other and penetrate through the second base material forming the latent image. The individual perforation positions of the group are arranged in a specific direction from the reference with respect to the individual perforation positions of the perforation group penetrating the first base material forming the image, and form the same image. The perforations penetrating the second base material and the perforations penetrating the second base material forming the latent image are partially overlapped, and the first base material and the second base A true / false discriminating body characterized in that materials are laminated, and when the true / false discriminating body is observed with reflected light or transmitted light from a direction perpendicular to the base material, Only an image consisting of a group of perforations formed by perforations penetrating can be visually recognized, and formed by perforations penetrating the base material when the authenticity determination formed body is tilted from a perpendicular direction with respect to the base material and observed with transmitted light. By drilling through the substrate in an image consisting of drilled perforations A authenticity discrimination formation member latent image consisting forms perforations group, characterized in that it is visible.
[0019]
Further, the present invention provides an image comprising a group of perforations formed by perforations penetrating the first base material arranged in a two-dimensional manner formed on the first base material, and a two-dimensional shape formed on the second base material. And at least two latent image images formed by perforations formed by perforations penetrating the second base material and the first base formed by perforations formed by perforations penetrating the second base material. An image identical to the image formed on the material is provided, and the individual perforation positions of the perforation group penetrating the second base material forming the at least two latent image images and the same image form the image. A true / false discrimination forming body arranged corresponding to each perforation position of a perforation group penetrating the first base material, the image formed on the first base material and the second base material Are arranged so that the same images formed on the at least two The perforation position of the perforation group that penetrates the second base material that forms the latent image of is based on the individual perforation position of the perforation group that penetrates the first base material that forms the image, The perforations penetrating the second base material forming the same image and the second two forming the at least two latent image images are arranged in different specific directions for each latent image image from the reference. A true / false discriminating body characterized in that the first base material and the second base material are laminated so that the perforations penetrating through the base material partially overlap each other. When the false discrimination formed body is observed with reflected light or transmitted light from a direction perpendicular to the base material, only an image composed of a group of perforations formed by perforations penetrating the base material can be visually recognized, and the true / false discrimination formed body The transmitted light is tilted from the vertical direction to the substrate in a different direction. When observed, at least two latent image images consisting of a perforation group formed by perforations penetrating the base material are visually recognized in an image consisting of a perforation group formed by perforations penetrating the base material. It is a true / false discrimination formation.
[0020]
Further, the present invention provides an image comprising a group of perforations formed by perforations penetrating the first base material arranged in a two-dimensional manner formed on the first base material, and a two-dimensional shape formed on the second base material. At least one latent image composed of a pair of perforations formed by perforations penetrating the second base material arranged in the first and the first perforations formed by perforations penetrating the second base material. An image identical to the image formed on the base material is provided, and individual perforation positions of a pair of perforation groups penetrating the second base material forming the at least one latent image are formed by the image forming the image. Corresponding to the individual perforation positions of the perforation group penetrating the second substrate, the individual perforation positions of the perforation group penetrating the second base material forming the same image form the image. Corresponding to the individual drilling positions of the drilling group penetrating the first substrate An at least one latent image, wherein the at least one latent image is an authenticity determination formed body, wherein the at least one latent image is disposed so that an image formed on the first base material and an identical image formed on the second base material overlap each other. An individual perforation position of one perforation group of the pair of perforation groups that penetrates the second substrate forming the image is an individual perforation of the perforation group that penetrates the first substrate forming the image. An individual perforation position of the other perforation group of the pair of perforation groups is an individual perforation position of the perforation group penetrating the first substrate forming the image. The perforation penetrating through the second base material forming the same image and the at least one latent image formed in a specific direction in a direction different from the one perforation group with reference to Arranged so that the perforations that penetrate the second base material partially overlap The individual perforations of the pair of perforation groups formed on the second base material are arranged and stacked at a position where the perforation group penetrating the first base material forming the image is a parallax barrier. A true / false discriminating body characterized in that when the authenticity discriminating body is observed with reflected light, only an image consisting of a perforation group formed by perforations penetrating the base material can be visually recognized, When the true / false discrimination formed body is observed with transmitted light from a direction perpendicular to the base material, it is formed by perforation penetrating the base material in an image composed of a perforation group formed by perforation penetrating the base material. An authenticity determination forming body characterized in that at least one latent image formed of a perforation group is viewed three-dimensionally.
[0021]
Further, the present invention is characterized in that the perforations constituting the image and the perforations constituting the latent image are formed in at least one of a right angle and a specific shape at a specific angle with respect to the substrate. It is a false discrimination formation.
[0022]
Further, the present invention is the authenticity determination formed body in which the perforations constituting the image and the perforations constituting the latent image are arranged at equal pitches.
[0023]
Further, the present invention is the authenticity determination formed body characterized in that the diameter of the perforations constituting the image and the perforations constituting the latent image is 50 μm to 1000 μm.
[0024]
Further, the present invention relates to a true / false discrimination formation characterized in that the shape of the perforations constituting the image and the perforations constituting the latent image is at least one of a circular shape, a polygonal shape and a special shape. is there.
[0025]
Further, in the present invention, the authenticity determination formed body, wherein the perforations constituting the image and the perforations constituting the latent image are formed in a shape in which the diameter of the perforation decreases in the depth direction. It is.
[0026]
In addition, the present invention is the authenticity determination formed body, wherein the image and the latent image are at least one of a character, a number, a symbol, and a picture.
[0027]
Further, the present invention provides a surface on which a latent image formed of a perforated group formed by perforations not penetrating the base material is formed in order to camouflage a latent image formed of a perforated group formed by perforations not penetrating the base material. A true / false discrimination formed body provided with perforations that do not penetrate.
[0028]
Further, the present invention is provided with perforations for camouflaging a latent image formed by a perforation group formed by perforations penetrating the second base material arranged in a two-dimensional manner formed on the second base material. This is a true / false discrimination formation.
[0029]
FIG. 24 is an explanatory diagram for the specific direction described above. Here, the specific direction is the direction in which the perforations (3c) are formed with respect to the perforations (3a).
[0030]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the authenticity determination forming body according to the present invention will be described with reference to the drawings. The true / false discrimination formed body of the present invention is characterized by an image comprising a group of perforations formed by perforations penetrating through a two-dimensionally arranged substrate formed on the substrate, and a two-dimensionally arranged base formed on the substrate. A latent image composed of a perforation group formed by perforation not penetrating the material is provided, and each perforation position of the perforation group not penetrating the base material forming the latent image is determined by the perforation group penetrating the base material forming the image. Arrangement corresponding to each perforation position makes it possible to observe a latent image formed by perforation that does not penetrate the substrate when observed from a specific observation direction with transmitted light. In addition, an image including a group of perforations formed by perforations penetrating the first base material formed on the first base material and the second base material formed on the second base material. A latent image formed by a perforation group formed by perforation penetrating through the second base material and an image identical to the image formed on the first base material formed by perforation group formed by the perforation penetrating the second base material are provided. The individual perforation positions of the perforation group penetrating the latent image and the second substrate forming the same image correspond to the individual perforation positions of the perforation group penetrating the first substrate forming the image. Thus, the latent image formed in the second description can be observed when observed from a specific observation direction with transmitted light.
[0031]
FIG. 1 shows a view in which an image (2a) is formed on a substrate (1a) by perforation (3a) and a sectional view taken along line XX ′. As shown in FIG. 1, the perforations (3a) need to penetrate the substrate. FIG. 2 shows a view in which only the latent image (2c) is formed on the substrate (1a) by perforation (3c) and a cross-sectional view taken along line XX ′. As shown in FIG. 2, the perforations (3c) need to be formed at a certain depth or a predetermined depth without penetrating the substrate. Authenticity discrimination formed body (4a) on which image (2a) formed by perforation (3a) shown in FIGS. 1 and 2 and latent image (2c) formed by perforation (3c) are applied, and its XX 'A cross-sectional view is shown in FIG. As shown in FIG. 3, the perforations (3c) that do not penetrate through the base material (1a) need to be regularly arranged so as to partially overlap the perforations (3a) that penetrate through the base material (1a). In this case, the perforations (3c) that do not penetrate the substrate (1a) are regularly arranged on the left side with respect to the perforations (3a) that penetrate the substrate (1a). Or what is necessary is just to arrange | position regularly so that it may partially overlap with the lower part etc., ie, the peripheral region of the piercing | piercing (3a) which penetrates a base material (1a).
[0032]
FIG. 5A shows a case where the authenticity determination formed body (4a) is observed with reflected light, and FIG. 5B shows a case where the authenticity determination formed body (4a) is transmitted with light from a direction perpendicular to the substrate. The figure when observed is shown. As shown in FIG. 5A, the perforations (3c) that do not penetrate the base material (1a) forming the latent image (2c) are the same color as the base material. An observer will recognize only the image (2a) by the perforation which penetrates a base material (1a). Further, as shown in FIG. 5B, when the authenticity determination formed body (4a) is observed with transmitted light from a direction perpendicular to the base material, the observer perforates through the base material (1a). In order to feel strongly the light transmitted through (3a), only the image (2a) by the perforations (3a) penetrating the substrate (1a) is recognized. In either case, the latent image (2c) cannot be visually recognized.
[0033]
FIG. 6 shows a view when the authenticity determination formed body (4a) is observed with transmitted light from the X direction shown in FIG. As shown in FIG. 6, the latent image (2c) by the perforation (3c) not penetrating the base material (1a) is clearly visible in the image (2a) by the perforation (3a) penetrating the base material (1a). (In this case the number 1). This is because the perforations (3c) constituting the latent image (2c) provided on the substrate (1a) partially overlap the perforations (3a) constituting the image (2a) provided on the substrate (1a). 4 is transmitted from a region where the perforations (3a) and the perforations (3c) are visually recognized by observing from the direction in which the transmitted light can be observed as shown in FIG. Since the amount of transmitted light is hardly recognized from a region where the amount of light is strong and the perforation (3a) and the perforation (3c) do not overlap, the difference in contrast causes a latent image in the image (2a) as shown in FIG. The image (2c) can be visually recognized.
[0034]
As to the observable direction, as shown in FIG. 7, the perforation (3c) that does not penetrate the base material (1a) constituting the latent image (2c) and the base material (1a) that constitutes the image (2a) are penetrated. Depends on the arrangement rule with the perforation (3a) to be performed. That is, as shown in the XX ′ sectional view of FIG. 7, the base material constituting the latent image (2c) with respect to the perforations (3a) penetrating the base material (1a) constituting the image (2a). When the perforations (3c) that do not penetrate (1a) are regularly arranged on the Y1 side, it is necessary to incline in the X1 direction and observe with transmitted light, and when they are regularly arranged on the Y2 side, It is necessary to incline in the X2 direction and observe with transmitted light. Moreover, it can be observed from the same direction as described above from either the front or back surface of the substrate.
[0035]
Next, FIG. 9 shows a case where the authenticity determination formed body (4b) in which different latent image images can be seen from four different directions with transmitted light is viewed from the surface where the perforations that do not penetrate the substrate are formed. As the substrate, a substrate in which the image shown in FIG. 1 is formed by perforation is used. In order to be able to visually recognize different images from four different directions with transmitted light, it is necessary to provide regularity to the perforations that do not penetrate the substrate and the perforations that penetrate the substrate. For example, as shown in FIGS. 8A to 8D, four latent image images, that is, a latent image (2c1), a latent image (2c2), a latent image (2c3), and a latent image (2c4). When these four images are desired to appear, it is necessary to form a latent image (2c) on the substrate (1a), and the latent image (2c) provided on the substrate (1a) The configured perforations (3c) need to be regularly arranged so as to partially overlap the perforations (3a) for perforating the substrate (1a). When the perforations (3c) that do not penetrate the substrate (1a) are regularly arranged at the Y1 position with respect to the perforations (3a) as shown in FIG. 9 (in this case, the latent image 2c1), the X1 direction It is necessary to observe with transmitted light tilted in the direction of X2, and when arranged regularly at the Y2 position (in this case, the latent image 2c2), it is necessary to observe with transmitted light tilted in the X2 direction. , Regularly arranged at the Y3 position (in this case, the latent image 2c3), it is necessary to incline in the X3 direction and observe with transmitted light, and regularly arranged at the Y4 position (in this case, the latent image 2c3). In the case of the image 2c4), it is necessary to incline in the X4 direction and observe with transmitted light. Moreover, it can be observed from the same direction as described above from either the front or back surface of the substrate.
[0036]
Therefore, the authenticity determination formed body (4b) provided with the latent image (2c) by the perforation that does not penetrate the base material (1a) has the base shown in FIG. In the case of observing with transmitted light tilted in the X1 direction from a surface where no perforations that do not penetrate the material are formed, a latent image (2c1) (in this case, the number 2) regularly arranged in Y1 is visually recognized, As shown in FIG. 10B, when observing with transmitted light tilted in the X2 direction shown in FIG. 9, the latent image (2c2) (in this case, the number 3) regularly arranged in Y2 is obtained. As shown in FIG. 10 (c), the latent image (2c3) regularly arranged in Y3 (in this case, a numerical number) when tilted in the X3 direction shown in FIG. 4) is visually recognized, and as shown in FIG. 10 (d), it is tilted in the X4 direction shown in FIG. Latent images which are regularly arranged in Y4 (2c4) (5 in this case is a number) it is visible when the Judging. That is, four different images can be visually recognized by tilting from four different directions with transmitted light. Moreover, it can be observed from the same direction as described above from either the front or back surface of the substrate.
[0037]
In the authenticity discrimination formation body (4b), four images have appeared. Needless to say, two or three images can also appear. The four latent image images of the latent image (2c1), the latent image (2c2), the latent image (2c3), and the latent image (2c4) are regularly arranged vertically and horizontally with respect to the perforation (3a). However, it may be arranged regularly in an oblique direction. In this case, eight latent image images are formed by combining the holes regularly arranged vertically and horizontally and the holes regularly arranged obliquely. It is also possible to make it appear. Further, by using such a plurality of latent image images, a part of each latent image is differentiated in a moving image to produce a true / false discriminating body, which is tilted by transmitted light, and an authenticity discriminating body. By rotating and observing, the latent image can move and be observed like a moving image. The four latent image images of the latent image (2c1), the latent image (2c2), the latent image (2c3), and the latent image (2c4) are all different images. Even if an image is used, a different image may be combined with the same image.
[0038]
As described above, when the authenticity determination formed bodies (4a) and (4b) are put together, the latent image formed by the perforations that do not penetrate the base material is formed by the perforations obtained by synthesizing n different latent image images. The perforations constituting the image are arranged with regularity so as to partially overlap the perforations constituting the image by the perforations penetrating the substrate, and the perforations constituting the latent image of n2, n3, n4. With respect to the perforations constituting the image by the perforation penetrating the base material, with regularity so as to partially overlap the perforations constituting the image by the perforation penetrating the base material, except for the region where the n1 latent image is provided. Need to be deployed.
[0039]
Next, a case where a three-dimensional image can be visually recognized when observed with transmitted light from a direction perpendicular to the substrate will be described. The image shown in FIG. 1 is used as an image by drilling through the substrate. In order to make a three-dimensional image visible when observed with transmitted light from a direction perpendicular to the substrate, it is necessary to provide regularity in the arrangement of the perforations that do not penetrate the substrate. As shown in FIG. 11, the pair of latent image images (2c1, 2c2) by the perforations (3c) that do not penetrate the substrate penetrates the substrate so as to partially overlap the perforations (3a) that penetrate the substrate. It is necessary to provide regularity symmetrically with respect to the perforation (3a) to be performed, such as left and right and up and down. Furthermore, the position where the pair of latent image (2c1, 2c2) by the perforation (3c) that does not penetrate the base material needs to be arranged at a position that takes binocular parallax into consideration (FIG. 11).
[0040]
A pair of latent image (2c1, 2c2) by a perforation (3c) that does not penetrate the base material is compared with a perforation (3a) that penetrates the base material so as to partially overlap the perforation (3a) that penetrates the base material. As shown in FIG. 12, the true / false discrimination formed body (4c) prepared symmetrically is observed with the transmitted light from the direction perpendicular to the base material. The latent image (2c1) provided by the perforation (3c) provided on the right side of the perforation (3a) that does not penetrate the base material is visually recognized, and the right eye of the observer has the perforation (3a) that penetrates the base material. The latent image (2c2) provided on the left side by the perforation (3c) that does not penetrate the base material is visually recognized, so that the latent image by the perforation that does not penetrate the base material is viewed three-dimensionally. That is, the pair of latent image images (2c1, 2c2) formed by the perforations that do not penetrate the base material needs to be arranged at positions where the images (2a) formed by the perforations that penetrate the base material are used as the parallax barrier.
[0041]
The perforation of the present invention can be applied with a laser perforation apparatus or the like, and the size is preferably 50 to 1000 microns. The size of the perforation is related to the thickness of the substrate and the resolution and number of images to be expressed. Naturally, when a high-resolution image is expressed in a specific area, a hole having a diameter as small as possible is necessary. However, if it is several tens of microns or less, it is difficult to create the hole. In addition, when a large-diameter perforation is used, an image that can be expressed becomes rough.
[0042]
The overlapping degree of the perforations that form the image of the present invention and the perforations that form the latent image is preferably 0% to 70% of the diameter of the perforations that form the latent image. The diameter of the perforations that form the latent image is related to the number of latent images that are provided, and is preferably 50% to 100% of the diameter of the perforations that form the image.
[0043]
The substrate used in the present invention is not particularly limited, and paper sheets, films, plastics and the like can be used. The thickness of the substrate is not particularly limited, but is preferably about 0.1 mm to 1.0 mm.
[0044]
The shape of the perforation of the present invention is not particularly limited, and it is necessary to form at least one of a circular shape, a polygonal shape, and a special shape. By using polygonal or specially shaped perforations, the anti-counterfeiting effect is improved because it becomes difficult to be duplicated.
[0045]
The perforation constituting the image of the present invention and the perforation constituting the latent image can be formed in at least one of a right angle and a specific angle with respect to the substrate. When it is formed obliquely at a specific angle, it becomes difficult to replicate, so the forgery prevention effect is improved. When the oblique angle is deepened at a specific angle, the observation angle at which the latent image is visually recognized becomes somewhat deeper.
[0046]
By forming the perforations of the present invention with at least one shape having the same perforation diameter and a smaller perforation diameter in the depth direction, the anti-counterfeiting effect is improved because the perforation according to the present invention is less likely to be duplicated.
[0047]
When the latent image of the present invention is at least one of a character, a number, a symbol, and a picture, the true / false discrimination effect is improved when the image is tilted with transmitted light.
[0048]
In order to camouflage a latent image formed of perforations formed by perforations not penetrating the substrate of the present invention, a non-penetrating perforation is provided on a surface on which a latent image formed of perforations formed by perforations not penetrating the substrate is formed. Thus, it is possible to prevent the latent image from being visually recognized from the back surface. The camouflage perforation is shown in FIG.
[0049]
By forming the latent image or / and the image with at least one of the density, size and arrangement of the perforations of the present invention, gradation can be imparted to the latent image or / and the image.
[0050]
FIG. 19 shows a conceptual arrangement of the relationship between the image and the latent image in the above configuration. FIG. 20 shows a case where the perforations forming the image and latent image of the present invention are formed obliquely at a specific angle with respect to the substrate. FIG. 20A shows a configuration showing the same configuration as the authenticity determination formed body (4a) except for the angle of perforation. FIG. 20B shows a configuration showing the same configuration as the authenticity determination formed body (4b) except for the angle of perforation. FIG. 20 (c) shows a configuration showing the same configuration as the authenticity determination formed body (4c) except for the perforation angle. The effect of FIGS. 20A and 20B is different from the authenticity determination formation body (4a, 4b), but the image cannot be observed when observed with transmitted light from the vertical direction, but when tilted and observed. An image is observed on the screen, and a latent image is observed when the image is further tilted. The effect of FIG. 20 (c) is different from the authenticity determination formation body (4c), but the image cannot be observed when observed with transmitted light from the vertical direction, but the latent image is observed stereoscopically when observed with an inclination. Is done. FIG. 21 shows a diagram in which the perforation of the present invention is formed so that the diameter of the perforation becomes smaller in the depth direction. FIG. 21 shows an example of a truncated cone. In addition, even when the size of the perforations forming the latent image on the substrate and the image of the present invention are the same, depending on the position of the perforations, the latent image having a gradation is visually recognized when the substrate is observed from an oblique direction. be able to.
[0051]
The authenticity-determining formed body (4a, 4b, 4c) described above is formed on a single substrate, but the present invention is not limited to this, and the effects of the present invention are also achieved by the following configuration. be able to. As shown in FIGS. 22A to 22C, a two-layer structure in which a first base material (11a) and a second base material (11b) are provided may be used. In this case, the image and latent image use perforations that penetrate the substrate. FIG. 22 (a) shows the same effect as the authenticity determination formed body (4a), and the first base material (11a) is provided with perforations (3a) penetrating the base material constituting the image (2a). Perforation (3c) penetrating through the base material constituting the latent image (2c) on the second base material (11b) and the same image (2a ′) as the image (2a) provided on the first base material (11a) Is provided. FIG. 22B shows the same effect as the true / false discrimination formed body (4b), and the first base material (11a) is provided with perforations (3a) penetrating the base material constituting the image (2a). Perforation (3c) penetrating through the base material constituting the latent image (2c) on the second base material (11b) and the same image (2a ′) as the image (2a) provided on the first base material (11a) Is provided. FIG. 22 (c) shows the same effect as the authenticity determination formed body (4c), and the first base material (11a) is provided with perforations (3a) penetrating the base material constituting the image (2a). Perforation (3c) penetrating through the base material constituting the latent image (2c) on the second base material (11b) and the same image (2a ′) as the image (2a) provided on the first base material (11a) Is provided. The first substrate (11a) and the second substrate (11b) may be bonded with an adhesive or the like. However, when the authenticity determination formed body (4a, 4b, 4c) is formed in a two-layer structure, it is composed of an image composed of perforations penetrating the first base material and perforations penetrating the second base material. The first substrate and the first substrate are overlapped so that the images formed by the perforations penetrating the first substrate overlap the images formed by the perforations penetrating the second substrate. 2 base materials need to be laminated. The shape, size, pitch, camouflage and the like of the perforations can use the same elements as the authenticity discrimination formed bodies (4a, 4b, 4c).
[0052]
【Example】
EXAMPLES Hereinafter, although this invention is demonstrated further in detail using an Example, the content of this invention is not limited to the range of these Examples.
[0053]
Example 1
Prepare a sheet of paper with a thickness of about 0.15 mm, and make a pattern (A) on this paper by drilling holes with a diameter of 0.1 mm in a grid pattern at regular intervals of 0.8 mm with a laser processing machine. (See FIG. 13). Further, a latent image pattern (B) was applied to the paper at a constant depth by drilling holes having a diameter of 0.1 mm at a constant interval of 0.8 mm without penetrating the paper with a laser processing machine (see FIG. 13). At this time, the perforations of the pattern (A) made on the paper and the perforations forming the latent image design (B) made on the paper are regularly arranged on the left side with respect to the perforations of the pattern (A). A discrimination formation (C1) was prepared (see FIG. 13). When this authenticity determination formed body (C1) is observed with reflected light, only the pattern (A) is visually recognized, and when observed with transmitted light from the direction indicated by the arrow in FIG. 13, as shown in FIG. In addition, the latent image pattern (B) was visible in the image (A). Moreover, it was observable from the same direction as described above from both the front and back surfaces of the substrate.
[0054]
(Example 2)
Prepare a sheet of paper with a thickness of about 0.15 mm. On this paper, drill holes with a diameter of 0.1 mm are formed in a lattice pattern at regular intervals of 0.8 mm, and the paper is penetrated by a laser machine. (See FIG. 15). Further, four latent image designs (B1) and latent image designs (B2) having different diameters of 0.1 mm diameter perforations at constant intervals of 0.8 mm without penetrating the paper with a laser processing machine. ), A latent image symbol (B) in which a latent image symbol (B3) and a latent image symbol (B4) are formed (see FIG. 15). The perforation of the pattern (A) made on the paper and the perforation forming the latent image design (B) made on the paper form the latent image design (B1) based on the perforation of the pattern (A). Are regularly arranged on the right side (90 degrees when the upper side is 0 degree), and the perforations forming the latent image pattern (B2) are regular on the left side (270 degrees when the upper side is 0 degree). The perforations forming the latent image pattern (B3) are regularly arranged on the lower side (180 degrees when the upper side is 0 degree) and forming the latent image design (B4). Are regularly arranged on the upper side (0 degree when the upper side is 0 degree) to produce a true / false discrimination formed body (C2) (see FIG. 15). When this authenticity determination formed body (C2) is observed with reflected light, only the pattern (A) is visually recognized, and the X1 direction from the surface where the perforated light that does not penetrate through the base material shown in FIG. 16A, the latent image symbol (B1) can be visually recognized in the symbol (A) as shown in FIG. 16A, and when observed from the X2 direction shown in FIG. As shown in (b), the latent image (B2) can be visually recognized in the pattern (A), and when viewed from the X3 direction shown in FIG. 15 with transmitted light, the design ( When the latent image symbol (B3) is visible in A) and observed from the X4 direction shown in FIG. 15 with transmitted light, the latent image symbol (B4) is displayed in the symbol (A) as shown in FIG. ) Was visible. Moreover, it was observable from the same direction as described above from both the front and back surfaces of the substrate.
[0055]
(Example 3)
Prepare a sheet of paper with a thickness of approximately 0.3 mm, and make a pattern (A) on this paper by drilling holes with a diameter of 0.08 mm in a lattice pattern at regular intervals of 0.8 mm with a laser machine. (See FIG. 17). In addition, a pair of latent images (B1, B2) with a depth of about 0.15 mm were made on this paper by drilling holes with a diameter of 0.08 mm at regular intervals of 0.8 mm without penetrating the paper with a laser processing machine. (See FIG. 17). At this time, the perforations of the pattern (A) applied to the paper and the perforations forming the pair of latent image patterns (B1, B2) applied to the paper are 0.04 mm on the left and right sides from the center of the perforation of the pattern (A). The authenticity determination formation body (C3) was created by shifting and arranging regularly (see FIG. 17). When this authenticity determination formed body (C3) is observed with reflected light, only the pattern (A) is visually recognized, and as shown in FIG. When viewing from a distance, since the latent image pattern (B1) and the latent image pattern (B2) are visible to the left eye and the right eye, respectively, a stereoscopic latent image must be visually recognized in the pattern (A). I was able to.
[0056]
Although the present invention has been described based on the embodiment of the present invention, the present invention is not limited to this embodiment, and various other implementations are possible within the scope of the technical idea described in the claims. Possible forms.
[0057]
【The invention's effect】
An image composed of a group of perforations penetrating the base material and a latent image formed of the perforations and a group of perforations not penetrating the base material are formed, and a perforation position penetrating the base material forming the image and a latent image are formed. By arranging the perforation positions that do not penetrate through the base material, the appearance of a clear latent image when observed with transmitted light, the appearance of different latent images from multiple directions, and a clear three-dimensional latent image Therefore, it is possible to become a true / fake discrimination formation with high falsification effect, falsification and anti-duplication effect, and counterfeiting, copying and falsification of banknotes, passports, securities, cards, stamps, etc. It can be applied to valuable prints that need to be prevented.
[0058]
In addition, an image composed of a perforation group penetrating the first base material and a latent image formed of the perforation group penetrating these perforations and the second base material are formed, and the first base material for forming the image is formed. By arranging the perforation position to penetrate and the perforation position to penetrate the second base material forming the latent image, and laminating the first base material and the second base material, When observed, a clear latent image appears, a different latent image appears from multiple directions, and a clear three-dimensional latent image appears. It can be a certain authenticity-determining body, and can be applied to valuable printed matter that needs to prevent counterfeiting, copying, and falsification of banknotes, passports, securities, cards, stamps and the like.
[0059]
In design, the second image can appear in a plurality of different observation directions, and anyone can determine authenticity on the spot without using an authenticity determination device or the like. In addition, when the device is counterfeited or tampered with, the positional relationship between the perforation penetrating the base material and the perforation not penetrating the base material, or the perforation penetrating the first base material and penetrating the second base material It is necessary to faithfully reproduce the positional relationship of the perforations, and it is very difficult to reproduce not only the fine perforations themselves but also their arrangement.
[0060]
The true / false discrimination formed body of the present invention can be manufactured even in an apparatus that constitutes a mass production line that irradiates a laser vertically and automatically conveys the base material in the horizontal direction without forming oblique perforations in the base material. Since a latent image can be formed, it can be produced without using a complicated processing machine.
[0061]
[Brief description of the drawings]
FIG. 1 is a diagram in which an image (2a) is formed on a substrate (1a) by perforation (3a) and a sectional view taken along line XX ′.
FIG. 2 is a diagram in which a latent image (2c) is formed on a substrate (1a) by perforation (3c) and a cross-sectional view taken along the line XX ′.
FIG. 3 is a view showing a true / false discrimination formed body (4a) and its XX ′ cross-sectional view.
FIG. 4 is a diagram showing the direction of transmitted light of the authenticity discrimination formed body (4a).
FIG. 5 is a view showing a case where the authenticity determination formed body (4a) is observed with reflected light or observed with transmitted light from the vertical direction.
6 is a diagram showing a case where the authenticity determination formed body (4a) is observed with transmitted light from the direction in which the transmitted light shown in FIG. 4 can be seen. FIG.
FIG. 7 is an explanatory diagram of directions that can be observed.
FIG. 8 is a diagram showing four latent image images of a latent image (2c1), a latent image (2c2), a latent image (2c3), and a latent image (2c4).
FIG. 9 shows a latent image (2c) created by synthesizing four latent images: a latent image (2c1), a latent image (2c2), a latent image (2c3), and a latent image (2c4). FIG.
FIG. 10 is a view when the authenticity determination formed body (4b) is tilted with transmitted light in the X1, X2, X3, and X4 directions.
FIG. 11 is a diagram showing a true / false discrimination formed body (4c) having a pair of latent image images (2c1, 2c2) and its XX ′ cross-sectional view.
FIG. 12 is a diagram showing the principle by which a stereoscopic image of a true / false discrimination formed body (4c) is visually recognized.
FIG. 13 is a diagram showing a true / false discrimination formed body (C1) composed of a pattern (A) made by perforation penetrating paper and a latent image design (B) made by perforation not penetrating paper.
14 is a view showing a case where a true / false discrimination formed body (C1) is observed with transmitted light from the direction shown in FIG. 11. FIG.
FIG. 15 shows a pattern (A) made by drilling through the paper and a latent image design (B1), latent image design (B2), latent image design (B3), latent image design (by a hole that does not penetrate the paper). It is a figure which shows the authenticity determination formation body (C2) which consists of the latent image design (B) which B4) synthesize | combined.
FIG. 16 is a diagram showing a case where the authenticity determination formed body (C2) is observed with transmitted light after being tilted in the X1, X2, X3, and X4 directions with transmitted light.
FIG. 17 is a diagram showing a true / false discrimination formed body (C3) composed of a pattern (A) given by perforation penetrating paper and a pair of latent image symbols (B1, B2) given by perforation not penetrating paper. .
FIG. 18 is a diagram showing an observation direction in which a stereoscopic image is visually recognized by a true / false discrimination formed body (C3).
FIG. 19 is a diagram conceptually simply showing an arrangement relationship between an image formed by perforation penetrating a base material and a latent image formed by perforation not penetrating the base material.
FIG. 20 is a diagram showing a case where the substrate is formed obliquely at a specific angle with respect to the substrate.
FIG. 21 is a view showing a case where the diameter of the perforation according to the present invention becomes smaller in the depth direction.
FIG. 22 is a diagram showing a two-layer structure in which a first base material (11a) and a second base material (11b) are provided.
FIG. 23 is an explanatory view of perforation of a camouflage according to the present invention.
FIG. 24 is an explanatory diagram of a specific direction referred to in the present invention.
[Explanation of symbols]
1a Base material
2a image
2a 'the same image
2c, 2c1, 2c2, 2c3, 2c4 latent image
3a Drilling through the substrate
3c, 3c1, 3c2, 3c3, 3c4 Perforations that do not penetrate the substrate
4a, 4b, 4c Authenticity discriminator
11a First base material
11b Second base material
A design
B, B1, B2, B3, B4 Latent image design
C1, C2, C3 Authenticity discriminator
S Camouflage perforation
Claims (13)
前記潜像画像を形成する前記基材を貫通しない穿孔群の個々の穿孔位置は、前記基材を貫通する穿孔群の個々の穿孔位置を基準とし、前記基準から特定方向に配置され、且つ、前記基材を貫通しない穿孔と前記基材を貫通する穿孔が一部重なるように配置されていることを特徴とする真偽判別形成体。A latent image formed of a perforation group formed by perforation penetrating the base material and a perforation group formed by perforation not penetrating the base material is provided, and each of the perforation group not penetrating the base material forming the latent image image is provided. The perforation position is a true / false discrimination formed body arranged corresponding to each perforation position of a group of perforations penetrating the substrate,
The individual perforation positions of the perforation group that does not penetrate the base material forming the latent image are based on the individual perforation positions of the perforation group that penetrate the base material, are arranged in a specific direction from the reference, and An authenticity determination formed body, wherein the perforations that do not penetrate the base material and the perforations that penetrate the base material partially overlap each other.
前記少なくとも二つの潜像画像を形成する前記基材を貫通しない穿孔群の個々の穿孔位置は、前記基材を貫通する穿孔群の個々の穿孔位置を基準とし、前記基準から特定方向に配置され、且つ、前記基材を貫通しない穿孔と前記基材を貫通する穿孔が一部重なるように配置され、更に、前記特定方向はそれぞれの潜像画像毎に異なる方向であることを特徴とする真偽判別形成体。Providing at least two latent image images comprising a perforation group formed by perforations penetrating the base material and a perforation group formed by perforations not penetrating the base material, and penetrating the base material forming the at least two latent image images The individual perforation position of the perforation group that is not a true / false discrimination formed body arranged corresponding to the individual perforation position of the perforation group penetrating the substrate,
The individual perforation positions of the perforation group that does not penetrate the base material forming the at least two latent image images are arranged in a specific direction from the reference with respect to the individual perforation positions of the perforation group that penetrate the base material. And the perforation that does not penetrate the base material and the perforation that penetrates the base material are partially overlapped, and the specific direction is different for each latent image. False discrimination formation.
前記少なくとも一つの潜像画像を形成する前記基材を貫通しない前記一対の穿孔群の一方の穿孔群の個々の穿孔位置は、前記基材を貫通する穿孔群の個々の穿孔位置を基準として特定方向に前記基材を貫通する穿孔と一部重なるように配置され、且つ、前記一対の穿孔群の他方の穿孔群の個々の穿孔位置は、前記基材を貫通する穿孔群の個々の穿孔位置を基準として前記一方の穿孔群とは異なる方向で特定方向に前記基材を貫通する穿孔と一部重なるように配置され、更に、前記基材を貫通しない前記一対の穿孔群は、前記基材を貫通する穿孔群をパララックスバリアとする位置に配置されていることを特徴とする真偽判別形成体。The base material provided with at least one latent image formed of a perforation group formed by perforation penetrating the base material and a pair of perforation groups formed by perforation not penetrating the base material to form the at least one latent image image The individual perforation positions of the pair of perforation groups that do not pass through is a true / false discrimination formed body arranged corresponding to the individual perforation positions of the perforation group that penetrates the substrate,
The individual perforation positions of one perforation group of the pair of perforation groups that do not penetrate the base material forming the at least one latent image is specified with reference to the individual perforation positions of the perforation group that penetrates the base material Are arranged so as to partially overlap the perforations penetrating the base material in the direction, and the individual perforation positions of the other perforation group of the pair of perforation groups are the individual perforation positions of the perforation group penetrating the base material The pair of perforation groups which are arranged so as to partially overlap with the perforations penetrating the base material in a specific direction in a direction different from the one perforated group with reference to A true / false discrimination formed body, which is disposed at a position where a group of perforations penetrating through is used as a parallax barrier.
前記第1の基材に形成された穿孔群と前記第2の基材に形成された同一の穿孔群が重なるように配置され、
前記潜像画像を形成する前記第2の基材を貫通する穿孔群の個々の穿孔位置は、前記第1の基材を貫通する穿孔群の個々の穿孔位置を基準とし、前記基準から特定方向に配置され、且つ、前記同一の穿孔群を形成する前記第2の基材を貫通する穿孔と前記潜像画像を形成する前記第2の基材を貫通する穿孔が一部重なるように配置され、前記第1の基材と前記第2の基材が積層されていることを特徴とする真偽判別形成体。A latent image formed by a perforation group formed by perforation penetrating the first base material and a perforation group formed by perforation penetrating the second base material, and a perforation formed by perforation penetrating the second base material A perforation group identical to the perforation group formed on the first base material is provided, and each perforation group of the perforation group penetrating the second base material forming the latent image and the same perforation group The position is a true / false discriminating body that is arranged corresponding to the individual perforation position of the perforation group that penetrates the first base material,
The perforation group formed on the first base material and the same perforation group formed on the second base material are arranged so as to overlap,
The individual perforation positions of the perforation group penetrating the second base material forming the latent image are based on the individual perforation positions of the perforation group penetrating the first base material, and are in a specific direction from the reference. And the perforations penetrating the second base material forming the same perforation group and the perforations penetrating the second base material forming the latent image are partially overlapped. A true / false discrimination formed body in which the first base material and the second base material are laminated.
前記第1の基材に形成された穿孔群と前記第2の基材に形成された同一の穿孔群が重なるように配置され、
前記少なくとも二つの潜像画像を形成する前記第2の基材を貫通する穿孔群の個々の穿孔位置は、前記第1の基材を貫通する穿孔群の個々の穿孔位置を基準とし、前記基準からそれぞれの潜像画像毎に異なる特定方向に配置され、且つ、前記同一の穿孔群を形成する前記第2の基材を貫通する穿孔と前記少なくとも二つの潜像画像を形成する前記第2の基材を貫通する穿孔が一部重なるように配置され、前記第1の基材と前記第2の基材が積層されていることを特徴とする真偽判別形成体。By a perforation group formed by perforations penetrating through the first substrate and at least two latent images formed by perforations formed by perforation penetrating the second substrate and perforations penetrating the second substrate A perforation group identical to the perforation group formed on the first base material formed of the formed perforation group is provided, and penetrates the second base material forming the at least two latent image images and the same perforation group. An individual perforation position of the perforation group is a true / false discrimination formed body arranged corresponding to each perforation position of the perforation group penetrating the first base material,
The perforation group formed on the first base material and the same perforation group formed on the second base material are arranged so as to overlap,
The individual perforation positions of the perforation group penetrating the second base material forming the at least two latent image images are based on the individual perforation positions of the perforation group penetrating the first base material, and the reference Are arranged in different specific directions for each of the latent image images, and the second holes for forming the at least two latent image images and the perforations penetrating the second base material forming the same hole group. A true / false discrimination formed body, wherein the first base material and the second base material are laminated such that a part of perforations penetrating the base material overlap each other.
前記少なくとも一つの潜像画像を形成する前記第2の基材を貫通する前記一対の穿孔群の一方の穿孔群の個々の穿孔位置は、前記第1の基材を貫通する穿孔群の個々の穿孔位置を基準として特定方向に配置にされ、且つ、前記一対の穿孔群の他方の穿孔群の個々の穿孔位置は、前記第1の基材を貫通する穿孔群の個々の穿孔位置を基準として前記一方の穿孔群とは異なる方向で特定方向に配置され、且つ、前記同一の穿孔群を形成する前記第2の基材を貫通する穿孔と前記少なくとも一つの潜像画像を形成する前記第2の基材を貫通する穿孔が一部重なるように配置され、前記第2の基材に形成された一対の穿孔群の個々の穿孔は、前記第1の基材を貫通する穿孔群をパララックスバリアとする位置に配置され積層されたことを特徴とする真偽判別形成体。At least one latent image composed of a perforation group formed by perforation penetrating the first base material and a pair of perforation groups formed by perforation penetrating the second base material, and the second base material are penetrated. A pair of perforations that penetrates the second base material provided with the same perforation group as the perforation group formed on the first base material, the perforation group formed by perforation, and that forms the at least one latent image. The individual perforation positions of the holes correspond to the individual perforation positions of the perforations group penetrating the second substrate, and the individual perforations of the perforation group penetrating the second substrate forming the same perforation group The position is a true / false discrimination forming body arranged corresponding to each perforation position of the perforation group penetrating the first base material, and the perforation group formed on the first base material and the first perforation group Arranged so that the same perforation group formed on the two substrates overlap,
An individual perforation position of one perforation group of the pair of perforation groups penetrating the second substrate forming the at least one latent image is an individual perforation group of the perforation group penetrating the first substrate. An individual drilling position of the other drilling group of the pair of drilling groups is set with reference to an individual drilling position of the drilling group penetrating the first base material. The second hole that is arranged in a specific direction in a different direction from the one hole group and that penetrates the second base material forming the same hole group and forms the at least one latent image. The perforations penetrating through the first base material are arranged so that a part of the perforations penetrating the base material overlap, and the individual perforations of the pair of perforated groups formed in the second base material are parallaxed. Truth characterized by being placed and laminated at the position to be the barrier Discrimination former.
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Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2006315202A (en) * | 2005-05-10 | 2006-11-24 | Nozaki Insatsu Shigyo Kk | Printing sheet with identification mark and its manufacturing method |
JP2009109653A (en) * | 2007-10-29 | 2009-05-21 | Dainippon Printing Co Ltd | Perforated plate |
JP2013039756A (en) * | 2011-08-18 | 2013-02-28 | National Printing Bureau | Forgery-proof support |
JP5224304B2 (en) * | 2009-03-26 | 2013-07-03 | 独立行政法人 国立印刷局 | Latent image pattern former |
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2003
- 2003-01-23 JP JP2003014218A patent/JP3873211B2/en not_active Expired - Fee Related
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2006315202A (en) * | 2005-05-10 | 2006-11-24 | Nozaki Insatsu Shigyo Kk | Printing sheet with identification mark and its manufacturing method |
JP2009109653A (en) * | 2007-10-29 | 2009-05-21 | Dainippon Printing Co Ltd | Perforated plate |
JP5224304B2 (en) * | 2009-03-26 | 2013-07-03 | 独立行政法人 国立印刷局 | Latent image pattern former |
JP2013039756A (en) * | 2011-08-18 | 2013-02-28 | National Printing Bureau | Forgery-proof support |
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