JP2019002063A - Imitation sword for training - Google Patents

Abstract

To provide an imitation sword for training which can be used as an imitation sword for Iaido training, has a plating layer hardly exfoliated, is superior in abrasion resistance to be hardly scratched, and is hardly discolored by deposition of trainee's sweat to be aesthetically excellent.SOLUTION: In an imitation sword 1 for training, intermediate plating layers 20 and 30 forming a blade 10 of the imitation sword 1 for training are provided with a blade crest pattern 50 forming a rough surface, within a range of their thickness, and the whole of the blade crest pattern 50 and a part 60 other than the blade crest pattern are covered with a finish plating layer 40 made of a chromium plating layer.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a simulated sword used for training in Iaido. In more detail, even if used for practice that is frequently extracted from the sheath or placed in the sheath, the blade is less likely to discolor due to adhesion of sweat, etc., and the beauty of the blade is less likely to be damaged and less likely to be damaged. Related to mock swords.

  The mock sword used in the practice of Iaido is a mock sword that has the same weight and beauty as a Japanese sword. Specifically, the practice sword is made of a zinc alloy containing any one of brass, copper, aluminum and the like, and a plating layer is formed on the surface thereof to decorate the blade.

  As a technique for improving the decorativeness of a mock sword, Patent Document 1 discloses a technique of a manufacturing method that can produce a mock sword that is indistinguishable from a real Japanese sword. In the technique described in this document, a copper layer, a nickel layer, and a chromium layer are plated on a smoothly polished zinc alloy blade, and then the copper-plated surface or zinc alloy ground exposed by polishing is subjected to sulfurization treatment. It is a technique of a method for manufacturing a mock sword that has a process of blackening the lower blade part that has been black-banded and matted and polished slightly with ferric chloride and further sharpening the blade crest part by rough matte polishing. .

  According to this technique, after the plated layer of the blade once plated is exposed to the underlying copper layer or the base of the zinc alloy, the blade pattern is formed by sulfidation and matte polishing, etc. It is said that it can be a high simulated sword. However, when the Ii practice of quickly removing the blade from the sheath and putting it in place, one of the layers between the lower copper layer, the nickel layer, and the chromium layer rubs and the plating layer is easily peeled off. There was a problem. Also, if sweat or the like during training adheres to the blade, the zinc alloy is likely to corrode, and the nickel layer is more easily discolored than the chrome layer, as will be described later, and the pattern of the blade pattern becomes uneven and the decorativeness decreases. There was a problem to do.

  On the other hand, Patent Document 2 discloses a technique of a manufacturing method that aims to provide a simulated sword that corrodes a concave pattern on a blade part and exhibits a high artistic beauty. The technique described in this document applies a photosensitive synthetic resin liquid to a blade part of a zinc alloy, and applies a transparent material on which a pattern is formed, and then exposes the concave part corresponding to the pattern on the blade part. Is formed by corrosion, and then copper, nickel, and chrome are plated, and each part of the blade portion is further polished and polished.

  The process of the technique described in Patent Document 2, specifically, a coating process of applying a photosensitive synthetic resin to the blade, an exposure process, a process of corroding the blade at the position of the recess formed in the resin layer by the above process, The copper layer, the nickel layer, and the chromium layer are plated after the step of smoothing the shape of the recess and after polishing with a cloth buff. Further, each part of the blade part is further polished with a cloth buff so that the other parts are slightly whiter than the blade crest part, so that it resembles a real Japanese sword. However, even with the technique described in Patent Document 2, there is a problem that the plating layer is easily damaged when polishing with a cloth buff to form the blade pattern portion.

  In order to form a three-layered plating layer, copper plating is performed to prepare the surface of the material, and then plating is performed in the order of silver nickel plating and further the same system color chromium plating step. In any of the techniques described in any of the above patent documents, the uppermost chromium plating layer is polished to form a blade of a simulated sword. Even if the thickness of the uppermost chromium plating layer may be damaged or damaged at any position of the blade including the blade crest, the blade crest portion and the other portions are the lower nickel plating layer. And the upper chrome layer were of the same color, so there was no immediate discomfort.

  Here, the Vickers hardness of the lower nickel plating layer is 450 to 550 HV, and the surface hardness is smaller than that of the upper chrome plating layer having a Vickers hardness of 800 to 900 HV. Then, as in the above manufacturing process, if the upper chrome plating layer is polished by buffing in order to adjust the aesthetics of the blade, the thickness of the upper chrome plating layer is thin, so the buff polishing tends to exceed the range of the chrome plating layer, When the upper chromium plating layer is damaged, the lower nickel plating layer is also easily damaged.

  In addition, the lower nickel plating layer is more easily discolored by sweat or the like during training than the upper chromium plating layer. Then, when polishing with the buff of the blade extends to the lower nickel plating layer, sweat or the like adheres to the blade while using the decorative simulated sword, and the nickel plating There existed a subject that the part and the part of chromium plating would be in the state discolored to the spot easily.

  In order to avoid the discoloration of the blade, the entire blade is also painted clear. However, during the Iai practice of quickly extracting the blade from the sheath, rubbing the sheath with the blade tends to damage the painted surface, making it difficult to keep the blade crest in a beautiful state without scratches. It was.

  On the other hand, Patent Document 3 discloses a technique of a gold-plated simulated sword provided with a blade pattern developed by the inventors of the present application. The gold plating simulated sword described in Patent Document 3 is provided with a gold plating layer as a finishing plating layer after forming a blade pattern on the intermediate plating layer. However, since the surface hardness of the gold-plated layer is small, using a simulated sword with a gold-plated layer that is pulled out of the sheath or placed in the sheath is easy to scratch the gold-plated layer and frequently rubs against the sheath. There was a problem that it was difficult to use a gold-plated simulated sword as a matching simulated sword.

Patent Document 1: Japanese Patent Laid-Open No. 51-62599 Patent Document 2: Japanese Patent Laid-Open No. 52-126325 Patent Document 3: Japanese Patent Laid-Open No. 2017-20075

  Therefore, the inventor of the present application can be used as a practice sword for Iaido practice, and the plating layer is difficult to peel off, has excellent scratch resistance, and is not easily damaged. It was an object to provide a mock sword for practicing that was difficult to wear and excellent in aesthetics, and showed a blade crest.

  The simulated sword for practice of Iai according to the first aspect of the present invention includes a smooth base material having a blade shape, a finish plating layer made of an intermediate plating layer and a chromium plating layer, and the blade blade side of the blade. The intermediate plating layer is provided with a blade pattern that forms a rough surface within the range of the thickness of the intermediate plating layer, and the finish plating layer covers the entire portion other than the blade pattern and the blade pattern. The chrome plating layer in the blade pattern portion is in a cloudy state with little shine, and the chrome plating layer in a portion other than the blade pattern is in a shine state.

  The material that forms the base material for the simulated sword is not limited to zinc alloys or resin materials such as brass, copper, and aluminum, but if the blade is formed from a die-cast zinc alloy, Can be of a weight close to. The intermediate plating layer serving as the base of the chromium plating may be a plating material having a hue that is not different from the color of the chromium plating layer. For example, it may be a blue / silver nickel plating layer.

  The intermediate plating layer may be formed by laminating multiple layers of different materials, or may be formed of a single layer of plating. The blade pattern may be formed by polishing with a buff having an outer peripheral surface attached or coated with an abrasive. The buff material may be made of a material such as cotton cloth or sisal linen. The film thickness of the chromium plating layer may be appropriately changed within a range where the blade pattern is in a cloudy state with little sparkle depending on the degree of rough surface by buffing.

  According to the first aspect of the present invention, when the finish plating layer is a chromium plating layer having a high surface hardness, when the practice sword is extracted from the sheath or when the practice sword is placed in the sheath In addition, the blade pattern of the mock sword for practice and the shining surface of the blade are hard to be damaged. Moreover, since the chromium plating layer covers the entire intermediate plating layer, the plating layer is difficult to peel off at the boundary between the intermediate plating layer and the finish plating layer. Furthermore, since part of the material and the intermediate plating layer is not exposed, the sweat of the practitioner does not adhere to the easily discolored material and the intermediate plating layer, and it is advantageous that the blade of the practice simulated sword is difficult to discolor to spots. There is an effect.

  According to a second aspect of the present invention, in the simulated sword for practice according to the first aspect, the intermediate plating layer includes a copper plating layer as a lower layer and a nickel plating layer as an upper layer, and the film of the nickel plating layer The thickness is 5 μm or more and 20 μm or less, and a blade pattern is provided in the range of the thickness of the nickel plating layer.

  Since the lower layer of the plating layer forming the intermediate plating layer is a copper plating layer having excellent ductility, irregularities such as pinholes on the surface of the substrate are smoothed. Further, since the upper layer is a nickel plating layer having the same hue as that of the chromium plating layer, it is preferable that the color of the lower copper plating layer is hidden and the hue of the surface of the finish plating layer is not affected.

  The blade base material is provided with a copper plating layer, smoothed so that there are no pinholes on the surface of the base material, and the nickel plating layer is provided as an intermediate plating layer. A blade pattern is formed. The thickness of the nickel plating layer is set to 20 μm or less so that unnecessary plating time can be omitted, and the thickness of the nickel plating layer is set to 5 μm or more so that the blade pattern is easily polished without damaging the copper plating layer.

  Then, the blade can be made smooth without being affected by pinholes and the like, and even in the step of forming the blade pattern, the nickel plating layer is left so as not to expose the copper plating layer. A pattern is formed. According to the second invention, the blade part other than the blade pattern is smooth and has no uneven color, shines in a silver color, and the mock blade for practice having a cloudy pattern with a blade pattern in the background It is said.

  According to a third aspect of the present invention, in the simulated mock sword of the first or second aspect, the chromium plating layer has a thickness of 1 μm or more and 3 μm or less.

  When the film thickness of the chromium plating layer is 1 μm or more, it is easy to make the chromium plating layer in a portion other than the blade pattern bright, and it is difficult to be scratched when being inserted into and removed from the sheath. Further, when the film thickness of the chrome plating layer is 3 μm or less, the blade pattern can be provided with a blade pattern with less brightness without changing the roughness of the surface of the portion where the blade pattern is polished.

  If it does so, it will become the practice simulated sword with which the blade body was prepared so that the state with few shine of the part in which the blade pattern was formed, and the state in which the part in which the blade pattern was not formed stand out mutually. Thereby, it is possible to obtain a simulated sword for practice that has a live blade pattern and is excellent in scratch resistance against the background of a blade shining in silver.

-According to the first invention of the present invention, when the mock sword for practice is extracted from the sheath, or when the mock sword for practice is placed in the scabbard, the blade pattern of the mock sword for practice and the blade shines Hard to damage the surface. Moreover, since the chromium plating layer covers the entire intermediate plating layer, the plating layer is difficult to peel off at the boundary between the intermediate plating layer and the finish plating layer. Furthermore, since part of the material and the intermediate plating layer is not exposed, the sweat of the practitioner does not adhere to the easily discolored material and the intermediate plating layer, and it is advantageous that the blade of the practice simulated sword is difficult to discolor to spots. There is an effect.
-According to the second invention of the present invention, the blade part other than the blade pattern is smooth and has no uneven color, shines in silver, and has a blade pattern with a cloudy pattern against the background of the blade It is considered a practice sword.
-According to the third invention of the present invention, it is possible to provide a practicing simulated sword that has a live blade pattern and is excellent in scratch resistance against the background of a shining blade of silver.

Explanatory drawing of the simulated sword for practice (Example 1). The partially expanded view of the simulated sword for practice, and a partially expanded sectional view (Example 1). The flowchart (Example 1) explaining the manufacturing process of the simulation sword for practice. A partially enlarged photograph of a blade of a practice mock sword (Example 1). A partially enlarged photograph of a conventional practice mock sword (conventional example).

  In the invention of the present application, the intermediate plating layer forming the blade of the simulated sword is provided with a blade pattern that forms a rough surface within the range of the film thickness, and the finish plating layer made of the chrome plating layer has a blade pattern. The whole part other than the part and the blade pattern was covered. As a result, it can be used as a simulated sword for practice in Iaido, the plating layer is difficult to peel off, it is excellent in scratch resistance and is not easily damaged, and it is difficult to discolor even if the sweat of the trainee adheres, and it is excellent in appearance. A practice sword with a blade crest was obtained.

  Here, the conventional practice mock sword 100 will be briefly described with reference to FIG. FIG. 5 shows a partially enlarged photograph of a conventional practice mock sword 100. As described above, in the conventional simulated sword 100 for practice, the plating layers are laminated in the order of the copper plating layer, the nickel plating layer, and the chromium plating layer on the blade made of zinc die casting. Then, the blade pattern 150 is provided by polishing the plating layer on the blade edge side. Therefore, at the portion of the blade pattern 150, the uppermost chromium plating layer is polished and removed, and the nickel plating layer that is easily damaged is exposed.

  Next, the scratch 170 on the blade will be described with reference to FIG. The conventional practice mock sword 100 has two streak-like scratches 170 on a part of the blade pattern 150. The scratch 170 is likely to be attached at the boundary between the blade pattern 150 and the portion 160 other than the blade pattern, and it is difficult to repair the scratch. Since the scratch can be made at a position where the simulated sword is in contact with the sheath, the scratches become conspicuous as the practice is repeated, and the beauty of the simulated sword decreases.

  In the first embodiment, an embodiment of the practice simulated sword 1 will be described with reference to FIGS. 1 to 4. FIG. 1 is an explanatory diagram of a practice mock sword 1 in which a blade pattern 50 appears. FIG. 2A shows a partially enlarged view of the simulated sword 1 for practice. FIG. 2B shows a partially enlarged cross section of the A portion surrounded by the alternate long and short dash line in FIG. 2A. FIG. 3 shows a flow diagram for explaining the manufacturing process of the simulated sword for practice. FIG. 4 shows a partially enlarged photograph of the blade of the practice mock sword 1.

  First, the configuration of the practice mock sword 1 will be described with reference to FIG. The simulated sword 1 for practice of the first embodiment includes a blade 10 made of zinc die-cast, and a copper plating layer 20 and a nickel plating layer 30 that form an intermediate plating layer. A crest pattern 50 is provided. Further, a finish plating layer made of a chromium plating layer 40 is provided on the surface of the nickel plating layer 30 provided with the blade pattern (see FIG. 2B).

  The intermediate plating layer includes a copper plating layer 20 as a lower layer and a nickel plating layer 30 as an upper layer, and the thickness of the nickel plating layer 30 is set to 5 μm or more and 20 μm or less. The blade pattern 50 is formed within the thickness range of the nickel plating layer 30 so as to form a linear cloudy blade pattern on the blade with a buff coated with an F240 abrasive. The abrasive is not limited to F240, and any buff of F230 to F360 may be used. In addition, the film thickness of the copper plating layer which makes a lower layer is not limited.

  The chromium plating layer 40 has a thickness of 1 μm or more and 3 μm or less, and is provided so as to cover the entire portion 60 of the nickel plating layer 30 except the blade pattern 50 and the portion 60 other than the blade pattern (FIG. 2A). (See the figure). Since the chromium plating layer 30 has a Vickers hardness as high as 800 to 900 HV, it has excellent scratch resistance and is hardly damaged. Since the film thickness of the chrome plating layer with excellent scratch resistance is 1 μm or more, when the sword is inserted into and removed from the sheath, the chrome plating layer is hardly scratched and maintained in an excellent aesthetic state. Can do.

  In addition, the chrome plating layer that is not discolored or altered by sweat covers the entire blade, so even if sweat or the like adheres to the blade during training, the blade will not be discolored and the aesthetics of the blade pattern Is maintained. In addition, when the film thickness of the chrome plating layer is 3 μm or less, the blade pattern is provided with a blade pattern in a cloudy state with little shine without changing the roughness of the surface where the blade pattern is polished. Can do.

  Here, the blade 10 and the appearance of the practice mock sword 1 will be described with reference to FIGS. The blade 10 of the simulated sword (see FIG. 2) is formed by die-casting into a mold having the shape of a Japanese sword by melting a zinc alloy containing zinc. On the blade edge side of the blade, the blade pattern 50 is provided as described above (see FIG. 1). The portion of the blade pattern 50 is diffusely reflected so that the light hitting the blade diffuses and becomes a cloudy state with little shine, and the portion 60 other than the blade pattern is in a state where the light is shined by regular reflection. (See FIG. 4).

  In the simulated sword 1 for practice, the entire portion of the blade pattern 50 and the portion 60 other than the blade pattern are covered with a chromium plating layer 40 (see FIG. 2B) that has a high surface hardness and is not easily damaged. Yes. For this reason, unlike the conventional practice mock sword 100 (see FIG. 5), the blade pattern 50 of the mock practice sword 1 is less likely to have a streak-like scratch and is less likely to lose its aesthetic appearance.

Here, the manufacturing process of the simulated sword 1 for practice of the present invention will be described with reference to FIG. FIG. 3 is a flowchart for explaining the manufacturing process of the simulated sword for practice.
(Substrate ground treatment process)
First, as a first step, a substrate base treatment is performed (S1). The blade made of zinc die cast as a base material is polished so that the surface is smooth by rotating a sisal buff or the like coated with an abrasive having a fine particle size of F600 to F800. The blade having a smooth surface is subjected to steps of alkali degreasing, water washing, electrolytic degreasing, water washing, weak acid immersion, and water washing to remove oil, oxide film, and the like. And in order to prevent the adhesive fall, a thin copper plating layer is formed by copper cyanide strike plating.

(Copper plating process)
Next, as a second step, a copper plating layer is electroplated on the surface of the blade having a smooth surface (S2). For copper plating, a copper cyanide bath is excellent in throwing power and is suitable for plating on a zinc die-cast blade substrate. Examples of the bath composition and plating conditions for copper plating using a copper cyanide bath are shown below. In addition, a copper plating layer should just smooth the surface of a base material, is not limited to the following bath composition and plating conditions, and thickness is not limited.

As a bath composition of the copper plating solution, per liter of copper plating aqueous solution, cuprous cyanide: 50 to 60 g, sodium cyanide: 60 to 80 g, free sodium cyanide: 8 to 15 g, rhodan potassium: 5 to 15 g, Rochelle salt: 30-50 g, potassium hydroxide: 10-20 g. As plating conditions, the bath temperature was 50 to 70 ° C., the pH was 11 to 12, the current density was 1 to 5 A / dm ² , and the plating bath time was 5 to 15 minutes.

(Nickel plating process)
Next, as a third step, the nickel plating layer is electroplated so as to be laminated on the copper plating layer (S3). Nickel plating uses a Watt bath mainly composed of nickel sulfate, nickel chloride, and boric acid, and has good adhesion to the base material and is suitable as a base plating. After washing with water, nickel plating is performed to obtain a plating film thickness of 5 to 20 μm. Examples of the bath composition and plating conditions necessary to make the nickel plating layer 5 to 20 μm are shown below. In addition, the following bath composition and plating conditions are only examples, and are not limited.

The bath composition of the nickel plating solution was: nickel sulfate: 250 g, nickel chloride: 45 g, boric acid: 40 g per liter of nickel plating aqueous solution. As plating conditions, the bath temperature was 40 to 55 ° C., the pH was 3.5 to 4.5, the current density was ² to 10 A / dm ² , and the plating bath time was 10 to 30 minutes.

(Blade pattern forming process)
Next, as a fourth step, a blade pattern is formed by buffing within the range of the thickness of the nickel plating layer (S4). An abrasive whose abrasive grain size is selected from F230 to F360 is applied to the polishing surface of the buff material. Then, while rotating the polishing surface at a high speed, a buff is pressed in the lateral direction of the blade and moved along the longitudinal direction of the blade to form a blade pattern at a position on the blade edge side of the blade. As the buff material, a buff made of a material such as cotton cloth or sisal linen is used as a base material, and the above-mentioned abrasive is adhered or applied to the outer peripheral surface thereof.

  The buff to which the abrasive is attached or applied is rotated at a rotation speed of 80 to 100 times / minute. In Example 1, the buff was rotated in the lateral direction of the blade to form a linearly clouded blade pattern. In addition, it is easy to grind the cloudy blade pattern so as to wave along the blade by rotating it later than usual. It is also possible to apply a template representing the outline of the blade pattern to be formed in advance to the blade, and to polish only the portion protruding from the template by buffing to form the blade pattern.

(Chrome plating process)
Next, as a fifth step, the chromium plating layer forming the finish plating layer is electroplated so as to cover the entire portion of the nickel plating layer other than the edge pattern and the edge pattern (S5). After the blade pattern is formed, the chromium plating layer is plated through degreasing and washing steps. Examples of the bath composition and plating conditions necessary to make the chromium plating layer have a thickness of 1 to 3 μm are shown below. The following bath composition and plating conditions are merely examples and are not limited.

As the bath composition of the chromium plating solution, chromic acid: 100 to 150 g, sulfuric acid (98% by weight of sulfuric acid component): 1.0 to 1.5 g per liter of the chromium plating aqueous solution. As plating conditions, the bath temperature was 45 to 55 ° C., the pH was 0 to 1.0, the current density was 10 to 30 A / dm ² , and the plating bath time was 5 to 15 minutes.

  By the above process, the chrome plating layer covers the entire portion of the blade pattern portion and the portion other than the blade pattern, and the chrome plating layer of the blade pattern portion is in a cloudy state with less shine. A simulated sword with a chrome plating layer other than the pattern in a shining state was obtained.

(Other)
-Of course, the simulated sword for practice of the present invention may be used for the performance of kendo, and of course, the shape of the blade pattern is not limited.
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The technical scope of the present invention is shown not by the above description but by the scope of the claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of the claims.

1 ... Mock sword for practice, 100 ... Mock sword for conventional practice,
10 ... blade, 20 ... copper plating layer, 30 ... nickel plating layer, 40 ... chromium plating layer,
50 ... blade pattern, 60 ... parts other than the blade pattern,
150 ... blade pattern, 160 ... parts other than the blade pattern, 170 ... scratches

  The present invention relates to a simulated sword used for training in Iaido. In more detail, even if used for practice that is frequently extracted from the sheath or placed in the sheath, the blade is less likely to discolor due to adhesion of sweat, etc., and the beauty of the blade is less likely to be damaged and less likely to be damaged. Related to mock swords.

  The mock sword used in the practice of Iaido is a mock sword that has the same weight and beauty as a Japanese sword. Specifically, the practice sword is made of a zinc alloy containing any one of brass, copper, aluminum and the like, and a plating layer is formed on the surface thereof to decorate the blade.

  As a technique for improving the decorativeness of a mock sword, Patent Document 1 discloses a technique of a manufacturing method that can produce a mock sword that is indistinguishable from a real Japanese sword. In the technique described in this document, a copper layer, a nickel layer, and a chromium layer are plated on a smoothly polished zinc alloy blade, and then the copper-plated surface or zinc alloy ground exposed by polishing is subjected to sulfurization treatment. It is a technique of a method for manufacturing a mock sword that has a process of blackening the lower blade part that has been black-banded and matted and polished slightly with ferric chloride and further sharpening the blade crest part by rough matte polishing. .

  According to this technique, after the plated layer of the blade once plated is exposed to the underlying copper layer or the base of the zinc alloy, the blade pattern is formed by sulfidation and matte polishing, etc. It is said that it can be a high simulated sword. However, when the Ii practice of quickly removing the blade from the sheath and putting it in place, one of the layers between the lower copper layer, the nickel layer, and the chromium layer rubs and the plating layer is easily peeled off. There was a problem. Also, if sweat or the like during training adheres to the blade, the zinc alloy is likely to corrode, and the nickel layer is more easily discolored than the chrome layer, as will be described later, and the pattern of the blade pattern becomes uneven and the decorativeness decreases. There was a problem to do.

  On the other hand, Patent Document 2 discloses a technique of a manufacturing method that aims to provide a simulated sword that corrodes a concave pattern on a blade part and exhibits a high artistic beauty. The technique described in this document applies a photosensitive synthetic resin liquid to a blade part of a zinc alloy, and applies a transparent material on which a pattern is formed, and then exposes the concave part corresponding to the pattern on the blade part. Is formed by corrosion, and then copper, nickel, and chrome are plated, and each part of the blade portion is further polished and polished.

  The process of the technique described in Patent Document 2, specifically, a coating process of applying a photosensitive synthetic resin to the blade, an exposure process, a process of corroding the blade at the position of the recess formed in the resin layer by the above process, The copper layer, the nickel layer, and the chromium layer are plated after the step of smoothing the shape of the recess and after polishing with a cloth buff. Further, each part of the blade part is further polished with a cloth buff so that the other parts are slightly whiter than the blade crest part, so that it resembles a real Japanese sword. However, even with the technique described in Patent Document 2, there is a problem that the plating layer is easily damaged when polishing with a cloth buff to form the blade pattern portion.

  In order to form a three-layered plating layer, copper plating is performed to prepare the surface of the material, and then plating is performed in the order of silver nickel plating and further the same system color chromium plating step. In any of the techniques described in any of the above patent documents, the uppermost chromium plating layer is polished to form a blade of a simulated sword. Even if the thickness of the uppermost chromium plating layer may be damaged or damaged at any position of the blade including the blade crest, the blade crest portion and the other portions are the lower nickel plating layer. And the upper chrome layer were of the same color, so there was no immediate discomfort.

  Here, the Vickers hardness of the lower nickel plating layer is 450 to 550 HV, and the surface hardness is smaller than that of the upper chrome plating layer having a Vickers hardness of 800 to 900 HV. Then, as in the above manufacturing process, if the upper chrome plating layer is polished by buffing in order to adjust the aesthetics of the blade, the thickness of the upper chrome plating layer is thin, so the buff polishing tends to exceed the range of the chrome plating layer, When the upper chromium plating layer is damaged, the lower nickel plating layer is also easily damaged.

  In addition, the lower nickel plating layer is more easily discolored by sweat or the like during training than the upper chromium plating layer. Then, when polishing with the buff of the blade extends to the lower nickel plating layer, sweat or the like adheres to the blade while using the decorative simulated sword, and the nickel plating There existed a subject that the part and the part of chromium plating would be in the state discolored to the spot easily.

  In order to avoid the discoloration of the blade, the entire blade is also painted clear. However, during the Iai practice of quickly extracting the blade from the sheath, rubbing the sheath with the blade tends to damage the painted surface, making it difficult to keep the blade crest in a beautiful state without scratches. It was.

  On the other hand, Patent Document 3 discloses a technique of a gold-plated simulated sword provided with a blade pattern developed by the inventors of the present application. The gold plating simulated sword described in Patent Document 3 is provided with a gold plating layer as a finishing plating layer after forming a blade pattern on the intermediate plating layer. However, since the surface hardness of the gold-plated layer is small, using a simulated sword with a gold-plated layer that is pulled out of the sheath or placed in the sheath is easy to scratch the gold-plated layer and frequently rubs against the sheath. There was a problem that it was difficult to use a gold-plated simulated sword as a matching simulated sword.

Patent Document 1: Japanese Patent Laid-Open No. 51-62599 Patent Document 2: Japanese Patent Laid-Open No. 52-126325 Patent Document 3: Japanese Patent Laid-Open No. 2017-20075

  Therefore, the inventor of the present application can be used as a practice sword for Iaido practice, and the plating layer is difficult to peel off, has excellent scratch resistance, and is not easily damaged. It was an object to provide a mock sword for practicing that was difficult to wear and excellent in aesthetics, and showed a blade crest.

  A simulated sword for practice of Iai according to the first aspect of the present invention is a simulated sword for practice of Iai, which is a smooth base having a blade shape, a copper plating layer forming a lower layer, and a nickel plating layer forming an upper layer An intermediate plating layer comprising: a finish plating layer comprising a single chrome plating layer, wherein the nickel plating layer has a thickness of 5 μm or more and 20 μm or less, and the intermediate portion on the blade edge side of the blade The plating layer is provided with a crest pattern that forms a rough surface within the range of the thickness of the nickel plating layer, and the single chromium plating layer that forms the finish plating layer has a plating thickness of 1 μm to 3 μm, and The surface hardness is 800 HV or more and 900 HV or less in terms of Vickers hardness, and the single chrome plating layer covers the whole of the blade pattern portion and the portion other than the blade pattern, and covers the blade pattern portion. The plating layer is Is a glow less cloudy state without changing the roughness of the surface of the Kihamon pattern, the chromium plating layer covering the portion other than the blade crest pattern is characterized in that it is a state with a shine.

  The material that forms the base material for the simulated sword is not limited to zinc alloys or resin materials such as brass, copper, and aluminum, but if the blade is formed from a die-cast zinc alloy, Can be of a weight close to.

  The intermediate plating layer includes a copper plating layer as a lower layer and a nickel plating layer as an upper layer. The blade pattern may be formed by polishing with a buff having an outer peripheral surface attached or coated with an abrasive. The buff material may be made of a material such as cotton cloth or sisal linen. The film thickness of the chromium plating layer may be appropriately changed within a range where the blade pattern is in a cloudy state with little sparkle depending on the degree of rough surface by buffing.

  Since the lower layer of the plating layer forming the intermediate plating layer is a copper plating layer having excellent ductility, irregularities such as pinholes on the surface of the substrate are smoothed. Further, since the upper layer is a nickel plating layer having the same hue as that of the chromium plating layer, it is preferable that the color of the lower copper plating layer is hidden and the hue of the surface of the finish plating layer is not affected.

  The blade base material is provided with a copper plating layer, smoothed so that there are no pinholes on the surface of the base material, and the nickel plating layer is provided as an intermediate plating layer. A blade pattern is formed. The thickness of the nickel plating layer is set to 20 μm or less so that unnecessary plating time can be omitted, and the thickness of the nickel plating layer is set to 5 μm or more so that the blade pattern is easily polished without damaging the copper plating layer.

  Then, the blade can be made smooth without being affected by pinholes and the like, and even in the step of forming the blade pattern, the nickel plating layer is left so as not to expose the copper plating layer. A pattern is formed. As a result, the blade portion other than the blade pattern is smooth and has no color unevenness, shines in silver, and the blade is used as a simulated mock sword with a cloudy pattern.

  When the film thickness of the single chrome plating layer is 1 μm or more and the surface hardness is 800 HV or more in terms of Vickers hardness, it is easy to make the chrome plating layer other than the blade pattern bright. At the same time, it becomes difficult to scratch when inserting and removing the sheath. Further, when the film thickness of the chrome plating layer is 3 μm or less, the blade pattern can be provided with a blade pattern with less brightness without changing the roughness of the surface of the portion where the blade pattern is polished.

  If it does so, it will become the practice simulated sword with which the blade body was prepared so that the state with few shine of the part in which the blade pattern was formed, and the state in which the part in which the blade pattern was not formed stand out mutually. Thereby, it is possible to obtain a simulated sword for practice that has a live blade pattern and is excellent in scratch resistance against the background of a blade shining in silver.

  According to the first aspect of the present invention, the finish plating layer is a single-layer chromium plating layer having a high surface hardness. Therefore, when the training simulated sword is extracted from the sheath, or the training simulated sword is sheathed. It is difficult to hurt the blade pattern of the mock sword for practice and the shining surface of the sword. Further, since the entire intermediate plating layer is covered with a single chromium plating layer, the plating layer is difficult to peel off at the boundary between the intermediate plating layer and the finish plating layer. Furthermore, since part of the material and the intermediate plating layer is not exposed, the sweat of the practitioner does not adhere to the easily discolored material and the intermediate plating layer, and it is advantageous that the blade of the practice simulated sword is difficult to discolor to spots. There is an effect.

-According to the first invention of the present invention, when the mock sword for practice is extracted from the sheath, or when the mock sword for practice is placed in the scabbard, the blade pattern of the mock sword for practice and the blade shines Hard to damage the surface. In addition, since the entire intermediate plating layer is covered with a single chromium plating layer, the plating layer is difficult to peel off at the boundary between the intermediate plating layer and the finish plating layer. Furthermore, since part of the material and the intermediate plating layer is not exposed, the sweat of the practitioner does not adhere to the easily discolored material and the intermediate plating layer, and it is advantageous that the blade of the practice simulated sword is difficult to discolor to spots. There is an effect. The blade part other than the blade pattern is smooth and has no color unevenness, shines in silver, and is considered a practice mock sword with a cloudy pattern on the background. With a silver-colored blade as a background, it has a live blade pattern and can be used as a practice sword with excellent scratch resistance.

Explanatory drawing of the simulated sword for practice (Example 1). The partially expanded view of the simulated sword for practice, and a partially expanded sectional view (Example 1). The flowchart (Example 1) explaining the manufacturing process of the simulation sword for practice. A partially enlarged photograph of a blade of a practice mock sword (Example 1). A partially enlarged photograph of a conventional practice mock sword (conventional example).

  In the invention of the present application, the intermediate plating layer forming the blade of the simulated sword is provided with a blade pattern that forms a rough surface within the range of the film thickness, and the finish plating layer made of the chrome plating layer has a blade pattern. The whole part other than the part and the blade pattern was covered. As a result, it can be used as a simulated sword for practice in Iaido, the plating layer is difficult to peel off, it is excellent in scratch resistance and is not easily damaged, and it is difficult to discolor even if the sweat of the trainee adheres, and it is excellent in appearance. A practice sword with a blade crest was obtained.

  Here, the conventional practice mock sword 100 will be briefly described with reference to FIG. FIG. 5 shows a partially enlarged photograph of a conventional practice mock sword 100. As described above, in the conventional simulated sword 100 for practice, the plating layers are laminated in the order of the copper plating layer, the nickel plating layer, and the chromium plating layer on the blade made of zinc die casting. Then, the blade pattern 150 is provided by polishing the plating layer on the blade edge side. Therefore, at the portion of the blade pattern 150, the uppermost chromium plating layer is polished and removed, and the nickel plating layer that is easily damaged is exposed.

  Next, the scratch 170 on the blade will be described with reference to FIG. The conventional practice mock sword 100 has two streak-like scratches 170 on a part of the blade pattern 150. The scratch 170 is likely to be attached at the boundary between the blade pattern 150 and the portion 160 other than the blade pattern, and it is difficult to repair the scratch. Since the scratch can be made at a position where the simulated sword is in contact with the sheath, the scratches become conspicuous as the practice is repeated, and the beauty of the simulated sword decreases.

  In the first embodiment, an embodiment of the practice simulated sword 1 will be described with reference to FIGS. 1 to 4. FIG. 1 is an explanatory diagram of a practice mock sword 1 in which a blade pattern 50 appears. FIG. 2A shows a partially enlarged view of the simulated sword 1 for practice. FIG. 2B shows a partially enlarged cross section of the A portion surrounded by the alternate long and short dash line in FIG. 2A. FIG. 3 shows a flow diagram for explaining the manufacturing process of the simulated sword for practice. FIG. 4 shows a partially enlarged photograph of the blade of the practice mock sword 1.

  First, the configuration of the practice mock sword 1 will be described with reference to FIG. The simulated sword 1 for practice of the first embodiment includes a blade 10 made of zinc die-cast, and a copper plating layer 20 and a nickel plating layer 30 that form an intermediate plating layer. A crest pattern 50 is provided. Further, a finish plating layer made of a chromium plating layer 40 is provided on the surface of the nickel plating layer 30 provided with the blade pattern (see FIG. 2B).

  The intermediate plating layer includes a copper plating layer 20 as a lower layer and a nickel plating layer 30 as an upper layer, and the thickness of the nickel plating layer 30 is set to 5 μm or more and 20 μm or less. The blade pattern 50 is formed within the thickness range of the nickel plating layer 30 so as to form a linear cloudy blade pattern on the blade with a buff coated with an F240 abrasive. The abrasive is not limited to F240, and any buff of F230 to F360 may be used. In addition, the film thickness of the copper plating layer which makes a lower layer is not limited.

  The chromium plating layer 40 has a thickness of 1 μm or more and 3 μm or less, and is provided so as to cover the entire portion 60 of the nickel plating layer 30 except the blade pattern 50 and the portion 60 other than the blade pattern (FIG. 2A). (See the figure). Since the chromium plating layer 30 has a Vickers hardness as high as 800 to 900 HV, it has excellent scratch resistance and is hardly damaged. Since the film thickness of the chrome plating layer with excellent scratch resistance is 1 μm or more, when the sword is inserted into and removed from the sheath, the chrome plating layer is hardly scratched and maintained in an excellent aesthetic state. Can do.

  In addition, the chrome plating layer that is not discolored or altered by sweat covers the entire blade, so even if sweat or the like adheres to the blade during training, the blade will not be discolored and the aesthetics of the blade pattern Is maintained. In addition, when the film thickness of the chrome plating layer is 3 μm or less, the blade pattern is provided with a blade pattern in a cloudy state with little shine without changing the roughness of the surface where the blade pattern is polished. Can do.

  Here, the blade 10 and the appearance of the practice mock sword 1 will be described with reference to FIGS. The blade 10 of the simulated sword (see FIG. 2) is formed by die-casting into a mold having the shape of a Japanese sword by melting a zinc alloy containing zinc. On the blade edge side of the blade, the blade pattern 50 is provided as described above (see FIG. 1). The portion of the blade pattern 50 is diffusely reflected so that the light hitting the blade diffuses and becomes a cloudy state with little shine, and the portion 60 other than the blade pattern is in a state where the light is shined by regular reflection. (See FIG. 4).

  In the simulated sword 1 for practice, the entire portion of the blade pattern 50 and the portion 60 other than the blade pattern are covered with a chromium plating layer 40 (see FIG. 2B) that has a high surface hardness and is not easily damaged. Yes. For this reason, unlike the conventional practice mock sword 100 (see FIG. 5), the blade pattern 50 of the mock practice sword 1 is less likely to have a streak-like scratch and is less likely to lose its aesthetic appearance.

Here, the manufacturing process of the simulated sword 1 for practice of the present invention will be described with reference to FIG. FIG. 3 is a flowchart for explaining the manufacturing process of the simulated sword for practice.
(Substrate ground treatment process)
First, as a first step, a substrate base treatment is performed (S1). The blade made of zinc die cast as a base material is polished so that the surface is smooth by rotating a sisal buff or the like coated with an abrasive having a fine particle size of F600 to F800. The blade having a smooth surface is subjected to steps of alkali degreasing, water washing, electrolytic degreasing, water washing, weak acid immersion, and water washing to remove oil, oxide film, and the like. And in order to prevent the adhesive fall, a thin copper plating layer is formed by copper cyanide strike plating.

(Copper plating process)
Next, as a second step, a copper plating layer is electroplated on the surface of the blade having a smooth surface (S2). For copper plating, a copper cyanide bath is excellent in throwing power and is suitable for plating on a zinc die-cast blade substrate. Examples of the bath composition and plating conditions for copper plating using a copper cyanide bath are shown below. In addition, a copper plating layer should just smooth the surface of a base material, is not limited to the following bath composition and plating conditions, and thickness is not limited.

  As a bath composition of the copper plating solution, per liter of copper plating aqueous solution, cuprous cyanide: 50 to 60 g, sodium cyanide: 60 to 80 g, free sodium cyanide: 8 to 15 g, rhodan potassium: 5 to 15 g, Rochelle salt: 30-50 g, potassium hydroxide: 10-20 g. As plating conditions, the bath temperature was 50 to 70 ° C., the pH was 11 to 12, the current density was 1 to 5 A / dm 2, and the plating bath time was 5 to 15 minutes.

(Nickel plating process)
Next, as a third step, the nickel plating layer is electroplated so as to be laminated on the copper plating layer (S3). Nickel plating uses a Watt bath mainly composed of nickel sulfate, nickel chloride, and boric acid, and has good adhesion to the base material and is suitable as a base plating. After washing with water, nickel plating is performed to obtain a plating film thickness of 5 to 20 μm. Examples of the bath composition and plating conditions necessary to make the nickel plating layer 5 to 20 μm are shown below. In addition, the following bath composition and plating conditions are only examples, and are not limited.

The bath composition of the nickel plating solution was: nickel sulfate: 250 g, nickel chloride: 45 g, boric acid: 40 g per liter of nickel plating aqueous solution. As plating conditions, the bath temperature was 40 to 55 ° C., the pH was 3.5 to 4.5, the current density was ² to 10 A / dm ² , and the plating bath time was 10 to 30 minutes.

(Blade pattern forming process)
Next, as a fourth step, a blade pattern is formed by buffing within the range of the thickness of the nickel plating layer (S4). An abrasive whose abrasive grain size is selected from F230 to F360 is applied to the polishing surface of the buff material. Then, while rotating the polishing surface at a high speed, a buff is pressed in the lateral direction of the blade and moved along the longitudinal direction of the blade to form a blade pattern at a position on the blade edge side of the blade. As the buff material, a buff made of a material such as cotton cloth or sisal linen is used as a base material, and the above-mentioned abrasive is adhered or applied to the outer peripheral surface thereof.

  The buff to which the abrasive is attached or applied is rotated at a rotation speed of 80 to 100 times / minute. In Example 1, the buff was rotated in the lateral direction of the blade to form a linearly clouded blade pattern. In addition, it is easy to grind the cloudy blade pattern so as to wave along the blade by rotating it later than usual. It is also possible to apply a template representing the outline of the blade pattern to be formed in advance to the blade, and to polish only the portion protruding from the template by buffing to form the blade pattern.

(Chrome plating process)
Next, as a fifth step, the chromium plating layer forming the finish plating layer is electroplated so as to cover the entire portion of the nickel plating layer other than the edge pattern and the edge pattern (S5). After the blade pattern is formed, the chromium plating layer is plated through degreasing and washing steps. Examples of the bath composition and plating conditions necessary to make the chromium plating layer have a thickness of 1 to 3 μm are shown below. The following bath composition and plating conditions are merely examples and are not limited.

As the bath composition of the chromium plating solution, chromic acid: 100 to 150 g, sulfuric acid (98% by weight of sulfuric acid component): 1.0 to 1.5 g per liter of the chromium plating aqueous solution. As plating conditions, the bath temperature was 45 to 55 ° C., the pH was 0 to 1.0, the current density was 10 to 30 A / dm ² , and the plating bath time was 5 to 15 minutes.

  By the above process, the chrome plating layer covers the entire portion of the blade pattern portion and the portion other than the blade pattern, and the chrome plating layer of the blade pattern portion is in a cloudy state with less shine. A simulated sword with a chrome plating layer other than the pattern in a shining state was obtained.

(Other)
-Of course, the simulated sword for practice of the present invention may be used for the performance of kendo, and of course, the shape of the blade pattern is not limited.
The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The technical scope of the present invention is shown not by the above description but by the scope of the claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of the claims.

1 ... Mock sword for practice, 100 ... Mock sword for conventional practice,
10 ... blade, 20 ... copper plating layer, 30 ... nickel plating layer, 40 ... chromium plating layer,
50 ... blade pattern, 60 ... parts other than the blade pattern,
150 ... blade pattern, 160 ... parts other than the blade pattern, 170 ... scratches

Claims (3)

A simulated sword for practice in Iai,
A smooth base material in the shape of a blade includes an intermediate plating layer and a finish plating layer composed of a chromium plating layer,
In the intermediate plating layer on the blade edge side of the blade, provided with a blade pattern that forms a rough surface in the thickness range of the intermediate plating layer,
The finish plating layer covers the entire portion of the blade pattern portion and the portion other than the blade pattern, and the chromium plating layer of the blade pattern portion is in a cloudy state with less brightness, and other than the blade pattern The chrome plating layer of the part is in a shining state,
A mock sword for practice characterized by that. The intermediate plating layer is composed of a lower copper plating layer and an upper nickel plating layer,
The nickel plating layer has a thickness of 5 μm or more and 20 μm or less,
It has a blade pattern in the range of the thickness of the nickel plating layer,
The simulated sword for practice according to claim 1. The chromium plating layer has a thickness of 1 μm or more and 3 μm or less,
The simulated sword for practice according to claim 1 or 2.