JPH071825A - Moldable transfer foil - Google Patents

Abstract

PURPOSE:To produce a valuable decorative member by enabling the transfer of patterns to a complicated three-dimensional object by improving and stabilizing the moldability of a transfer foil. CONSTITUTION:As the base material sheet 3 of a transfer foil, a polyvinyl chloride film 1 characterized by that a temp. range wherein 200% modulus strength becomes 5-15kg/cm<2> in the vicinity of the molding temp. of the transfer foil is 30 deg.C or higher and a thickness is 80mum or less is used and a transfer layer 7 composed of a pattern layer 5 is formed on the film 1 to obtain the transfer foil. Further, the base material sheet 3 having a release layer 2 composed of an ionizing radiation curable resin formed thereto on the side coming into contact with the transfer layer 7 is used to obtain the transfer foil more excellent in heat resistance or the like.

Description

Detailed Description of the Invention

[0001]

FIELD OF THE INVENTION The present invention relates to a transfer foil having moldability. In particular, it is a transfer foil having good deep drawing performance, capable of stably forming a transfer foil, and suitable for transferring a pattern or the like to a complicated three-dimensional surface of an object to be transferred.

[0002]

2. Description of the Related Art Conventionally, as a method of transferring a pattern or the like onto a surface of an object to be transferred using a transfer foil, a method of transferring it to a material to be formed and a method of forming the material to be transferred are transferred. There is a method. As the former method, for example, there is a method of transferring from a moldable transfer foil to a wooden three-dimensional member by using a vacuum lamination method. On the other hand, as the latter method, for example, an injection molding simultaneous painting transfer method used for a plastic molded product is well known. That is, when manufacturing a plastic molded product, it is a method of transferring a pattern simultaneously with injection molding.The transfer foil is placed in the injection molding die, and then the molten resin is injected into the die, This is a method of transferring a desired pattern or the like from the transfer foil to the surface of the injection resin molded product by using the heat pressure at the same time as the molding. In this case, a polyester film has heretofore been mostly used as a base material sheet which is a support for the transfer foil. Further, according to Japanese Patent Application Laid-Open No. 57-47632, a film such as nylon, polypropylene, polyethylene, or fluorine resin is used as a base material sheet in the simultaneous molding transfer painting on a plastic molded product having a high rising and a complicated three-dimensional curved surface. It was considered that a non-stretched film having excellent stretchability such as the above is suitable. On the other hand, actual fairness 4-5358
According to the technique disclosed in Japanese Patent Publication No. JP-A-2003-264, in injection molding simultaneous painting, as a base sheet for a transfer foil having excellent formability such as vacuum forming, by laminating two kinds of synthetic resin films each having different physical properties, a final sheet is obtained. Can have the required physical properties. That is, in order to have the three required physical properties of dimensional stability, heat resistance, and moldability, a first synthetic resin film having dimensional stability and moldability and a second synthetic resin film having heat resistance and moldability In this method, a synthetic resin film is laminated to form a base sheet. In this case, examples of the first synthetic resin film include a polyvinyl chloride resin film (particularly, a non-plastic material having a hardness of 5 PHR) and an acrylic resin film such as a polymethylmethacrylate resin film. On the other hand, as the second synthetic resin film, 6-
Examples thereof include polyamide resin films such as nylon and 66-nylon, acrylic resin films such as polymethylmethacrylate, and the like. When a non-stretched polyester film is used instead of a general stretched polyester film, heat resistance is inferior to that of the stretch-treated product, but moldability is obtained. Regarding the point that the heat resistance becomes weak, there is also a formable transfer foil substrate sheet having a release layer made of a thermosetting resin applied during or after film formation.

Here, the necessity of the three physical properties of dimensional stability, heat resistance and moldability described above will be described with reference to the case of simultaneous injection molding and picture transfer. The dimensional stability means that the film is less likely to expand and contract when a pattern or the like is formed by printing on the film which is the support. This is because the drying temperature of the ink such as a printed pattern is usually kept under a temperature condition of up to about 70 ° C., and if the film expands and contracts greatly, misregistration occurs in multicolor printing. In particular, when a continuous transfer foil having a long continuous shape is formed by printing, tension is usually applied in the longitudinal direction of the substrate sheet, and therefore, it easily expands under dry heating. Incidentally, the misregistration is usually desired to be 0.1 mm or less. Further, heat resistance also means ensuring dimensional stability that can withstand the drying temperature, but here also means heat resistance that can withstand the heat and pressure under the conditions for transferring the transfer foil. That is, in the injection molding, the surface of the transfer foil receives the heat of the injection resin and is usually kept at a temperature of 100 ° C. or higher. This is because if the base sheet of the transfer foil is deformed or swelled by this heat, the pattern layer is melted, the pattern on the molded body is distorted, or wrinkles are formed. Further, the moldability means the ability to be sufficiently molded into a target mold shape in preforming such as vacuum forming of a transfer foil prior to injection molding. Usually, the molding temperature of the preforming is 100 ° C. or higher. However, from the point of the present invention, the meaning of this moldability is to mean that the transfer foil is heated and pressed against the mold surface by utilizing the heat and pressure of the resin at the time of injection molding, and at the same time the resin is infused. Moldability is also acceptable.

[0004]

The above-mentioned conventional methods have the following drawbacks. First, in a transfer foil using a general polyester film as a base sheet, the base sheet has excellent dimensional stability and heat resistance, but since the formability is poor, the transferred surface to be transferred is The shape of was not suitable for complicated shapes. That is,
Since the molding could not be performed sufficiently, the base sheet was broken. The simplest method of using a polyester film is to place the transfer foil in the mold and use the heat pressure when the injection resin is pressed into the mold to make the transfer foil follow the mold surface. It is a method of transferring. However, in this method, the transfer foil is formed along the mold surface using the heat and pressure of the press-fit resin, so the resin temperature must satisfy the temperature conditions suitable for resin molding. It cannot be said that the transfer foil is provided with the optimum temperature condition for the foil forming conditions, and there is a severe limit to the shape of the transfer surface that can be applied. Therefore, in order to raise the limit of molding by the above method, the transfer foil is heated in advance before being press-fitted into a state where it is easy to mold,
There is a method in which even a more complicated shape can be applied by press-fitting a resin after molding by an appropriate method such as using vacuum or compressed air alone or both with a mold itself or another mold other than the mold. there were. However, even with this method, due to the limitation of the molding performance of the molded sheet, it was not possible to apply even complicated intricate shapes. Further, even in the case of a non-stretchable polyester film having moldability, the moldability is improved to some extent but the heat resistance is lowered, and the temperature range in which it can be practically molded is narrow, and stable molding is difficult and satisfactory. There wasn't. As described above, in any case, as long as the polyester film is used as the base material sheet, the shape of the transfer surface is limited due to the difficulty of molding due to the base material sheet itself, and the applicable transfer target is limited. It was being done. In this respect, base material sheets other than polyester films have been proposed. But,
For example, some films disclosed in JP-A-57-47632 and those having satisfactory performance for complicated shapes as described in JP-B-4-5358. There was no. That is, although the nylon film had good moldability and heat resistance, it had poor dimensional stability. In addition, the polypropylene film had insufficient moldability and was inferior in heat resistance. On the other hand, polyethylene films are inferior in heat resistance and dimensional stability, and fluorine-based films are inferior in moldability. As described above, with a base sheet made of a kind of film, it is impossible for a complicated shape,
Therefore, a base sheet composed of two kinds as disclosed in Japanese Utility Model Publication No. 4-5358 has been proposed.
However, even with the two types of base material sheets according to the above invention, there are still many restrictions on the shape of the transfer target material. This is because plastic molded products whose shapes can be freely designed have been widely used as a non-transfer body, and recently, many curved molded products have been used as a design trend. In addition, there is an increasing need for surface cosmetics for articles with slits or lattice-shaped holes or grooves, which are found in, for example, indoor units of air conditioners, and which have a complicated external shape that cannot be obtained by conventional methods. Was there. These are due to the requirement to increase the value of the product by making the surface cosmetic so as to make it a more differentiated product without being tired of the surface simply utilizing the basis of the molded product. In view of such a historical background, there has been a strong demand for a transfer foil having better moldability than ever before.

[0005]

In order to solve the above problems and achieve the object, the present invention has a 200% modulus strength of 5 to 15 Kg / c around the temperature at which the transfer foil is formed.
A moldable transfer foil was obtained in which a transfer layer was laminated on a base material sheet made of a polyvinyl chloride film having a temperature range of 30 ° C. or more in the range of m ² and a thickness of 80 μm or less. Further, a release layer made of an ionizing radiation-curable resin may be formed on the surface side of the polyvinyl chloride film, which is the base material sheet, in contact with the transfer layer.

Conventionally, a polyvinyl chloride film has been said to have poor moldability and dimensional stability, but poor heat resistance, as already described in Japanese Utility Model Publication No. 4-5358. This is because moldability and heat resistance are generally in a trade-off relationship. That is, for example, when the transfer foil is subjected to true pressure forming, if the foil is too stretchable at the forming temperature, the formability is sufficient, but it partially melts, and conversely, if the foil is too difficult to extend, the transfer foil cannot be sufficiently formed. . Therefore, if it is a material that at least both performances are compatible,
The conditions for the base sheet of the formable transfer foil are not satisfied.
However, although polyvinyl chloride films are generally inferior in heat resistance, when we confirm the performance of various polyvinyl chloride films, those with certain physical properties are heat resistant enough to withstand use. Found that there is.

That is, among the polyvinyl chloride films, a polyvinyl chloride film having a temperature range in which the 200% modulus strength is in the range of 5 to 15 kg / cm ² is 30 ° C. or more and the thickness is 80 μm or less is the base sheet. It is suitable as a material. 200% modulus strength is 5 ~ 15Kg / cm ²
Is a measure of elongation suitability, but in true pressure forming,
If the strength exceeds the above range, it cannot be fully drawn, and if the strength is less than the above range, it melts locally. 200% means the elongation of the transfer foil required to the extent that it can stand out to a complicated shape of the transfer target, which has been impossible in the past. Further, if the temperature range in which this strength is expressed is 30 ° C. or less, uniform and stable molding cannot be performed. This is because the transfer foil is heated in order to make it easier to squeeze it by vacuum forming, etc., but the temperature at which the transfer foil is actually heated is uneven in parts, and as a result, it is easy to stretch locally and hard to stretch. Because you can Also, the molding conditions change subtly every time or on different molding days, and stable molding cannot be performed due to these changes. Therefore, it is desirable that the temperature range of the strength development is as wide as possible and preferably 50 ° C. or higher in order to absorb and allow these variations. The thickness of the polyvinyl chloride film is 80 μm.
When placing the transfer foil in the injection mold if it exceeds
The transfer layer near the gate portion where the molten resin flows into the mold is fluidly deformed. This is because the transfer foil acts as a heat insulating layer in order to interpose the transfer foil between the molten resin flowing into the mold and the mold for cooling and solidifying the molten resin so as to embody it in a certain shape. However, the thicker the transfer foil, the greater the heat insulating effect. For this reason,
The temperature on the transfer layer side of the transfer foil is closer to the molten resin temperature. In particular, the temperature of the molten resin is high near the gate. Therefore, if the heat resistance of the transfer layer or the base material sheet of the base is insufficient, they will start to melt. By setting the thickness to 80 μm or less, in the case of simultaneous injection molding and transfer painting, the molding can be performed well even if the mold temperature is 40 to 80 ° C. For this reason, it is not necessary to set the mold temperature low in order to supplement the heat resistance of the transfer foil. Therefore, the decrease in productivity due to the increase in cycle time due to the longer solidification time of the injection resin is less affected.

The substrate sheet may be a polyvinyl chloride film alone, or may have a release layer formed thereon.
This is appropriately selected in consideration of factors such as adhesion between the transfer layer and the base sheet, releasability, and heat resistance required for the base sheet depending on the transfer foil molding conditions. It is preferable to provide the release layer because the release property can be easily controlled. Also,
By using a release layer with irregularities formed on the surface, the release layer is used for the purpose of forming irregularities such as matte feeling on the surface of the transfer pattern and expressing a texture in a meaning different from the pattern. Be seen. The release layer used in the present invention is not particularly limited, but a curable resin is preferable. This is because it has an effect of compensating for the heat resistance limit of the polyvinyl chloride film which causes the flow phenomenon of the transfer layer in the vicinity of the gate portion. This is because the curable resin layer is non-fluid. As such a curable release layer, a thermosetting resin having an elongation of 200% or more and an ionizing radiation curable resin which can be cured by ultraviolet rays or electron beams can be used. Particularly, as the latter, for example, those mainly containing a prepolymer or oligomer of polyfunctional acrylates such as urethane acrylate and epoxy acrylate, acrylic modified alkyd, acrylic modified polyester and the like can be used. Among them, preferred urethane acrylate prepolymers or oligomers having elongation suitability include, for example, diisocyanate, diols having hydroxyl groups at both ends and a weight average molecular weight of 200 to 5,000, and radically polymerizable monomers having hydroxyl groups at the ends. A urethane acrylate oligomer or prepolymer formed by bonding with an acrylate compound having a saturated group may be used alone or as a mixture with another resin.

As a first method of forming a surface-molded release layer, an ionizing radiation curable resin is applied to a cylindrical drum having an uneven surface disclosed in JP-A-2-131175, A method of irradiating ionizing radiation to cure the resin while winding and running the film around the film, transferring the ionizing radiation-curable resin onto the film, and at the same time forming concavities and convexities of the cylindrical drum on the resin by reverse formation (hereinafter, drum There is a printing system). As a second method, there is also a method of curing the resin in a state in which a film whose surface is shaped like a mat is in close contact and then peeling off the film. Further, as a third method, there is a method of forming a coating liquid containing a matting material directly on the film by a known coating method such as roll coating or a printing method such as gravure printing. In order to provide the transfer foil, which is the object of the present invention, with moldability, it is necessary to consider the release layer for surface shaping. That is, in a general case where moldability is not required, the matte material-containing resin layer is generally formed by the third method which can be performed simultaneously with pattern printing when the transfer layer is formed by printing. However, according to the third method, since the matte material is contained in the release layer, the extensibility of the release layer is deteriorated. Therefore, according to the first method or the second method, the matting material is not required, the stretchability is not impaired, and the moldability is not impaired, and the release layer preferable as the moldability transfer foil can be formed. If surface shaping is unnecessary, the third method is sufficient. Further, when forming the release layer, a known primer coat may be applied for the purpose of improving the adhesion to the underlying polyvinyl chloride film.

Further, a low temperature curing type urethane can be used as a material for another release layer. For example, a system composed of a resin obtained by mixing an acrylic polyol and an isocyanate and a tin-based catalyst can be used. As the method of forming these, the third method, or a method of applying a catalyst in advance and then applying urethane can be used. Further, a polyamide resin can be used as a material for another release layer. As a coating method, a known coating method, printing method, or a method of performing in-line at the same time when the transfer layer is formed may be used.

In addition to the above, the mold release layer may be formed by another method as long as it has mold releasability, heat resistance and moldability to some extent. That is, the moldable polyester 3 to
A thin film having a thickness of about 25 μm is laminated on a polyvinyl chloride film with an appropriate adhesive to form a base sheet. However, in this method, although two types of films are used, the degree of freedom in designing the required performance is increased, but the production of the base sheet is complicated and the cost is high. As another method, a polyester film is used as a carrier film, a thermosetting resin is applied onto the carrier film, then semi-cured, and then a polyvinyl chloride resin is cast-coated, and finally the thermosetting resin is used. Is completely cured, the carrier film is peeled off, and a release layer made of a thermosetting resin layer is formed on the polyvinyl chloride film to obtain a base sheet. Alternatively, by co-extruding a polyvinyl chloride resin, an acrylic resin, and a vinylidene fluoride 2-3 resin,
The base sheet has a release layer of 3 μm of fluororesin.

Next, regarding the transfer layer, the transfer layer is composed of at least a pattern layer, and if necessary, a release layer is provided on the side of the base material sheet, while a heat-sensitive adhesive layer is provided on the side in contact with the transferred material. It consists of stacked layers. The meanings of the release layer and the release layer here are defined. The release layer means a layer that remains on the base material sheet side after transfer and facilitates separation from the transfer layer. On the other hand, the peeling layer means a layer which is transferred to the transferred material after transfer and serves as a surface protective layer of the pattern layer. Therefore, when both the release layer and the release layer are present, the release is performed between the release layer and the release layer.

The base sheet may not have a release layer as long as the release layer has a good release property with respect to the polyvinyl chloride film. As the release layer in such a case, for example, known cellulose resins such as cellulose nitrate and cellulose triacetate, vinyl resins such as polyvinyl butyral, and acrylic resins can be used. When the solvent resistance is insufficient when these release layers are transferred to the surface of the transfer target, it is possible to compensate by providing a reinforcing layer made of acrylic resin or the like between the release layer and the pattern layer. it can. Further, as the release layer used when the release layer is provided on the base material sheet side, for example, acrylic resin, vinyl chloride-vinyl acetate copolymer, urethane resin or the like can be used.

The pattern layer may be formed by a known ink and printing method. For example, as a vehicle for the ink, a vinyl resin such as a chlorinated polypropylene resin, an ethylene-vinyl acetate resin, a vinyl chloride-vinyl acetate copolymer, or an acrylic resin can be used.

The adhesive layer may be formed by a known ink and printing method. For example, a thermoplastic resin such as cellulose resin, styrene resin, vinyl resin or acrylic resin can be used. The formation of each layer of the transfer layer may be performed by a known printing method, for example, gravure printing, gravure offset printing, offset printing, flexo printing, silk screen printing, or the like can be used.

As a method for producing a decorative member using the above-described moldable transfer foil of the present invention, it can be used in various methods because of its excellent performance. That is, the transfer method can be broadly classified into two types, and it can be used both for a transfer material which has already formed a shape and for a transfer material which forms at the same time as transfer. The former method includes, for example, transfer to wooden furniture, doors, frame agents, home appliance cabinets by vacuum press molding, vacuum lamination molding, or stamping transfer.
In these cases, the transfer foil is heated by an appropriate heating means, and transferred by being brought into pressure contact with the surface of the transfer target by vacuum, compressed air, or mechanical pressure. The latter method is a method of transferring simultaneously with molding of a plastic molded product, which is used in injection molding, reaction injection molding, low pressure injection molding, compression molding, transfer molding and the like. In these cases, the transfer foil is placed in the molding die and heated appropriately by using preheating or the amount of heat at the time of molding, and the resin is pressed into contact with the transfer target by using the pressure that fills the mold. Then, transfer is performed. Among these methods, the use in the injection molding method is well known as simultaneous injection molding painting transfer, but it is required for the transfer foil in terms of resin temperature, pressure and resin flow rate near the local gate part. The heat resistance is severe, and in this respect, the formable transfer foil according to the present invention has a performance in which such a severe injection molding method is sufficiently taken into consideration.

[0017]

The function of the transfer foil of the present invention will be described below. By using a base sheet made of a polyvinyl chloride film having specific physical properties, it is possible to achieve both dimensional stability and heat resistance and moldability. That is, if the base material sheet is selected by paying attention to the temperature region and the range showing a constant modulus strength, the moldability is emphasized and the base material sheet does not easily become too stretched and the base material sheet does not easily break. This is because it was found that there is a condition that the moldability is good. Also,
By forming a constant release layer instead of the polyvinyl chloride film alone as the base sheet, not only the release suitability of the base sheet can be improved but also the heat resistance can be reinforced. This is because the release layer is made of a curable resin and maintains non-fluidity even at high temperature. By the way,
The release layer acts like a thin skin on the polyvinyl chloride film that is thermoplastic, and even if the base sheet is exposed to near the heat resistance limit and fluidization is likely to occur, the transfer layer on the base sheet It serves to prevent the deformation of the.
In this way, a practical transfer foil having excellent balance of moldability and other properties and excellent in moldability can be obtained.

[0018]

【Example】

<< Example 1 >> Three polyvinyl chloride films (Hishilex made by Mitsubishi resin, 80 μm thick) were coated with three UV-curable resins (C2-222 made by Dainippon Ink and Chemicals) using a gravure reverse coater. The resin to be applied has a viscosity of 1
It was diluted with ethyl acetate for 5 seconds / Zahn cup # 3, and the coating thickness was dried to 20 μm. Next, the applied resin was air-dried, and a polypropylene film (YM-17 manufactured by Toray Co., Ltd., 25 μm thick) was dry laminated on the application side of the ultraviolet curable resin and irradiated with 4 units of 80 W ultraviolet lamps. Then, the polypropylene film was peeled off, and the base material sheet on which the ultraviolet curable resin was formed as a release layer was wound up. A release layer, a pattern layer, and a heat-sensitive adhesive layer were sequentially printed on the release layer surface of the base sheet by gravure printing to obtain a moldable transfer foil shown in FIG.
The release layer, the pattern layer, and the heat-sensitive adhesive layer were all manufactured by Showa Ink Mfg. Co., Ltd. and were peeled 46-7 and BC-7, respectively.
2. Using HS-32 mat, viscosity is 15 seconds / Zahn cup # 4, air dry. The diluent solvent is M for BC-72
EK: toluene = 1: 1, and HS-32 mat has ethyl acetate: toluene = 1: 1. The Helio plate making condition is 54 lines / cm and the angle condition is 0.

Example 2 An ultraviolet-curing resin (C2-222, manufactured by Dainippon Ink and Chemicals, Inc.) was used on a polyvinyl chloride film (Hishilex, 80 μm thick manufactured by Mitsubishi Plastics) using a drum printing system. Applied. Ultraviolet irradiation was performed with two units of an 80 W ultraviolet lamp, and the coating thickness was dry and 10 μm. In this way, the substrate sheet on which the ultraviolet curable resin was formed as the mat-shaped release layer was wound up. Thereafter, a release layer, a pattern layer and a heat-sensitive adhesive layer were formed in the same manner as in Example 1 to obtain a moldable transfer foil shown in FIG.

Example 3 Butyral ink (TJ-No5 manufactured by The Inktech Co., Ltd.) was applied by gravure coating to a polyvinyl chloride film (R type, manufactured by Riken Vinyl Industry Co., Ltd., 80 μm thick) to form a release layer. Then
A pattern layer and a heat-sensitive adhesive layer were formed in-line by gravure printing to obtain a moldable transfer foil shown in FIG. These were formed under the same conditions as those used in Example 1.
The diluent solvent for TJ-No5 was ethyl acetate: toluene: IPA = 4: 4: 2, the viscosity was 15 seconds / Zahn cup # 4, and the Helio platemaking conditions were the same as in Example 1.

Example 4 A polyvinyl chloride film (BHS type manufactured by Bando Kagaku Co., Ltd., 80 μm thick) was coated with a polyamide ink (TJ-No2 manufactured by The Inktech Co., Ltd.) by gravure coating to form a release layer. In addition,
TJ-No. 2 dilution solvent, viscosity is TJ-No.
Same as 5. Then, a release layer, a pattern layer, and a heat-sensitive adhesive layer were formed in-line by gravure printing to obtain a moldable transfer foil shown in FIG. These were formed under the same conditions as those used in Example 1.

[0022]

As described above, according to the formable transfer foil of the present invention, the following effects can be obtained. It is possible to obtain a transfer foil which has dimensional stability and heat resistance, has excellent contradictory moldability, and enables deep drawing. Therefore, the transfer foil can be transferred to a transfer target having a complicated shape such as a lattice or slit, a large aperture ratio, and a shape having a small radius of curvature, which has been impossible in the past, without tearing the transfer foil. At the same time, since the dimensional stability is good, the misregistration is not noticeable even when multicolor printing is performed in the printing process. Also, because it has good heat resistance,
Even when used for injection molding, pattern distortion, flow, wrinkles, etc. are less likely to occur due to the heat of the injection resin. Since it also has strength, the base material sheet does not break in the middle when it is peeled off after transfer. Further, even if there is some variation in the molding temperature of the transfer foil, the transfer foil can be stably molded. Therefore, the product yield is improved and the productivity is improved. In addition, when the base material sheet does not use two kinds of films, the base material sheet is easily manufactured, and the manufacturing cost is low.

[Brief description of drawings]

FIG. 1 is a vertical sectional view of an example of a formable transfer foil.

FIG. 2 is a vertical sectional view of another embodiment of the formable transfer foil.

[Explanation of symbols]

 1 Polyvinyl Chloride Film 2 Release Layer 3 Base Sheet 4 Release Layer 5 Picture Layer 6 Thermal Adhesive Layer 7 Transfer Layer

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Inventor Hirohisa Yoshikawa 1-1-1, Ichigayaka-cho, Shinjuku-ku, Tokyo Dai Nippon Printing Co., Ltd.

Claims (2)

[Claims] 1. A transfer foil having a structure in which a transfer layer is laminated on a substrate sheet, and has a 200% modulus strength in the range of 5 to 15 kg / cm ² around the temperature at which the transfer foil is formed. A moldable transfer foil comprising a base sheet made of a polyvinyl chloride film having a temperature range of 30 ° C. or higher and a thickness of 80 μm or less. 2. The moldable transfer foil according to claim 1, wherein the mold release layer made of an ionizing radiation curable resin is a base sheet formed on the side in contact with the transfer layer.