Thermal activation device and adhesive label printer provided with platen roller

Abstract

An adhesive label printer has a thermal activation device that thermally activates a thermally active adhesive layer of a thermally active adhesive sheet. The thermally active sheet has a recording surface formed on one side of a sheet-like base and the thermally active layer formed on the other side thereof. A recording device records information on the recording surface of the thermally active adhesive sheet. A platen roller conveys the thermally active adhesive sheet and has a roller portion made of least a fluorine atom containing rubber material.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a platen roller for conveying a thermally active adhesive sheet having a thermally active adhesive layer on a back-surface side of a recording surface of a sheet-like substrate, and a recording device, a thermal activation device, and a sticking label printer which are provided with the platen rollers.

2. Description of the Related Art

Heretofore, in many cases, a sticking label such as a POS label for foods, a physical distribution and delivery label, a medical label, a baggage tag, and a display label for bottles and cans is supplied in a tentatively bonded state in which a pressure-sensitive adhesive layer is disposed on a backside of a recording surface (printing surface), and separate paper (separator) is attached onto the layer. Moreover, after printing a predetermined barcode, price or the like on the recording surface, the sticking label is peeled from the separate paper, and attached for use. However, after this type of sticking label is used, the separate paper remains, and there is a problem that a waste is generated.

To solve the problem, there has been investigated utilization of a thermally active adhesive sheet having a thermally active adhesive layer on a backside, of a recording surface of a sheet-like substrate as the sticking label which does not generate any waste after use. The thermally active adhesive layer is formed of a material which does not have any adhesive property approximately at room temperature but which is thermally activated to develop the adhesive property when heated at, for example, about 50 to 150° C. The material forming the thermally active adhesive layer is constituted of a heat-sensitive adhesive material containing main components such as a thermoplastic resin and a solid plasticizer as disclosed in, for example, Patent Documents (Japanese Patent Application Laid-Open No. 10-140117, Japanese Patent Application Laid-Open No. 2002-105414, Japanese Patent Application Laid-Open No. 2002-114953, Japanese Patent Application Laid-Open No. 2002-114954, Japanese Patent Application Laid-Open No. 2002-114955, Japanese Patent Application Laid-Open No. 11-79152). When the solid plasticizer is heated and molten, the adhesive property is imparted to the thermoplastic resin. Since the molten solid plasticizer is brought into an overcooled state and gradually crystallized, the adhesive property is sustained for a predetermined time. While the sticking label has this adhesive property, the label can be attached to an object such as a glass bottle.

As thermal activation means for thermally activating the thermally active adhesive layer of such thermally active adhesive sheet, there are considered applications of various heating systems such as a system using a heating roll, a hot air spraying system, an infrared radiation system, and a system using an electrothermal heater or a dielectric coil. In Patent Document 6, there is disclosed a technology in which a thermal head is used as the thermal activation means. The thermal head is broadly utilized as a recording thermal head of a thermal printer, and has a plurality of resistors (heating elements) disposed on a ceramic substrate as heat sources. The thermal head is brought into contact with the thermally active adhesive layer of the thermally active adhesive sheet to heat the layer.

Here, FIG. 1 shows a schematic diagram of a general constitution of an adhesive or sticking label printer in which the thermal head is used as recording means for recording information on a recording surface and thermal activation means for thermally activating the thermally active means for thermally activating the thermally active adhesive layer. This sticking label printer is provided with a recording device 1, a thermal activation device 2, and a cutter unit 3. Moreover, when a thermally active adhesive sheet 4 wound into a roll shape is introduced into this sticking label printer, predetermined recording is performed on the recording surface of the thermally active adhesive sheet 4 by means of a recording thermal head 11 of the recording device 1, the thermally active adhesive sheet 4 is cut into an appropriate size by the cutter unit 3, the thermally active adhesive layer of the thermally active adhesive sheet 4 is thermally activated by a thermally activating thermal head 21 of the thermal activation device 2, and a targeted sticking label is discharged. This series of treatment is performed while the thermally active adhesive sheet 4 is conveyed by rollers such as appropriately disposed platen rollers. A dimethyl silicone rubber having a low compressive permanent set property is generally used as a material forming a roller portion of the platen roller.

However, in a case where the thermally active adhesive sheet is subjected to the recording and the thermal activating by the above-described sticking label printer, an adhesive force of the thermally active adhesive layer of the discharged thermally active adhesive sheet weakens or disappears depending on a place. The platen roller for use in the above-described sticking label printer deteriorates fast, and needs to be changed with a high frequency.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a platen roller capable of inhibiting at least one of drop of an adhesive force of a thermally active adhesive layer and deterioration of the platen roller which are seen in a case where recording and thermal activating are performed with respect to a thermally active adhesive sheet having the thermally active adhesive layer on a backside of a recording surface of a sheet-like substrate, and a recording device, a thermal activation device, and a sticking label printer which are provided with the platen rollers.

According to the present invention, there is provided a platen roller for conveying a thermally active adhesive sheet having a thermally active adhesive layer on a backside of a recording surface of a sheet-like substrate, wherein a roller portion contains a fluorine atom containing rubber.

Moreover, according to the present invention, there is provided a recording device comprising: recording means for recording on a recording surface of a thermally active adhesive sheet having a thermally active adhesive layer on a backside of the recording surface of a sheet-like substrate; and the above-described platen roller of the present invention.

Furthermore, according to the present invention, there is provided a thermal activation device comprising: thermal activation means for thermally activating a thermally active adhesive layer of a thermally active adhesive sheet having the thermally active adhesive layer on a backside of a recording surface of a sheet-like substrate; and the above-described platen roller of the present invention.

Additionally, according to the present invention, there is provided a sticking label printer which records information on a recording surface of a thermally active adhesive sheet having a thermally active adhesive layer on a backside of the recording surface of a sheet-like substrate and which thermally activates the thermally active adhesive layer to make a sticking label, the printer comprising:

recording means for the recording on the recording surface; thermal activation means for thermally activating the thermally active adhesive layer; and the above-described platen roller of the present invention.

According to the present invention, it is possible to inhibit at least one of drop of an adhesive force of a thermally active adhesive layer and deterioration of a platen roller which are seen in a case where recording and thermal activating are performed with respect to a thermally active adhesive sheet having the thermally active adhesive layer on a backside of a recording surface of a sheet-like substrate.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic diagram showing a general constitution of a sticking label printer which performs recording and thermal activating with respect to a thermally active adhesive sheet to make a sticking label;

FIG. 2 is a perspective view showing a constitution of a platen roller;

FIGS. 3A-3B are sectional views showing a layer constitution of the thermally active adhesive sheet for use in the sticking label printer which performs recording in a heat-sensitive system;

FIG. 4 is a diagram showing a state at a time when the thermally active adhesive sheet is pretreated in an adhesive strength disappearance test;

FIG. 5 is a top plan view of the thermally active adhesive sheet to be tested after the pretreatment;

FIG. 6 is a diagram showing a state at a time when an adhesive strength of the thermally, active adhesive sheet is measured; and

FIG. 7 is a diagram showing one example of an adhesive strength measurement result of the thermally active adhesive sheet.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[Platen Roller]

A platen roller of the present invention is used for conveying a thermally active adhesive sheet having a thermally active adhesive layer on a backside of a recording surface of a sheet-like substrate. Especially, the platen roller is suitable as a platen roller disposed while brought into contact under pressure with recording means for recording information in the recording surface of the thermally active adhesive sheet, especially a recording thermal head and/or a platen roller disposed while brought into contact under pressure with thermal activation means for thermally activating the thermally active adhesive layer of the thermally active adhesive sheet, especially a thermally activating thermal head. The recording surface of the thermally active adhesive sheet to be conveyed may be subjected to recording such as printing, or the sheet may be before subjected to recording such as the printing.

For example, as shown in FIG. 2, the platen roller is constituted of a shaft core member 101, and a roller portion 102 disposed on an outer periphery of the member.

As the shaft core member 101, there can be used a member which functions as a support member of the roller portion 102 of a platen roller 100 and which is rotatable by a power of a driving system. The shaft core member is usable which is made of: a metal such as iron, aluminum, titanium, copper, or nickel; an alloy such as stainless steel, duralumin, brass, or bronze; a resin such as tetrafluoroethylene or polyethylene terephthalate; a composite material of carbon black or carbon fiber and resin or the like. The shaft core member 101 may have a columnar shape, or a cylindrical shape whose central portion is hollow.

In a recording device, a thermal activation device, an adhesive or sticking label printer or the like provided with the platen roller, the platen roller 100 is disposed while brought into contact under pressure with the thermal head, another roller or the like, and has a function of conveying a sheet sandwiched between them. As a material which has heretofore formed the roller portion 102 of the platen roller 100, there is generally used a dimethyl silicone rubber having a low compressive permanent set property.

On the other hand, in the platen roller of the present invention, the roller portion contains a fluorine atom containing rubber. As the fluorine atom containing rubber, for example, a fluorosilicone rubber (FVMQ or the like), a copolymer fluorosilicone rubber, a fluorine rubber (FM, FEPM, FFKM or the like) or the like can be used.

The fluorosilicone rubber is also called a fluorinated silicone rubber, and all or a part of hydrogen atoms present in a substituent of a usual silicone rubber is replaced with fluorine atoms. The copolymer fluorosilicone rubber is obtained by appropriately combining and copolymerizing monomers of the fluorosilicone rubber and the usual silicone rubber. The fluorine rubber is also called a fluorocarbon rubber, and there is known a vinylidene-fluoride-based copolymer, a tetrafluoroethylene-propylene copolymer, a tetrafluoroethylene-propylene-vinylidene fluoride copolymer, a tetrafluoroethylene-perfluorovinyl ether copolymer or the like. The fluorine atom containing rubber may be used alone or may be used by appropriately combining two or more types.

In the present invention, the material constituting the roller portion of the platen roller may be the fluorine atom containing rubber alone, or the fluorine atom containing rubber for use together with another rubber component. When the rubber is used together with the other rubber component, the material constituting the roller portion contains preferably 90% by mass or more, more preferably 95% by mass or more, most preferably 98% by mass or more of the fluorine atom containing rubber.

Examples of the other rubber component include: diene-based rubbers such as a natural rubber (NR), a styrene butadiene rubber (SBR), a butadiene rubber (BR), a nitrile rubber (NBR), an isoprene rubber (IR), and a chloroprene rubber (CR); and non-diene-based rubbers such as a butyl rubber (IIR), an ethylene propylene rubber (EP, EPDM, EPM), a chlorosulfonated rubber (CSM), an acryl rubber (ACM), an urethane rubber (U), and a silicone rubber (Q). Above all, non-diene-based rubbers are preferable such as the butyl rubber, the ethylene propylene rubber, the chlorosulfonated rubber, the acryl rubber, the urethane rubber, and the silicone rubber. The butyl rubber, the ethylene propylene rubber, the acryl rubber, or the silicone rubber is more preferable because it is superior in heat resistance, and the silicone rubber is especially preferable. As the other rubber component, one type of component may be used, or two or more types of components may be appropriately combined and used.

In addition, if necessary, an appropriate amount of a vulcanizing agent, a flame retardant, a coloring agent, an ultraviolet absorber, an anti-aging agent, an oxidation inhibitor, a conductivity imparting agent or the like may be blended in the material constituting the roller portion of the platen roller of the present invention.

A method of forming the roller portion of the platen roller of the present invention can be appropriately selected depending on a type of material forming the roller portion. For example, there is: a method of disposing beforehand a shaft core member in a molding mold to inject a material forming the roller portion into the mold; a method of molding the material forming the roller portion beforehand into a roller portion shape, and thereafter inserting the shaft core member whose surface is provided with a bonding layer to bond the member or the like. A diameter of the platen roller, or a length thereof in a longitudinal direction can be appropriately set in accordance with a device or the like in which the platen roller is to be installed.

It is to be noted that the platen roller of the present invention is not limited to the above-described constitution, and may have, for example, a constitution having the bonding layer or the like between the shaft core member and the roller portion, a constitution of the roller portion only without disposing any shaft core member, a constitution in which the roller portion has a multilayered structure or the like. When the roller portion has the multilayered structure, at least an outermost layer may contain the fluorine atom containing rubber as described later, and a material constituting an inner layer may be appropriately selected.

As properties of the roller portion of the platen roller, usually, a compressive permanent set property, rubber hardness, rebound resiliency and the like are important. As to these properties, there are demanded a cold resistance (changes of the respective properties are small, e.g., when the material is left to stand at 0° C.), a heat resistance (changes of the respective properties are small, e.g., when the material is left to stand at 200° C.), and a chemical resistance (changes of the respective properties are small, e.g., when the material is left to stand in oil). In the present invention, these properties can be adjusted by a material, a method or the like for forming the roller portion of the platen roller. For example, it is preferable to appropriately select the material or the method for forming the roller portion of the platen roller in such a manner that the compressive permanent set (180° C./22 h, JIS K6262) of the roller portion is about 3 to 30%, the rubber hardness (JIS K6253, durometer A hardness) is about 30 to 60 degrees, and the rebound resiliency (JIS K6255) is about 20 to 80%.

[Recording Device, Thermal Activation Device, and Sticking Label Printer]

In the present invention, a recording device is a device for the recording with respect to a thermally active adhesive sheet having a thermally active adhesive layer on a backside of a recording surface of a sheet-like substrate. The device is provided with the platen roller of the present invention as a platen roller for conveying the thermally active adhesive sheet. As a typical constitution of the recording device, the device includes recording means for recording information on the recording surface of the thermally active adhesive sheet, and the platen roller of the present invention. In the recording device in which the platen roller of the present invention is disposed while brought into contact under pressure with the recording means, effects of the present invention are great.

The recording device of the present invention is preferably usable as a recording device constituting a sticking label printer described later.

In the present invention, a thermal activation device is a device for thermally activating the thermally active adhesive sheet having the thermally active adhesive layer on the backside of the recording surface of the sheet-like substrate, and the device is provided with the platen roller of the present invention as the platen roller for conveying the thermally active adhesive sheet. As a typical constitution of the thermal activation device, the device includes thermal activation means for thermally activating the thermally active adhesive layer of the thermally active adhesive sheet, and the platen roller of the present invention. In the thermal activation device in which the platen roller of the present invention is disposed while brought into contact under pressure with the thermal activation means, the effects of the present invention are great.

The thermal activation device of the present invention is preferably usable as the thermal activation device constituting the sticking label printer described later.

In the present invention, the sticking label printer performs recording and thermal activating with respect to the thermally active adhesive sheet having the thermally active adhesive layer on the backside of the recording surface of the sheet-like substrate to make a sticking label, and the printer is provided with the platen roller of the present invention. As a typical constitution of the sticking label printer, the printer includes: recording means for recording the information on the recording surface of the thermally active adhesive sheet; thermal activation means for thermally activating the thermally active adhesive layer of the thermally active adhesive sheet; and the platen roller of the present invention. In a case where the platen roller of the present invention is disposed while brought into contact under pressure with the recording means or the thermal activation means, the effects of the present invention are great. Furthermore, in the sticking label printer which is provided with at least two platen rollers of the present invention and in which one of the rollers is disposed while brought into contact under pressure with the recording means, and the other roller is disposed while brought into contact under pressure with the thermal activation means, the effects of the present invention are especially great.

Typical constitution examples of the recording device, the thermal activation device, and the sticking label printer of the present invention will be described hereinafter. FIG. 1 is a diagram showing a schematic constitution of the sticking label printer utilizing a system to perform the recording and the thermal activating by use of a thermal head. This sticking label printer includes: a recording device 1 which subjects the recording surface of a thermally active adhesive sheet 4 to predetermined recording; a thermal activation device 2 which heats the thermally active adhesive layer of the thermally active adhesive sheet 4 to develop an adhesive property; and a cutter unit 3 which is disposed between these devices and which cuts the thermally active adhesive sheet 4.

In the sticking label printer of FIG. 1, the recording device 1 includes: a recording thermal head 11 as recording means for the recording on the recording surface of the thermally active adhesive sheet 4; and a platen roller 12. The platen roller 12 is disposed while brought into contact under pressure with the recording thermal head 11 by pressurizing means (not shown), and the thermally active adhesive sheet 4 is pressed and held between the roller and the head. When the platen roller 12 is rotated (counterclockwise in FIG. 1) by a driving system (not shown), the thermally active adhesive sheet 4 is drawn from the roller and conveyed. At this time, a rotation speed of the platen roller 12 is controlled based on a recording signal from a recording control unit (not shown), and the recording thermal head 11 is operated. Accordingly, the recording surface of the thermally active adhesive sheet 4 is subjected to the desired recording.

It is to be noted that a recording system in the recording device 1 is a heat-sensitive system, but a system other than the heat-sensitive system may be used as long as it is possible to perform the desired recording on the recording surface of the thermally active adhesive sheet. For example, a thermal transfer system, an ink jet system, an electrophotographic system or the like may be used. In this case, the recording device 1 may be constituted of the recording means required for the recording by the corresponding system, and the platen roller of the present invention. In the recording device having the recording means of the heat-sensitive system or the thermal transfer system, the effects of the present invention are great. In the recording device having the recording means of the heat-sensitive system, the effects of the present invention are greater.

The thermally active adhesive sheet 4 subjected to the desired recording in the recording device of the sticking label printer of FIG. 1 is conveyed to the cutter unit 3. In the sticking label printer, the cutter unit 3 includes a movable blade 31 and a fixed blade 32 as cutting means. The movable blade 31 is operable at a predetermined timing by a cutting control unit and a driving source (either is not shown), and is capable of cutting the thermally active adhesive sheet 4 into an appropriate length.

It is to be noted that the cutter unit 3 can be formed into a constitution other than the above-described constitution as long as the thermally active adhesive sheet 4 can be cut into the appropriate length. For example, the cutter unit may be constituted of two movable blades. The cutter unit 3 may be disposed between the recording device 1 and the thermal activation device 2 as described above, or may be installed in a portion through which the thermally active adhesive sheet 4 passes before the recording device 1 or after the thermal activation device 2.

The thermally active adhesive sheet 4 cut into the appropriate length by the cutter unit of the sticking label printer of FIG. 1 is next conveyed into the thermal activation device 2 by means of insertion rollers 23 of the thermal activation device 2. The thermal activation device 2 includes: a thermally activating thermal head 21 as thermal activation means for thermally activating the thermally active adhesive layer of the thermally active adhesive sheet 4; and a platen roller 22 disposed while brought into contact under pressure with the thermally activating thermal head 21 by the pressurizing means (not shown). Moreover, the thermally activating thermal head 21 operates at a predetermined timing by means of a thermal activation control unit (not shown), and can heat the thermally active adhesive layer of the thermally active adhesive sheet 4 to thereby thermally activate the layer. When the platen roller 22 is rotated (clockwise in FIG. 1) by a driving system (not shown), the thermally active adhesive sheet 4 is conveyed, and the sticking label is discharged to the outside via discharging rollers 24. It is detected by a discharge detecting sensor 25 that the sticking label has been discharged, and treatments such as recording, cutting, and thermal activating are performed in such a manner that the next sticking label is discharged at a predetermined timing.

It is to be noted that as to a thermal activation system in the thermal activation device 2, there may be used a system other than the above-described system in which the thermally activating thermal head is brought into contact with the thermally active adhesive layer of the thermally active adhesive sheet to heat the layer, as long as the thermally active adhesive layer of the thermally active adhesive sheet can be thermally activated. For example, there may be used a system using a heating roll, a hot air spraying system, an infrared radiation system, a system using an electrothermal heater or a dielectric coil or the like. In this case, the thermal activation device 2 can be constituted of thermal activation means required for the thermal activating by the corresponding system, and the platen roller of the present invention. In the thermal activation device having the thermal activation means in which the thermally activating thermal head or the heating roll is used, the effects of the present invention are great. In the thermal activation device having the thermal activation means in which the thermally activating thermal head is used, the effects of the present invention are greater.

As to the thermally active adhesive sheet 4 usable in the sticking label printer in which the recording is performed with respect to the recording surface by a heat-sensitive system, and the thermally active adhesive layer is heated by the thermally activating thermal head as in the sticking label printer of FIG. 1, for example, a thermally active adhesive sheet is usable which is constituted by disposing a heat-sensitive layer 52 on the recording surface of a sheet-like base or substrate 51, and disposing a thermally active adhesive layer 53 on a backside of the substrate as shown in a layer constitution of FIG. 3A. Alternatively, as shown in FIG. 3D, a thermally active adhesive sheet may be used which is provided with an insulating layer 55 between the sheet-like substrate 51 and the heat-sensitive layer 52.

The thermally active adhesive layer 53 is formed of a material which does not have any adhesive property approximately at room temperature but which is thermally activated to develop the adhesive property, when heated at about 50 to 150° C. The layer is usually constituted of a heat-sensitive adhesive material containing main components such as a thermoplastic resin and a solid plasticizer as disclosed in, for example, Patent Documents 1 to 5. When the solid plasticizer is heated and molten, the adhesive property is imparted to the thermoplastic resin. Since the molten solid plasticizer is brought into an overcooled state and gradually crystallized, the adhesive property is sustained for a predetermined time. While the sticking label has this adhesive property, the label can be attached to an object such as a glass bottle.

Examples of a usable thermoplastic resin include a (meth)acrylic ester copolymer, a styrene-isoprene copolymer, a styrene-acrylic ester copolymer, a styrene-butadiene copolymer, an acrylonitrile-butadiene copolymer, an ethylene-vinyl acetate copolymer, a vinyl acetate-acrylic ester copolymer, an ethylene-polyvinyl chloride copolymer, an ethylene-acrylic ester copolymer, a vinyl-acetate-ethylene-polyvinyl chloride copolymer, a vinyl acetate-ethylene-acrylic ester copolymer, a vinyl acetate-ethylene-styrene copolymer, polybutadiene, and polyurethane. A glass transition temperature of the thermoplastic resin for use is preferably −70 to 20° C., more preferably −67 to 0° C. A weight-average molecular weight of the thermoplastic resin is preferably 100,000 to 300,000.

As the solid plasticizer, a compound may be appropriately selected which is capable of imparting the adhesive property to the thermoplastic resin when molten at a desired temperature (e.g., about 50 to 150° C.). Examples include a benzotriazole-based compound, a hindered phenol-based compound, an aromatic sulfone amide compound, and a phthalate compound. Especially in the thermally active adhesive sheet containing the benzotriazole-based compound as the solid plasticizer, the effects of the present invention are great.

The benzotriazole-based compound refers to benzotriazole or a benzotriazole derivative, and benzotriazole is a compound represented by the following formula (I):

The benzotriazole derivative is a compound in which at least one of hydrogen atoms of benzotriazole is replaced with another substituent. Examples include methyl benzotriazole in which the hydrogen atom is replaced with a methyl group, carboxybenzotriazole in which the hydrogen atom is replaced with a carboxy group, nitrobenzotriazole in which the hydrogen atom is replaced with a nitro group, hydroxylbenzotriazole in which the hydrogen atom is replaced with a hydroxyl group, aminobenzotriazole in which the hydrogen atom is replaced with an amino group, and chlorobenzotriazole in which the hydrogen atom is replaced with a chlorine atom. The examples also include a compound constituted by coupling a second nitrogen atom of benzotriazole to substituent R and represented by the following formula (II) having the following structure unit, and a compound constituted by replacing at least one of the hydrogen atoms with another substituent (methyl group, carboxy group, nitro group, hydroxyl group, amino group, chlorine atom or the like) described above.

For example, as a compound in which one of the hydrogen atoms of the compound represented by the above formula (II) is replaced with the chlorine atom, there is the following (IIa).

In the above (II), R is arbitrary, but the substituent represented by the following formula (III) or (IV) is preferable from a viewpoint of a melting point or a handling property.

The above R¹, R², and R³ are independent substituents selected from the hydrogen atom, an alkyl group having 1 to 22 carbon atoms, an alkenyl group having 1 to 22 carbon atoms, and an alkoxy group including the groups. The above R¹, R², and R³ are more preferably independent alkyl groups having 1 to 12 carbon atoms, most preferably independent alkyl groups having 1 to 8 carbon atoms. The alkyl group, the alkenyl group, and the alkoxy group including these groups may have a straight chain structure, a branched-chain structure, or a cyclic structure.

A content of the solid plasticizer in the thermally active adhesive layer can be appropriately set in such a manner as to develop a targeted thermally activated property, and the content is preferably 50 to 500 parts by mass, more preferably 100 to 400 parts by mass with respect to 100 parts by mass of the thermoplastic resin.

The thermally active adhesive layer may contain components other than the thermoplastic resin and the solid plasticizer.

The recording device of the present invention can be preferably used as a recording device constituting a sticking label printer which performs recording and thermal activating on demand as described above, but the device may be constituted of the recording device alone that does not have any thermal activation device. For example, the device may be constituted to supply a recorded thermally active adhesive sheet whose recording surface is subjected beforehand to recording such as the printing. A device may be constituted of the recording device of the present invention, and cutting means capable of cutting the thermally active adhesive sheet into a desired size. For example, the device may be constituted in such a manner that the recording surface of the thermally active adhesive sheet is subjected beforehand to recording such as the printing, and a recorded sticking label cut into a desired size is supplied.

In the present invention, the thermal activation device is preferably usable as a thermal activation device constituting the sticking label printer which performs the recording and the thermal activating on demand as described above, but the device may be constituted of the thermal activation device alone that does not have any recording device. For example, the device may be constituted in such a manner that the recording surface of the thermally active adhesive sheet is subjected beforehand to recording such as the printing, and the recorded sticking label cut into the desired size is subjected to the thermal activating. The device may have the thermal activation device of the present invention, and cutting means capable of cutting the thermally active adhesive sheet into the desired size. For example, the device may be constituted to cut the recorded thermally active adhesive sheet whose recording surface is subjected beforehand to recording such as the printing, and thermally activate the sheet.

It is to be noted that mechanisms are presumed as follows, respectively. The mechanisms can inhibit at least one of drop of an adhesive force of the thermally active adhesive layer and deterioration of the platen roller which are seen in a case where the recording and the thermal activating are performed with respect to the thermally active adhesive sheet having the thermally active adhesive layer on the backside of the recording surface of the sheet-like substrate, when the recording device, the thermal activation device, or the sticking label printer is constituted using the platen roller of the present invention.

First, the present inventors have made investigations, and accordingly found that when: performing the recording and the thermal activating with respect to the thermally active adhesive sheet to make the required number of sticking labels; leaving the thermally active adhesive sheet to stand (e.g., for about several hours) in a state in which the sheet is not completely used; and restarting the recording and the thermal activating of the thermally active adhesive sheet in order to make the sticking labels, the adhesive force of the thermally active adhesive layer easily drops. That is, the following causes have been considered: when the platen roller of the recording device and the thermally active adhesive layer are held while pressed in the state in which this thermally active adhesive sheet is not used up yet, the thermally active adhesive layer of the thermally active adhesive sheet and the platen roller interact, and the adhesive force of the thermally active adhesive layer drops. As this interaction, it is supposed that the solid plasticizer contained in the thermally active adhesive layer moves toward the platen roller. Moreover, when the platen roller provided with the roller portion that contains the fluorine atom containing rubber is used, affinity with the solid plasticizer differs owing to the presence of the fluorine atoms. Therefore, the solid plasticizer does not easily move toward the platen roller, and the drop of the adhesive force of the thermally active adhesive layer can be inhibited.

Moreover, according to the investigations of the present inventors, it has been found that the deterioration of the platen roller is remarkable especially in the platen roller disposed while brought into contact under pressure with the thermal activation means. That is, as the cause, it is supposed that while a step of performing the recording and the thermal activating with respect to the thermally active adhesive sheet is stopped, or between a time when the thermally active adhesive sheet cut into the appropriate size passes and a time when the next thermally active adhesive sheet passes, the thermal activation means is brought into direct contact with the platen roller, and the deterioration of the platen roller therefore quickly proceeds owing to the heat of the thermal activation means. As another cause, it is supposed that a component such as the solid plasticizer contained in the thermally active layer of the thermally active adhesive sheet once adheres to the thermal activation means, the component moves toward the platen roller, and a heat resistance of the roller portion of the platen roller drops. Moreover, it is supposed that when the platen roller provided with the roller portion that contains the fluorine atom containing rubber is used as in the present invention, the heat resistance of the roller portion is enhanced owing to the presence of the fluorine atoms, therefore the proceeding of the thermal deterioration is retarded, and the deterioration of the platen roller can be inhibited.

EXAMPLES

The present invention will be described specifically hereinafter in accordance with experiment examples.

[Preparation of Thermally Active Adhesive Sheet]

As a solid plasticizer, 100 parts by mass of 2-[5′-(1″,1″,3″,3″-tetramethyl butyl)-2′-hydroxyphenyl]benzotriazole (melting point at 103° C., manufactured by Nagase & Co., Ltd., hereinafter referred to as the compound (i)) were blended with 5 parts by mass of sodium salt of polyacrylic acid as a dispersant (manufactured by Toagosei Co., Ltd., trade name.: Alon T-40), and water was added in such a manner that a solid content concentration of the compound (i) was 50% by mass. This mixture was wet-crushed using a ball mill type crusher until an average grain size reached 2 μm, and a solid plasticizer dispersion liquid was obtained.

Moreover, 180 parts by mass of this solid plasticizer dispersion liquid were mixed with 100 parts by mass of vinyl acetate-ethylene-acrylic copolymer emulsion as a thermoplastic resin (manufactured by Sumitomo Chemical Co., Ltd., trade name: Sumica Flex 910) and 100 parts by mass of a rosin ester dispersion liquid as an adhesive property imparting agent (manufactured by Arakawa Kagaku Kogyo Kabushiki Kaisha, trade name: Super Ester E-730), and a dispersion liquid for forming a thermally active adhesive layer, having a solid content concentration of 50% by mass, was obtained.

Moreover, a back surface of a heat-sensitive sheet (mass of a sheet-like substrate: 100 g/m², mass of an insulating layer: 5 g/m², mass of a heat-sensitive layer: 5 g/m²) whose one surface was provided with the insulating layer and the heat-sensitive layer was coated with the dispersion liquid for forming the thermally active adhesive layer obtained as described above, and dried so that a dry mass was 25 g/m². The thermally active adhesive layer was formed, and a thermally active adhesive sheet was obtained.

[Preparation of Platen Roller]

A shaft core member made of stainless steel was set in a platen roller molding mold, and a material of a certain type of rubber mixed and kneaded with a predetermined amount of vulcanizing agent was pressurized on an outer periphery of the member to form a roller portion. Molding conditions (primary vulcanization) were set to 165° C./10 minutes.

Thereafter, a molded article was taken out of the mold, and subjected to secondary vulcanization on conditions of 200° C./4 hours in a baking furnace to prepare a platen roller.

Experiment Example 1

Adhesive Strength Disappearance Resistance Test

First, the thermally active adhesive sheet was subjected to the following pretreatment. As shown by a state at a pretreatment time in FIG. 4, two platen rollers 100 were disposed on the thermally active adhesive layer of a thermally active adhesive sheet 120, and a weight 110 was laid on the rollers to apply a load of 1.2 kgf (11.8 N), and the sheet was left to stand in this state for one day (or two weeks).

Moreover, the pretreated thermally active adhesive layer surface was observed with a microscope.

Furthermore, the thermally active adhesive sheet 120 was set in such a manner that a direction vertical to a contact portion 121 of a roller portion of the platen roller was a length direction as shown in a top plan view of FIG. 5, and the sheet was cut into a length of 150 mm× a width of 40 mm. Thereafter, the thermally activate layer of the thermally active adhesive sheet was thermally activated. The thermal activation was performed by means of a thermally activating thermal head, and detailed conditions were set as follows:

• • all dots were energized;
  • there was heat history correction (control to cancel a heating member portion surface temperature rise due to accumulated heat);
  • activating energy: 0.28 mJ/dot (heating member resistance value: 800 Ω);
  • one dot size: 0.125 mm×0.125 mm;
  • pressing force with respect to a thermal head: 20 gf/mm (1.96 N/m);
  • sheet feeding speed: 100 mm/sec;
  • two-division driving (driving method of dividing a heating member array into two areas, successively allowing members to generate heat, and reducing an increase of a power capacity, instead of heating the whole heating member array once); and
  • 26° C., 60% RH.

On the other hand, a member to be attached was prepared by attaching a polyolefin wrap (manufactured by Mitsubishi Plastics Inc., trade name: Dia Wrap Super) to a measurement base made of SUS by use of a double-faced adhesive tape (manufactured by Dainippon Ink & Chemicals, Inc., trade name: #8103D).

Moreover, the thermally active adhesive sheet was laid on the member to be attached in such a manner that the thermally active adhesive layer of the thermally active adhesive sheet subjected to the thermal activation turned on the side of the member to be attached, and the sheet was pressurized twice by moving a 2 kgf (19.6 N) pressurizing roller inwardly from the front. Thereafter, end portions of the thermally active adhesive sheet were fixed to an adhesive strength measurement unit (digital force gauge, manufactured by Imada Co., trade name: DPX-5TR) via clips, and a load at a time when the sheet was pulled in a direction of 180 degrees at a speed of 300 mm/min was measured at an interval of 0.5 second (see FIG. 6).

As shown by one example of the measurement result of FIG. 7, there was seen a tendency that the load decreased in a place corresponding to a contact portion with the roller portion of the platen roller, and it was found that the adhesive strength of the thermally active adhesive sheet dropped owing to the contact with the roller portion of the platen roller. A decrease ratio of the adhesive strength was estimated. It is to be noted that a load at a time when it was judged that there was not any drop of the adhesive strength was estimated from load changes before and after the time, and the drop ratio of the adhesive strength was calculated from the load and an actually measured load.

The platen rollers in which the roller portions were formed using various materials were investigated as described above, and an adhesive property disappearance resistance was evaluated by use of the following standards based on the state of the resultant thermally active adhesive layer surface and the drop ratio of the adhesive strength. The results are shown in Table 1.

“⊚”: The drop ratio of the adhesive strength was less than 50%, and there was not any change in the state of the thermally active adhesive layer in a case where the sheet was left to stand for one day or two weeks.

“◯”: The drop ratio of the adhesive strength was less than 50%, and there was not any change in the state of the thermally active adhesive layer in a case where the sheet was left to stand for one day (excluding the above-described “⊚” evaluation).

“Δ”: The drop ratio of the adhesive strength was less than 50%, but unevenness was seen on the surface of the thermally active adhesive layer in a case where the sheet was left to stand for one day.

“x”: The drop ratio of the adhesive strength was 50% or more in a case where the sheet was left to stand for one day.

TABLE 1
		Adhesive
		property
Roller portion forming		disappearance
material.	Trade name	resistance
Fluorosilicone rubber	FE241-U1)	⊚
	FE251-U1)	⊚
	FE261-U1)	⊚
	FE271-U1)	⊚
	FE351-U1)	⊚
	FSE75402)	⊚
	XE24-C10372)	⊚
	LS422-BASE3)	⊚
Copolymer type	FE451-U1)	◯
fluorosilicone rubber
Fluorine rubber	MV4544)	⊚
	MV1604)	⊚
	MV1804)		⊚
Fluorosilicone	FSE75402)/	99/1 (mass	◯
rubber/silicone rubber	KE5521)	ratio)
		98/2 (mass	◯
		ratio)
		95/5 (mass	◯
		ratio)
		90/10 (mass	Δ
		ratio)
Fluorosilicone	FSE75402)/	95/5 (mass	⊚
rubber/fluorine rubber	MV4544)	ratio)
Silicone rubber	KE552-U1)	X
	KE7010-U1)	X
	TSE221-3U2)	X
	TSE221-6U2)	X
	SH861U3)	X
	EL5307F5)	X
	EL13015)	X
	EL14015)	X
	EL43005)	X
	EL44065)	X
1)Trade name by Shin-Etsu Chemical Co., Ltd.
2)Trade name by GE Toshiba Silicone Co., Ltd.
3)Trade name by Dow Corning Toray Silicone Co., Ltd.
4)Trade name by Dupont Elastomer Co., Ltd.
5)Trade name by Asahi Chemical Industry Wacker Co., Ltd.

As described above, the adhesive strength disappearance resistance is high in a case where the roller portion contains the fluorine atom containing rubber. That is, it is seen that when the platen roller provided with the roller portion that contains the fluorine atom containing rubber is used, the drop of the adhesive force of the thermally active adhesive layer can be inhibited.

Experiment Example 2

Deterioration Resistance Test

A thermally active adhesive sheet was actually subjected to recording and thermal activating by a sticking label printer prototype machine having a constitution shown in FIG. 1. It is to be noted that as the thermally active adhesive sheet, a rolled sheet having a width of 100 mm was used, and cut into a length of 150 mm by a cutter unit to make sticking labels. It is to be noted that a recording period was set to 1.25 msec, and thermal activating conditions were set in the same manner as in Experiment Example 1.

A platen roller in which a roller portion was formed by use of a certain type of material was used as a platen roller disposed while brought into contact under pressure with a thermally activating thermal head, and a test was conducted on the above-described conditions until the thermally active adhesive sheet ran 20 km, and a deterioration resistance was evaluated by use of the following standards based on a diameter change (presence of swelling) of platen roller and a result of surface observation by a microscope. Results are shown in Table 2.

“⊚”: There was not the swelling, and there was not any change in a surface state.

“◯”: There was not the swelling, but slight bulging was seen on the surface (no practical problem.

“Δ”: The slight bulging was seen on the surface (no practical problem), and the swelling was seen.

“x”: The swelling was seen, and wart-like deformation was seen on the surface.

TABLE 2
Roller portion forming		Deterioration
material	Trade name	resistance
Fluorosilicone rubber	FE261-U1)	⊚
Copolymer type	FE451-U1)	◯
fluorosilicone rubber
Fluorine rubber	MV4544)	⊚
Fluorosilicone rubber/	FSE75402)/	90/10 (mass	◯
silicone rubber	KE5521)	ratio)
Silicone rubber	KE7010-U1)	Δ
	EL5307F5)	X
1)Trade name by Shin-Etsu Chemical Co., Ltd.
2)Trade name by GE Toshiba Silicone Co., Ltd.
4)Trade name by Dupont Elastomer Co., Ltd.
5)Trade name by Asahi Chemical Industry Wacker Co., Ltd.

As described above, the deterioration resistance was high in a case where the roller portion contained the fluorine atom containing rubber. That is, it is seen that the deterioration can be inhibited by use of the platen roller provided with the roller portion which contains the fluorine atom containing rubber.

Claims

1. A thermal activation device comprising: thermal activation means for thermally activating a thermally active adhesive layer of a thermally active adhesive sheet, the thermally active adhesive sheet having a recording surface formed on one side of a sheet-like base and the thermally active adhesive layer formed on the other side thereof; anda platen roller that conveys the thermally active adhesive sheet and that is disposed in a state in which the platen roller is brought into pressure contact with the thermal activation means, the platen roller having a roller portion made of at least a fluorine atom containing rubber material.

2. A thermal activation device according to claim 1; wherein the fluorine atom containing rubber material comprises fluorosilicone rubber.

3. A thermal activation device according to claim 1; wherein the fluorine atom containing rubber material comprises copolymer fluorosilicone rubber.

4. A thermal activation device according to claim 1; wherein the fluorine atom containing rubber material comprises fluorine rubber.

5. A thermal activation device according to claim 1; wherein the roller portion contains 90% by mass or more of- the fluorine atom containing rubber material.

6. A thermal activation device according to claim 1; wherein the roller portion is further made of a silicone rubber material.

7. A thermal activation device according to claim 1; wherein the thermal activation means comprises a thermally activating thermal head.

8. An adhesive label printer that records information on a recording surface of a thermally active adhesive sheet formed on one side of a sheet-like base and that thermally activates a thermally active adhesive layer of the thermally active adhesive sheet formed on another side of the sheet-like base to thereby produce an adhesive label, the adhesive label printer comprising: recording means for the recording information on the recording surface of the thermally active adhesive sheet;thermal activation means for thermally activating the thermally adhesive layer of the thermally active adhesive sheet; anda platen roller that conveys the thermally active adhesive sheet, the platen roller having a roller portion made of at least a fluorine atom containing rubber material.

9. An adhesive label printer according to claim 8; wherein the platen roller is disposed in a state in which the platen roller is brought into pressure contact with the recording means.

10. An adhesive label printer according to claim 9; wherein the recording means comprises a recording thermal head.

11. An adhesive label printer according to claim 8; wherein the platen roller is disposed in a state in which the platen roller is brought into pressure contact with the thermal activation means.

12. An adhesive label printer according to claim 11; wherein the thermal activation means comprises a thermally activating thermal head.

13. An adhesive label printer according to claim 8; wherein the platen roller comprises at least first and second platen rollers, the first platen roller being disposed in a state in which the first platen roller is brought into pressure contact with the recording means, and the second platen roller being disposed in a state in which the second platen roller is brought into pressure contact with the thermal activation means.

14. An adhesive label printer according to claim 13; wherein the recording means comprises a recording thermal head.

15. An adhesive label printer according to claim 13; wherein the thermal activation means comprises a thermally activating thermal head.

16. An adhesive label printer according to claim 8; further comprising cutting means for cutting the thermally active adhesive sheet into a desired size.

17. An adhesive label printer comprising: a thermal activation device that thermally activates a thermally active adhesive layer of a thermally active adhesive sheet, the thermally active adhesive sheet having a recording surface formed on one side of a sheet-like base and the thermally active adhesive layer formed on the other side thereof;a recording device that records information on the recording surface of the thermally active adhesive sheet; anda platen roller that conveys the thermally active adhesive sheet, the platen roller having a roller portion made of at least a fluorine atom containing rubber material.

18. An adhesive label printer according to claim 17; wherein the platen roller is disposed in pressure contact with the thermal activation device.

19. An adhesive label printer according to claim 17; wherein the thermal activation device comprises a thermally activating thermal head.

20. An adhesive label printer according to claim 17; wherein the fluorine atom containing rubber material comprises fluorosilicone rubber.

21. An adhesive label printer according to claim 17; wherein the fluorine atom containing rubber material comprises copolymer fluorosilicone rubber.

22. An adhesive label printer according to claim 17; wherein the fluorine atom containing rubber material comprises fluorine rubber.

23. An adhesive label printer according to claim 17; wherein the roller portion contains 90% by mass or more of the fluorine atom containing rubber material.

24. An adhesive label printer according to claim 17; wherein the roller portion is further made of a silicone rubber material.