JP2007231113A - Pressure bonding sheet - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a pressure bonding sheet for postcards which is improved in lowering of performance, when it is produced from waste paper pulp and has improved hiding power, adhesivity and offset-printability. <P>SOLUTION: The pressure bonding sheet is composed of a base sheet containing raw material pulp and fillers as the major ingredients. The base sheet has an adhesive layer at least on either of the top surface or the back surface. All or a part of the fillers are regenerated particles containing calcium, silicon and aluminum. A wavelength optical contact ratio (pressure: 24.4 kg/cm<SP>2</SP>, wavelength: 0.5 μm) of the surface on the adhesive side as determined by microtopography is ≥8%. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a pressure-sensitive paper having pressure-bonding properties and easy peelability.

  The pressure-sensitive paper is a paper in which an adhesive layer is provided on at least one surface of the base paper. Characteristically, the adhesive layer has no adhesion / tackiness in the normal state, but has the performance (hereinafter referred to as “crimpability”) in which the adhesives in an overlapped state exert adhesiveness by a predetermined pressure. Combined with the ability to be easily peeled later (hereinafter referred to as “easy peelability”). Thereby, by folding and pressing the surfaces in contact with each other so that the adhesive layers face each other, the information on the printed surface (adhesive layer surface) is easily concealed and peeled off at the interface between the adhesive layers when necessary. The printed information can be read again.

  Many of such pressure-bonded papers are often used for postcards (hereinafter referred to as pressure-bonded postcards) for communicating information that needs to be concealed (hereinafter referred to as “hidden information”).

  In other words, the printed postcard prints the concealment information on the surface to be crimped, so that the concealment information can be mailed without leaking to the outside, and the concealment information can be read easily by the recipient. is there. Further, the concealment part is adhered so as to be peeled off at a predetermined pressure. Usually, it is difficult to artificially adhere the concealment part again after the separation, so that confirmation of concealment information only by the recipient is ensured.

  In addition, the crimped postcard has the advantage of being able to be mailed at the same rate as ordinary mail because it can be easily configured in the same size as a commonly used postcard. The use of concealment information is rapidly spreading as concealment information transmission means and concealment information transmission means replacing sealed mail.

  As is clear from the above-mentioned embodiment of the crimped postcard, the crimped postcard can be bonded with a predetermined pressure at the time of processing, can be easily peeled off when necessary, can conceal concealment information (concealment), and information after receiving Therefore, it is always necessary to design a base paper that satisfies such requirements.

  However, the prior art has not yet satisfied all the above-mentioned requirements.

  Japanese Patent Laid-Open No. 2001-109383 discloses a technique for containing 10 to 30% by weight of a general filler in a base paper in an image recording pressure-sensitive adhesive sheet in which a paper base, a pressure-sensitive adhesive layer, and a release material are sequentially laminated. Although the filler in this technology contributes to the prevention of curling at the time of electrophotographic printing and the prevention of bleeding in ink jet printing, ensuring the delamination strength between the adhesive layer and the base paper, and pseudo-pressure bonding There is no suggestion regarding the stability of the pressure bonding strength in the case, and it is not considered that it has been improved due to the action of the conventional general filler addition.

Further, the present applicant relates to the pseudo-bonding paper, and in JP-A-2004-67858, by adjusting the density of the base paper to 0.5 to 0.9 g / m ² using a bulking agent, the peel strength change Although we proposed a technology to reduce the rate and increase the opacity, there is a need for operational improvements that allow easy adjustment of the US basis and paper thickness to comply with the weights stipulated in the Postal Code when used in crimped postcards. In addition, there is room for improvement in such extremely low-density paper because printing and workability are not always easy. Furthermore, the use of the bulking agent may cause the base paper to break during re-peeling or may cause cleavage in the thickness direction because the strength of the base paper decreases. In particular, waste paper pulp, unlike virgin pulp, has a low pulp strength, and this problem may occur remarkably.

In addition, as a measure for improving the adhesiveness and peelability required for the pressure-bonded paper, the present applicant has combined an elastic roll having a Shore hardness of HS 70 to 95 and a metal roll in Japanese Patent Application Laid-Open No. 2004-107837. When the calendered by the calendar and the smoothness by the microtopograph is 8% or more at the set pressure of 24.4 kg / cm ² , the pressure-sensitive adhesive paper that is removably bonded peels off inadvertently in the middle of mailing, and concealment information Has proposed a technique capable of obtaining a peel strength that will not be disclosed. However, with this technique, a new calendar facility is required, and the cushioning property of the pressure-bonded paper is lowered. Therefore, there is a possibility that it is difficult to always have a constant peel strength during the pressure-bonding process.

In addition, as an improvement of the problem that the natural rubber mainly used for the adhesive of the pressure-bonding paper causes a yellowing change or a change in the adhesive strength due to a change over time, the applicant described in Japanese Patent Laid-Open No. 10-166664 as a pseudo adhesive layer. We have proposed a technology that prevents the deterioration phenomenon due to the oxidation of the adhesive, using neutral paper with a pH of 5.5 or higher as the base material as the base paper. However, the deterioration phenomenon of the adhesive is caused not only by contact with oxygen in the atmosphere disclosed in this document and oxidation by ultraviolet absorption, but also by lignin in the raw material pulp constituting the raw material contained in the base paper. It has been found. In particular, it has been found that the deterioration of the adhesive is accelerated by the presence of mechanical pulp having a large amount of lignin. Therefore, when only virgin pulp not targeted for paper pulp is used as a raw material, this technology is relatively useful, but considering the expansion of the use of waste paper pulp containing a large amount of high mechanical pulp, sufficient adhesive can be used. It cannot be said that deterioration prevention technology is sufficient.
JP 2001-109383 A JP-A-2004-67858 JP 2004-107837 A JP-A-10-166664

  The main problem to be solved by the present invention is to make full use of the characteristics of recyclable reusable particles made from deinked floss as the main raw material, effectively utilizing resources, concealability, adhesiveness, peelability, offset printing The object is to provide a crimped postcard paper with improved suitability.

The present invention that has solved the above-described problems and the effects thereof are as follows.
<Invention of Claim 1>
A pressure-sensitive adhesive paper having an adhesive layer on at least one of the front and back surfaces of a base paper containing raw pulp and filler as main components,
A pressure-sensitive adhesive paper, wherein all or part of the filler is regenerated particles.

<Invention of Claim 2>
^{2. The} pressure-sensitive adhesive paper according to claim 1, wherein the wavelength optical contact ratio of the surface of the adhesive layer measured at a wavelength of 0.5 μm under a pressure of 24.4 kg / cm ² using a microtopograph is 8% or more.

<Invention of Claim 3>
The regenerated particles contain deinked floss as the main raw material and contain calcium, silicon and aluminum obtained through the dehydration process, drying process, firing process and pulverization process, and they are analyzed by elemental analysis using an X-ray microanalyzer. The pressure-sensitive paper according to claim 1, wherein the mass ratio of silicon and aluminum is 30 to 82: 9 to 35: 9 to 35 in terms of oxide.

  In the present invention, due to the high opacity, porous property, and cushioning property of the regenerated particles, it can be bonded with a predetermined pressure required for crimping paper, can be easily peeled when necessary, and concealment information can be concealed ( (Concealment) is satisfied. Furthermore, due to the porous nature of the regenerated particles, a high anchoring property to the adhesive layer is shown in the base paper, thereby preventing delamination between the adhesive layer and the base paper. Furthermore, since the regenerated particles have high stability, quality control is easy and stable neutral papermaking is possible. The neutral papermaking makes it possible to prevent deterioration of the adhesive due to the mechanical pulp contained in the used paper pulp, thereby promoting the use of the used paper pulp in the pressure-bonded paper.

Next, embodiments of the present invention will be described in detail below.
The present invention is a pressure-sensitive paper having an adhesive layer on at least one of the front and back surfaces of a base paper containing raw pulp and filler as main components, wherein all or part of the filler is regenerated particles. .

  The regenerated particles in the present invention are particles obtained by using deinked floss as a main raw material (50% or more of the raw material) through at least a dehydration step, a drying step, a firing step, and a pulverization step, preferably calcium, silicon And aluminum. The aluminum is mainly derived from aluminum in clay, trivalent aluminum sulfate added as an auxiliary in the papermaking process, 18 hydrate, and aluminum contained in talc as impurities. Compared with the conventional inorganic filler which shows anionic property, aluminum improves the bond strength with anionic pulp fiber. Therefore, when aluminum is contained, yield and chemical fixability are improved.

  On the other hand, since the primary particles of silica made of silicon are fine, the optical refractive index is high, and the inclusion of silicon improves opacity.

  On the other hand, when calcium is internally added to the raw material pulp, the whiteness of the paper is improved. Here, the calcium carbonate has homogeneous images such as hexagonal calcite crystal (calcite) and orthorhombic aragonite crystal (aragonite). Most limestones produced in nature are calcite crystals, and shellfish contain aragonite crystals in addition to calcite crystals. Furthermore, although not natural, calcium carbonate also has vaterite crystals. There are various kinds of calcium obtained from the deinking floss, but it becomes a substantially uniform calcium carbonate property by calcination and aggregation. Therefore, the calcium contributes to the quality stability of the regenerated particles themselves, and the regenerated particles are agglomerates composed of different components such as calcium, silicon, and aluminum, and exhibit a porous and stable cushioning property.

Here, the ratio of calcium, silicon and aluminum in the regenerated particles was measured by elemental analysis with an X-ray microanalyzer (model number: E-MAX S-2150, manufactured by Hitachi, Ltd./Horiba, Ltd.). The ratio suitable for the present invention is, in terms of oxide, calcium: silicon: aluminum 30 to 82: 9 to 35: 9 to 35, and further 40 to 82: 9 to 30: 9 to 30, In particular, the mass ratio is 60 to 82: 9 to 20: 9 to 20. In particular, when the regenerated particles are silica-coated regenerated particles described later, the ratio of calcium, silicon and aluminum is 30:62:29 to 55: 9 to 35: calcium: silicon: aluminum in terms of oxide. It is preferable that Thus, when the mass ratio of calcium, silicon and aluminum is adjusted, the pore volume of the regenerated particles is 0.15 to 0.60 cc / g, the pore surface area is 10 to 25 m ² / g, and the pore radius is 300 to 1000. It can be angstrom. The total content of oxides in the elemental analysis of calcium, silicon and aluminum in the regenerated particles is preferably 90% by mass or more, particularly preferably 93% by mass or more.

  As a method of adjusting the oxide equivalent ratio of calcium, silicon and aluminum in the regenerated particles, in addition to the method of adjusting the raw material composition in the deinking floss, the coating floss and adjustment that have a clear source in the drying / classification process and firing process It can also adjust by the method of containing process froth in a process with a spray etc., the method of containing incinerator scrubber lime, etc.

  In addition, for example, the amount of neutral papermaking wastewater sludge and the amount of wastewater sludge in the coated paper manufacturing process are adjusted to adjust calcium in the regenerated particles, and a large amount of opacity improver is added to adjust silicon. Newspaper manufacturing wastewater sludge is used, and aluminum is adjusted by appropriately using papermaking wastewater sludge such as acid papermaking and other wastewater sludge in high-quality papermaking processes that use clay. be able to. In this case, when the total content of calcium, silicon and aluminum is adjusted to 90% by mass or more in terms of oxide, it is achieved by selectively removing iron, which is a causative substance that lowers whiteness by oxidation. As a means for this, for example, a means of using a flocculant containing no iron for the agglomeration treatment of drainage sludge, a manufacturing equipment process is designed or lined with a material other than iron, and the iron is contained in the system by abrasion or the like. It is possible to employ a means for preventing iron from mixing, or by installing a high magnetic material such as a magnet in the drying / classifying equipment.

  The regenerated particles preferably have an oil absorption of 30 to 100 ml / 100 g.

  On the other hand, when obtaining regenerated particles, it is desirable to treat the particles having a size of 40 μm or less to 90% or more before the pulverization step after the dehydration step, the drying step, the firing step, and the like. This makes it possible to perform a one-stage pulverization process by a wet process without performing a multi-stage pulverization process such as the pulverization of large particles by dry pulverization and the formation of fine particles by wet pulverization. And the peak height of the average particle diameter in the differential curve of the particle size distribution by the Coulter counter method can be set to 30% or more, and the variation in the particle diameter of individual particles can be reduced.

  In addition, when obtaining regenerated particles, it is desirable to provide various sensors in the remanufactured particle production facility to control the state of the object to be processed, the facility, the processing speed, and the like.

  In addition, it is preferable to granulate the deinked floss that has been dehydrated in the previous stage of the drying process, and more preferably to classify the granulated product uniformly so that coarse or fine particles are formed. The quality can be further stabilized by feeding back the grains to the previous process. In granulation, ordinary granulation equipment can be used, and equipment such as a rotary type, a stirring type, and an extrusion type is preferable.

  It is preferable to remove foreign substances other than regenerated particles in the production facility. For example, it is possible to remove foreign substances such as sand, plastic, metal, etc. with a pulper, screen, cleaner, etc. before reaching the deinking process of the used paper pulp manufacturing process. From the viewpoint of removal efficiency. In particular, as described above, the iron content is preferably removed by avoiding the iron content from being mixed because the oxidation causes generation of a substance causing a decrease in the whiteness of the regenerated particles. Therefore, each process is designed or lined with materials other than iron to prevent iron from being mixed into the system due to wear, etc., and a high-magnetic material such as a magnet is installed in the drying / classifying equipment, etc. In particular, it is preferable to remove iron.

  Here, in this embodiment, regenerated particles can be used alone as a filler, but usually used as such regenerated particles and pigment, heavy calcium carbonate, light calcium carbonate, talc, clay, kaolin, titanium dioxide, At least one pigment (particle) selected from inorganic particles such as synthetic silica and aluminum hydroxide, synthetic polymer fine particles such as polystyrene resin and urea formaldehyde resin, and the like can also be used in combination.

  Further, if necessary, a filler such as inorganic particles regenerated using clay, calcium carbonate, titanium dioxide, or papermaking sludge as a raw material, in particular, deinked floss as a raw material may be added.

  Furthermore, in the present invention, silica-coated regenerated particles in which the surface of the particles is coated with silica can be particularly suitably used as the regenerated particles internally added to the raw material pulp. Silica is further precipitated on the surface of the regenerated particles to form silica-coated regenerated particles. When internally added to the raw material pulp, the paper white color is further increased than when regenerated particles not coated with silica are used. Each effect such as degree, opacity, surface strength, ink drying property, ink absorption unevenness, and bulkiness can be remarkably improved. Moreover, in the used paper processing process in circulation use, it can be made to react with sodium hydroxide, and can contribute also to circulation use of the raw material for paper manufacture, and an inorganic particle as a buffering agent or a bleaching adjuvant.

  Here, about the silica which coat | covers the surface of reproduction | regeneration particle | grains, if it is not the silica produced naturally but the synthetic silica by some chemical reaction, it can be used without a restriction | limiting especially. Specific examples include colloidal silica, silica gel, and anhydrous silica. These synthetic silicas make use of excellent properties such as high specific surface area, high gas adsorbing capacity, fineness, permeability to pores and large adsorbing power, high adhesion, and high oil absorption. It is used in a wide range of fields. Among these, colloidal silica has a shape such as a spherical shape, a chain shape, and an amorphous shape, in which impurities are removed from a silicic acid compound to form an anhydrous silicic acid sol, and the sol is stabilized by adjusting pH and concentration. Amorphous silica. Silica gel is hydrous silicic acid obtained by decomposing sodium silicate with an inorganic acid. Anhydrous silica is obtained by hydrolysis of silicon tetrachloride.

  The method for depositing silica on the surface of the regenerated particles to obtain silica-coated regenerated particles is not particularly limited. For example, the following method can be suitably employed. First, regenerated particles are added to and dispersed in an alkali silicate solution, and after preparing a slurry, the temperature of the liquid is maintained at about 70 to 100 ° C., more preferably at a predetermined pressure in a sealed container, while heating and stirring. Add to produce silica sol. Subsequently, silica can be deposited on the surface of the regenerated particles by adjusting the pH of the final reaction solution to a range of 8-11. Silica precipitated on the surface of the regenerated particles in this way, using alkali silicate (for example, sodium silicate: water glass) as a raw material, reacts with a dilute solution of mineral acid such as sulfuric acid, hydrochloric acid, nitric acid at high temperature, Silica sol particles having a particle size of about 10 to 20 nm, obtained by hydrolysis reaction and polymerization of silicic acid.

  In addition, silica sol fine particles having a particle size of about several nanometers, which are generated by adding an acid such as dilute sulfuric acid to an alkali silicate solution such as a sodium silicate solution, cover the entire porous surface of the regenerated particles. The silica is deposited on the surface of the regenerated particles by the bond between the silica sol fine particles on the surface of the inorganic fine particles and the silicon, calcium, or aluminum included in the regenerated particles accompanying the crystal growth of the silica sol fine particles. You can also. In this case, the pH when adding the acid to the alkali silicate solution is in a neutral to weakly alkaline range, and the pH is preferably adjusted in the range of 8-11. This is because if the acid is added until the pH reaches an acidic condition of less than 7, white carbon may be generated instead of silica sol particles.

The type of the alkali silicate solution is not particularly limited, but a sodium silicate solution (No. 3 water glass) is particularly desirable from the viewpoint of easy availability. The concentration of the alkali silicate solution is such that the silica component in the regenerated particles is reduced and the silica content (SiO ₂ equivalent) in the solution is 3 so that silica does not easily precipitate on the surface of the regenerated particles. The silica deposited on the surface of the regenerated particles is preferably white carbon from the form of the silica sol, impairing the porosity of the regenerated particles and insufficiently improving the opacity and toner fixability. In order to eliminate the risk of becoming, it is preferable that the silicic acid content is 10% by mass or less.

  On the other hand, the pressure-sensitive adhesive paper of this embodiment has a paper ash content of 6 to 22% measured based on JIS P 8251. When the ash content is less than 6%, the opacity is low and the concealability of the print information cannot be ensured. In addition, the cushioning property produced by the gap between the raw pulp fibers due to the presence of the regenerated particles and the regenerated particles themselves is low, and the delamination strength between the adhesive layer and the base paper cannot be improved. If it is 22% or more, it will be difficult to maintain the paper quality strength of the pressure-bonded paper, and there will be a problem that the concealment information is damaged at the time of peeling and the base paper is broken.

  Further, the ratio of regenerated particles in the ash is preferably 50 to 100%, preferably 60 to 100% by mass in the ash, and more preferably 80 to 100% by mass in the ash. The ratio of regenerated particles in the ash is determined by elemental analysis using an X-ray microanalyzer (model number: E-MAX · S-2150, Hitachi, Ltd./Horiba, Ltd.) It can be calculated from the proportion of the inorganic particle mass detected by combining each element. If the ratio of the regenerated particles is less than 50%, the regenerative particles may have insufficient expression of affinity and ink absorbability with an adhesive having an opaqueness, cushioning property and porous property.

  On the other hand, the base paper of the present invention can be a mixed pulp of virgin pulp and waste paper pulp, and preferably only waste paper pulp can be used as raw material pulp, and the proportion of mechanical pulp in the raw material pulp species constituting the base paper is It can be 5% or more. The amount of mechanical pulp from the base paper can be analyzed based on JIS P 8120.

  There is no particular limitation on the type of virgin pulp that can be used for the base paper, and for example, a known pulp that is used in the production of fine paper can be used. Specific examples of such virgin pulp include kraft pulp (KP) such as sulfite pulp (SP), soda pulp (AP), hardwood bleached kraft pulp (LBKP) and softwood bleached kraft pulp (NBKP), and chemiground pulp (CGP). ), Semi-chemical pulp (SCP), bleached pulp (BPGW) crushed under pressure, and the like, and these can be used alone or in combination of two or more. Such virgin pulp is used after being bleached if necessary. In this case, it is preferable to employ a bleaching method not using chlorine. That is, when bleached pulp is used, it is desirable to use pulp bleached by chlorine-free bleaching such as TotalChlorineFree (TCF) and ElementalChlorineFree (ECF). Such chlorine-free bleached pulp does not use elemental chlorine and hypochlorous acid, and is subjected to ozone bleaching or oxygen bleaching. Although it is not clear, the end groups of fibers (cellulose) constituting the pulp are not clear. Since it is activated by oxygen, it is a pulp that has a high affinity with a cationic wet paper strength agent and an anionic dry paper strength agent, and is more effective in improving the paper strength.

  On the other hand, as used paper pulp, used paper pulp that has been bleached, in particular, reduced-bleached with thiourea dioxide (FAS), can be suitably used. The reason why FAS-bleached waste paper pulp is not clear compared to conventional chlorine-bleached pulp is high in affinity with cationic wet paper strength agent and anionic dry paper strength agent, and more effective in improving paper strength. It is suitably demonstrated and environmental protection and cost reduction can be realized.

  In the present invention, the content of mechanical pulp in the pulp type in the raw material pulp is preferably 5% by mass or more. By using 5% by mass or more of mechanical pulp in this manner, the opacity is high and the concealment property of the recorded information is high as compared with the base paper having only the same basis weight of virgin pulp. It can be used more suitably. In view of sufficiently maintaining the surface strength of the base paper, the content of mechanical pulp in the raw material pulp is preferably 50% by mass or less.

  As the raw material pulp of the base paper, Canadian standard conforming to the method described in “7. Test pieces and disaggregation” of JISP8120 from the viewpoint of improving the water resistance of the pressure-bonded paper, specifically the paper strength of the base paper. The freeness (hereinafter referred to as CSF) is beaten in the range of 350 mL or more, preferably 400 mL or more and 600 mL or less, preferably 550 mL or less. When the CSF of the raw material pulp is less than 350 mL, the stiffness and strength of the base paper itself are lowered without exhibiting the paper strength improvement effect, and the printability may be inferior. Moreover, when the CSF of raw material pulp exceeds 600 mL, formation may deteriorate, for example, it may be inferior in printability at the time of inkjet printing, surface unevenness of the base paper due to formation unevenness, or easy peelability. There may be a problem with the adhesive strength. Note that a known beating machine such as a refiner or a kneader is used for beating the raw material pulp, but the CSF of the raw material pulp can be adjusted by classifying the short fiber and the long fiber using a classifier. By appropriately adjusting the treatment concentration and treatment time, a raw material pulp having a CSF within the above range can be obtained.

  The regenerated particles described in the present invention are porous, porous and irregular in shape, and calcium: silicon: aluminum has an element ratio of 30 to 62:29 to 55: 9 to 35 in the structure. Both the enhancer and the anionic dry paper strength enhancer have a high affinity, and even if the regenerated particles are used as a filler, the effect of reducing the paper strength is small.

  In producing base paper from raw pulp, it is desirable to add a cationic wet paper strength agent and an anionic dry paper strength agent to the raw material pulp. The cationic wet paper strength agent has an action of improving the wet tensile strength of the base paper, and the anionic dry paper strength agent improves the fixability of the cationic wet strength paper to the base paper. Has an effect.

  Examples of the cationic wet paper strength agent include those obtained by imparting cationicity to resins such as polyamide resin, urea-formaldehyde resin, melamine-formaldehyde resin, polyamide-polyamine-epichlorohydrin resin, polyethyleneimine, and the like. Or two or more can be used simultaneously. For example, in the case of urea-formaldehyde resin, these resins are modified with a polyvalent amine such as ethylenediamine or diethylenetriamine to promote the fixing to pulp fibers to impart a cationic property. In the case of a melamine-formaldehyde resin, heat condensation is performed in the presence of hydrochloric acid to form a so-called acid colloid having a cationic property. Among these cationic wetting paper strength agents, polyamide resins, polyamide-polyamine-epichlorohydrin resins, and polyethyleneimines can be suitably used in consideration of environmental aspects due to recent restrictions on free formalin and the like.

  Examples of the anionic dry paper strength agent include polyacrylamide (hereinafter referred to as “PAM”), PVA, carboxymethylcellulose, and the like, and these can be used alone or in combination of two or more. When PVA is used as such an anionic dry paper strength agent, as will be described later, since the PVA is contained in the adhesive composition forming the adhesive layer, the base paper and the adhesive layer The familiarity becomes better, and the adhesion between them can be further enhanced.

The addition amount of the cationic wet paper strength agent and the anionic dry paper strength agent to the raw material pulp is not particularly limited, and the wet tensile strength of the base paper is 0.7 to 1.8 kgf / 15 mm (MD). It is desirable to adjust as appropriate. In order to obtain a sufficient effect of improving the water resistance of the base paper, the cationic wet paper strength agent is preferably 10 parts or more per 10 ³ kg (absolutely dry) of the raw material pulp. At the same time as avoiding high costs, when considering the environmental impact so that the base paper can be recycled as waste paper, 20 parts of cationic wet paper strength agent is used for 10 ³ kg (absolutely dry) of the raw pulp. In the following, it is further preferable that the amount be 15 parts or less. Although disaggregation is possible in the range of more than 15 parts and 20 parts or less, disaggregation time is required, or chemical addition such as sodium hypochlorite is required to disaggregate. If it is 15 parts or less, it can be disaggregated with a normal high-concentration pulper.

  The cationic wet paper strength agent and the anionic dry paper strength agent described above are balanced in proportion to each other so that the cationic wet paper strength agent is easily fixed on the base paper at the time of papermaking. To be adjusted. Specifically, the ratio of the cationic wet paper strength agent to the anionic dry paper strength agent (cationic wet paper strength agent / anionic dry paper strength agent (mass ratio)) is 1/4 or more, and further 1 / It is preferable to adjust to 3.9 or more, 1/3 or less, and further 1/3 or less. When the ratio of both is less than 1/4, the effect of improving the wet tensile strength is reduced. When the ratio is more than 1/3, the blending ratio of the anionic dry paper strength agent is reduced. Fixing property of wet paper strength agent decreases.

  The regenerated particles described in the present invention are porous, porous and irregular in shape, and calcium: silicon: aluminum has an element ratio of 30 to 62:29 to 55: 9 to 35 in the structure. Both the enhancer and the anionic dry paper strength enhancer have high affinity, and even if the regenerated particles are used as a filler, the effect of reducing the paper strength is small.

  The method for producing the base paper is not particularly limited, and the base paper can be produced by making paper using a general paper making technique in a neutral or acidic region. That is, after the raw pulp is made into a slurry, the paper may be made using a long net paper machine, a round net paper machine, a twin wire type paper machine, a multilayer paper machine, or the like.

  It is important that the base paper has a wet tensile strength (also referred to as “wet tensile strength”) in a specific range. In other words, if the wet tensile strength is too high, it is extremely difficult to tear even when it gets wet with water. However, the waste paper generated in the process of manufacturing the base paper cannot be reused as waste paper because it is extremely difficult to dissociate, and cannot be said to be environmentally friendly. On the contrary, when the wet tensile strength is low, the base paper is delaminated when it gets wet with water, and the interfacial delamination of the adhesive layers stacked as the pressure-bonded paper cannot be realized. For this reason, it is desirable that the wet tensile strength is in a specific range. In the base paper according to the present invention, the wet tensile strength is preferably in the range of 0.7 to 1.8 kgf / 15 mm (MD). When the wet tensile strength in the MD direction of the base paper is less than 0.7 kgf / 15 mm (MD), an adhesive layer made of an adhesive composition containing a cationic wet paper strength agent may be applied later. There is a possibility that the wet paper strength of the entire pressure-bonded paper may not be sufficient, and interface peeling may not be realized when the paper is wet, so that information printed on the pressure-bonded surface may not be reliably read. When the wet tensile strength exceeds 1.8 kgf / 15 mm (MD), it becomes difficult to reuse the base paper as used paper.

  Further, the base paper preferably has a paper delamination strength in the range of 10 to 50 gf / 15 mm when wet. If the thickness is less than 10 gf / 15 mm, the information printed on the pressure-bonded surface cannot be reliably read due to separation between paper layers when wet. When the paper delamination strength when wet exceeds 50 gf / 15 mm, it becomes difficult to reuse the base paper as waste paper, which is not preferable from the viewpoint of resource recovery.

  Here, the wet tensile strength and the paper delamination strength when wet will be described in detail. The wet tensile strength according to the present invention is a value measured in accordance with the method described in JIS P 8135 after dipping the base paper in water for 10 minutes. The paper delamination strength is a value obtained by measuring the T-type peel strength after immersing the base paper in water for 10 minutes. The reason why the immersion time in water is set to 10 minutes is not based on the premise that the pressure-bonded paper made of the base paper is immersed in water. This is because it is sufficient if it has water resistance that can withstand even when it gets wet due to rain or an accident. The wet tensile strength and wet paper delamination strength were measured in a wet state.

On the other hand, the surface strength can be further increased by applying a size press liquid containing an inorganic pigment, starch or the like to the surface of the base paper as required. Further, the basis weight of the base paper used in the present invention is not particularly limited, and may be, for example, about 100 to 150 g / m ^2. It is necessary to make paper.

On the other hand, the pressure-sensitive adhesive paper according to the present invention has a wavelength optical contact ratio of 8% or more on the surface of the adhesive layer measured at a wavelength of 0.5 μm under a pressure of 24.4 kg / cm ² using a microtopograph. Is desirable. It is necessary to evaluate the smoothness of the surface of the adhesive layer under pressure. The wavelength optical contact rate in the present invention can be measured using a commercially available microtopograph (trademark, manufactured by Toyo Seiki Seisakusho Co., Ltd.).

  Here, the optical contact rate by the microtopograph will be briefly described. When the surface to be measured is pressure-bonded to one surface of the prism and parallel light is incident at an angle of 45 degrees from the prism side, reflection occurs at the boundary surface of the medium having a different refractive index. At this time, the light digs into the boundary surface, that is, the inside of the surface to be measured in accordance with the wavelength thereof (the shorter the wavelength, the shallower the digging depth is, the easier it is to reflect near the surface). Microtopographs use these light properties to measure the optical contact rate (expressed as a percentage) between the prism and the measured surface under pressure from the ratio of the reflected light amount to the incident light amount. The larger the value of this optical contact ratio, the better the surface smoothness of the surface to be measured under pressure.

In the microtopograph (manufactured by Toyo Seiki Co., Ltd.) used in the present invention, four wavelengths of 0.5, 0.9, 1.3, and 1.7 μm are selected as specific wavelengths, and the optical contact ratio F (λi) for each specific wavelength. And the optical contact rate curve F (λ) is estimated from this. Here, F (λ) is the ratio of the amount of light that penetrates into the paper at a depth corresponding to that wavelength with respect to the amount of incident light of a certain wavelength. If the ratio to the amount of incoming light is integrated from 0 to ∞ with respect to the wavelength λ, a physical quantity proportional to the total capacity of the paper depressions or the average depth of the depressions can be obtained. This is defined as Rp (Printing Roughness) represented by the following formula, and it can be determined that the larger the value, the rougher the surface and the worse the smoothness.
Rp = ∫ [1-F (λ)] dλ

In the present invention, when measuring the pressure-bonded paper, the pressure on the surface of the adhesive layer when the coating amount of the adhesive layer is 6 to 12 g / m ² is 24.4 kg / cm ² using the microtopograph. The pressure is pressed onto one surface of the prism, and the optical contact ratio is measured using light having a wavelength of 0.5 μm. The range is 8% or more, preferably 10% or more, and particularly preferably 10 to 30%. When the optical contact ratio is 8% or less, the surface smoothness under pressure may not be sufficient, and good adhesion between the adhesive layers may not be obtained. On the other hand, when the optical contact ratio exceeds 30%, the surface smoothness under pressure is improved and the adhesiveness between the adhesive layers is improved. On the other hand, the adhesive strength variation in the sealer is increased, and the stable peel strength is obtained. There is a possibility that problems that cannot be obtained occur.

  The optical contact rate in the present invention can be appropriately adjusted by the blending of raw material pulp constituting the base paper and the blending ratio of regenerated particles added internally as a filler. In particular, in order to ensure the paper quality of the base paper, at least 5 to 50% mechanical pulp and 19 to 25% NBKP are blended in the raw material pulp of the base paper, and the recycled filler is used as the total filler in the equipment paper. Is preferably obtained at a ratio of 60% or more, and the offset printability is also improved.

  Next, the adhesive layer of the pressure-bonded paper according to the present invention will be described in detail. The adhesive layer is preferably formed from an adhesive composition containing at least a binder component containing natural rubber, PVA and fine particles, for example. In addition, when the wet paper strength after application is further increased to make a compressed postcard, it becomes highly water-resistant, and even when it gets wet, the crimped surface can be easily peeled off when necessary without damaging the recorded information. Therefore, it is desirable to contain a cationic wet paper strength agent in the adhesive composition.

  The binder component includes, for example, natural rubber. In addition to natural rubber, latex, synthetic rubber, synthetic resin and the like that are usually used as a binder component of an adhesive can be used in combination. Among them, for example, natural rubber latex obtained by sulfur-free vulcanization of natural rubber and mixed with methyl methacrylate, natural rubber latex obtained by graft copolymerization of methyl methacrylate with natural rubber, acrylic modified rubber latex, rubber latex And a mixture of a protective colloidal acrylic copolymer emulsion alone or in combination of two or more thereof can be particularly preferably used from the viewpoints of blocking resistance, aging resistance, and ink inking property. The amount of the natural rubber in the binder component is not particularly limited, and is usually 50% by mass or more, and more preferably about 55 to 95% by mass.

  In addition, starch, a dispersant, a humectant, a water resistant agent, a surfactant, and the like may be included as long as the properties as the binder component are not impaired. Examples of such a dispersant include polyethylene oxide and calcium stearate. Examples of the humectant include acrylic acid, acrylic acid ester, carboxymethyl cellulose and the like. Examples of the water-proofing agent include urea formalin resin and polyamide polyurea resin, and examples of the surfactant include silicone wax “GZ-650” (trade name, manufactured by Seiko PMC).

  The fine particles control the pseudo-adhesion between the pressure-bonded adhesive layers, and facilitate the peeling of the pressure-bonding surface when necessary. As the fine particles, recycled particles contained in the base paper in the present invention can be suitably used. The regenerated particles are irregular and porous aggregates of fine particles, which can improve the strength of the adhesive layer and stabilize the peel strength due to its cushioning properties. Other fine particles include, for example, pigments such as silica, clay and calcium carbonate, amorphous synthetic silica powders having different average particle diameters, calcined kaolin, acid clay, activated clay, colloidal silica, colloidal alumina, zeolite, magnesium carbonate. , Titanium dioxide, zinc oxide, aluminum hydroxide, corn starch, potato starch, wheat starch, polyethylene fine particles, polystyrene fine particles and the like, and these can be used alone or in combination of two or more. In the pressure-sensitive adhesive paper of the present invention, the ash content including the base paper and the adhesive layer falls within the range of 6 to 22% in order to satisfy both the weight of the pressure-sensitive adhesive paper based on the postal method and the required pressure-sensitive adhesive paper strength. preferable.

  If the particle size of the fine particles is too small, blocking of the adhesive layer and re-peeling failure will occur, resulting in a problem that the concealment information will be damaged, and tend to cause conveyance failure and double feeding in printing and processing processes Therefore, the average particle diameter is preferably 1 μm or more, more preferably 3 μm or more. Also, if the particle size of the fine particles is too large, inadvertent peeling may occur and the concealability may be impaired, and since the fine particles form unique protrusions protruding from the adhesive layer, printing defects and Since there is a tendency that workability defects occur in the processing and printing steps, and the printing appearance tends to deteriorate, the average particle diameter is preferably 25 μm or less, more preferably 20 μm or less.

  The blending amount of the fine particles is 1 part by mass or more, further 3 parts by mass or more with respect to 100 parts by mass of the binder component so that the pseudo-adhesiveness between the adhesive layers is sufficiently controlled to a desired level. It is preferable that If there are too many fine particles, the fine particles will not be sufficiently fixed on the surface of the adhesive layer, causing fine particles to drop off during processing and printing / recording processes. Since the quality may be deteriorated, the amount of the fine particles is preferably 10 parts by mass or less, more preferably 8 parts by mass or less with respect to 100 parts by mass of the binder component. In the present invention, two or more kinds of fine particles having different particle diameters may be used simultaneously.

There is no particular limitation on the method for preparing the adhesive composition. For example, PVA and fine particles with an appropriately blended ratio are added to a dispersion of a binder component containing natural rubber and other components as necessary, and a uniform composition is obtained. What is necessary is just to mix at appropriate temperature so that it may become. The viscosity and solid content concentration of the obtained adhesive composition are not particularly limited as long as the object of the present invention is not impaired, and may be in a range that can sufficiently exert the action as the adhesive layer in the pressure-bonded paper. For example, the viscosity at 25 ° C. (measured with a B-type viscometer) is preferably about 13 × 10 ^{−3 to} 35 × 10 ⁻³ Pa · s, and the solid content concentration is preferably about 5 to 50%. For example, an adhesive layer is formed by applying the adhesive composition having the above composition to the base paper.

  The method for applying the adhesive composition is not particularly limited, and a method using a normal coating machine can be employed. Examples of such a coating machine include an air knife coater, a blade coater, a rod metering coater, a curtain coater, and a roll coater. However, in particular, when a colored adhesive composition is applied, the coating is performed more uniformly. It is preferable to use a curtain coater that can be worked. In addition to the method using these coating machines, a method of printing by a printing method such as gravure offset, letterpress, or flat plate can also be employed.

The coating amount of the adhesive composition is preferably a 6 to 12 g / m ^2. If it is less than 6 g / m ² , the desired adhesive strength between the adhesive layers cannot be obtained, and unintended peeling tends to occur, and if it exceeds 12 g / m ² , the adhesive strength becomes too strong and easily peels. together but tends to be low, leading to the cause of paint deposition on the blanket during offset printing, so easily lead to quality problems during printing, be 6 to 12 g / m ² and even more to 8~10g / m ² preferable.

  After the adhesive composition is coated on the base paper, it is preferable to smooth the coated surface, and a normal calendering process can be employed when performing the smoothing process. The calendar process can be performed by a coating machine and a series of calendars (on-machine calendar), or by a completely separate calendar (off-machine calendar) instead of a series of coating machines. . The type of the calendar is not particularly limited, and a known calendar such as a calendar provided with a metal roll and an elastic roll, or a calendar obtained by combining metal rolls can be used.

  Here, when the coating amount of the adhesive layer formed on the base paper is too small, the pressure-bonding property is low, for example, there is a possibility that peeling occurs during the mailing of the pressure-bonded postcard. If the amount of work is large, the adhesive layer strength may decrease and the adhesive composition may protrude during press bonding, and the thickness of the adhesive layer may be 10 to It is preferable to adjust to about 20 μm.

  The above-described pressure-bonded paper is a so-called “front paste method” in which an adhesive layer is formed on a base paper before information is printed. For example, when creating a crimped postcard from a pre-bonded pressure-bonded paper, after printing shared data, which is immutable information, on the pressure-bonded paper, variable data that requires concealment of personal information etc. is printed on the adhesive layer. Printing is performed, and the pressure-sensitive paper is folded in two or three (Z-fold) so as to conceal at least variable data that needs to be concealed, and is pressure-bonded by a pressure sealer or the like. The pressure-bonded postcard configured in this way contributes to the promotion of the use of waste paper pulp and sufficiently exhibits the basic performance as a pressure-bonded postcard. In addition, it is highly water-resistant, and even when wet, the adhesive layer is not destroyed, and the crimping surface can be easily peeled off when necessary, and the information printed on the crimping surface can be read reliably. be able to.

  Note that the pressure-sensitive adhesive sheet of the present invention is not limited to the one formed by such a front paste method, and may be a post paste method.

  Next, the crimping paper of the present invention will be described in more detail based on the following examples and comparative examples. In addition, this invention is not limited only to this Example.

(About production of base paper)
In a pulp slurry adjusted to CSF 420 cc using pulp with a blending ratio shown in Table 1 as a raw material pulp, a cationic wet paper strength agent (cationic polyamide resin, trade name: WS4002, manufactured by Seiko PMC, solid content 25%) and anion -Based dry paper strength agent (PAM, trade name: Hermide EX, manufactured by Harima Kasei Co., Ltd., solid content 20%) is added in the amount shown in Table 1 (amount based on raw material pulp and ton (absolutely dry)). Paper was made with a net paper machine to obtain a base paper. At the time of paper making, the opening of the head box raw material discharge port (lip), the adjustment of the paper making raw material discharge amount with respect to the paper making speed, and the shaking of the wire in the wire part (rolling) were performed. Moreover, the starch was apply | coated to the front and back of each base paper 1.5g / m < ² > per single side | surface. Furthermore, the basis weights were all adjusted to 130 g / m ² . The ratio of the pulp type in the base paper was measured based on JIS P 8120.

(Preparation of adhesive composition)
Graft-copolymerized natural rubber emulsion (27 parts by weight) obtained by graft-copolymerizing 100 parts by weight of natural rubber latex (NR) and 10 parts by weight of methyl methacrylate (MMA), 25 parts by weight of modified starch and silica (trade name: Carptex #) 80DDSL Japan) mixed with 45 parts by weight of a dispersion containing 20 parts, PVA (manufactured by Kuraray Co., Ltd.) and 10 parts by weight of latex (manufactured by Nippon Zeon) and cationic wet paper strength agent (cationic polyamide resin, trade name) : WS4002, manufactured by Seiko PMC Co., Ltd.) and these were sufficiently mixed at room temperature to obtain an adhesive composition. In addition, the saponification degree, polymerization degree, and addition rate of PVA used in each example are shown in Table 1 below.

(Production of each example (crimp postcard))
The adhesive composition was applied to the base paper at a coating amount shown in Table 1 below using a blade coater at 10 g / m ² to obtain a pressure-sensitive adhesive paper according to each example.

(Test 1: wet tensile strength of base paper)
After the base paper was immersed in water for 10 minutes, the wet tensile strength in the MD direction was measured in accordance with JIS P 8135.

(Test 2: base paper disintegration)
The sample was cut into a 3.0 cm square and charged into a TAPPI standard disaggregator so as to have a concentration of 2%, and then disaggregated at 3,000 rpm for 15 minutes. A hand-sheet was prepared from the sample dispersion thus obtained using a TAPPI square sheet machine so that the rice basis weight was 70 g / m ² , dehydrated and dried. When the undissolved material was not visually observed in the sheet, the disintegration property was good, and when the undissolved material remained, the disintegration property was poor. The evaluation criteria in Table 1 are as follows: ◎: No undissolved material is found in the sheet, ○: Only a few undissolved materials are seen in the sheet, ×: Undissolved material remains remarkably in the sheet Respectively.

(Test 3: Suitability for offset printing)
Using a business form printer (model number: MVF, manufactured by Miyakoshi Co., Ltd.), one-color UV offset printing was performed on the pressure-bonded paper. Form printing by bellows folding was performed at a printing speed of 150 m / min. After form printing was performed at a printing speed of 150 m / min, the presence or absence of paint residue on the blanket and the printed surface were visually observed and evaluated based on the following evaluation criteria. In Table 1, ◎: No problem in transportability and printability, ○: Slight accumulation of debris was observed on the blanket, but no printing failure occurred on the printed surface, △: Blanket Some residue deposits are seen on the printed matter, and some stains are also seen on the printed matter. X: The residue deposits are seen on the blanket, and printing defects are clearly seen on the printed surface of the printed matter.

(Test 4: Pressure bonding / peeling property)
After offset printing is performed on the pressure-sensitive paper, it is folded in three so that the adhesive layer faces each other, and a pressure-bonding sealer (model number: MS-9100, manufactured by Dai Nippon Printing Co., Ltd.) is used, and pressure-bonding is performed under the conditions of the sealer gap 17. The surfaces facing each other were pressure-bonded. Subsequently, the pressure-bonded paper was peeled from the bonded surface, and the state was evaluated based on the following evaluation criteria. In the case of wet, it was immersed in water for 10 minutes as a pretreatment, wiped off, and then similarly tested. The evaluation criteria in Table 1 are: ◎: No special force required, very easy to peel, ○: Easy to peel, Δ: Slightly heavy and difficult to peel, ×: Very easy to peel This indicates that the material is heavy and difficult to peel off, or the base material breaks down, so that it cannot be peeled off properly, or unintentional peeling occurs because it is too light.

(Test 5: Adhesive layer strength)
The uneven state on the surface of the adhesive layer in each example after Test 4 was observed with an optical microscope, and the roughness when the layer surface was rubbed by hand was examined and evaluated based on the following evaluation criteria. Evaluation criteria in Table 1 are as follows: ◎: smooth with no unevenness, no roughness, ○: almost no unevenness, slight roughness, △: several small irregularities are confirmed, and there is a little roughness, ×: The figure shows that the entire surface is uneven, rough, and the adhesive layer is significantly broken.

(Physical property measurement method 1: Opacity)
Measured based on JIS P 8149.

(Physical property measurement method 2: hot water extraction PH)
It was measured based on “Testing method for pH of paper, paperboard and pulp-water extract” described in JIS P 8133.

(Physical property measurement method 3: Optical contact rate)
Using a microtopograph (trademark, manufactured by Toyo Seiki Seisakusho Co., Ltd.), the optical contact rate of the adhesive layer side surface was measured at 24.4 kg / cm ² and a wavelength of 0.5 μm.

  The crimping paper according to the present invention can be used for a label, a lottery material, etc. in addition to a crimped postcard that transmits confidential information as concealment information by mail.

Claims (3)

A pressure-sensitive adhesive paper having an adhesive layer on at least one of the front and back surfaces of a base paper containing raw pulp and filler as main components,
A pressure-sensitive adhesive paper, wherein all or part of the filler is regenerated particles. ^{2. The} pressure-sensitive adhesive paper according to claim 1, wherein the wavelength optical contact ratio of the surface of the adhesive layer measured at a wavelength of 0.5 μm under a pressure of 24.4 kg / cm ² using a microtopograph is 8% or more.   The regenerated particles contain deinked floss as the main raw material and contain calcium, silicon and aluminum obtained through the dehydration process, drying process, firing process and pulverization process, and they are analyzed by elemental analysis using an X-ray microanalyzer. The pressure-sensitive paper according to claim 1, wherein the mass ratio of silicon and aluminum is 30 to 82: 9 to 35: 9 to 35 in terms of oxide.