JPH0718120B2 - Paper that simultaneously has the three effects of deodorization, adsorption, and effect as a neutral paper, and the function of absorbing and radiating energy in the far infrared region near room temperature. - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial field of application] The present invention is a raw material pulp for Japanese paper and foreign paper, and is a shell fossil produced from Toyama Mine and Takaoka Mine in Takaoka City, Toyama Prefecture The present invention relates to paper manufactured by mixing the powder of

[Prior Art] Conventionally, many means have been tried to improve the quality of paper such as Japanese paper and foreign paper. However, conventional paper almost always entangles the plant fibers closely and flatly, and if necessary, size, filler,
It is not out of the scope to mix pigments.

[Problems to be Solved by the Invention] Since the conventional paper is as described above, the action of maintaining freshness of fruits and foods for a long period of time, the action of absorbing odor, the action of strengthening water absorption, the action of preventing deterioration of paper quality, The effect as a far-infrared radiator that absorbs and emits energy in the far-infrared region near room temperature could not be obtained. The absorption and radiation of energy in the far infrared region of shell fossils are important functions that are indispensable for the combined action effect of the paper of the present invention, and the present invention has a single effect as deodorant, adsorption, and neutral paper. The purpose is to obtain a complex action effect that cannot be obtained.

[Means for Solving Problems] The present invention relates to a raw material pulp of Japanese paper and foreign paper, a component of a shell fossil produced from the Toyama mine of Takaoka city, Toyama prefecture, and a Takaoka mine of Kokuchi, and a component similar to the component of the shell fossil. The paper is made by mixing the fossil shell powder.

[Operation] The present invention has a normal paper-like function according to the above-mentioned constitution. Foraminifera, bivalve molluscs, snails, and lime algae having a calcareous shell inhabiting the sea are buried in the seabed alive by crustal movement, Today, tens of millions of years after being transferred, the remains of extremely fine porosity after the elimination of organic substances (collagen, etc.) that form part of these organisms, namely Calcite and Ara.
It becomes a gonite, which exhibits active adsorptivity, odor absorption, and water absorption, and is also effective as a far-infrared radiator due to the coexisting α-Quartz. Also, it stabilizes at pH 7.2 to 8.0 and acts to prevent deterioration of paper quality as neutral paper.

[Examples] In this specification, shell fossils are archaeological names, foraminiferal fossils, geological names, calcareous rock formations, and were mined at Iwatsubo A, B, C mining sites in Toyama Mine, Takaoka City, Toyama Prefecture. On August 7, 1979, the samples were excavated at the following quantitative analysis table 1 that had an analysis report (54 people Tsusan Kogyo No. 564) from the Nagoya Trade and Industry Bureau and at the Kokuchi Toyama mine mine in Takaoka City, Toyama Prefecture. Regarding the sample, it means the one according to the following quantitative analysis table 2 which was reported by Nagoya Bureau of International Trade and Industry on October 20, 1977 (52 persons, Tsusan Kogyo No. 1071).

Further, the shell fossils mined in Takaoka City, Toyama Prefecture are characterized by a large difference in the composition and molecular assembly form of the shell fossils mined in other regions of Japan, and in particular the high proportion of calcium carbonate. Therefore, it is designated as a legal mineral as a national resource because it is different from other similar shell fossils.

In the drawing, 1 is a paper made from pulp, and is made of Japanese paper, Western paper, or paperboard. For paper A, prepared pulp 1 is about 20% or more by weight, and fossil shellfish produced from the Toyama mine in Takaoka City, Toyama Prefecture is burned and processed into fine powder 2 at about 80% or less by weight. Mix and mix appropriately using a beater, and further prepare an appropriate amount of size, filler, and pigment according to the purpose. This is applied to a toothed roll of a paper machine to beat the fiber bundle to make the whole itchy. Then, it is sent to a screen of a paper making machine through a liquid remover, a roll, a belt conveyor, etc., heated and dried, sent to a winder or a cutting machine via a glossing machine, and made into paper. The shell fossil fine powder 2 is obtained by destroying the shell fossil in the mine into sand, removing the crystal water in the shell fossil by heat treatment, and then processing it into fine powder. ) As shown in FIG. 1), or integrally coated on the surface of the paper or the non-woven fabric B as shown in FIG. 1 (b) or as a sandwich in the paper or non-woven fabric B as shown in FIG. 1 (c). It is sandwiched. The shell fossils have been put to practical use as a water quality improving material, a fertilizer, a soil improving material, and a livestock feed. It is the active adsorption of calcite and aragonite, which are the components of this shell fossil and extremely fine porosity,
This is because the odor absorbing property and the water absorbing property as well as the ion exchanging property and the physical and chemical action are simultaneously promoted. Also, pH 8.6-10.
Because it is 0, it has an effect function of stabilizing them in a weak alkali by mixing them in acidic soil and acidic water quality.

[Effect] With the above-mentioned constitution, the present invention exerts an effect as a far-infrared radiator by α-quartz coexisting with active adsorption, odor absorption, and water absorption of extremely fine porous calcite and aragonite. This allows the fruit to last for a long time,
Since it has the effect of maintaining the freshness of foods, it is effective for wrapping paper and packaging, and can be used as part of a disposable diaper by taking advantage of its odor absorbing and water absorbing properties. Prevents deterioration of paper quality due to oxidation and is ideal for long-term storage paper. Further, since it is a far-infrared radiator (a blackbody ratio of 100% emissivity is about 80%), the paper of the present invention will be widely used for medical purposes, health maintenance, activation of plants and living bodies, etc. There is an effect that can be done.

In addition, as a practical test example of odor absorption, according to the test report of the Japan Chemicals Inspection Association (see below), handmade paper mixed with the fossil shell of the present invention at the Shizuoka Paper Industry Test Site
The deodorizing efficiency of malodorous elements, hydrogen sulfide (acidic type) and trimethylamine (alkaline type), was tested, and the result was proved to absorb the amphoteric malodorous element.

That is, the fossil shell of the present invention has a pH of 8.6 to 10.0, and since it has an effect function of stabilizing in weak alkali, the entire paper is in the neutral range of pH 7.2-8.0, and the deodorizing effect also has an amphoteric element. It will have the function of absorbing odors. Paper for which deodorization is practically made by mixing other inorganic substances similar to the present invention does not have a function of absorbing an amphoteric element, and the function is biased to either one. Similar to the function of the present invention, there is a paper containing activated carbon for absorbing amphoteric elements, but this is a wide paper because the color of the activated carbon itself is black and the color of the paper is gray or black fibers are conspicuous. There is a limit to practical use.
In comparison, in the present invention, since the shell fossil powder is almost white, the practical range is wide as a paper having a deodorizing function,
Paper with high practical value.

1. Test period From December 8, 1986 to December 15, 1986 2. Test purpose and items Paper containing fossil shells (10%, 30%, 60%), hydrogen sulfide by commercial deodorizing paper, trimethylamine Deodorization efficiency 3. Test method Put each sample in a Tedra pack (11), seal it, seal each test gas (hydrogen sulfide-15.9ppm, trimethylamine-10.8ppm), and test gas concentration after 20 minutes and 60 minutes. Is analyzed by gas chromatography.

4. Test results 5. Test paper Prototype conditions at the Shizuoka Paper Industry Testing Station are as follows.

Pulp LBKP (hardwood) 8: NBKP (softwood) 2 Refining degree 350 ml csf Shell fossil Quantitative analysis Table 2 powder 75 micron pH8.6 Internal additive chemicals (against raw material = pulp + shell fossil) Polistron 191 0.4% High holder 351 0.01% Hi-Lex 104 0.2% [Specific examples] (Papermaking at Technical Research Center Research Laboratories, Tokushu Paper Making Co., Ltd.) The present invention will be described with reference to examples, except fossil shells and fibrous substances in the present invention. The additive of (1) is not limited to the following examples.

Example 1 Fossil oysters (quantitative analysis, powder 5 micron in Table 2, pH 10.0) 70
Parts by weight and beaten pulp (NBKP: LBKP = 1: 1 beaten degree CSF30c
c) 0.002 parts by weight of cationic polyacrylic amide-based coagulant (solid content) while stirring in an aqueous suspension containing 30 parts by weight (concentration 3%), anionic polyacrylic amide-based coagulant 0.
002 parts by weight (solid content) were sequentially added and stirred to obtain an aggregated slurry. Next, this slurry was made into a sheet having a basis weight of 218 g / m ² using a Fourdrinier paper machine.

Example.2 Shell fossils (quantitative analysis, powder in Table 2, 5 microns, pH 10.0) 15
Parts by weight and beaten pulp (NBKP: LBKP = 1: 1 beatenness CSF450c
c) A slurry was prepared by sequentially adding 0.2 parts by weight of alkyl ketene dimer, 0.2 parts by weight of anionic polyacrylic amide, and 1.0 parts by weight of cationic starch to an aqueous suspension (concentration 2%) containing 85 parts by weight with stirring. . Next, this slurry was made into a sheet having a basis weight of 96.0 g / m ² using a Fourdrinier paper machine.

[Specific deodorizing tests of Examples 1 and 2] 1. Test period From March 2, 1987 to April 11, 1987 2. Test purpose and items Paper with fossil shells (70%, 15%) Grasping the deodorizing effect of hydrogen sulfide and trimethylamine by 3. Test method Put each sample in Tedrapack (1), seal, and test gas (hydrogen sulfide-15.9ppm, trimethylamine-10.8ppm)
After 20 minutes and 60 minutes, each test gas concentration is analyzed by gas chromatography.

4. Test results [Far Infrared Emissivity Measurement of Specific Example 1.2] (Toray Research Center, Inc.) 1. Measurement period From July 15, 1987 to August 11, 1987 2. Measurement purpose Radiation of shell fossils Efficiency assessment 3. Samples NO.1: Shell fossil powder 4 points (5 microns) NO.2: Shell fossil powder (75 microns) NO.3: Shell fossil mixed paper (15%) [Example-2] NO. 4: Shellfish fossil mixed paper (70%) [Example 1] 4. Measurement method “Emission spectrum measurement by FT-IR” Device: IFS-113V (manufactured by Bruker) Detector: DTGS, condition: resolution = 8 cm ^-1 , Integration count = 256 times Attached device: Attached device for emission spectrum measurement, Reference sample:
Blackbody 60 ℃ 5. Measurement results (see attached sheet) Fig. 2: NO.3 emissivity (reference sample 60 ℃ blackbody, horizontal axis: 2 to 25)
Fig. 3: Emissivity of NO.4 (reference sample 60 ℃, blackbody, horizontal axis: 2 to 25)
Fig. 4: Ideal blackbody, (60 ℃) luminescence energy distribution and sample (NO.3, 4) luminescence energy distribution (horizontal axis: 2-25μ)
m) Assuming that the blackbody used has an ideal blackbody emission intensity distribution, the ideal blackbody emission intensity distribution curve (Plank
The formula of Plank where the emission distribution of each sample is calculated by multiplying the formula of (1) by the emissivity of each sample-Omitted 6.Measurement manager Toray Research Center, Co., Ltd. Attached sheet evaluation Far-infrared wavelengths required by organisms for growth (6
The emissivity of about 14 μm is about 80% of that of a black body at 60 ° C. Also in the luminescence energy distribution, since it is added to the distribution line of the ideal black body at about 80% or less, the paper manufactured in Examples 1 and 2 of the present invention effectively absorbs the far infrared region,
It turns out that it is radiant paper.

(Resources) Toyama Mine No. 99 Block 25,011 ares Kokuchi Takaoka Mine No. 104 Block 29,008 are Most of the above mines are forests within 50 meters above sea level. 20
It forms a thick layer up to about 30 meters, mining is an open-pit moat, and natural resources are limited, but it is abundant and resource utilization is meaningful. The shell fossils produced in other parts of Japan contain calcium carbonate below 28% by more than a few percent, and the content of silicic acid is very high. Therefore, it is not recognized as a legal mineral. That is, the shell fossils produced from both mines in Takaoka City, Toyama Prefecture are legal minerals with chemical functions and components that are not present anywhere in Japan. It is also a mineral that has a far infrared emissivity of about 80% with respect to an ideal black body (60 ° C).

[Brief description of drawings]

FIG. 1 (a) is an enlarged cross-sectional view of a paper produced by mixing pulp and fine fossil shell powder, and FIG. 1 (b) is a paper integrally coated with fine fossil shell powder on the surface of a paper or non-woven fabric. Fig. 1 (c) is an enlarged cross-sectional view of paper in which fine shell fossil powder is sandwiched between paper or non-woven fabric in a sandwich form, and Fig. 2 is fossil shell mixed paper (15%) Far Infrared Emissivity Measurement Graph, No. 3
The figure shows the far-infrared emissivity measurement graph of fossil-containing paper (70%), and Fig. 4 shows the luminescent energy distribution of ideal blackbody (60 ° C) and the fossil-containing paper (15%) and fossil-containing paper (70%). ) Comparison diagram of the emission energy distribution of FIG. Fig. 5 is a graph of the emissivity measurement of fossil shells, and Fig. 6 is an ideal blackbody at 60 ℃, shell fossil No. 1 (5μ), and shell fossil No. 2
The comparison figure of the distribution of the luminescence energy of (75μ).

Continuation of the front page (56) Reference JP-A-58-98494 (JP, A) JP-A-58-98493 (JP, A) JP-A-58-91898 (JP, A) JP-A-51-141457 (JP , A) JP-A-56-67579 (JP, A)

Claims (2)

[Claims] 1. A fossil shellfish produced from Toyama Mine and Takaoka Mine in Takaoka City, Toyama Prefecture is heat-processed into pulp and mixed with ultrafine shell fossil powder (hereinafter referred to as shell fossil powder). Paper made from paper. 2. A shellfish fossil produced from a region other than the Toyama mine in Takaoka city, Toyama prefecture and the Takaoka mine in Kokuchi, which is the same or similar to the components of the fossil shells produced in the Toyama mine and Takaoka mine in Kokuchi. The paper according to claim 1, which is produced by mixing fossil powder. The same or similar component refers to a calcium fossil containing 28% or more of calcium carbonate (legal mineral).