JP2007126562A - Method for condensing latex through centrifugation - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a deproteinized, condensed latex through a centrifugal method, with a reduced amount of wastewater deriving from a deproteinization treatment and without emitting ammonia odor. <P>SOLUTION: In the condensation method, within 3 hr after collecting a field latex, KOH is added to the field latex to adjust its pH to ≥12. Then, dibasic ammonium phosphate, an anionic surfactant, ethylenediamine tetraacetic acid and polyethylene glycol are further added to the latex, which is subsequently condensed to achieve a rubber particle content of ≥60 wt.% and deproteinized through the centrifugal method. The KOH concentration in the condensed latex is kept at 0.2-0.3 wt.%. The first-step centrifuged latex, which has been treated once, is diluted with a KOH water solution to achieve a dry latex solid content of 26 wt.%, and dibasic ammonium phosphate etc. are added again to condense the latex through the centrifugal method. The potassium hydroxide concentration in the second-step centrifuged latex is kept at 0.2-0.3 wt.%. The method comprises a stepwise double condensing/deproteinizing treatment using potassium hydroxide. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a method for concentrating a field latex (rubber sap) collected from a rubber tree (Hevea brasiliensis) by a centrifugal separation method.

The field latex is a coagulated rubber state in which a coagulant such as formic acid or acetic acid is added to coagulate rubber particles to remove serum, or natural rubber latex in which rubber particles are dispersed in water (hereinafter simply referred to as latex). Business) and used as a raw material for rubber products.
The amount of rubber particles in the field latex is generally 40% by weight or less. Therefore, a large amount of moisture occupying 60% by weight or more is transferred in the field latex business process. Therefore, in order to reduce the distribution cost of the field latex, the field latex is concentrated so that the amount of rubber particles occupied in the latex becomes 60% by weight or more. Such concentrated field latex is referred to as concentrated latex.

The field latex is concentrated by either the heating evaporation method or the centrifugal separation method. In any of these methods, the pH of the latex is set to 9 or more, the aggregation and decay of the latex due to the generation of volatile fatty acids are prevented, and the rubber particles are dispersed to maintain the latex in a mechanically stable state. A water-soluble alkali of either ammonia or alkali metal is added to the field latex.
In the heating evaporation method, a non-volatile alkali metal such as sodium hydroxide or potassium hydroxide is used as a water-soluble alkali. Ammonia volatilizes by heating in the concentration step of the heating evaporation method. For this reason, ammonia is not used as a concentration of field latex by a heating evaporation method that requires heating, but is used as a water-soluble alkali for concentration by a centrifugal separation method that does not require heating. On the other hand, non-volatile alkali metals such as sodium hydroxide and potassium hydroxide are not used in a centrifugal separation system that does not require heating.

In order to maintain the mechanical stability in which the rubber particles are dispersed in water, a surfactant is added to the field latex. The field latex also contains a metal component.
In the concentration step by centrifugation, dibasic ammonium phosphate ((NH ₄ ) ₂ HPO ₄ ) (hereinafter referred to as DAHP), which is a kind of metal chelating agent, is added to the field latex, and metal components (magnesium) are added. Ions) form a metal chelate with DAHP and precipitate to be removed.

Field latex contains protein. The protein includes serum-soluble protein dissolved in serum and rubber particle-adsorbed protein adsorbed on rubber particles. Serous lysed protein is removed by centrifugation together with serous fluid in a concentration step using a centrifugal separation method. However, the rubber particle adsorption protein remains in the concentrated latex without being removed in the concentration step.
This remaining protein is a dangerous substance that causes allergies, and becomes a problem in rubber products made of latex rubber particles, particularly medical rubber products. A proteolytic enzyme such as a protease is used for the deproteinization treatment for removing the rubber particle adsorbing protein from the concentrated latex (see, for example, Patent Documents 1, 2, 3, and 4).
Japanese Patent No. 3294903 (JP-A-6-329702) Japanese Patent No. 3568155 (JP 2001-122906 A) Japanese Patent No. 3593368 (JP-A-8-143606) JP 2004-197052

In Patent Document 1, the concentrated latex is subjected to a deproteinization treatment with an enzyme and a graft copolymerization treatment with an organic compound having an unsaturated bond.
In Patent Document 2, the concentrated latex is subjected to deproteinization treatment with an enzyme, and sodium silicofluoride and zinc white are added to enhance the mechanical stability of the concentrated latex.
In Patent Document 3, the concentrated latex is subjected to deproteinization treatment with an enzyme, and washed by adding any salt of carbonate, hydrogen carbonate, thiosulfate, borate, organic acid salt, and amine salt, The protein content contained in the concentrated latex is further reduced.
In Patent Document 4, the concentrated latex is subjected to deproteinization treatment with an enzyme, saponified by adding an alkali metal, and concentrated again by a centrifugal separation method.
In the deproteinization treatment with an enzyme, the concentrated latex is diluted so that the rubber particle content is 10% by weight, and the pH of the latex is lowered.
A surfactant is added to the latex in order to suppress the coagulation of the rubber particles that occurs as the pH decreases.

Deproteinization treatment with an enzyme as described in paragraph [0035] (Examples 1 to 11) of Patent Document 2 and paragraphs [0026] to [0027] (Examples 1 to 12) of Patent Document 3 , The latex is diluted so that the rubber particle content is 10% by weight. For this reason, in the deproteinization process by an enzyme, a lot of water is required, and the waste water process after a deproteinization process becomes a problem.
In particular, volatile ammonia is contained in the concentrated latex by centrifugal separation. For this reason, an ammonia odor is generated in the deproteinization process. The ammonia odor causes pollution problems because it destroys and pollutes the environment.
The field latex contains an organic component that functions as a stabilizer and maintains the dispersed state of the rubber particles. In the deproteinization treatment with an enzyme, the organic component is also decomposed by the enzyme. Therefore, a large amount of a surfactant must be added in the deproteinization treatment with an enzyme. However, a latex having a high surfactant content is difficult to form a coating film. Therefore, the latex deproteinized by the enzyme is difficult to handle in the rubber product manufacturing process.

Accordingly, a first object of the present invention is to obtain a concentrated latex having no ammonia odor by a centrifugal separation method.
The second object of the present invention is to perform latex deproteinization treatment and latex concentration at the same time, reduce the amount of dilution water and surfactant used in the deproteinization treatment, and delate latex deproteinization treatment. And to solve the problem of wastewater treatment due to concentration.

  In the present invention, potassium hydroxide (hereinafter referred to as KOH) is added to the field latex within 3 hours immediately after collection, and the pH of the subsequent field latex is maintained at 12 or more. The first feature is that the content of the styrene is concentrated to 60% by weight or more, the concentration of KOH contained in the latex after the concentration is maintained at 0.2 to 1.0% by weight, and the pH is 12 or more. To do.

In addition to the above first feature, the second feature of the present invention is ethylenediaminetetraacetic acid (C ₁₀ H ₁₄ N ₂ Na ₂ O ₈ .2H ₂ O) (below) in addition to DAHP and a fatty acid salt anionic surfactant. EDTA) and polyethylene glycol (hereinafter referred to as PEG) are added to the field latex and concentrated by centrifugation.

  The third feature of the present invention is that in addition to the second feature, DAHP, a fatty acid salt anionic surfactant, EDTA and PEG are added to the field latex, and the step of concentrating the latex by centrifugation is performed twice. This is the point to repeat.

According to the present invention, since KOH is added to the field latex within 3 hours immediately after collection, the aggregation and decay of rubber particles due to the generation of volatile fatty acids are suppressed immediately after collection of the field latex, and concentration with good mechanical stability is achieved. Latex is obtained by centrifugation.
The KOH is a non-volatile water-soluble alkali, unlike ammonia conventionally used for concentrated latex by centrifugal separation. For this reason, no odor is generated in the concentration step of the field latex according to the present invention. Therefore, according to the present invention, it is possible to concentrate deproteinized latex that passes the ISO latex standard without causing the problem of environmental pollution.

In the present invention, EDTA added to the field latex together with DAHP and a fatty acid salt anionic surfactant in addition to KOH is a kind of metal chelating agent like DAHP. For this reason, EDTA forms metal chelates with metal components (divalent metal ions such as copper, magnesium and calcium) in the field latex. EDTA has not only a function as a metal chelating agent but also a protein removal function. PEG added to the field latex together with EDTA has a binding action such as van der Waals. PEG has a function of reacting with a protein by its binding action and removing the protein.
Therefore, according to the present invention, it is possible to deproteinize the field latex without using a proteolytic enzyme such as a protease. PEG also has a function of improving the fluidity of latex.

EDTA and PEG functioning as a deproteinizing agent are added to the field latex together with KOH, DAHP, and a fatty acid salt anionic surfactant in a concentration step by a centrifugal separation method. Therefore, according to the present invention, the field latex is deproteinized simultaneously with the concentration.
In the present invention, since no enzyme is required for the deproteinization treatment, it is not necessary to dilute the latex to such an extent that the rubber particle content is 10% by weight.
Therefore, according to the present invention, the pH of the latex does not decrease during the deproteinization treatment process, there is no danger of rubber particles aggregating with a decrease in PH, and it is not necessary to add a large amount of surfactant to the latex. .

Therefore, according to the present invention, it is possible to obtain a latex that has a low surfactant content, is easy to form a coating film, and is easy to handle in the production process of a rubber product to be a coating film.
And according to this invention, the usage-amount of the water used for the deproteinization process and concentration of latex reduces, the burden for the wastewater treatment also reduces, and the cost of latex reduces.
Further, according to the present invention, the concentration step and the deproteinization treatment step are performed simultaneously in one step instead of separately, so that the cost of the latex is reduced in this respect as well.

Fatty acid salt anionic surfactants include lauric acid, myristic acid, palmitic acid, stearic acid, oleic acid, elaidic acid, ricinoleic acid, linoleic acid, linolenic acid, arachidic acid, arachidonic acid, behenic acid, cetreic acid, elca Acid, brassic acid or the like is used.
A preferred fatty acid salt-based anionic surfactant is lauric acid having a low molecular weight.
The addition of KOH to the field latex within 3 hours immediately after collection suppresses the formation of volatile fatty acids in the field latex as described above, and suppresses the aggregation and decay of the latex due to the volatile fatty acids. This is to maintain the mechanical stability of the.
For this purpose, KOH is preferably injected into a collection container attached to a rubber tree in order to collect field latex. The concentration of the added KOH is set to 0.9% by weight or more.

The concentration of DAHP added to the field latex is set according to the content of magnesium contained in the field latex.
DAHP may be added to the latex at a ratio of DAHP 66 gram to 12.1 gram magnesium.
The concentration of lauric acid added to the field latex is generally 0.14 p. H. R. (The meaning of 0.14 parts by weight of lauric acid with respect to 100 parts by weight of rubber solids. The same shall apply hereinafter).

The concentration of EDTA added to the field latex is set according to the content of copper contained in the field latex.
EDTA may be added to the field latex at a ratio of 372.24 grams of EDTA to 63.56 grams of copper.
However, EDTA is also used as a deproteinization treatment agent.
As such, the concentration of EDTA added to the field latex serving both as a deproteinizing agent and a metal chelating agent is set to 500 ppm or more.
However, a concentration of EDTA of 500 ppm is sufficient.

PEG works effectively to remove soluble proteins.
For this reason, PEG should be added in two stages.
That is, the step of adding DAHP, lauric acid, EDTA and PEG to the field latex and concentrating the latex by centrifugation is repeated twice or more.

According to the experimental results, the concentration of soluble protein that was 5000 to 6000 μgram / gram rubber contained in the field latex was drastically reduced to less than 50 μgram / gram by adding PEG having a molecular weight of 4000.
The concentration of the added PEG is optimally 450 to 500 ppm.

KOH, DAHP, lauric acid, and in addition to them, field latex to which EDTA and PEG are added are used for reacting these additives with the components of the field latex, and for precipitating the product resulting from the reaction. And let stand for several hours before concentrating by centrifugation.
The standing time is generally set to 18 hours or longer.
The standard of the concentrated latex is defined in the ISO standard as shown in Table 1 below.

In order to achieve a dry latex solid content (TSC) of 61.50% or more, the amount of raw latex introduced into the centrifugal separator and the amount of concentrated latex removed from the centrifugal separator are set to the centrifugal separator. Adjust the valve and take-off valve.
In order to increase the dry rubber solid content (DRC) to 60% or more, washing water is added to the once extracted latex to dilute it, and it is passed through a centrifugal separator again to remove impurities.

Regarding the specific gravity of the concentrated latex, the concentrated latex once taken out may be diluted by adding washing water, or the concentrated latex once taken out may be repeatedly passed through a centrifugal separator so that the specific gravity of the concentrated latex is 0.945. I can do it.
According to the present invention, a concentrated latex that satisfies the ISO standard and has no ammonia odor can be obtained.

Example 1 A concentrated latex is produced from a field latex by the following procedure.
[Procedure 1] Place the field latex collected from Hevea brazilian wood in a polyethylene resin tank, and add potassium hydroxide to the field latex until the KOH concentration becomes 0.9% by weight within 3 hours after the collection. Added.
[Procedure 2] DAHP was added to the field latex, and the DAHP content of the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 3] Lauric acid was added to the field latex, and the content of lauric acid in the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 4] KOH is added to the field latex, and the pH of the field latex is increased to 12 or more.
[Procedure 5] The field latex to which DAHP, lauric acid and KOH have been added is stirred for 1 hour.
[Procedure 6] PEG was added to the field latex, and the PEG content of the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 7] EDTA was added to the field latex, and the EDTA content of the field latex was 0.14 P.O. H. R. To.
[Procedure 8] The field latex is diluted with KOH water until the solid content concentration of the field latex is 24% by weight.
[Procedure 9] The field latex is left in a polyethylene resin tank for 24 hours.
[Procedure 10] The field latex is passed through a centrifuge, the serum is removed, and a latex cream having a solid content of 65% by weight is taken out.
[Procedure 11] The pH of the latex cream is increased to 12 or more by adding KOH water, the solid content concentration (TSC) of the latex cream is adjusted to 61.5% by weight, and the content of lauric acid is 0.0004 P.P. H. R. Adjust to.
The characteristic values of the concentrated latex thus obtained are as shown in [Table 2].

[Example 2] A concentrated latex is produced from a field latex by the following procedure.
[Procedure 1] Place the field latex collected from Hevea brazilian wood in a polyethylene resin tank, and add potassium hydroxide to the field latex until the KOH concentration becomes 0.9% by weight within 3 hours after the collection. Added.
[Procedure 2] DAHP was added to the field latex, and the DAHP content of the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 3] Lauric acid was added to the field latex, and the content of lauric acid in the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 4] KOH is added to the field latex, and the pH of the field latex is increased to 12 or more.
[Procedure 5] The field latex to which DAHP, lauric acid and KOH have been added is stirred for 1 hour.
[Procedure 6] PEG was added to the field latex, and the PEG content of the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 7] The field latex is diluted with KOH water until the solid content concentration of the field latex is 24% by weight.
[Procedure 8] The field latex is left in a polyethylene resin tank for 24 hours.
[Procedure 9] The field latex is passed through a centrifuge, the serum is removed, and a latex cream having a solid content of 65% by weight is taken out.
[Procedure 10] KOH water is added to make the pH of the latex cream 12 or more, and the content of lauric acid is 0.067 P.P. H. R. Adjust to.
[Procedure 11] DAHP is added to the one-stage centrifuged latex that has been once processed according to the above-described procedures 1 to 10, and the DAHP content of the one-stage centrifuged latex is set to 0.03 P.O. H. R. To.
[Procedure 12] Lauric acid is added to the one-stage centrifuged latex, and the lauric acid content of the one-stage centrifuged latex is 0.28 P.P. H. R. To.
[Procedure 13] KOH is added to the one-stage centrifuged latex, and the pH of the one-stage centrifuged latex is increased to 12 or more.
[Procedure 14] PEG was added to the one-stage centrifuged latex, and the PEG content of the one-stage centrifuged latex was 0.14 P.O. H. R. To.
[Procedure 15] The one-stage centrifuged latex is diluted with KOH water until the solid concentration of the one-stage centrifuged latex is 24% by weight.
[Procedure 16] The one-stage centrifuged latex to which DAHP, lauric acid, KOH and PEG have been added is stirred for 1 hour.
[Procedure 17] The latex subjected to the one-stage centrifugal separation treatment is allowed to stand for 24 hours while being placed in a polyethylene resin tank.
[Procedure 18] The latex subjected to the one-stage centrifugation treatment is passed through a centrifuge, the serum is removed, and a latex cream having a solid content of 65% by weight is taken out.
[Procedure 19] KOH water was added to make the pH of the latex cream 12 or more, the solid content concentration (TSC) of the latex cream was adjusted to 61.0% by weight, and the content of lauric acid was 0.067 P.P. H. R. Adjust to.
The characteristic values of the two-stage centrifuged latex obtained in this way are as shown in [Table 2].

[Example 3] A concentrated latex is produced from a field latex by the following procedure.
[Procedure 1] Place the field latex collected from Hevea brazilian wood in a polyethylene resin tank, and add potassium hydroxide to the field latex until the KOH concentration becomes 0.9% by weight within 3 hours after the collection. Added.
[Procedure 2] DAHP was added to the field latex, and the DAHP content of the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 3] Lauric acid was added to the field latex, and the content of lauric acid in the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 4] KOH is added to the field latex, and the pH of the field latex is increased to 12 or more.
[Procedure 5] The field latex to which DAHP, lauric acid and KOH have been added is stirred for 1 hour.
[Procedure 6] EDTA was added to the field latex, and the EDTA content of the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 7] The field latex is diluted with KOH water until the solid content concentration of the field latex is 24% by weight.
[Procedure 8] The field latex is left in a polyethylene resin tank for 24 hours.
[Procedure 9] The field latex is passed through a centrifuge, the serum is removed, and a latex cream having a solid content of 65% by weight is taken out.
[Procedure 10] KOH water is added to make the pH of the latex cream 12 or more, and the content of lauric acid is 0.067 P.P. H. R. Adjust to.
[Procedure 11] DAHP is added to the one-stage centrifuged latex that has been once processed according to the above-described procedures 1 to 10, and the DAHP content of the one-stage centrifuged latex is set to 0.03 P.O. H. R. To.
[Procedure 12] Lauric acid is added to the one-stage centrifuged latex, and the lauric acid content of the one-stage centrifuged latex is 0.28 P.P. H. R. To.
[Procedure 13] KOH is added to the one-stage centrifuged latex, and the pH of the one-stage centrifuged latex is increased to 12 or more.
[Procedure 14] EDTA is added to the one-stage centrifuged latex, and the EDTA content of the one-stage centrifuged latex is 0.11 P.L. H. R. To.
[Procedure 15] Dilute the one-stage centrifuged latex with KOH water until the solid concentration of the one-stage centrifuged latex is 26% by weight.
[Procedure 16] The one-stage centrifuged latex to which DAHP, lauric acid, KOH and EDTA have been added is stirred for 1 hour.
[Procedure 17] The latex subjected to the one-stage centrifugal separation treatment is allowed to stand for 24 hours while being placed in a polyethylene resin tank.
[Procedure 18] The latex subjected to the one-stage centrifugation treatment is passed through a centrifuge, the serum is removed, and a latex cream having a solid content of 65% by weight is taken out.
[Procedure 19] KOH water was added to make the pH of the latex cream 12 or more, the solid content concentration (TSC) of the latex cream was adjusted to 61.0% by weight, and the content of lauric acid was 0.067 P.P. H. R. Adjust to.
The characteristic values of the two-stage centrifuged latex obtained in this way are as shown in [Table 2].

Example 4 A concentrated latex is produced from a field latex by the following procedure.
[Procedure 1] Place the field latex collected from Hevea brazilian wood in a polyethylene resin tank, and add potassium hydroxide to the field latex until the KOH concentration becomes 0.9% by weight within 3 hours after the collection. Added.
[Procedure 2] DAHP was added to the field latex, and the DAHP content of the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 3] Lauric acid was added to the field latex, and the content of lauric acid in the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 4] KOH is added to the field latex, and the pH of the field latex is increased to 12 or more.
[Procedure 5] The field latex to which DAHP, lauric acid and KOH have been added is stirred for 1 hour.
[Procedure 6] PEG was added to the field latex, and the PEG content of the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 7] EDTA was added to the field latex, and the EDTA content of the field latex was 0.14 P.O. H. R. To.
[Procedure 8] The field latex is diluted with KOH water until the solid content concentration of the field latex is 24% by weight.
[Procedure 9] The field latex is left in a polyethylene resin tank for 24 hours.
[Procedure 10] The field latex is passed through a centrifuge, the serum is removed, and a latex cream having a solid content of 65% by weight is taken out.
[Procedure 11] KOH water is added to make the pH of the latex cream 12 or more, and the content of lauric acid is 0.067 P.P. H. R. Adjust to.
[Procedure 12] DAHP is added to the one-stage centrifuged latex that has been once treated according to the above-described procedures 1 to 11, and the DAHP content of the one-stage centrifuged latex is set to 0.03 P.O. H. R. To.
[Procedure 13] Lauric acid is added to the one-stage centrifuged latex, and the content of lauric acid in the one-stage centrifuged latex is 0.28 P.P. H. R. To.
[Procedure 14] The pH of the single deforming latex is prepared by the addition of the KOH so that the pH of the single comprising latex is more than 12.
[Procedure 15] PEG is added to the one-stage centrifuged latex, and the PEG content of the one-stage centrifuged latex is 0.11 P.O. H. R. To.
[Procedure 16] PEG was added to the one-stage centrifuged latex, and the PEG content of the one-stage centrifuged latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 17] The latex subjected to the one-stage centrifuge treatment is diluted with KOH water until the solid concentration of the one-stage centrifuge-treated latex is 26% by weight.
[Procedure 18] The latex subjected to the one-stage centrifugal treatment to which DAHP, lauric acid, KOH, PEG and EDTA are added is stirred for 1 hour.
[Procedure 19] The latex subjected to the one-stage centrifugation treatment is allowed to stand for 24 hours while being put in a polyethylene resin tank.
[Procedure 20] The latex subjected to the one-stage centrifugation treatment is passed through a centrifuge, the serum is removed, and a latex cream having a solid content of 65% by weight is taken out.
[Procedure 21] KOH water was added to increase the pH of the latex cream to 12 or more, the solid content concentration (TSC) of the latex cream was adjusted to 60.5% by weight, and the content of lauric acid was 0.067 P.P. H. R. Adjust to.
The characteristic values of the two-stage centrifuged latex obtained in this way are as shown in [Table 2].

[Comparative Example] Concentrated latex is produced from field latex by the following procedure.
[Procedure 1] Field latex collected from Hevea brazilian wood is placed in a polyethylene resin tank, and within 3 hours after the collection, NH ₃ concentration is 0.3 wt% and TMTD concentration is 0.015 wt. %, NH ₃ , TMTD and ZnO are added to the field latex until the ZnO concentration is 0.015 wt%.
[Procedure 2] DAHP was added to the field latex, and the DAHP content of the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 3] Lauric acid was added to the field latex, and the content of lauric acid in the field latex was adjusted to 0.14 P.O. H. R. To.
[Procedure 4] NH ₃ is added to the field latex, and the PH of the field latex is increased to 12 or more.
[Procedure 5] The field latex to which DAHP, lauric acid and NH ₃ are added is stirred for 1 hour.
[Procedure 6] The field latex is diluted with NH ₃ water until the solid content concentration of the field latex is 24% by weight.
[Procedure 7] The field latex is left in a polyethylene resin tank for 24 hours.
[Procedure 8] The field latex is passed through a centrifuge to remove the serum, and a latex cream having a solid content of 65% by weight is taken out.
[Procedure 9] NH ₃ water is added to increase the pH of the latex cream to 12 or more, the solid content concentration (TSC) of the latex cream is adjusted to 61.5% by weight, and the NH ₃ content is 0.3. Wt%, TMTD content to 0.015 wt%, ZnO content to 0.015 wt%, and lauric acid content to 0.067 P.p. H. R. Adjust each.
The characteristic values of the concentrated latex thus obtained are as shown in [Table 2].

Claims (8)

  Within 3 hours immediately after the collection, potassium hydroxide is added to the field latex, the pH of the subsequent field latex is maintained at 12 or more, and the content of rubber particles is concentrated to 60% by weight or more by a centrifugal separation method. Centrifugal latex concentration method in which the concentration of potassium hydroxide contained in the latex after the concentration is maintained at 0.2 to 1.0% by weight.   Within 3 hours immediately after collection, potassium hydroxide is added to the field latex, and the pH of the subsequent field latex is maintained at 12 or more, together with dibasic ammonium phosphate and fatty acid salt anionic surfactant, ethylenediaminetetraacetic acid At least one of polyethylene glycol and polyethylene glycol is added to the field latex, the rubber particle content is concentrated to 60% by weight or more by a centrifugal separation method, and the concentration of potassium hydroxide contained in the latex after the concentration is 0.2. Centrifugal latex concentration method maintained at ~ 1.0 wt%.   The centrifugal latex concentration method according to claim 2, wherein the fatty acid salt-based anionic surfactant is lauric acid.   4. The method according to claim 2, wherein the step of adding at least one of ethylenediaminetetraacetic acid and polyethylene glycol according to claim 2 to the field latex and concentrating the latex by centrifugation is repeated twice or more. Centrifugal latex concentration method described in 1.   Within 3 hours immediately after collection, potassium hydroxide is added to the field latex, and the pH of the subsequent field latex is maintained at 12 or more, together with dibasic ammonium phosphate and fatty acid salt anionic surfactant, ethylenediaminetetraacetic acid And polyethylene glycol are added to the field latex, and the content of rubber particles is concentrated to 60% by weight or more by a centrifugal separation method, and the concentration of potassium hydroxide contained in the latex after the concentration is 0.2 to 1.0. Centrifugal latex concentration method maintained at% by weight.   The centrifugal latex concentration method according to claim 5, wherein the fatty acid salt-based anionic surfactant is lauric acid.   A step of adding the second ammonium phosphate, fatty acid salt anionic surfactant, ethylenediaminetetraacetic acid and polyethylene glycol according to any one of claims 5 and 6 to the field latex and concentrating the latex by a centrifugal separation method. The centrifugal latex concentration method according to any one of claims 5 and 6, which is repeated twice or more.   The centrifugal latex concentration method according to any one of claims 1, 2, 3, 4, 5, 6, and 7, wherein the concentration of potassium hydroxide contained in the latex after concentration is 0.2 to 0.3. The centrifugal latex concentration method according to any one of claims 1, 2, 3, 4, 5, 6, and 7 maintained at% by weight.