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A procedure for arranging water circulations in an integrated paper mill, the paper making process of which having three partly separate process phases concerning the water circulations (I, II, III). In the first phase, the fiber raw material is pretreated, defibered and cleaned for producing mechan

A procedure for arranging water circulations in an integrated paper mill, the paper making process of which having three partly separate process phases concerning the water circulations (I, II, III). In the first phase, the fiber raw material is pretreated, defibered and cleaned for producing mechanical, chemi-mechanical and recycled pulp, in the second phase the pulp is treated further for improving the quality, and in the third phase it is made into paper or board. The circulation waters of the first process phase are concentrated by circulating the filtrates of the concentration and pressing phases counter-current inside the water circulation (I), and the circulation water thus concentrated is conducted into an effluent evaporation plant to be concentrated and then burnt in a combustion boiler. The water quantity discharged from the water circulation (I) of the first process phase is replaced by conducting such circulation waters of the paper mill into the front dilution of the press.

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A procedure for arranging water circulations in an integrated paper mill, the paper making process of which having three partly separate process phases concerning the water circulations (I, II, III). In the first phase, the fiber raw material is pretreated, defibered and cleaned for producing mechan

A procedure for arranging water circulations in an integrated paper mill, the paper making process of which having three partly separate process phases concerning the water circulations (I, II, III). In the first phase, the fiber raw material is pretreated, defibered and cleaned for producing mechanical, chemi-mechanical and recycled pulp, in the second phase the pulp is treated further for improving the quality, and in the third phase it is made into paper or board. The circulation waters of the first process phase are concentrated by circulating the filtrates of the concentration and pressing phases counter-current inside the water circulation (I), and the circulation water thus concentrated is conducted into an effluent evaporation plant to be concentrated and then burnt in a combustion boiler. The water quantity discharged from the water circulation (I) of the first process phase is replaced by conducting such circulation waters of the paper mill into the front dilution of the press. inner peripheral wall portion of the substantially annular plate is shaped to be concentric to the pitch circle. 4. The flexible shaft coupling as claimed in claim 2, wherein a length of the first radial-outward arm portion is dimensioned to be substantially identical to a length of the second radial-inward arm portion. 5. The flexible shaft coupling as claimed in claim 4, wherein the first radial-outward arm portion and the second radial-inward arm portion are formed to be substantially parallel to the hypothetical line segment. 6. The flexible shaft coupling as claimed in claim 2, wherein the coupling arm portion being in tension by a tensile force acting between the two adjacent mounting holes during power transmission in a normal rotational direction comprises the first radial-outward arm portion and the second radial-inward arm portion, and the coupling arm portion being in compression by a compressive force acting between the two adjacent mounting holes during the power transmission in the normal rotational direction comprises only the first radial-outward arm portion. 7. The flexible shaft coupling as claimed in claim 1, wherein the substantially annular plate has the coupling arm portions formed therein by pressing. 8. The flexible shaft coupling as claimed in claim 1, wherein the coupling arm portion extending between the two adjacent mounting holes is placed outside of a hypothetical line segment between and including centers of the two adjacent mounting holes in a radial direction. 9. The flexible shaft coupling as claimed in claim 1, wherein the coupling arm portion extending between the two adjacent mounting holes is placed inside of a hypothetical line segment between and including centers of the two adjacent mounting holes in a radial direction. 10. An axially flexible shaft coupling for a vehicle, comprising: a substantially annular plate serving as a torque-transmission member for rotational directions and having a plurality of mounting holes formed therein and having a relatively higher stiffness for the rotational directions than a stiffness for axial directions; a first group of coupled portions fixedly connected to a first shaft and circumferentially spaced with respect to each other; a second group of coupled portions fixedly connected to a second shaft and circumferentially spaced with respect to each other; the first and second groups of coupled portions being coupled with each other through the substantially annular plate placed therebetween, so that the first group of coupled portions circumferentially alternate with the second group of coupled portions; the substantially annular plate having coupling arm portions each extending between two adjacent mounting holes of the mounting holes to absorb vibrations for the axial directions by elastic deformation of each of the coupling arm portions; and a thickness of each of the coupling arm portions being dimensioned to be thinner than a thickness of a peripheral region of each of the mounting holes. 11. A flexible shaft coupling for a vehicle, comprising: a substantially annular plate serving as a torque-transmission member for rotational directions and having a plurality of mounting holes formed therein; a first group of coupled portions fixedly connected to an output shaft and circumferentially spaced with respect to each other; a second group of coupled portions fixedly connected to an input shaft and circumferentially spaced with respect to each other; the first and second groups of coupled portions being coupled with each other through the substantially annular plate placed therebetween by way of fastening means, so that the first group of coupled portions circumferentially alternate with the second group of coupled portions; the substantially annular plate having coupling arm portions each extending between two adjacent mounting holes of the mounting holes for the fastening means to absorb vibrations for axial directions by elastic d eformation of each of the coupling arm portions; each of the coupling arm portions has a lightening hole formed therein, and each of the coupling arm portions is divided by the lightening hole into a first radial-outward arm portion placed outside of a hypothetical line segment between and including centers of the two adjacent mounting holes and a second radial-inward arm portion placed inside of the hypothetical line segment; and a sum of a radial width of the first radial-outward arm portion and a radial width of the second radial-inward arm portion being dimensioned to be narrower than a radial width of a peripheral region of each of the mounting holes. 12. The flexible shaft coupling as claimed in claim 11, wherein the lightening holes are formed as circular-arc shaped holes arranged concentrically with respect to a pitch circle passing through the centers of the mounting holes formed in the substantially annular plate, and an inner peripheral wall portion of the substantially annular plate is shaped to be concentric to the pitch circle. 13. The flexible shaft coupling as claimed in claim 11, wherein a length of the first radial-outward arm portion is dimensioned to be substantially identical to a length of the second radial-inward arm portion. 14. The flexible shaft coupling as claimed in claim 13, wherein the first radial-outward arm portion and the second radial-inward arm portion are formed to be substantially parallel to the hypothetical line segment. 15. The flexible shaft coupling as claimed in claim 13, wherein the coupling arm portion being in tension by a tensile force acting between the two adjacent mounting holes during power transmission in a normal rotational direction comprises the first radial-outward arm portion and the second radial-inward arm portion, and the coupling arm portion being in compression by a compressive force acting between the two adjacent mounting holes during the power transmission in the normal rotational direction comprises only the first radial-outward arm portion. 16. The flexible shaft coupling as claimed in claim 2, wherein the substantially annular plate has a relatively higher stiffness for rotational directions than a stiffness for axial directions.