WO2010119610A1 - 密閉式混練機及び混練ロータ - Google Patents
密閉式混練機及び混練ロータ Download PDFInfo
- Publication number
- WO2010119610A1 WO2010119610A1 PCT/JP2010/001789 JP2010001789W WO2010119610A1 WO 2010119610 A1 WO2010119610 A1 WO 2010119610A1 JP 2010001789 W JP2010001789 W JP 2010001789W WO 2010119610 A1 WO2010119610 A1 WO 2010119610A1
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- WIPO (PCT)
- Prior art keywords
- rotor
- kneading
- long
- blades
- axial direction
- Prior art date
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-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29B—PREPARATION OR PRETREATMENT OF THE MATERIAL TO BE SHAPED; MAKING GRANULES OR PREFORMS; RECOVERY OF PLASTICS OR OTHER CONSTITUENTS OF WASTE MATERIAL CONTAINING PLASTICS
- B29B7/00—Mixing; Kneading
- B29B7/02—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type
- B29B7/06—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices
- B29B7/10—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices rotary
- B29B7/18—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices rotary with more than one shaft
- B29B7/20—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices rotary with more than one shaft with intermeshing devices, e.g. screws
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29B—PREPARATION OR PRETREATMENT OF THE MATERIAL TO BE SHAPED; MAKING GRANULES OR PREFORMS; RECOVERY OF PLASTICS OR OTHER CONSTITUENTS OF WASTE MATERIAL CONTAINING PLASTICS
- B29B7/00—Mixing; Kneading
- B29B7/02—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type
- B29B7/06—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices
- B29B7/10—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices rotary
- B29B7/18—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices rotary with more than one shaft
- B29B7/183—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices rotary with more than one shaft having a casing closely surrounding the rotors, e.g. of Banbury type
- B29B7/186—Rotors therefor
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01F—MIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
- B01F27/00—Mixers with rotary stirring devices in fixed receptacles; Kneaders
- B01F27/60—Mixers with rotary stirring devices in fixed receptacles; Kneaders with stirrers rotating about a horizontal or inclined axis
- B01F27/72—Mixers with rotary stirring devices in fixed receptacles; Kneaders with stirrers rotating about a horizontal or inclined axis with helices or sections of helices
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29B—PREPARATION OR PRETREATMENT OF THE MATERIAL TO BE SHAPED; MAKING GRANULES OR PREFORMS; RECOVERY OF PLASTICS OR OTHER CONSTITUENTS OF WASTE MATERIAL CONTAINING PLASTICS
- B29B7/00—Mixing; Kneading
- B29B7/02—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type
- B29B7/06—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices
- B29B7/10—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices rotary
- B29B7/18—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices rotary with more than one shaft
- B29B7/183—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type with movable mixing or kneading devices rotary with more than one shaft having a casing closely surrounding the rotors, e.g. of Banbury type
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29B—PREPARATION OR PRETREATMENT OF THE MATERIAL TO BE SHAPED; MAKING GRANULES OR PREFORMS; RECOVERY OF PLASTICS OR OTHER CONSTITUENTS OF WASTE MATERIAL CONTAINING PLASTICS
- B29B7/00—Mixing; Kneading
- B29B7/02—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type
- B29B7/22—Component parts, details or accessories; Auxiliary operations
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29B—PREPARATION OR PRETREATMENT OF THE MATERIAL TO BE SHAPED; MAKING GRANULES OR PREFORMS; RECOVERY OF PLASTICS OR OTHER CONSTITUENTS OF WASTE MATERIAL CONTAINING PLASTICS
- B29B7/00—Mixing; Kneading
- B29B7/02—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type
- B29B7/22—Component parts, details or accessories; Auxiliary operations
- B29B7/24—Component parts, details or accessories; Auxiliary operations for feeding
- B29B7/246—Component parts, details or accessories; Auxiliary operations for feeding in mixers having more than one rotor and a casing closely surrounding the rotors, e.g. with feeding plungers
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29B—PREPARATION OR PRETREATMENT OF THE MATERIAL TO BE SHAPED; MAKING GRANULES OR PREFORMS; RECOVERY OF PLASTICS OR OTHER CONSTITUENTS OF WASTE MATERIAL CONTAINING PLASTICS
- B29B7/00—Mixing; Kneading
- B29B7/02—Mixing; Kneading non-continuous, with mechanical mixing or kneading devices, i.e. batch type
- B29B7/22—Component parts, details or accessories; Auxiliary operations
- B29B7/26—Component parts, details or accessories; Auxiliary operations for discharging, e.g. doors
- B29B7/263—Component parts, details or accessories; Auxiliary operations for discharging, e.g. doors from the underside in mixers having more than one rotor and a a casing closely surrounding the rotors
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B29—WORKING OF PLASTICS; WORKING OF SUBSTANCES IN A PLASTIC STATE IN GENERAL
- B29B—PREPARATION OR PRETREATMENT OF THE MATERIAL TO BE SHAPED; MAKING GRANULES OR PREFORMS; RECOVERY OF PLASTICS OR OTHER CONSTITUENTS OF WASTE MATERIAL CONTAINING PLASTICS
- B29B7/00—Mixing; Kneading
- B29B7/74—Mixing; Kneading using other mixers or combinations of mixers, e.g. of dissimilar mixers ; Plant
- B29B7/7476—Systems, i.e. flow charts or diagrams; Plants
- B29B7/7495—Systems, i.e. flow charts or diagrams; Plants for mixing rubber
Definitions
- the present invention relates to a closed kneader and a kneading rotor thereof.
- Patent Document 1 discloses a conventional meshing kneading rotor.
- the ratio l / L between the length l of the rotor long blade and the axial length L of the rotor is 0.6 or more, and the rotor long blade
- the ratio a / L of the axial length a of the portion between the end of the rotor and the end of the rotor in the axial direction and L is 0.2 or less. Therefore, efficient material kneading with long blades is possible. Further, since the material flow can be branched from both ends of the long blade, there is no material kneading unevenness.
- both the material flow performance (distribution performance) and the material shear performance (dispersion performance) are important.
- the flow performance (distribution performance) increases, but the shear performance (dispersion performance) decreases.
- An object of the present invention is to provide a closed kneader and a kneading rotor that solve the above-mentioned problems.
- Another object of the present invention is to provide a closed kneader and a kneading rotor that are excellent in both flow performance and shear performance.
- a kneading rotor is a meshing type kneading rotor used in a closed kneading machine including a casing in which a chamber is provided, and includes a rotor portion disposed in the chamber.
- the rotor part has a columnar rotor part main body, one long blade and two short blades provided on the surface of the rotor part main body, and the length of the long blades in the rotation direction of the rotor part L4 is greater than half the total length L5 of the rotor portion main body in the rotation direction, and the length L1 of the long blades in the axial direction of the rotor portion and the total length L2 of the rotor portion main body in the axial direction. (L1 / L2) is 0.6 or more and less than 1, and the axial distance x from the end of the long blade to the end of the rotor body is the rotor body in the axial direction.
- the ratio (x / L2) to the total length L2 is greater than 0 and less than or equal to 0.2, and a pair of the rotor portions are arranged in parallel with each other in the chamber of the hermetic kneader so as to be opposite to each other. Two short blades such that when rotating, the two short blades of one of the rotor portions alternately repeat approaching and separating in the rotation direction of the rotor portion with respect to the long blades of the other rotor portion.
- the long blades of the other rotor part are sandwiched in the axial direction by the two short blades of one of the rotor parts, and the
- the pair of rotor parts are arranged parallel to each other inside the chamber and rotated in opposite directions, the rear end part in the rotation direction of the rotor part of the long blades of one of the rotor parts
- the long blades are arranged so that the front end portion in the rotation direction of the rotor portion of the other rotor portion of the other rotor portion repeats approaching and separating alternately, and the proximity state
- the rear end portion and the front end portion face each other with respect to the rotation direction of the rotor portion on a line connecting the axes of the pair of rotor portions.
- a kneading rotor is a meshing kneading rotor used in a closed kneading machine including a casing in which a chamber is provided, and includes a rotor portion disposed in the chamber.
- the rotor part has a columnar rotor part main body, one long wing provided on the surface of the rotor part main body and two short wings, and the length of the long wing in the rotation direction of the rotor part
- the length L4 is greater than half the total length L5 of the rotor body in the rotational direction, and the length L1 of the long blades in the axial direction of the rotor section and the total length of the rotor body in the axial direction.
- the ratio (L1 / L2) to L2 is not less than 0.6 and less than 1, and the distance x in the axial direction from one end of the long blade to the end of the rotor part main body and the rotor part in the axial direction Book
- the ratio (x / L2) to the total length L2 is greater than 0 and less than or equal to 0.2, and the pair of rotor portions are arranged in parallel to each other in the chamber of the hermetic kneader, and are opposite to each other.
- FIG. 3 is a front view of the kneading rotor (viewed from the arrow A of the kneading rotor shown in FIG. 2).
- FIG. 3 is a rear view of the kneading rotor (viewed from the B arrow of the kneading rotor shown in FIG. 2).
- deployment top view of the kneading part of a kneading rotor deployment top view of the kneading part of a kneading rotor.
- FIG. 4 is an exploded development view of a kneading part of a first kneading rotor and a kneading part of a second kneading rotor. It is a right view of a 1st kneading rotor. It is a right view of the 2nd kneading rotor.
- FIG. 12 is a front view of the first kneading rotor and the second kneading rotor shown in FIG. 11.
- FIG. 12 is a rear view of the first kneading rotor and the second kneading rotor shown in FIG. 11.
- FIG. 9 is a schematic cross-sectional view of both kneading rotors at a position G-G ′ in FIG.
- FIG. 16 is a schematic cross-sectional view showing a state in which the rotation of both kneading rotors has further advanced from the state of FIG. 15.
- FIG. 17 is a schematic cross-sectional view showing a state in which the rotation of both kneading rotors has further advanced from the state of FIG. 16.
- FIG. 16 is an enlarged view of a schematic cross-sectional view in a state where the long blades of both kneading rotors shown in FIG. 15 are close to each other.
- FIG. 10 is an exploded development view of a kneading portion of a pair of kneading rotors according to a modified example. It is an overlapping development view of a kneading part of a pair of kneading rotors concerning a comparative example.
- the closed kneader 80 is a biaxial batch mixer, and is used, for example, for kneading rubber raw materials.
- the closed kneader 80 includes a casing 70, a drop door 73, a pair of kneading rotors (first kneading rotor 1 and second kneading rotor 5), a material supply cylinder 77, a pneumatic cylinder 78, and a floating weight 74.
- the casing 70 is a main body of the closed kneader 80 and is made of a metal material.
- the casing 70 is supported by a metal support. Inside the casing 70, two chambers (kneading chambers) 70s are formed. Each chamber 70s is formed in a hollow shape having a substantially circular cross section.
- a material supply port 71 for supplying the material to be kneaded into the chamber 70s is provided in the upper part of the casing 70, and a material for discharging the material kneaded in the chamber 70s is provided in the lower part of the casing 70.
- a material discharge port 72 is provided.
- the material discharge port 72 is formed to extend along the axial direction D of the kneading rotor (the direction perpendicular to the paper surface in FIG. 1 and the direction of arrow D in the other drawings). In the casing 70, the material supply port 71, the two chambers 70s, and the material discharge port 72 communicate with each other.
- the two chambers 70s house a pair of kneading rotors made of a metal material.
- the pair of kneading rotors are rotated in opposite directions by being powered by a motor (not shown) (see the directions of arrows F and F ′ in FIG. 1).
- the drop door 73 is made of a metal material and functions as a lid member that closes the material discharge port 72 of the casing 70.
- the drop door 73 is provided so that it can move up and down. When the material discharge port 72 is opened, the drop door 73 is lowered, and when the material discharge port 72 is closed, the drop door 73 is raised.
- the material supply cylinder 77 extends vertically above the casing 70, and the internal space of the material supply cylinder 77 is continuous with the material supply port 71.
- the material supply cylinder 77 is provided with a hopper 76.
- the floating weight 74 is disposed inside the material supply cylinder 77. The floating weight 74 is fixed to the lower end of the piston rod 75 and can move up and down together with the piston rod 75.
- a pneumatic cylinder 78 is provided above the material supply cylinder 77.
- a piston 78 s is disposed inside the pneumatic cylinder 78, and the piston 78 s is fixed to the upper end of the piston rod 75.
- kneading rotor Next, a pair of kneading rotors (first kneading rotor 1 and second kneading rotor 5) will be described.
- the pair of kneading rotors are accommodated in a chamber (kneading chamber) 70 s inside the casing 70 and are arranged in parallel to each other.
- the pair of kneading rotors are meshing rotors.
- Each kneading rotor rotates in a different direction. Specifically, the first kneading rotor 1 rotates in the rotation direction F (see the direction of arrow F in the figure), and the second kneading rotor 5 rotates in the rotation direction F ′ (see the direction of arrow F ′ in the figure). .
- the first kneading rotor 1 includes a rotor unit 10, a rotating shaft 10j, and a rotating shaft 10k (see FIGS. 2 and 9).
- the rotor unit 10 is attached to the rotating shaft 10j and the rotating shaft 10k, and the rotor unit 10, the rotating shaft 10j, and the rotating shaft 10k are arranged coaxially.
- One rotation shaft 10j extends so as to protrude from one end of the rotor portion 10 in the axial direction, and the other rotation shaft 10k extends so as to protrude from the other end of the rotor portion 10 in the axial direction.
- the rotor unit 10, the rotation shaft 10j, and the rotation shaft 10k are made of metal.
- the 2nd kneading rotor 5 is provided with the rotor part 10, the rotating shaft 10j, and the rotating shaft 10k similarly to the 1st kneading rotor 1 (refer FIG. 10).
- the rotor unit 10 is attached to the rotating shaft 10j and the rotating shaft 10k in an arrangement opposite to the arrangement of the rotor unit 10 with respect to the rotating shaft 10j and the rotating shaft 10k in the first kneading rotor 1. (See FIGS. 9 and 10). Specifically, in the first kneading rotor 1, the rotor unit 10 is disposed on the rotating shaft 10j so that the later described middle blade 40 is disposed on the rotating shaft 10k side, and the later-described short blade 30 is disposed on the rotating shaft 10j side.
- the middle blade 40 described later is disposed on the rotational shaft 10j side
- the short blade 30 described later is disposed on the rotational shaft 10k side.
- the rotor unit 10 is attached to the rotary shaft 10j and the rotary shaft 10k. Except for this arrangement direction, the structure of the rotor unit 10, the rotating shaft 10j and the rotating shaft 10k of the second kneading rotor 5 is the same as the structure of the rotor unit 10, the rotating shaft 10j and the rotating shaft 10k of the first kneading rotor 1. is there.
- first kneading rotor 1 will be mainly described, and the description of the second kneading rotor 5 will be omitted.
- rotation direction F in the description of the first kneading rotor 1 may be replaced with “rotation direction F ′”.
- the rotor unit 10 is a portion that is disposed in the chamber 70s and kneads the material to be kneaded in the chamber 70s.
- the rotor unit 10 includes a rotary shaft 10j and a cylindrical rotor unit body 15 that is coaxially attached to the rotary shaft 10k, three kneading blades, that is, a long blade 20 and two short blades (short blade 30 and middle blade). 40).
- the long blade 20 and the two short blades (the short blade 30 and the middle blade 40) are provided on the surface (circumferential surface) of the rotor body 15.
- the tip clearance is a gap between a tip portion (kneading blade top) formed as a tip surface of the kneading blade and an inner surface of the casing 70 forming the chamber 70s.
- these kneading blades are formed so as to be spiral in the axial direction D with respect to the rotor portion 10 with the axial center of the rotor portion 10 as the center.
- the flow of the material to be kneaded along the axial direction D is generated by the rotation of the two kneading rotors.
- FIG. 8 shows a development view of the kneading part (rotor part 10) of the first kneading rotor 1 and a development view of the kneading part (rotor part 10) of the second kneading rotor 5 superimposed in the same phase. That is, FIG. 8 is a view in which the portions facing each other during rotation of the kneading portions of both the kneading rotors 1 and 5 are overlapped.
- the shape of the kneading portion of the first kneading rotor 1 shown in FIG. 8 corresponds to the shape shown in FIG. 6, and the shape of the kneading portion of the second kneading rotor 5 shown in FIG. This corresponds to the shape shown in FIG.
- the shape of the kneading portion of the second kneading rotor 5 shown in FIG. 8 is in a mirror image relationship with the shape shown in FIG. Moreover, in FIG. 8, about the part contained in the 2nd kneading rotor 5, the code
- FIG. 8 is an exploded view of the rotors 1 and 5 in a state where the phase of the first kneading rotor 1 and the phase of the second kneading rotor 5 coincide with each other.
- the direction F ′ coincides.
- FIG. 12 is a front view of the two kneading rotors 1 and 5, that is, a view from the arrow A in FIG. 11, and FIG. 13 is a rear view of both the kneading rotors 1 and 5, that is, a view from the arrow B in FIG. That is, the views in the direction of the arrow K in FIGS. 12 and 13 correspond to FIG.
- FIG. 9 corresponds to a view of the first kneading rotor 1 viewed in the K direction in the state of FIG. 12, and FIG. 10 corresponds to a view of the second kneading rotor 5 viewed in the K direction in the state of FIG. 5 to 13, the relationship between the position in the rotation direction and the angle indicating the phase is the same in each figure.
- the long blades 20 are formed so as to be linear in the development plan view of the surface of the rotor portion 10 of the first kneading rotor 1. Further, the twist angle ⁇ 1 of the long blade 20 with respect to the axial direction D of the rotor portion 10 is 50 degrees (see FIG. 5).
- the long wing 20 is formed so as to extend from the upper left to the lower right. In FIG. 5, the left side corresponds to the rotating shaft 10j side, and the right side corresponds to the rotating shaft 10k side.
- a tip portion 21 as a kneading surface is formed at the blade top portion of the long blade 20.
- the tip portion 21 is formed substantially parallel to the surface of the rotor portion main body 15.
- a first end portion 22 is formed at the rear end portion (F2 end portion) of the long blade 20 in the rotation direction F (the broken line circles in FIGS. 2 to 5, 8, and 9). And FIG. 18). Moreover, the 1st front-end
- An inclined surface 29 is formed on the first end portion 22.
- the inclined surface 29 is inclined with respect to the axial direction D.
- the normal direction of the inclined surface 29 is inclined toward the rotation axis 10 j with respect to a virtual plane perpendicular to the axial direction D. Therefore, the inclined surface 29 is visible in the front view of FIG. 3, but the inclined surface 29 is not visible in the rear view of FIG.
- the inclined surface 29 does not need to be formed in the long wing (refer to the modified example described later).
- a second end portion 23 is formed at the front end portion (the end portion on the F1 side) of the long blade 20 in the rotation direction F (the broken line circles in FIGS. 2 to 5, 8, and 10). 18). Further, a second tip 23t is formed at the tip of the second end portion 23 (see the broken-line circle in FIG. 4 and FIGS. 5 and 18). The second tip 23t is included in the second end 23, and the second end 23 is wider than the second tip 23t.
- first facing surface 24 is formed on a front portion of the long blade 20 in the rotation direction F
- second facing surface 25 is formed on a rear portion of the long blade 20 in the rotation direction F. Is formed (see FIG. 5).
- the first facing surface 24 and the second facing surface 25 are surfaces (side surfaces) formed between the tip portion 21 and the surface of the rotor portion main body 15.
- the length L1 of the center line of the tip portion 21 in the axial direction D is larger than 1 ⁇ 2 of the total length L2 of the rotor portion main body 15 in the axial direction D (see FIG. 5).
- the length L4 of the long blade 20 in the rotation direction F (rotation direction F ′ in the second kneading rotor 5) is the total length L5 of the rotor body 15 in the rotation direction F, that is, the rotor portion in a cross section perpendicular to the axial direction D. It is larger than the half length of the circumference of the main body 15 (see FIG. 5). That is, the phase difference between both ends of the long blade 20 in the rotation direction F is greater than 180 degrees.
- L1 is the length of the long blade 20 in the axial direction D
- L2 is the total length of the rotor body 15 in the axial direction D.
- the ratio between L1 and L2 (L1 / L2) is 0.6 or more and less than 1.
- a is the distance in the axial direction D from one end of the long blade 20 (the left end of the long blade 20 in FIGS. 5 and 8) to the end of the rotor unit body 15 closer to one end of the long blade 20.
- the ratio (a / L2) between a and L2 is larger than 0 and 0.2 or less.
- B is the axial direction between the other end of the long blade 20 (the right end of the long blade 20 in FIGS.
- a b. Note that a and b may be different. According to the configuration of the long blade 20, it is possible to knead the material more efficiently with the long blade 20 than when the long blade is short. Further, in the configuration of the long blade 20, since the material flow can be branched so as to pass outside the both ends of the long blade 20, the material can be uniformly kneaded.
- the short blade 30 is formed so as to be linear in the development plan view of the surface of the first kneading rotor 1. Further, the twist angle ⁇ 2 of the short blade 30 with respect to the axial direction D is 50 degrees (see FIG. 5). In FIG. 5, unlike the long wing 20, the short wing 30 is formed to extend from the upper right to the lower left.
- a tip portion 31 as a kneading surface is formed on the blade top portion of the short blade 30.
- the tip part 31 is formed substantially parallel to the surface of the rotor part main body 15.
- an opposing surface 32 is formed on the front side of the short blade 30 in the rotational direction F.
- the facing surface 32 is a surface (side surface) formed between the tip portion 31 and the surface of the rotor body 15.
- the length L3 of the center line of the tip portion 31 in the axial direction D is equal to or less than 1 ⁇ 2 of the total length L2 of the rotor body 15 (see FIG. 5).
- the middle blade 40 is formed to be linear in the development plan view of the surface of the first kneading rotor 1. Further, the twist angle ⁇ 3 of the middle blade 40 with respect to the axial direction D is 50 degrees (see FIG. 5). In FIG. 5, the middle blade 40 is formed so as to extend from the upper left to the lower right, like the long blade 20.
- a tip portion 41 as a kneading surface is formed on the blade top portion of the middle blade 40.
- the tip part 41 is formed substantially parallel to the surface of the rotor part main body 15.
- a facing surface 42 is formed on a rear side portion (rear side end portion in the blade longitudinal direction) of the middle blade 40 in the rotation direction F.
- the facing surface 42 is a surface (side surface) formed between the tip portion 41 and the surface of the rotor portion main body 15.
- the length L3 'of the center line of the tip portion 41 in the axial direction D is not more than 1 ⁇ 2 of the total length L2 of the rotor body 15 (see FIG. 5).
- L3 ' is larger than L3.
- Proximity A Along with the rotation of the two kneading rotors, the two short blades (short blade 30 and middle blade 40) of the rotor portion 10 (one rotor portion) of the first kneading rotor 1 become the rotor portion 10 ( The approach and separation are alternately repeated in the rotation direction F (rotation direction F ′) with respect to the long blade 20 of the other rotor portion (see the vicinity of 20 to 120 degrees in FIG. 8).
- the proximity (meshing) between the two short blades (30, 40) of the first kneading rotor 1 and the long blades 20 of the second kneading rotor 5 is referred to as proximity A.
- the facing surface 42 of the middle blade 40 of the first kneading rotor 1 and the first facing surface 24 of the long blade 20 of the second kneading rotor 5 face each other in the rotational direction.
- the facing surface 32 of the short blade 30 of the first kneading rotor 1 and the second facing surface 25 of the long blade 20 of the second kneading rotor 5 face each other in the rotational direction (see FIG. 8).
- the central portion (the central portion in the rotation direction F) of the long blade 20 of the second kneading rotor 5 is in the axial direction D by the two short blades (30, 40) of the first kneading rotor 1. Sandwiched.
- the facing surface 42 of the middle blade 40 of the second kneading rotor 5 and the first facing surface 24 of the long blade 20 of the first kneading rotor 1 face each other in the rotational direction.
- the facing surface 32 of the short blade 30 of the second kneading rotor 5 and the second facing surface 25 of the long blade 20 of the first kneading rotor 1 face each other in the rotational direction (see FIG. 8).
- proximity C. 8 and 11 The proximity of the first end portion 22 of the first kneading rotor 1 and the second end portion 23 of the second kneading rotor 5 is referred to as proximity C. 8 and 11, a portion C surrounded by a broken-line circle is a proximity portion between the first end portion 22 of the first kneading rotor 1 and the second end portion 23 of the second kneading rotor 5 in the state of proximity C. .
- the states of proximity A, proximity B, proximity C, and proximity D are in close proximity with the rotation of the first kneading rotor 1 in the rotation direction F and the rotation of the second kneading rotor 5 in the rotation direction F ′. It occurs in the order of A, proximity C, proximity B, and proximity D. Further, the occurrence of each proximity state in this order is periodically repeated as the kneading rotors 1 and 5 rotate.
- the proximity A, B, C, and D do not indicate the contact state between the blades of the two kneading rotors 1 and 5. That is, in each state of proximity A, B, C, and D, a slight gap is formed between the blades of the two kneading rotors 1 and 5.
- FIGS. 14 to 18 show one section of the kneading part of both the kneading rotors perpendicular to the axial direction D.
- the positions of these sections are the position GG ′ in FIG. 8 and the position HH in FIG. Corresponds to position.
- FIG. 18 corresponds to the enlarged view of FIG.
- D1 is the axis of the rotor portion 10 (one rotor portion) of the first kneading rotor 1 in the direction M (refer to the arrow M direction in FIG. 18) connecting the shaft centers of the pair of rotor portions 10 and its axis.
- the distance between the tip of the long blade 20 of the rotor unit 10 (first tip 22t) is used.
- D2 is a distance between the axial center of the rotor portion 10 (the other rotor portion) of the second kneading rotor 5 and the tip of the long blade 20 of the rotor portion 10 (second tip 23t) in the direction M.
- D3 be the distance between the axes of the rotor portions 10 of the two kneading rotors 1 and 5. In FIG. 18, the relationship of D1 + D2> D3 is satisfied.
- the front end of the long blade 20 of the first kneading rotor 1 located on the rear side is more forward than the rear end of the long blade 20 of the second kneading rotor 5 located on the front side.
- being located at “overlapping” also corresponds to “overlapping”.
- the length indicated by L OL is the overlap length. Further, in one cross section perpendicular to the axial direction D of both the kneading rotors 1 and 5 shown in FIG. 18, the overlap length is D1 + D2-D3.
- the “long blade proximity state” is a state in which the relationship of D1 + D2> D3 is established and (D1 + D2 ⁇ D3) is maximized.
- the positional relationship between the long blades 20 of the two kneading rotors 1 and 5 changes in the order of FIGS. 14, 15, 16, and 17 as the two kneading rotors 1 and 5 rotate.
- the long blade proximity state occurs twice for one rotation of the two kneading rotors 1 and 5.
- One of the two long blade proximity states that occurs twice is the first long blade proximity state, and the other is the second long blade proximity state.
- FIG. 18 illustrates the relationship of D1 + D2> D3 in the example of the first long blade proximity state (the state of facing A and the state of proximity C described later), but this relationship is the second long blade proximity state ( The same holds true for the opposite B state and the proximity D state described later.
- D1 in the equation D1 + D2> D3 is the axis of the rotor portion 10 (the other rotor portion) of the second kneading rotor 5 and the length of the rotor portion 10 in the direction M.
- the distance between the tip of the blade 20 (first tip 22t) and D2 is the axis in the rotor portion 10 (one rotor portion) of the first kneading rotor 1 and the tip of the long blade 20 (with respect to the direction M). The distance between the second tip 23t).
- the first kneading rotor 1 is a meshing type kneading rotor of the hermetic kneader 80 and includes the rotor portion 10 disposed in the chamber 70s of the hermetic kneader 80.
- the rotor unit 10 includes a columnar rotor unit body 15, one long blade 20 and two short blades (30, 40) provided on the surface of the rotor unit body 15, and the rotation of the rotor unit 10.
- the length L4 of the long blade 20 in the direction F is larger than half the total length L5 of the rotor body 15 in the rotation direction F.
- the ratio (L1 / L2) between the length L1 of the long blade 20 in the axial direction D of the rotor part 10 and the total length L2 of the rotor body 15 in the axial direction D is 0.6 or more and less than 1, and
- the ratio (a / L2) between the distance a in the axial direction D from one end of the long blade 20 to the end of the rotor body 15 and the total length L2 of the rotor body 15 in the axial direction D is greater than 0 and 0. 2 or less.
- the first end portion 22 which is the rear end portion in the rotation direction F of the rotor portion 10
- the long blades 20 of the first kneading rotor 1 are arranged so that the second end portion 23 which is the front end portion in the rotation direction F ′ of the rotor portion 10 alternately repeats approaching and separating from each other, and In the close state (closed state of the first long blade), the first end portion 22 of the first kneading rotor 1 and the second kneading rotor 5 are crossed in one cross section (GG ′ cross section) perpendicular to the axial direction D.
- the second end portion 23 is a pair of rotors Opposite to each other with respect to the rotational direction F of the rotor section 10 on the straight line L (direction J) connecting the axial center between the 10.
- the length L4 of the long blade 20 in the rotation direction F of the rotor unit 10 is larger than half the total length L5 of the rotor unit body 15 in the rotation direction F, and the pair of rotor units 10
- the first end portion 22 and the second end portion 23 of the long blades 20 rotate in the rotational direction F of the rotor portion 10 on the straight line L connecting the axes of the pair of rotor portions 10. That is, they are opposed to each other in the direction perpendicular to the straight line L that connects the axes of the pair of rotor portions 10.
- the opposite end portions of the long blades 20 of the pair of rotor portions 10 block the material leakage flow path in the chamber 70s, thereby reducing or preventing leakage of material from between the two end portions. Can be eliminated. For this reason, the shear performance of the material by the kneading rotor can be increased. Further, in this configuration, since the shear performance of the material of the kneading rotor can be enhanced by the end portions of the pair of long blades 20, the flow performance of the material of the kneading rotor is increased by increasing the twist angle of the long blades 20. Also, high shear performance can be maintained. Therefore, in this configuration, a kneading rotor excellent in both material flow performance and shear performance can be obtained.
- the long blades 20 have a twist angle of 50 degrees with respect to the axial direction D. Since the twist angle of the long blade 20 is not less than 50 degrees and not more than 57 degrees, variation in mixing performance due to the kneading rotor can be sufficiently suppressed.
- the hermetic kneader 80 is provided with a chamber 70 s therein, a material supply port 71 at a position above the chamber 70 s, and a material discharge port 72 at a position below the chamber 70 s,
- Each kneading rotor 1, 5 has a rotor part 10, and each rotor part 10 includes a columnar rotor part main body 15 and one long blade 20 provided on the surface of the rotor part main body 15. It has two short blades (short blade 30 and middle blade 40).
- the length L4 of the long blade 20 in the rotation direction F (rotation direction F ′) of the rotor unit 10 is 1 of the total length L5 of the rotor unit body 15 in the rotation direction F (rotation direction F ′). It is larger than the length of / 2.
- the ratio (L1 / L2) between the length L1 of the long blade 20 in the axial direction D of the rotor unit 10 and the total length L2 of the rotor unit main body 15 in the axial direction D is 0.6 or more and
- the ratio (a / L2) between the distance a in the axial direction D from one end of the long blade 20 to the end of the rotor body 15 and the total length L2 of the rotor body 15 in the axial direction D is less than 0. And 0.2 or less.
- the two short blades (30, 40) of the rotor portion 10 of the first kneading rotor 1 are 2
- the two short blades (30) of the first kneading rotor 1 so as to repeat the approach and separation alternately with respect to the long blades 20 of the rotor unit 10 of the kneading rotor 5 in the rotation direction F (rotation direction F ′) of the rotor unit 10 , 40) are arranged, and in the close state, the two blades (30, 40) of the rotor portion 10 of the first kneading rotor 1 cause the long blades 20 of the rotor portion 10 of the second kneading rotor 5 to be disposed.
- the long blades 20 of the first kneading rotor 1 are disposed so that the second end portion 23 alternately repeats approaching and separating from each other, and in the close state (first long blade close state), the axial direction In one cross section perpendicular to D, the rotor portion on a straight line L where the first end portion 22 of the first kneading rotor 1 and the second end portion 23 of the second kneading rotor 5 connect the axes of the pair of rotor portions 10 to each other.
- rotation directions F (direction J) Opposed to each other.
- the length L4 of the long blade 20 in the rotation direction of the rotor unit 10 is greater than half the total length L5 of the rotor unit body 15 in the rotation direction, and the length of the pair of rotor units 10
- the first end portion 22 and the second end portion 23 of the long blades 20 are in the rotational direction F of the rotor portion 10 on the straight line L connecting the axes of the pair of rotor portions 10, that is, , They are opposed to each other in the direction perpendicular to the straight line L connecting the axial centers of the pair of rotor portions 10.
- the opposite end portions of the long blades 20 of the pair of rotor portions 10 block the material leakage flow path in the chamber 70s, thereby reducing or preventing leakage of material from between the two end portions. Can be eliminated.
- the shear performance of the material of the closed kneader 80 can be increased.
- the twist angle of the long blades 20 can be increased to increase the shearing performance of the closed kneader 80. Even if the flow performance of the material is increased, high shear performance can be maintained. Therefore, in this structure, the closed kneader 80 excellent in both the fluidity and shearing performance of the material can be obtained.
- the first kneading rotor 1 is a meshing type kneading rotor of the hermetic kneader 80, and includes the rotor portion 10 disposed in the chamber 70s of the hermetic kneader 80.
- the rotor unit 10 includes a columnar rotor unit body 15, one long blade 20 and two short blades (30, 40) provided on the surface of the rotor unit body 15, and the rotation of the rotor unit 10.
- the length L4 of the long blade 20 in the direction F is larger than half the total length L5 of the rotor body 15 in the rotation direction F.
- the ratio (L1 / L2) between the length L1 of the long blade 20 in the axial direction D of the rotor portion 10 and the total length L2 of the rotor portion 10 in the axial direction D is 0.6 or more and less than 1, and the long blade 20
- the ratio (a / L2) of the distance a in the axial direction D from one end of the rotor to the end of the rotor body 15 and the total length L2 of the rotor body 15 in the axial direction D is greater than 0 and 0.2 or less.
- the first kneading is performed.
- the two short blades (30, 40) of the rotor unit 10 of the rotor 1 approach and separate from the long blades 20 of the rotor unit 10 of the second kneading rotor 5 in the rotation direction F (rotation direction F ′) of the rotor unit 10.
- the two short blades (30, 40) of the first kneading rotor 1 are arranged so as to repeat alternately, and in the close state, the two short blades ( 30, 40), the long blades 20 of the rotor part 10 of the second kneading rotor 5 are sandwiched in the axial direction D. Further, when the rotor unit 10 of the first kneading rotor 1 and the rotor unit 10 of the second kneading rotor 5 are arranged in parallel with each other in the chamber 70s of the closed kneading machine 80 and are rotated in the opposite directions, the first.
- the first end portion 22 which is the rear end portion in the rotation direction F of the rotor portion 10
- the long blades 20 of the first kneading rotor 1 are arranged so that the second end portion 23 which is the front end portion in the rotation direction F ′ of the rotor portion 10 alternately repeats approaching and separating from each other, and In the close state, in one cross section (GG ′ cross section) perpendicular to the axial direction D, the axis of the rotor unit 10 of the first kneading rotor 1 in the direction M connecting the shaft centers of the pair of rotor units 10 Heart and long wing 20 first A distance D1 between the end 22t, a distance D2 between the axis of the rotor portion 10 of the second kneading rotor 5 and the second tip 23t of the long blade 20, and a distance D3 between the axes of the pair of rotor portions 10 The relationship of D1 + D2> D3 is satisfied.
- the length L4 of the long blade 20 in the rotation direction F of the rotor unit 10 is larger than half the total length L5 of the rotor unit body 15 in the rotation direction F, and the pair of rotor units 10
- the distances D1, D2, and D3 in the direction M that connects the two axes satisfy the relationship of D1 + D2> D3. Therefore, in the overlapping development view of the pair of kneading rotors 1, 5, there are portions that overlap each other in the rotational direction of the rotor portion 10 at the ends of the long blades 20 of the pair of kneading rotors 1, 5.
- the front end of the long blade 20 positioned on the rear side in the rotation direction of the rotor portion 10 is the front end of the long blade 20 positioned on the front side in the rotation direction of the rotor portion 10.
- a portion located on the front side of the rear end is generated (see region E in FIG. 8).
- the hermetic kneader 80 is provided with a chamber 70 s therein, a material supply port 71 at a position above the chamber 70 s, and a material discharge port 72 at a position below the chamber 70 s,
- Each kneading rotor 1, 5 has a rotor part 10, and each rotor part 10 includes a columnar rotor part main body 15 and one long blade 20 provided on the surface of the rotor part main body 15. It has two short blades (short blade 30 and middle blade 40).
- the length L4 of the long blade 20 in the rotation direction F (rotation direction F ′) of the rotor unit 10 is 1 of the total length L5 of the rotor unit body 15 in the rotation direction F (rotation direction F ′). It is larger than the length of / 2.
- the ratio (L1 / L2) between the length L1 of the long blade 20 in the axial direction D of the rotor unit 10 and the total length L2 of the rotor unit main body 15 in the axial direction D is 0.6 or more and
- the ratio (a / L2) between the distance a in the axial direction D from one end of the long blade 20 to the end of the rotor body 15 and the total length L2 of the rotor body 15 in the axial direction D is less than 0. And 0.2 or less.
- the two short blades (30, 40) of the rotor portion 10 of the first kneading rotor 1 are 2
- the two short blades (30) of the first kneading rotor 1 so as to repeat the approach and separation alternately with respect to the long blades 20 of the rotor unit 10 of the kneading rotor 5 in the rotation direction F (rotation direction F ′) of the rotor unit 10 , 40) are arranged, and in the close state, the two blades (30, 40) of the rotor portion 10 of the first kneading rotor 1 cause the long blades 20 of the rotor portion 10 of the second kneading rotor 5 to be disposed.
- the long blades 20 of the first kneading rotor 1 are arranged so that the second end portion 23 alternately repeats approaching and separating from each other, and in the close state, in one cross section perpendicular to the axial direction D,
- the distance D3 between the axis of the distance D2 and a pair of rotor portions 10 between the tip of the long blade 20 of the 10 satisfy the relation of D1 + D2> D3.
- the length L4 of the long blade 20 in the rotation direction F of the rotor unit 10 is larger than half the total length L5 of the rotor unit body 15 in the rotation direction F, and the pair of rotor units 10
- the distances D1, D2, and D3 in the direction M that connects the two axes satisfy the relationship of D1 + D2> D3. Therefore, in the overlapping development view of the pair of kneading rotors 1, 5, there are portions that overlap each other in the rotational direction of the rotor portion 10 at the ends of the long blades 20 of the pair of kneading rotors 1, 5.
- the front end of the long blade 20 positioned on the rear side in the rotation direction of the rotor portion 10 is the front end of the long blade 20 positioned on the front side in the rotation direction of the rotor portion 10.
- a portion located on the front side of the rear end is generated (see region E in FIG. 8).
- the opposite end portions of the long blades 20 of the pair of rotor portions 10 block the material leakage flow path in the chamber 70s, thereby reducing or preventing leakage of material from between the two end portions. Can be eliminated. For this reason, the shear performance of the material of the closed kneader 80 can be increased.
- the shear performance of the material of the closed kneader 80 can be enhanced by the end portions of the pair of long blades 20, the twist angle of the long blade 20 is increased to increase the material of the closed kneader 80. Even if the flow performance is increased, high shear performance can be maintained. Therefore, in this structure, the closed kneader 80 excellent in both the fluidity and shearing performance of the material can be obtained.
- the material to be kneaded attached to the kneading blade of one kneading rotor remains attached without being scraped off by the kneading blade of the other kneading rotor. It remains on the surface of the kneading blade of the kneading rotor.
- the number of the kneading blades of the two kneading rotors 1 and 5 is close to each other.
- the long blade 20 of one rotor section 10 faces two short blades (short blade 30 and middle blade 40) of the other rotor section 10 at two locations.
- the long blade 20 faces the long blade 20 of the other rotor portion 10 at two locations, the first end portion 22 and the second end portion 23. That is, one long blade 20 has four adjacent portions with respect to the other long blade 20.
- the material to be kneaded remains partially attached to the surface of the rotor portion 10 of the kneading rotor and the material to be kneaded covers the surface of the rotor portion 10 together with the rotor portion 10. Rotation is suppressed.
- the proximity frequency of the kneading blades of the pair of kneading rotors 1 and 5 is high, the time for the contact surface to be covered with the material to be kneaded is small. Therefore, an excellent kneading effect can be obtained by the closed kneader 80.
- Test 1 a kneading test of a material to be kneaded was performed using a closed kneader (BB-16 manufactured by Kobe Steel) incorporating a kneading rotor according to an example of the present invention, and the quality of the material after kneading was evaluated (test) 1).
- the quality of the material was evaluated by measuring the ⁇ G ′ value of the material.
- the ⁇ G ′ value is the difference between the storage elastic modulus at the time of small deformation strain of the material after kneading and the storage elastic modulus at the time of large deformation strain of the material after kneading.
- ⁇ G ′ is represented by a difference in transverse elastic modulus between a material containing silica and a material not containing silica.
- S-SBR 96 BR: 30 Silica: 80 Silica coupling agent: 6.4 ZnO: 3.0 Stearic acid: 2.0 AROMA oil: 15 Rubber deterioration inhibitor 6PPD: 1.5 ANTIOZONANT WAX: 1.0
- PHR Parts
- S-SBR is a solution polymerized styrene butadiene rubber
- BR is a butadiene rubber
- PPD is p-phenylenediamine.
- kneading rotor 901 and kneading rotor 905 shown in the superimposed development view of FIG. 23 are used.
- the kneading rotor 901 and the kneading rotor 905 according to this comparative example include a columnar rotor portion main body 915 and three kneading blades (long blade 920, short blade 930, and middle blade) provided on the surface of the rotor portion main body 915.
- Rotor portions 910 having blades 940).
- reference numerals 901, 905, 910, 915, 920, 921, 924, 925, 929, 930, 931, 932, 940, 941, 942 are denoted by reference numerals 1, It corresponds to the part to which 5, 10, 15, 20, 21, 24, 25, 29, 30, 31, 32, 40, 41, 42 are attached. Further, in FIG. 23, the portions included in the kneading rotor 901 are not underlined with the reference numerals, while the portions included in the kneading rotor 905 are underlined with the reference numerals.
- the length of the long blade 920 in the rotation direction F of the kneading rotor 901 is smaller than half the total length of the rotor body 915 in the rotation direction F.
- yen N of FIG. 23 there is no overlap part in the both ends of a pair of long blade 920.
- FIG. and the part between the edge parts of both the long blades 920 shown in this broken-line circle N will become a leakage channel of material.
- the twist angles of the long blades 920, the short blades 930, and the middle blade 940 with respect to the axial direction D are equivalent to the twist angles of the corresponding portions in the kneading rotor according to the example of the present invention used in Test 1 above. It has become. Further, in the pair of kneading rotors of the comparative example, the long blades 920 of one kneading rotor and the two short blades (short blade 930 and middle blade 940) of the other kneading rotor are axially moved along with the rotation. These two short blades repeat the approach and separation with respect to the long blade 920 while being sandwiched at D.
- the kneading result when the first kneading rotor 1 and the second kneading rotor 5 of the above example are used is indicated by a solid line
- the kneading result when the kneading rotor of the comparative example is used is indicated by a broken line.
- the vertical axis of the graph is the ⁇ G ′ value
- the horizontal axis is the temperature of the material after kneading discharged from the material discharge port 72 (discharge temperature).
- the result of the kneading test shows that the value of ⁇ G ′ according to the example is lower than the value of ⁇ G ′ of the comparative example in the material temperature range of 155 ° C. to 160 ° C. . From this result, according to the present Example, it turned out that the quality of the material after kneading
- a silane coupling agent is added to bond silica and rubber.
- the silane coupling agent has a material temperature in the range of 140 ° C. to 160 ° C. (high temperature, for example). Reacts with silica at (range). Therefore, in order to efficiently cause the reaction between the silica and the silane coupling agent, it is necessary to uniformly knead the silica and the silane coupling agent in a temperature range of about 140 ° C. to 160 ° C.
- the twist angle of the three kneading blades (long blade, middle blade and short blade) of the kneading rotor is set to 45 degrees or more and 61 degrees or less, the silica and the silane coupling agent can be uniformly kneaded.
- silica is blended in the material to be kneaded.
- the closed type equipped with the kneading rotor according to this embodiment If a kneader is used, a good effect can be obtained with respect to the dispersibility of the blended material.
- the material extrusion amount is an index of the flow performance of the material in the axial direction D of the kneading rotor in the closed kneader, and the larger this value, the higher the flow performance and the uniform kneading of the material.
- the material extrusion amount Q is expressed by the following equation.
- FIG. 20 shows the result of calculation by the above formula.
- the vertical axis represents the relative value of the material extrusion amount
- the horizontal axis represents the twist angle of three kneading blades (long blade, middle blade, and short blade).
- the test results show that when the twist angle of the kneading blade is too small and too large, the extrusion amount of the material becomes small.
- the amount of material extrusion increases within the range where the twist angle of the kneading blade is not less than 43 degrees and not more than 61 degrees, it has been found that the flowability of the material is enhanced in this range. .
- Test 3 a bead test was performed using the closed kneader according to the example of the present invention (Test 3).
- the bead test is a test in which a simulated material containing a large number of beads is kneaded, and the distribution state (flow state) of the beads in the kneaded material is evaluated. In addition, this test was carried out when the material kneading time was 30 seconds and when it was 40 seconds.
- the length of the long blades in the rotation direction F is larger than half the total length of the rotor portion 10, and the overlap portion is formed between the ends of the long blades of the two kneading rotors.
- the long blades are arranged such that the kneading blades of each kneading rotor with respect to the axial direction D have the same twist angle as that of the kneading blades of the kneading rotor used in Test 1
- the kneading test was conducted using In this kneading test, the simulated material containing the beads is kneaded in the chamber, and then the chamber is divided into a plurality of regions having substantially the same volume, and a certain amount of the simulated material is taken out from each region, and each of the taken simulated materials is taken out.
- the number of beads contained in each was measured. Then, the average value and the standard deviation of the number of beads included in the measured simulated material for each region are calculated, and the standard deviation value / average value is obtained by dividing the standard deviation value by the average value. Asked. The calculation result is shown in FIG.
- the vertical axis in FIG. 21 is the standard deviation / average value, and the smaller this value, the more uniformly the beads are mixed in the simulated material. That is, it can be evaluated that the smaller the standard deviation / average value is, the more excellent the distribution performance and mixing performance of the kneading rotor and the kneader equipped with the kneading rotor.
- the horizontal axis of FIG. 21 is the twist angle of three kneading blades (long blade, middle blade, and short blade). The two-dot chain line of “ave 30s / 40s” in FIG.
- 21 indicates the value of “standard deviation / average value” when the kneading time is 30 seconds and “standard deviation / average value” when the kneading time is 40 seconds. "Represents the average value. This average value is the difference between the value of “standard deviation / average value” when the kneading time is 30 seconds and the value of “standard deviation / average value” when the kneading time is 40 seconds for each twist angle of the kneading blades. Each of the arithmetic mean values is taken.
- the test result was evaluated by the value of “ave 30s / 40s”. From the results shown in FIG. 21, when the twist angle of the kneading blade is 45 degrees or more and 61 degrees or less, the standard deviation / average value is small, and in particular, the twist angle of the kneading blade is 50 degrees or more and 57 degrees. It was found that the standard deviation / average value was remarkably small when the degree was less than or equal to the degree. That is, it has been found that the variation in the mixing performance of the kneading rotor is particularly effectively suppressed when the twist angle of the kneading blade is not less than 50 degrees and not more than 57 degrees.
- FIG. 22 is an exploded development view of a pair of kneading rotors according to the modification.
- the description will focus on parts different from the above-described embodiment, and the description of the same parts and matters as those of the above-described embodiment will be omitted.
- the portions denoted by reference numerals 201, 205, 220, 221, 222, 222t, 224, and 225 are denoted by reference numerals 1, 5, 20, 21, 22, 22t, 24, and 25 in the above embodiment, respectively.
- the portions included in the first kneading rotor 201 are not underlined with the reference numerals, while the portions included in the second kneading rotor 205 are underlined with the reference numerals.
- the shape of the long blades 220 is different from the shape of the long blades 20 of the above embodiment.
- the shape of the second end portion 23 which is the front end portion of the long blade 220 in the rotation direction of the kneading rotor is the same as the shape of the second end portion 23 of the long blade 20 of the above embodiment.
- the shape of the first end portion 222 which is the rear end portion of the long blade 220 in the rotation direction of the kneading rotor is different from the shape of the first end portion 22 of the long blade 20 of the above embodiment. That is, the inclined surface 29 is not formed at the first end portion 222 of the long blade 220. Further, the length of the long blade 220 in the axial direction D of the kneading rotor is smaller than the length of the long blade 20 of the above embodiment in the same direction. More specifically, the first end portion 222 has no tip portion including the inclined surface 29 in the first end portion 22 of the above-described embodiment, and the first end portion 222 is equivalent to that of the above-described embodiment. Shorter than the first end 22.
- the kneading rotor may be configured as in this modification.
- the cross-sectional view of the kneading rotor at the P-P ′ position in FIG. 22 is the same as the cross-sectional view of the kneading rotor at the G-G ′ position in the above embodiment (FIG. 18).
- Embodiments of the present invention are not limited to the above-described embodiments and modifications.
- the shapes of the rotary shaft 10j and the rotary shaft 10k are different, but the shapes of these rotary shafts may be the same. That is, the shape of the two rotating shafts sandwiching the rotor unit 10 may be a symmetrical shape. According to such a configuration, the same kind of kneading rotor can be used for each of the pair of kneading rotors only in different arrangement directions, so that the assembly time and cost can be reduced.
- the kneading rotor is a meshing kneading rotor used in a closed kneading machine including a casing in which a chamber is provided, and includes a rotor portion disposed in the chamber. .
- the rotor part has a cylindrical rotor part main body, and one long blade and two short blades provided on the surface of the rotor part main body.
- the length L4 of the long blade in the rotation direction of the rotor portion is larger than half the total length L5 of the rotor portion main body in the rotation direction, and the length of the long blade in the axial direction of the rotor portion.
- the ratio (L1 / L2) between L1 and the total length L2 of the rotor part body in the axial direction is 0.6 or more and less than 1, and the axis from one end of the long blade to the end of the rotor part body
- the ratio (x / L2) between the distance x in the direction and the total length L2 of the rotor body in the axial direction is greater than 0 and 0.2 or less.
- the two short blades are arranged so as to alternately repeat approaching and separating in the rotation direction of the rotor part with respect to the long blades, and in the close state, the two rotors of one of the rotor parts
- the long blades of the other rotor part are sandwiched in the axial direction by the short blades.
- the length L4 of the long blade in the rotation direction of the rotor portion is larger than half the total length L5 of the rotor portion main body in the rotation direction, and the long blades of the pair of rotor portions are close to each other.
- the end portions of the long blades face each other with respect to the rotation direction of the rotor portion on the line connecting the shaft centers of the pair of rotor portions, that is, the direction perpendicular to the line connecting the shaft centers of the pair of rotor portions.
- the opposite end portions of the long blades of the pair of rotor portions block the material leakage flow path in the chamber, thereby reducing or eliminating material leakage between the two end portions. be able to.
- the shear performance of the material can be increased.
- the twist angle of the kneading blade is increased, the shear performance is deteriorated.
- the shear performance of the material can be enhanced by the end portions of the pair of long blades as described above. Therefore, even if the twist angle of the long blade is increased to increase the material flow performance, high shear performance can be maintained.
- a kneading rotor excellent in both flow performance and shear performance can be obtained.
- the “long blade” is a kneading in which the length of the center line of the tip portion provided at the top of the kneading blade is longer than 1 ⁇ 2 of the total length L2 of the rotor portion in the axial direction.
- Short blade means that the length of the center line of the tip portion provided at the top of the kneading blade with respect to the axial direction of the rotor portion is 1 ⁇ 2 or less of the total length L2 of the rotor portion in the axial direction. It is a kneading blade that is long.
- One end of the long wing may be either end in the longitudinal direction of the long wing. Further, the distance from one end of the long blade to the end of the rotor portion closer to the one end of the long blade and the distance from the other end of the long blade to the end of the rotor portion closer to the other end of the long blade May be the same or different.
- Tro short blades provided in one rotor portion may have the same length in the axial direction of the rotor portion, or may have different lengths.
- a closed kneader kneads materials such as rubber and plastic in a batch process.
- “Chamber” refers to a kneading chamber that houses a kneading rotor. Inside the chamber, the materials are kneaded by the kneading rotor.
- the cross section in which the rear end portion and the front end portion face each other with respect to the rotation direction of the rotor portion on the line connecting the shaft centers of the pair of rotor portions in the proximity state is a kneading rotor.
- a cross section in which the end portion is separated may exist in the kneading rotor.
- the long blades may have a twist angle of 45 degrees or more and 61 degrees or less with respect to the axial direction.
- This configuration can suppress variation in mixing performance due to the kneading rotor.
- the long wing may have a twist angle of 50 degrees or more and 57 degrees or less with respect to the axial direction.
- This configuration can further suppress variation in mixing performance due to the kneading rotor.
- the closed kneader has a chamber provided therein, a material supply port at the upper position of the chamber, and a material discharge port at the lower position of the chamber.
- the pair of kneading rotors each have a rotor portion, and each rotor portion has a columnar rotor portion body, one long blade and two short blades provided on the surface of the rotor portion body. .
- the length L4 of the long blade in the rotation direction of the rotor portion is larger than 1 ⁇ 2 of the total length L5 of the rotor portion main body in the rotation direction.
- the ratio (L1 / L2) between the length L1 of the long blade in the axial direction of the rotor portion and the total length L2 of the rotor body in the axial direction is 0.6 or more and less than 1.
- the ratio (x / L2) between the axial distance x from one end of the long blade to the end of the rotor body and the total length L2 of the rotor body in the axial direction is greater than 0 and 0 .2 or less.
- the two short blades of one of the rotor parts approach and separate in the rotation direction of the rotor part with respect to the long blades of the other rotor part.
- Two short blades are arranged so as to repeat alternately, and in the close state, the two short blades of one rotor portion cause the long blades of the other rotor portion to be in the axial direction. Sandwiched.
- the rear end portion in the rotation direction of the rotor portion and the long blades of the other rotor portion are arranged so that the front end portion in the rotational direction of the rotor portion alternately repeats approaching and separating from each other, and in the close state, in a cross section perpendicular to the axial direction
- the rear end portion and the front end portion oppose each other with respect to the rotation direction of the rotor portion on a line connecting the axes of the pair of rotor portions.
- the length L4 of the long blade in the rotation direction of the rotor portion is larger than half the total length L5 of the rotor portion main body in the rotation direction, and the long blades of the pair of rotor portions are close to each other.
- the end portions of the long blades face each other with respect to the rotation direction of the rotor portion on the line connecting the shaft centers of the pair of rotor portions, that is, the direction perpendicular to the line connecting the shaft centers of the pair of rotor portions.
- the opposite end portions of the long blades of the pair of rotor portions block the material leakage flow path in the chamber, thereby reducing or eliminating material leakage between the two end portions. be able to.
- the shear performance of the material can be increased.
- the twist angle of the kneading blade is increased, the shear performance is deteriorated.
- the shear performance of the material can be enhanced by the end portions of the pair of long blades as described above. Therefore, even if the twist angle of the long blades is increased to increase the flow performance, high shear performance can be maintained.
- a closed kneader excellent in both flow performance and shear performance can be obtained.
- the kneading rotor is a meshing kneading rotor used in a closed kneading machine including a casing in which a chamber is provided, and includes a rotor portion disposed in the chamber. ing.
- the rotor part has a cylindrical rotor part main body, and one long blade and two short blades provided on the surface of the rotor part main body.
- the length L4 of the long blade in the rotation direction of the rotor portion is larger than 1 ⁇ 2 of the total length L5 of the rotor portion main body in the rotation direction.
- the ratio (L1 / L2) between the length L1 of the long blade in the axial direction of the rotor portion and the total length L2 of the rotor body in the axial direction is 0.6 or more and less than 1, and the long blade
- the ratio (x / L2) of the distance x in the axial direction from one end of the rotor to the end of the rotor body and the total length L2 of the rotor body in the axial direction is greater than 0 and 0.2 or less.
- the two short blades are arranged so as to alternately and repeatedly approach and separate in the rotation direction of the rotor portion with respect to the long blades, and in the close state, the two of the one rotor portion
- the long blades of the other rotor part are sandwiched in the axial direction by the short blades.
- the length L4 of the long blade in the rotation direction of the rotor portion is larger than 1 ⁇ 2 of the total length L5 of the rotor portion main body in the rotation direction, and the shaft centers of the pair of rotor portions are connected to each other.
- the distances D1, D2, and D3 in the direction satisfy the relationship of D1 + D2> D3. Therefore, in the overlapping development view of the pair of kneading rotors, there are portions that overlap each other in the rotation direction of the rotor portion at the ends of the long blades of the pair of kneading rotors.
- the front end of the long blade positioned rearward in the rotation direction of the rotor portion is more forward than the rear end of the long blade positioned forward in the rotation direction of the rotor portion.
- the part which is located arises.
- the opposite end portions of the long blades of the pair of rotor portions block the material leakage flow path in the chamber, thereby reducing or eliminating material leakage between the two end portions. be able to. For this reason, the shear performance of the material can be increased. In general, when the twist angle of the kneading blade is increased, the shear performance is deteriorated.
- the shear performance of the material can be enhanced by the end portions of the pair of long blades as described above. Therefore, even if the twist angle of the long blade is increased to increase the material flow performance, high shear performance can be maintained. As described above, according to this configuration, a kneading rotor excellent in both flow performance and shear performance can be obtained.
- the closed kneader has a chamber provided therein, a material supply port at the upper position of the chamber, and a material discharge port at the lower position of the chamber.
- Each of the pair of kneading rotors has a rotor portion, and each rotor portion has a columnar rotor portion body, one long blade and two short blades provided on the surface of the rotor portion body. is doing.
- the length L4 of the long blade in the rotation direction of the rotor portion is larger than 1 ⁇ 2 of the total length L5 of the rotor portion main body in the rotation direction.
- the ratio (L1 / L2) between the length L1 of the long blade in the axial direction of the rotor portion and the total length L2 of the rotor body in the axial direction is 0.6 or more and less than 1.
- the ratio (x / L2) of the distance x in the axial direction from one end of the long blade to the end of the rotor portion main body and the total length L2 of the rotor portion in the axial direction is greater than 0 and 0.
- the two short blades are arranged so as to alternately repeat approaching and separating at the same time, and, in the close state, the two short blades of one of the rotor portions cause the long blade of the other rotor portion to In the axial direction Of the long blades of one of the rotor parts when the pair of rotor parts are rotated in opposite directions, the rear end part in the rotation direction of the rotor part and the other of the rotor parts
- the long blades are arranged so that the front end portion in the rotation direction of the rotor portion of the long blades alternately repeats approaching and separating from each other, and in the close state, the long blades are perpendicular to the axial direction.
- the distance D2 between the shaft center and the tip of the long blade of the rotor portion and the distance D3 between the shaft centers of the pair of rotor portions satisfy the relationship of D1 + D2> D3.
- the length L4 of the long blade in the rotation direction of the rotor portion is larger than 1 ⁇ 2 of the total length L5 of the rotor portion main body in the rotation direction, and the shaft centers of the pair of rotor portions are connected to each other.
- the distances D1, D2, and D3 in the direction satisfy the relationship of D1 + D2> D3. Therefore, in the overlapping development view of the pair of kneading rotors, there are portions that overlap each other in the rotation direction of the rotor portion at the ends of the long blades of the pair of kneading rotors.
- the front end of the long blade positioned rearward in the rotation direction of the rotor portion is more forward than the rear end of the long blade positioned forward in the rotation direction of the rotor portion.
- the part which is located arises.
- the opposite end portions of the long blades of the pair of rotor portions block the material leakage flow path in the chamber, thereby reducing or eliminating material leakage between the two end portions. be able to. For this reason, the shear performance of the material can be increased. In general, when the twist angle of the kneading blade is increased, the shear performance is deteriorated.
- the shear performance of the material can be enhanced by the end portions of the pair of long blades as described above. Therefore, even if the twist angle of the long blade is increased to increase the material flow performance, high shear performance can be maintained. As described above, according to this configuration, a closed kneader excellent in both flow performance and shear performance can be obtained.
- the present invention can be used in a closed kneader for kneading materials such as rubber.
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Abstract
Description
以下、本発明の一つの実施形態について、図面を参照しつつ説明する。
次に、一対の混練ロータ(第1混練ロータ1及び第2混練ロータ5)について説明する。一対の混練ロータは、ケーシング70の内部のチャンバー(混練室)70sに収容され、且つ互いに平行に配置されている。また、一対の混練ロータは、噛み合い型のロータである。
長翼20は、第1混練ロータ1のロータ部10の表面の展開平面図において直線状となるように形成されている。また、ロータ部10の軸方向Dに対する長翼20のねじれ角度θ1は、50度となっている(図5参照)。図5において、長翼20は、左上から右下へ延びるように形成されている。なお、図5において、左側が回転軸10j側に相当し、右側が回転軸10k側に相当する。
次に、短翼30について説明する。短翼30は、第1混練ロータ1の表面の展開平面図において直線状となるように形成されている。また、軸方向Dに対する短翼30のねじれ角度θ2は、50度となっている(図5参照)。図5において、短翼30は、長翼20とは異なり、右上から左下へ延びるように形成されている。
次に、中翼40について説明する。中翼40は、第1混練ロータ1の表面の展開平面図において直線状となるように形成されている。また、軸方向Dに対する中翼40のねじれ角度θ3は、50度となっている(図5参照)。図5において、中翼40は、長翼20と同様、左上から右下へ延びるように形成されている。
以下、チャンバー70sの内部において、一対の混練ロータを互いに逆方向に回転させたとき、すなわち、第1混練ロータ1を回転方向Fに回転させるとともに第2混練ロータ5を回転方向F’に回転させたときの、一対の混練ロータの噛み合い状態について説明しながら、各混練翼の相対的な位置関係についてより詳細に説明する。
二つの混練ロータの回転に伴い、第1混練ロータ1のロータ部10(一方のロータ部)の二つの短翼(短翼30及び中翼40)が、第2混練ロータ5のロータ部10(他方のロータ部)の長翼20に対して回転方向F(回転方向F’)において近接と離反を交互に繰り返す(図8中の20度~120度付近参照)。この第1混練ロータ1の二つの短翼(30,40)と第2混練ロータ5の長翼20との近接(噛み合い)を、近接Aとする。
また、二つの混練ロータの回転に伴い、第2混練ロータ5のロータ部10(他方のロータ部)の二つの短翼(短翼30及び中翼40)が、第1混練ロータ1のロータ部10(一方のロータ部)の長翼20に対して回転方向F(回転方向F’)において近接と離反を交互に繰り返す(図8中の200度~300度付近参照)。この第2混練ロータ5の二つの短翼と第1混練ロータ1の長翼20との近接(噛み合い)を、近接Bとする。
また、二つの混練ロータの回転に伴い、第1混練ロータ1のロータ部10(一方のロータ部)の長翼20のうち回転方向Fにおける後方側の第1末端部22と第2混練ロータ5のロータ部10(他方のロータ部)の長翼20のうち回転方向F’における前方側の第2末端部23とが、互いに近接と離反を交互に繰り返す(図8中の320度から30度付近参照)。この第1混練ロータ1の第1末端部22と第2混練ロータ5の第2末端部23との近接を、近接Cとする。図8及び図11において破線円で囲われたC部分が、近接Cの状態における第1混練ロータ1の第1末端部22と第2混練ロータ5の第2末端部23との近接部分である。
また、二つの混練ロータの回転に伴い、第2混練ロータ5のロータ部10(他方のロータ部)の長翼20のうち回転方向F’における後方側の第1末端部22と第1混練ロータ1のロータ部10(一方のロータ部)の長翼20のうち回転方向Fにおける前方側の第2末端部23とが、互いに近接と離反を交互に繰り返す(図8中の130度から200度付近参照)。この第2混練ロータ5の第1末端部22と第1混練ロータ1の第2末端部23との近接を、近接Dとする。
次に、図14~図18を用いて、二つの混練ロータの長翼同士が近接する状態である長翼近接状態について説明する。図14~図18は、軸方向Dに垂直な両混練ロータの混練部の一断面を示しており、この断面の位置は、図8のG-G’位置、及び、図11のH-H位置に相当する。また、図18は、図15の拡大図に相当する。
第1長翼近接状態では、第1混練ロータ1の長翼20の第1末端部22と第2混練ロータ5の長翼20の第2末端部23とが、両混練ロータ1,5のロータ部10の軸心同士を結ぶ線(図18の一点鎖線L参照)上におけるロータ部10の回転方向、すなわち、直線Lに垂直な方向J(図18の矢印J方向参照)に関して互いに対向する。これを対向Aとする。対向Aは、近接Cに伴って生じる。
第2長翼近接状態では、第2混練ロータ5の長翼20の第1末端部22と第1混練ロータ1の長翼20の第2末端部23とが、両混練ロータ1,5のロータ部10の軸心同士を結ぶ線(図18の一点鎖線L参照)上におけるロータ部10の回転方向、すなわち、直線Lに垂直な方向J(図18の矢印J方向参照)に関して互いに対向する。これを対向Bとする。対向Bは、近接Dに伴って生じる。
次に、本実施形態に係る混練ロータ及び密閉式混練機80によって得られる効果について説明する。
まず、本発明の実施例に係る混練ロータを組み込んだ密閉式混練機(神戸製鋼所製BB-16)を用いて被混練材料の混練試験を行ない、混練後の材料の品質を評価した(試験1)。ここで、材料の品質については、材料のΔG’値を測定することにより評価した。ここで、ΔG’値とは、混練後の材料の小変形ひずみ時における貯蔵弾性率と混練後の材料の大変形ひずみ時における貯蔵弾性率との差のことであり、混練後の材料中のフィラーの分散に関する品質を判断するために用いられる指標である。なお、混練後の材料の小変形ひずみ時における貯蔵弾性率は、未加硫ゴム組成物の粘弾性特性から得られる。そして、ΔG’値が小さいほど、フィラーの分散に関する混練後の材料の品質が良い。また、ΔG’は、シリカを配合した材料とシリカを配合していない材料との横弾性係数の差で表される。
以下、本試験において被混練材料として配合される材料と、そのPHRとを示す。
BR:30
シリカ:80
シリカカップリング剤:6.4
ZnO:3.0
ステアリン酸:2.0
AROMAオイル:15
ゴム劣化防止剤 6PPD:1.5
ANTIOZONANT WAX:1.0
次に、試験1の比較例について説明する。比較例に係る密閉式混練機では、図23の重ね合わせ展開図に示す二つの混練ロータ(混練ロータ901及び混練ロータ905)を使用している。なお、本比較例に係る混練ロータ901及び混練ロータ905は、円柱状のロータ部本体915と、そのロータ部本体915の表面に設けられた三つの混練翼(長翼920、短翼930及び中翼940)とを有するロータ部910をそれぞれ備えている。
次に、混練ロータの軸方向Dにおける混練中の材料の押出量と混練翼のねじれ角度との関係を計算した。材料押出量は、密閉式混練機における混練ロータの軸方向Dについての材料の流動性能の指標であり、この値が大きいほど、流動性能が高くなり、材料の均一な混練が可能となる。材料押出量Qは、以下の式で表わされる。
Q:材料押出量
N:ロータ回転数[s-1]
μ:粘度[Pa・s]
ΔP:圧力変化値[Pa]
α、β、γ:ロータ形状に関する係数
次に、本発明の実施例に係る密閉式混練機を用いて、ビーズテストを行なった(試験3)。ビーズテストとは、多数のビーズを入れた模擬材料を混練し、混練後の材料におけるビーズの分配状態(流動状態)を評価する試験である。また、この試験は、材料の混練時間を30秒にした場合と40秒にした場合とについて実施した。
次に、上記の実施形態の変形例について、図22を用いて説明する。なお、図22において、上記の実施形態と同様の部分については、上記実施形態の該当部分と同一の符号を付している。図22は、当該変形例に係る一対の混練ロータの重ね合わせ展開図である。以下、上記の実施形態とは異なる部分を中心に説明し、上記の実施形態と同様の部分及び事項については、その説明を省略する。なお、図22において符号201、205、220、221、222、222t、224、225を付した部分は、それぞれ、上記の実施形態において符号1、5、20、21、22、22t、24、25を付した部分に相当する。また、図22において、第1混練ロータ201に含まれる部分については、符号に下線を付さない一方、第2混練ロータ205に含まれる部分については、符号に下線を付している。
本発明の実施の形態は、上記の実施形態及び変形例には限られない。例えば、上記の実施形態においては、回転軸10jと回転軸10kとの形状が異なるが、これらの回転軸の形状を同一としてもよい。すなわち、ロータ部10を挟む二つの回転軸の形状を対称形状としてもよい。このような構成によれば、前記一対の混練ロータのそれぞれに同種の混練ロータを配置方向だけを異ならせて用いることができるため、組み立ての時間及びコストを低減できる。
前記実施形態をまとめると、以下の通りである。
Claims (6)
- チャンバーが内部に設けられたケーシングを備えた密閉式混練機に用いられる噛み合い型の混練ロータであって、
前記チャンバー内に配設されるロータ部を備え、
前記ロータ部は、円柱状のロータ部本体と、そのロータ部本体の表面に設けられた一つの長翼と二つの短翼とを有し、
前記ロータ部の回転方向における前記長翼の長さL4は、前記回転方向における前記ロータ部本体の全長L5の1/2の長さよりも大きく、
前記ロータ部の軸方向における前記長翼の長さL1と前記軸方向における前記ロータ部本体の全長L2との比(L1/L2)は0.6以上且つ1未満であり、且つ、前記長翼の一端から前記ロータ部本体の端までの前記軸方向における距離xと前記軸方向における前記ロータ部本体の全長L2との比(x/L2)は0よりも大きく且つ0.2以下であり、
前記密閉式混練機の前記チャンバーの内部において一対の前記ロータ部を互いに平行に配置して互いに逆方向に回転させた場合に一方の前記ロータ部の二つの前記短翼が他方の前記ロータ部の前記長翼に対して前記ロータ部の回転方向において近接と離反を交互に繰り返すように二つの前記短翼が配置されており、且つ、前記近接の状態では、一方の前記ロータ部の二つの前記短翼によって他方の前記ロータ部の前記長翼が前記軸方向において挟まれ、
前記密閉式混練機の前記チャンバーの内部において一対の前記ロータ部を互いに平行に配置して互いに逆方向に回転させた場合に一方の前記ロータ部の前記長翼のうちそのロータ部の回転方向における後方側の末端部と他方の前記ロータ部の前記長翼のうちそのロータ部の回転方向における前方側の末端部とが互いに近接と離反を交互に繰り返すように前記長翼が配置されており、且つ、前記近接の状態では、前記軸方向に垂直な一断面において、前記後方側の末端部と前記前方側の末端部とが一対の前記ロータ部の軸心同士を結ぶ線上における前記ロータ部の回転方向に関して互いに対向する、混練ロータ。 - 請求項1に記載の混練ロータにおいて、
前記長翼は、前記軸方向に対して45度以上且つ61度以下のねじれ角度を有する、混練ロータ。 - 請求項2に記載の混練ロータにおいて、
前記長翼は、前記軸方向に対して50度以上且つ57度以下のねじれ角度を有する、混練ロータ。 - 内部にチャンバーが設けられているとともに、前記チャンバーの上部の位置に材料供給口が設けられ、且つ、前記チャンバーの下部の位置に材料排出口が設けられ、当該材料供給口及び当該材料排出口が閉じられることにより前記チャンバーが密閉状態となるケーシングと、
前記チャンバー内に収容され且つ互いに平行に配置された噛み合い型の一対の混練ロータとを備え、
前記一対の混練ロータは、ロータ部をそれぞれ有し、
前記各ロータ部は、円柱状のロータ部本体と、そのロータ部本体の表面に設けられた一つの長翼と二つの短翼とを有し、
前記各ロータ部において、そのロータ部の回転方向における前記長翼の長さL4は、その回転方向における前記ロータ部本体の全長L5の1/2の長さよりも大きく、
前記各ロータ部において、そのロータ部の軸方向における前記長翼の長さL1と前記軸方向における前記ロータ部本体の全長L2との比(L1/L2)は0.6以上且つ1未満であり、且つ、前記長翼の一端から前記ロータ部本体の端までの前記軸方向における距離xと前記軸方向における前記ロータ部本体の全長L2との比(x/L2)は0よりも大きく且つ0.2以下であり、
一対の前記ロータ部を互いに逆方向に回転させた場合に一方の前記ロータ部の二つの前記短翼が他方の前記ロータ部の前記長翼に対して前記ロータ部の回転方向において近接と離反を交互に繰り返すように二つの前記短翼が配置されており、且つ、前記近接の状態では、一方の前記ロータ部の二つの前記短翼によって他方の前記ロータ部の前記長翼が前記軸方向において挟まれ、
一対の前記ロータ部を互いに逆方向に回転させた場合に一方の前記ロータ部の前記長翼のうちそのロータ部の回転方向における後方側の末端部と他方の前記ロータ部の前記長翼のうちそのロータ部の回転方向における前方側の末端部とが互いに近接と離反を交互に繰り返すように前記長翼が配置されており、且つ、前記近接の状態では、前記軸方向に垂直な一断面において、前記後方側の末端部と前記前方側の末端部とが一対の前記ロータ部の軸心同士を結ぶ線上における前記ロータ部の回転方向に関して互いに対向する、密閉式混練機。 - チャンバーが内部に設けられたケーシングを備えた密閉式混練機に用いられる噛み合い型の混練ロータであって、
前記チャンバー内に配設されるロータ部を備え、
前記ロータ部は、円柱状のロータ部本体と、そのロータ部本体の表面に設けられた一つの長翼と二つの短翼とを有し、
前記ロータ部の回転方向における前記長翼の長さL4は、前記回転方向における前記ロータ部本体の全長L5の1/2の長さよりも大きく、
前記ロータ部の軸方向における前記長翼の長さL1と前記軸方向における前記ロータ部本体の全長L2との比(L1/L2)は0.6以上且つ1未満であり、且つ、前記長翼の一端から前記ロータ部本体の端までの前記軸方向における距離xと前記軸方向における前記ロータ部本体の全長L2との比(x/L2)は0よりも大きく且つ0.2以下であり、
前記密閉式混練機の前記チャンバーの内部において一対の前記ロータ部を互いに平行に配置して互いに逆方向に回転させた場合に一方の前記ロータ部の二つの前記短翼が他方の前記ロータ部の前記長翼に対して前記ロータ部の回転方向において近接と離反を交互に繰り返すように二つの前記短翼が配置されており、且つ、前記近接の状態では、一方の前記ロータ部の二つの前記短翼によって他方の前記ロータ部の前記長翼が前記軸方向において挟まれ、
前記密閉式混練機の前記チャンバーの内部において一対の前記ロータ部を互いに平行に配置して互いに逆方向に回転させた場合に一方の前記ロータ部の前記長翼のうちそのロータ部の回転方向における後方側の末端部と他方の前記ロータ部の前記長翼のうちそのロータ部の回転方向における前方側の末端部とが互いに近接と離反を交互に繰り返すように前記長翼が配置されており、且つ、前記近接の状態では、前記軸方向に垂直な一断面において、一対の前記ロータ部の軸心同士を結ぶ方向における、一方の前記ロータ部の軸心とそのロータ部の前記長翼の先端との間の距離D1、他方の前記ロータ部の軸心とそのロータ部の前記長翼の先端との間の距離D2及び一対の前記ロータ部の軸心間の距離D3がD1+D2>D3の関係を満たす、混練ロータ。 - 内部にチャンバーが設けられているとともに、前記チャンバーの上部の位置に材料供給口が設けられ、且つ、前記チャンバーの下部の位置に材料排出口が設けられ、当該材料供給口及び当該材料排出口が閉じられることにより前記チャンバーが密閉状態となるケーシングと、
前記チャンバー内に収容され且つ互いに平行に配置された噛み合い型の一対の混練ロータとを備え、
前記一対の混練ロータは、ロータ部をそれぞれ有し、
前記各ロータ部は、円柱状のロータ部本体と、そのロータ部本体の表面に設けられた一つの長翼と二つの短翼とを有し、
前記各ロータ部において、そのロータ部の回転方向における前記長翼の長さL4は、その回転方向における前記ロータ部本体の全長L5の1/2の長さよりも大きく、
前記各ロータ部において、そのロータ部の軸方向における前記長翼の長さL1と前記軸方向における前記ロータ部本体の全長L2との比(L1/L2)は0.6以上且つ1未満であり、且つ、前記長翼の一端から前記ロータ部本体の端までの前記軸方向における距離xと前記軸方向における前記ロータ部の全長L2との比(x/L2)は0よりも大きく且つ0.2以下であり、
一対の前記ロータ部を互いに逆方向に回転させた場合に一方の前記ロータ部の二つの前記短翼が他方の前記ロータ部の前記長翼に対して前記ロータ部の回転方向において近接と離反を交互に繰り返すように二つの前記短翼が配置されており、且つ、前記近接の状態では、一方の前記ロータ部の二つの前記短翼によって他方の前記ロータ部の前記長翼が前記軸方向において挟まれ、
一対の前記ロータ部を互いに逆方向に回転させた場合に一方の前記ロータ部の前記長翼のうちそのロータ部の回転方向における後方側の末端部と他方の前記ロータ部の前記長翼のうちそのロータ部の回転方向における前方側の末端部とが互いに近接と離反を交互に繰り返すように前記長翼が配置されており、且つ、前記近接の状態では、前記軸方向に垂直な一断面において、一対の前記ロータ部の軸心同士を結ぶ方向における、一方の前記ロータ部の軸心とそのロータ部の前記長翼の先端との間の距離D1、他方の前記ロータ部の軸心とそのロータ部の前記長翼の先端との間の距離D2及び一対の前記ロータ部の軸心間の距離D3がD1+D2>D3の関係を満たす、密閉式混練機。
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ES10764197.9T ES2527020T3 (es) | 2009-04-15 | 2010-03-12 | Rotor de amasado, y máquina amasadora cerrada que comprende un par de tales rotores |
KR1020117027012A KR101240859B1 (ko) | 2009-04-15 | 2010-03-12 | 밀폐식 혼련기 및 혼련 로터 |
CA2758427A CA2758427C (en) | 2009-04-15 | 2010-03-12 | Closed kneading machine and kneading rotor |
EP10764197.9A EP2409822B1 (en) | 2009-04-15 | 2010-03-12 | Kneading rotor, and closed kneading machine comprising a pair of such rotors |
RU2011146160/05A RU2477683C1 (ru) | 2009-04-15 | 2010-03-12 | Закрытая месильная машина и месильный ротор |
US13/259,954 US8882337B2 (en) | 2009-04-15 | 2010-03-12 | Closed kneading machine and kneading rotor |
MX2011010867A MX336352B (es) | 2009-04-15 | 2010-03-12 | Maquina para amasar cerrada y rotor de amasado. |
BRPI1015187-7A BRPI1015187B1 (pt) | 2009-04-15 | 2010-03-12 | Máquina de amassar fechada e rotor de amassar |
CN201080017273.7A CN102395452B (zh) | 2009-04-15 | 2010-03-12 | 密闭式混炼机以及混炼转子 |
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JP (1) | JP4542605B1 (ja) |
KR (1) | KR101240859B1 (ja) |
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AR (1) | AR076304A1 (ja) |
BR (1) | BRPI1015187B1 (ja) |
CA (1) | CA2758427C (ja) |
ES (2) | ES2532722T3 (ja) |
MX (1) | MX336352B (ja) |
RU (1) | RU2477683C1 (ja) |
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AR076304A1 (es) | 2011-06-01 |
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EP2409822B1 (en) | 2014-12-17 |
EP2409822A4 (en) | 2013-08-21 |
EP2626180A1 (en) | 2013-08-14 |
KR20120022936A (ko) | 2012-03-12 |
TW201036696A (en) | 2010-10-16 |
RU2477683C1 (ru) | 2013-03-20 |
US8882337B2 (en) | 2014-11-11 |
MX336352B (es) | 2016-01-06 |
KR101240859B1 (ko) | 2013-03-07 |
US20120014206A1 (en) | 2012-01-19 |
CN102395452A (zh) | 2012-03-28 |
JP2010247412A (ja) | 2010-11-04 |
EP2409822A1 (en) | 2012-01-25 |
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