• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to multi-screw extruders and provides a self-cleaning type extruder including a cylinder (2) and at least two screws (1,1 min ) therein adapted to rotate in the same directions, said screws (1,1 min ) being in such a relation that at any position in at least a part of the screws (1,1 min ) which lies in the longitudinal direction of the extruder, the contour of one screw in a cylinder cross-section taken at right angles to the screw axes is in substantial contact at one point with the contour in the same cross-section of another screw intermeshing therewith; wherein each of said screws (1,1 min ) has at least two screw flights (3, 5; 3 min , 5 min ), and the top (4,4 min ) of at least one of the screw flights (3,3 min ) is substantially in contact with the inner wall surface of the cylinder and the top (6,6 min ) of at least one other screw flight (5,5 min ) has a predetermined tip clearance (8) with respect to the inner wall surface of the cylinder (2).
    公开号:SU1190979A3
    申请号:SU792788708
    申请日:1979-07-17
    公开日:1985-11-07
    发明作者:Сакагами Мамору
    申请人:Секисуи Кагаку Когио Кабусики Кайся (Фирма);
    IPC主号:
    专利说明:

    one . Because of this, the type is a self-cleaning type multi-screw extruder type and can be used in the polymer processing industry. A well-known, self-cleaning type of machine is known, containing two screws mounted with the possibility of mutual engagement and rotation in the same direction with respect to the axes of rotation coinciding with the central axes of screws L. The function of this type of extruder is to eliminate pulsations of production or speed of displacement of the mixture, which are blocked by blocking powders in the zone of transfer of solids and / or plasticization, and preventing deterioration of pressure caused by adhesion of degenerated products in the zone of melt transportation. This extruder is used in kneading, melting and mixing polymeric materials. The self-cleaning type extruder has a special design defined by a coral of screws in cross section. At a right angle to their axes. It contains at least two screws adapted for rotation in one direction, each of which has one or several cuts and which are in such a relation that in any position at least in the part of the screws, which is located in the longitudinal direction of the extruder, the contour of one screw in cross section taken at a right angle to the axis of the screw is in firm contact e at one point with a contour in the same cross section that is connected with another worm. The vertices cut by each of the screws in this extruder of self-cleaning type are in strong contact with the inner surface of the cylinder wall, and each channel of the screw forms a space that is virtually completely isolated from adjacent channels. In accordance with this, the raw materials supplied to one channel of one screw, while rotating the screws, inevitably move into the channel of another screw. It then moves to the same channel of the first screw, etc. 792 Thus, in this extruder of the self-cleaning type, the path along which the raw material flows; completely for- hanging from the worm channel to which raw materials are initially fed. The polymer that entered the same channel of the screw is neither partially nor fully combined with the raw materials in the adjacent channels, i.e. the exchange of raw materials between the channels of one worm and between the channels of two meshed worm does not occur. . Thus, the disadvantage of this extruder is the low capacity for mixing and dispersing the polymer fed to it. . The closest to the invention to the technical essence and the achieved result is an extruder of self-cleaning type, containing a cylinder and at least two screws, mounted with the possibility of intermeshing and rotation in one direction relative to the axes of rotation, coinciding with the central axis of the screws, and contact in any position at least in the Screw-on Stations located in the longitudinal direction of the extruder, fto the cross-sectional contour of one of the screws located perpendicular Street central axis of the screws, at one point with the cross-sectional contour of the other screw, each of the screws being made with at least two cuts, the upper part of the first of which is mounted in contact with the inner surface of the cylinder, and part of the transverse contour the cross section formed by the upper part of the first cut is made in the form of an arc with a radius equal to R / 2 and with the center of the arc placed on the central axis of the screw, while the upper part of the second cut is located with a gap relative to the inner surface of qi lindra and is formed by an arcuate section of the cross section of the L2J worm. In the well-known extruder, due to the presence of two slices of different heights, the material is mixed while retaining the advantages of a self-cleaning type extruder based on polymer exchange between adjacent screw channels in the axial direction of the screws and between the channels of the two screws that are in engagement. The disadvantage of a natural extruder is that it does not both bake an intense shearing effect on the material by the mesquat on the surface of the cylinder wall and this surface of the channels of the screw ka.pri saved high extrusion speed, because the extruder does not have data on the specific cutting of the screws . This fact is explained as follows. Typically, the magnitude of the shear force of the screw, independent of the properties of the raw materials and the working conditions, is determined by the product of the average shear rate (velocity gradient) and time. Since time depends on the change in the screw size in the axial direction, the shear rate at the surface of the cylinder wall is a parameter characterizing the effect of shear: it is interconnected with the shape of the extruder in its cross section taken at a right angle to its axis. The shear rate (i.) At the surface of the wall is usually proportional to H / I ((jctR / H), where R is the outer diameter of each screw, and H is the depth of the screw channel. If the distance between the axes of the two are engaged the screws through L then, since AND R-L, the following equation can be made: As can be seen from equation (1), the shear rate at the wall surface increases if the distance L between the axis of the screws approaches the cutting diameter R the worm, and thus the H channel depth, is reduced. C. by reducing the H channel depth by The volume of the part of the screws that is in the engagement decreases and, consequently, the time during which the raw material undergoes a shifting action decreases. This leads to a decrease in the effect of mixing the polymer and a sharp drop in productivity. Cutting several worms of a known extruder itself of the cleaning type have the same outer diameter R. If R and L are constant, then the channel depth H () is uniquely determined, therefore, the shear rate at the wall is also uniquely determined. This means that in order to obtain an intensive shift at a given speed of rotation of the screws in a known self-cleaning type extruder, it is necessary to reduce the outer diameter R of the cutting of the screw as compared to the distance C between the axes of the two screws that are engaged, namely, reduce the depth of the worm channel. However, if this is done, the effect of the polymer mixing screws is reduced and the rate of extrusion of the polymer drops sharply. Thus, in order to obtain a high shear rate at the wall surface, the polymer transfer efficiency and the cracking speed or productivity should be reduced. The purpose of the invention is to increase the efficiency and intensity of mixing of the material. I. The goal is achieved by the fact that in an extruder a self-cleaning type comprising a cylinder and at least two screws mounted interlinkably and rotating in one direction relative to the axis of rotation coinciding with the central axes of the screws and with the possibility of contacting in any position along at least in the areas of the screws arranged in the longitudinal direction of the extruder, along the cross-sectional contour of one of the screws located perpendicular-. coolly with the central axis of the screws, at one point with the cross-sectional contour of the other screw, each of the screws being made with at least two cuts, the upper part of the first of which is mounted in contact with the inner surface of the cylinder, and part of the cross-sectional contour formed by the upper part of the first cut, made in the form of an arc with a radius equal to R / 2, and with the center of the arc placed on the central axis of the screw, while the upper part of the second cut is located with a gap relative to the inner surface the cylinder and is formed by the arcuate section of the cross-sectional contour of the screw; the gap between the upper part of the second cutting and the inner surface of the cylinder is chosen as a constant value S, determined from the ratio R / 100. & H / 2 and the arcuate portion of the contour of the second cut is formed by a radius equal to R / 2-S, with the center of the arc located on the central axis of the screw, where R is the outer diameter of the screw defined by the value of twice the vertical maximum distance from the top of the first thread of the screw to its central axis, I is the depth of the channel of the screw, is equal to R - L, where I, is the center-to-center distance of the intermeshing worms.
    In addition, the constant value O of the gap between the upper part of the second cut and the inner surface of the cylinder is determined from the ratio R / 50 6 "H / 2, where R and H are the indicated values.
    Due to the specific implementation of the screw profile, polymer is circulated between adjacent channels of one screw and channels of another screw.
    Fig. 1 shows a variant of the extruder, a section. In the part of the screw, a view in the glider of Fig. 2, section A-A in Fig. 1, in Fig. 3, a second embodiment of the extruder, a section in the part of the screw in Fig. .4 is the same as the embodiment, in FIGS. 5 and 6, the contours of the screws in the cross section of the cylinder, taken at a right angle to the axis of the screw of the caster, containing two cuts on the screw.
    The screws used in the extruder have at least two. cutting. Theoretically, any number of cuts can be made, but in the proposed extruder, screws are preferable, each of which has a mouth of two to four cuts
    Several screws embedded in the proposed extruder have a single outer diameter. But they may have outer diameters that differ from one another. The proposed extruder can have on. at least two such worms.
    The extruder is self-cleaning; it (Fig, 1) has two screws 1 and 1 with the same outer diameter, each of which has two cuts. Worms 1 and 1 are located in cylinder 2 and are cut, respectively. 3 and 3, the vertices 4 and 4 of which are in strong contact with the inner surface of the wall of cylinder 2, and the cuts 5 and 5 with vertices 6 and 6 are separated from the inner surface of the wall of cylinder 2 by a predetermined radial clearance U.
    The cross-sectional shapes of screws 1 and 1 are mirrored relative to each other (figure 2). In any intermediate phase of rotation, the cross-sectional contour of the worm 1 is in firm contact with the contour of the cross-section of the worm 1 at only one point. The cross-sectional shapes of the screws 1 and 1 are usually designed in such a way that the contact point P (P) falls to the junction line of the crests a and b of cylinder 2.
    The term in firm contact means that the two elements are in frictional contact with one another with the possibility of sliding, or the two elements are facing one another with such a small gap between them that. the polymer to be mixed and pressed does not actually pass through them.
    The radial clearance can vary according to the application of the extruder in the following ranges of the outer diameter (R) of the screw and the depth () of the screw channel, determined by the distance L between the axes in the mutual engagement of the screws.
     8 / 1ob8 and / 2.
    Preferably
    R / 5Q S H / 2.
    The outer diameter of the screw indicates the value obtained by doubling the maximum vertical distance from the tip of the screw cutting to its central axis.
    The extruder in the embodiment of FIG. 3 contains two screws with the same outer diameter f (FIGS. 1 and .2), each of which has two cuts. The difference is that while in the embodiment of the construction of FIGS. 1 and 2 in each worm, two cuttings exist independently of one another, the two cuttings at each worm are similar to those of the construction of FIG. 3. mc and form a single cutting irregular shape. As can be seen from FIG. 3, the extruder according to this embodiment of the structure contains two screws 7 and each of which has two cuts 8 and 9, or 8 and 9 respectively. It can be seen from FIG. 3 that the two cuts are connected to obtain the construction of the combined cuts 10, the top of which is in strong contact with the inner surface of the wall of the cylinder 11, and the plane 12 is separated from the inner surface of the wall of the cylinder 11 by a predetermined radial clearance B. In the embodiment of the extruder design shown in FIG. 3, in the cross section of the screws taken at a right angle to the axis of the screw going in the longitudinal direction of the extruder, the circuit of the screw 7 is in firm contact with the circuit of the screw 7 only in one point, and the radial clearance corresponds to the clearance obtained by adjusting the radial clearance of cuttings 5 and 5 of the screw to 1 and 1 of the extruder shown in FIG. 1 up to half of I f5 - / R-Ll / sT of the depth of the screw channel, t. e. This thread has a special shape with the largest possible radial clearance G. The extruder shown in Fig. 4 contains two screws 13 and 13, each of which has three cuts 14, 16 and 15 or 14, 1b and 15, respectively. of the vertices 17 and 17, the cuts 16, 16 have a radial clearance d relative to the inner surface of the wall of the cylinder 18, and the remaining vertices 19 and 20 or 19 and 20 of the cuts 14 and 15 or 14 and 15 are in firm contact with the inner surface of the wall of the cylinder 18. In the extruder of FIG. 4, only one of the three cuts has a radial clearance relative to the inner surface of the cylinder wall, however, such screws can be designed so that the tops of two cuts of the three have radial gaps relative to the inside surface of the cylinder. The radial gaps of the two na-dezok may be the same or differ from one another. The method for designing the cross section of screws used in the proposed extruder, including a screw with the same external diameter, each of which has ve slicing (Figures 1 and 2), is described in more detail below. Worm screws according to other embodiments of the invention can be constructed in exactly the same way. The contours of the cross-sections of the two screwed-in screws are shown in FIGS. 5 and 6, from which it can be seen that the contour of the cross-section of the screw, taken at a right angle to its axis, is a combination of groups of arcs AB, CO , EF and / QH with the axis as the center and the group of curves 6Е, FD, AQ and НС, determined by the method of analytical geometry. Fig. 5 shows the outline of a single screw in cross section, taken at a right angle to its axis, in a phase in which the apex of one cut converges with a ridge on the cylinder. Figure 6 shows a similar view in which the apex of one of the cuts of the worm is in the phase of some deviation from the cylinder ridge b. . . . - The contour 21 of the inner surface of the cylinder defines an extruder characteristic of the invention. As a result, the distance L between the axes O and O of two screws 22 and 22 is determined. From the fact that the apex of one cut is in firm contact with the contour 21 of the cylinder, the outer diameter R of the worm can be determined. If, in FIG. 5, the angle LbccJ is formed by II — a straight line C forming an angle of 45 with the horizontal. the axis О-б, passing through the axes О and О and the straight line L-О connecting the comb on the cylinder with the axis O, is oi / 2, then the arc AB can be expressed as an arc, and the radius R / 2 with a central angle oii / 2 on both sides of the O – C straight line. This arc A8 defines the contour of a cutting tip, which is in firm contact with the inner surface of the cylinder wall. The arc EF is an arc having a radius (/ U -) with a central angle o6 / 2 on both sides of the straight line e-f, which passes through the axis o and crosses the straight line C-J at a right angle to it. It defines the bottom surface of the canal in a black box in its lowest position. When the vertices of the two cuts are in firm contact with the inner surface of the cylinder wall, in a known type of screw, the entire contour of the cross section of the screw, taken at a right angle to the axis of the screw, is symmetrical with respect to the straight line C - J and can be vrahsen curve A - B EF- (O) -3- II E-A. It is established that, on the basis of the information of analytical geometry, the curves, -. 8E and F3 can be expressed by the following equation (J). . On the other hand, the contour of the top of a cut having a radial clearance {with the inner surface of the cylinder wall is determined by the arc bv. Doug. hectares can be expressed as an arc having a central angle Z. COO when the circle is with a radius (drawn relative to O as the center, and the intersection point of the circle with the curve F is denoted by D. The central angle of the LCOO can be defined as follows. in which the circle having radius / - Rd intersects the straight line q - b connecting the crests a and b of the cylinder behind point O is point k, then the central angle L CoD can be determined under the assumption that the Soss angle is equal to the angle / iCOo. The arc GM is an arc, named yroniCtOi (-) u is equal to the angle i Sooi, and the angle HOf to the angle / DO 5. The arcs AG and Not bored with the following equation (i). The contours of the screws in their cross section taken at the right angle to their axis can be determined by the described In this way, it determines the design of the screws used in the proposed extruder. If we look at Fig. 6, which shows the state of Fig. in the deviation stage, the angle Cf, ur 1e (l) can be made as follows in a way. FIG. The 6 and 5 contours of the cross sections of the two screws are the same, with the same parts being indicated by the same positions. Done the reference line is the bisector with -J of the vertical angle AOW of cutting the screw 22, the apex of which is in firm contact with the inner surface of the cylinder wall. If the distance from the axis O to the contour of the screw 22 in a cross section taken perpendicular to its axis, at a point offset from this line of reference by the angle Cp is t, then the following equation can be made up: Rb5in (6-qw;) Rb eosie-Mu;) ir cose-U С 8 + - | - - (- 8, where - L –Rd) J Q - the angle of engagement formed by the straight line b - O connecting the crest b of the cylinder with the axis O and the horizontal axis jh, 6 is the horizontal angle formed by the straight line О-О connecting the point of contact of two screws with the axis. Oj and the horizontal axis — h J pt — is the vertical cutting angle formed by the straight line A-0 and R-0 (or A-O ib-o) connecting the axis O (or O) with the tops of the DI (or A and B) cuts of the worm whose vertices are in firm contact with the inner surface of the cylinder wall; (f angle L bpa, which is itself the angle of rotation of the vertex L of cutting the worm from the ridge b of the cylinder C) —the angle formed by subtracting 06/2 from the angle formed by the straight line connecting the vertex with or or C) ka, having a radial gap of the axis O (or O and the reference line c-J (or c-d). From the above equation, r can be determined at any given angle Cf. If. G with If, is plotted in the system of rectangular coordinates, from g to ordinate axis and y on the x-axis, then curves BE, FD, fb,, NA contour of the worm can be drawn cross section, taken at a right angle to its axis. The AND, FO, AQ and He contours of the screw thus obtained can be represented by the following equation (i). i () - T | v «- ° - t (i) -coe (-l) ir. (. u) q, C). and where R is the outer diameter of the screw; m is the number of cuts of the screw, 8 is the radial clearance of cutting of the screw i (R, S) is the function (and 5, corresponding to (I: - S), 8) is the function of C and (j corresponds to Sc а «(h :) The extruder operates as follows. Since the proposed extruder is designed so that at least one of the several cuts of the screw has a specific radial clearance relative to the cylinder, an effective mixing action can be achieved in plastics processing (Figures 1 and 2) The polymer supplied, for example, to the channel C, and the screw l, moves past the lower thread. at 5 through the radial gap between it and the inner surface of the cylinder wall using the pushing action of cutting 3 in the left-hand direction and merging with the polymer in the adjacent channel C. When the screw is rotated, the polymer melt flow shown in Fig. 1 the arrow X, is formed by rubbing the polymer against the inner surface of the cylinder 2. The polymer, which flows upward in the direction of the arrow K, is divided along the channel C at the point of mutual engagement of screws 1 and 1 into a stream that moves along the normal path in the direction Z along the channel 1} in the screw, and the flow which moves to the channel of the screw 17, for cutting the bottom vertex b is 5, and thus advances in a direction shown by the arrow Zg. The polymer that moves to the Bg channel of the worm is mixed with the polymer in the channel O, adjacent to it through the Bottom Cut 5 through the flow between the channels in the direction shown by the arrow X 2. 7912. The polymer that moves to the D channel of the worm 1 from the channel C, the worm 1, is similarly mixed with the polymer; H. Thus, in the proposed self-cleaning type extruder, intensive mixing of the polymer can be achieved by exchanging polymer flows with the channels of the same screw and between the channels of the two meshed screws due to the specific cut, and the choice of the size of the constant gap 8. In addition, the polymer circulates between adjacent channels through radial ripping of the cuts, as shown, for example, by arrows X, Xg, X and X. Due to the narrow radial clearance, A is subjected to an intense shearing action. When a non-melted polymer or a high-viscosity polymer is co-present in the channels, the radial gap performs a filtering action to make the melt viscosity of the polymer extremely uniform. In particular, in the extruder of FIG. 3, the amount of polymer that is subjected to such a shearing action, and the time during which it is subjected to this shearing action can be maximized, and the channels of the screw have a configuration close to the configuration of well-known machines worm com. Worm channels of this type (Fig. 3) create a factor due to the configuration of the channel, which provides high displacement efficiency and can give a very intense general shift at a fixed pressure rate. The extruder according to the invention can carry out uniform and intensive polymer movement.
    1190979
    / 4-A
    FIG. 2
    tlfvj
    1012
    Fig.Z
    20 Iff 19
    18
    t9t l7t620f5
    权利要求:
    Claims (2)
    [1]
    1. Extruder self-cleaning type, containing a cylinder, and at least two worms mounted with the possibility of intermeshing and rotation in one direction relative to the axis of rotation, coinciding with the Central axis of the worms, and with the possibility of contact in. at any position in at least parts of the worms located in the longitudinal direction of the extruder, along the contour of the cross section of one of the worms, perpendicular to the central axes of the worms, at one point with the contour of the cross section of the other worm, each of the worms being made with at least two cuts , the upper part of the first of which is mounted in contact with the inner surface of the cylinder, and the part of the cross-sectional contour formed by the upper part of the first thread is made in the form of an arc radius ,. equal to R / 2, and with the center of the arc located on the central axis of the worm, while the upper part of the second cut is located with a gap relative to the inner surface of the cylinder and is formed by an arcuate portion of the contour of the cross section of the worm, characterized in that, in order to increase the efficiency and the intensity of mixing of the material, the gap between the upper part of the second cut and the inner surface of the cylinder is selected as a constant value S, determined from the ratio R / 100 έ δ ί H / 2, and the arcuate section of the contour of the second bunk The hezzer is formed by a radius equal to R / 2-S, with the center of the arc located on the central axis of the worm, where R is the outer diameter of the worm, determined by the value of the doubled vertical maximum distance · from the top. first slicing of the worm to its central axis,.
    H is the depth of the channel of the worm, equal to R-L, where b is the center-to-center distance of the interlocking worms.
    [2]
    2. The extruder according to claim 1, characterized in that it is a constant value. S the gap between the upper part of the second thread and the inner surface of the cylinder is determined from the ratio R / 50 ^ 6 ^ H / 2, where R and H have the indicated values.
    Sy_ ™> JJLAQ97SL
    1 1190979 2
    类似技术:
    公开号 | 公开日 | 专利标题
    SU1190979A3|1985-11-07|Self-cleaning extruder
    US4215978A|1980-08-05|Resin moulding screws
    US3164375A|1965-01-05|Apparatus for intensive mixing
    US4173417A|1979-11-06|Extrusion apparatus and method
    US6048088A|2000-04-11|Multi-shaft screw-type extruder, in particular twin-shaft extruder
    US4136969A|1979-01-30|Mixing apparatus
    KR100265690B1|2000-10-02|Twin-screw kneading apparatus
    CA1213115A|1986-10-28|Controlled shear cold-feed mixture extruder
    US4131371A|1978-12-26|Co-rotating multiple screw processor
    US5798077A|1998-08-25|Screw for plasticating apparatus and method of use
    KR900001957B1|1990-03-27|Cavity transfer mixing extruder
    US3751015A|1973-08-07|Screw extruder with radially projecting pins
    US3085288A|1963-04-16|Material treating apparatus
    US5318357A|1994-06-07|Extruder injection apparatus
    EP2093037B1|2011-08-03|Kneading disc segment and twin-screw extruder
    US5516205A|1996-05-14|Twin extruder
    US4356140A|1982-10-26|Extrusion method with short cycle multichannel wave screw
    US4444507A|1984-04-24|Apparatus and method for melting and conveying plasticated material
    CA1204431A|1986-05-13|Rotary processor
    US3721427A|1973-03-20|Extruder for working on thermoplastic materials and non-cross-linked elastomeric materials
    Potente et al.1990|Throughput characteristics of tightly intermeshing co-rotating twin screw extruders
    US6106142A|2000-08-22|Pressure variable, multiscrew, continuous mixing machine for plasticizable compounds with variable height backfeed threads
    US10350809B2|2019-07-16|Plastic processing screw
    EP1093905A2|2001-04-25|Twin screw extruder with mixing screw elements
    US5975449A|1999-11-02|Extrusion micro-mixing
    同族专利:
    公开号 | 公开日
    DE2861917D1|1982-08-12|
    AU4171278A|1979-05-24|
    IT7829902D0|1978-11-17|
    CA1124973A|1982-06-08|
    EP0002131B2|1987-04-22|
    MX150779A|1984-07-16|
    JPS5472265A|1979-06-09|
    US4300839A|1981-11-17|
    WO1979000305A1|1979-05-31|
    JPS5829733B2|1983-06-24|
    EP0002131A1|1979-05-30|
    IT1101116B|1985-09-28|
    AU520866B2|1982-03-04|
    EP0002131B1|1982-06-23|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE4239220A1|1992-11-21|1994-05-26|Blach Verfahrenstechnik Gmbh|Efficient lower-wear design of equi-pitch double-screw extruder - has three flights on all identical screws whose crests differ in their width and distance from barrel wall|
    RU2496643C2|2008-06-20|2013-10-27|Байер Матириальсайенс Аг|Method of plastics extrusion|
    RU2500533C2|2008-06-20|2013-12-10|Байер Интеллектуэль Проперти Гмбх|Screws for extrusion of plastics|
    RU2522624C2|2008-06-20|2014-07-20|Байер Интеллектуэль Проперти Гмбх|Screw elements with reduced ridge inclination|
    RU2550175C2|2009-12-18|2015-05-10|Байер Интеллектуэль Проперти Гмбх|Auger elements for extrusion of viscoelastic compounds, application and process|DE14109C|W. C. BROWN in Sheffield, England|Innovations in devices or apparatus to keep bodies floating in water|
    US3104420A|1960-12-06|1963-09-24|Gerhard Kestermann K G|Masticator for plastic materials|
    DE1554751B1|1966-09-10|1971-01-07|Kestermann Maschf Rolf|Screw extruder|
    DE1802593B2|1968-10-11|1971-12-02|DOUBLE SCREW PRESS FOR PLASTICS|
    JPS498936B1|1968-10-21|1974-03-01|
    FR2093483A5|1970-05-08|1972-01-28|Plast Elastverarbeitungsmasch|
    US3900187A|1973-10-29|1975-08-19|Baker Perkins Inc|Continuous mixing and/or kneading machine with co-wiping single lead screws|
    DE2446436A1|1974-09-28|1976-04-08|Bayer Ag|MULTI-SHAFT SCREW MACHINE|
    US4131371A|1977-08-03|1978-12-26|E. I. Du Pont De Nemours And Company|Co-rotating multiple screw processor|DE3038973A1|1980-10-15|1982-05-27|Bayer Ag, 5090 Leverkusen|METHOD AND DEVICE FOR CRYSTALLIZING MELT WITH SIMULTANEOUS CRUSHING|
    JPS59134627U|1983-02-28|1984-09-08|
    IT1279683B1|1995-11-10|1997-12-16|Babbini & C Sas Flli|SCREW DEHYDRATING PRESS|
    IT1282578B1|1996-02-07|1998-03-31|Pomini Spa|PROCESS AND MACHINE FOR THE MIXING WITH CONTINUOUS LAMINATION OF THERMOPLASTIC MATERIAL|
    US6062719A|1996-09-24|2000-05-16|The Dow Chemical Company|High efficiency extruder|
    EP0934151A1|1996-09-24|1999-08-11|The Dow Chemical Company|Multiple-screw extruder|
    JP3499414B2|1996-12-24|2004-02-23|株式会社神戸製鋼所|Twin screw kneader|
    DE19950917A1|1999-10-21|2001-04-26|Degussa|Twin screw extruder with new screw elements|
    US6783270B1|2000-07-31|2004-08-31|Steer EngineeringLimited|Fractional and higher lobed co-rotating twin-screw elements|
    DE10114727B4|2001-03-22|2005-05-12|Berstorff Gmbh|Worm element for co-rotating multi-screw extruder|
    DE10122462C1|2001-05-09|2002-10-10|3 & Extruder Gmbh|Screw extruder has at least three parallel, intermeshing screws and casing with apertures in its side|
    DE10143570A1|2001-09-05|2003-03-20|Buehler Ag|Degassing of flowable masses in a multi-screw extruder|
    DE10233214B4|2002-07-22|2005-01-27|3+Extruder Gmbh|Extruder for continuous processing and / or processing of flowable materials|
    DE10233213B4|2002-07-22|2004-09-09|3+Extruder Gmbh|extruder|
    DE102004003448B3|2004-01-22|2005-11-10|Nestle S.A.|Deep-temperature extrusion process for microstructuring frozen, aerated masses, such as ice cream, and cryogenic extrusion apparatus for carrying out this process|
    US7390118B2|2004-10-15|2008-06-24|Husky Injection Molding Systems Ltd.|Extruder assembly|
    DE102004052055B4|2004-10-26|2014-11-20|Blach Verwaltung Gmbh & Co.Kg|extruder|
    DE102005053907B4|2005-11-11|2009-05-20|Blach Verwaltung Gmbh & Co.Kg|Multi-screw extruder|
    EP1832281A1|2006-03-10|2007-09-12|Abbott GmbH & Co. KG|Process for producing a solid dispersion of an active ingredient|
    DE102008016862C5|2008-04-02|2019-12-19|Blach Verwaltungs Gmbh & Co. Kg|extruder|
    US8783939B2|2009-07-16|2014-07-22|Blach Verwaltungs Gmbh & Co. Kg|Extruder|
    JP5318709B2|2009-08-26|2013-10-16|ポリプラスチックス株式会社|Screw element piece and screw|
    AT509710B1|2010-03-24|2011-11-15|Josef Ing Blach|EXTRUDER|
    CN102259416A|2011-05-31|2011-11-30|四川金鑫螺杆成套设备有限公司|Triple thread element and double-screw extruder using same|
    AT512974B1|2012-05-23|2015-02-15|Josef A Ing Blach|Multi-screw extruder|
    EP3013551B1|2013-06-24|2018-03-21|Covestro Deutschland AG|Screw elements for multi-screw machines and method of producing same|
    DE102014219706B3|2014-09-29|2016-03-31|Battenfeld-Cincinnati Austria Gmbh|extruder screw|
    CN104527025B|2014-12-29|2017-05-17|广东轻工职业技术学院|Same-direction self-cleaned twin-screw extruder with baffle plates and processing method thereof|
    AT519286B1|2016-10-19|2018-12-15|Gruber Dietmar|TWIN SCREW EXTRUDER|
    WO2020173729A1|2019-02-27|2020-09-03|Covestro Intellectual Property Gmbh & Co. Kg|Screw element having an axially asymmetrical screw profile which has at least two construction points located within the screw profile|
    FR3093459A1|2019-03-06|2020-09-11|Compagnie Generale Des Etablissements Michelin|Temperature Management of Rubber Mixtures Coming Out of a Conical Conical Twin Screw Mixer|
    FR3093456A1|2019-03-06|2020-09-11|Compagnie Generale Des Etablissements Michelin|Outlet Mechanism of a Conical Conical Twin Screw Mixer|
    FR3093457A1|2019-03-06|2020-09-11|Compagnie Generale Des Etablissements Michelin|Twin Screw Mixing and Extrusion Machine with Removable Elements|
    FR3093458A1|2019-03-06|2020-09-11|Compagnie Generale Des Etablissements Michelin|Self-Cleaning Twin Screw Extrusion and Mixing Machine and Method of Use|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    JP52139248A|JPS5829733B2|1977-11-19|1977-11-19|
    [返回顶部]