阅读说明：本技术 具有渐缩式锥形双螺杆的混合器的输出机构 (Output mechanism of mixer with tapered double screw ) 是由 B·迪萨尔迪耶 A·图尔内彼茨 T·亚布洛涅 R·齐拉沃 于 2020-01-28 设计创作，主要内容包括：用于制造橡胶混合物的混合挤出机器(10),包括具有渐缩式锥形双螺杆的混合器(12),所述混合器(12)具有支撑套筒(16)的固定架(14)。以一定角度安装的两个螺杆(18)在所述混合器(12)中以如下方式安装：使得以平移移动的方式在布置于套筒的上游的开口(22)与布置于套筒的下游的出口(25)之间移动。螺杆与可移动门一起安装于套筒中,所述可移动门包括相对于出口(25)安装的滑动式窗板(40)。滑动式窗板在关闭位置与打开位置之间线性移动,在所述关闭位置时所述滑动式窗板防止混合器排出混合物,在打开位置时所述滑动式窗板防止混合物从就位于出口下游的辊鼻型系统的两个反向旋转辊(32)的侧面排出。(A mixing-extrusion machine (10) for manufacturing rubber mixtures, comprising a mixer (12) with tapered twin screws, said mixer (12) having a holder (14) supporting a sleeve (16). Two screws (18) mounted at an angle are mounted in the mixer (12) in the following manner: so as to move in a translational movement between an opening (22) arranged upstream of the sleeve and an outlet (25) arranged downstream of the sleeve. The screw is mounted in the sleeve together with a movable door comprising a sliding shutter (40) mounted relative to the outlet (25). The sliding louvers move linearly between a closed position, in which the mixer is prevented from discharging the mixture, and an open position, in which the sliding louvers prevent the mixture from being discharged from the sides of two counter-rotating rollers (32) of a roller-nose system located immediately downstream of the outlet.)

1. A mixing-extrusion machine (10) for producing rubber mixtures, said machine (10) comprising: a tapered conical twin-screw mixer (12) having a mount (14) supporting a sleeve (16), two screws (18) being mounted angularly in the sleeve (16) between an opening (22) provided upstream of the sleeve, at which opening (22) an intake hopper (24) of the machine (10) feeds the screws, and an outlet (25) provided downstream of the sleeve, at which outlet (25) the mixer (12) discharges the mixture at the end of the mixing cycle; one or more motors (20) that rotate the two screws in the barrel during a mixing cycle; and one or more movable gates arranged at said outlet (25) so as to cause the rubber mixture to be discharged and shaped during a mixing cycle, wherein:

the screw is mounted in the sleeve (16) together with a movable door conforming to the shape of the screw, the movable door comprising a sliding shutter (40), the sliding shutter (40) being mounted with respect to the outlet (25) such that it moves linearly between a closed position, in which it prevents the mixture from leaving the mixer (12), and an open position, in which it prevents the mixture from being discharged from the sides of two counter-rotating rollers (32) of a roller-nose system arranged immediately downstream of the outlet (25), so as to force the mixture to pass between the two rollers and form a sheet of mixture discharged from the mixer (12) with a predetermined thickness and width.

2. Machine (10) according to claim 1, further comprising a plunger (30) having an inner surface (30a) with a shape complementary to the outer profile of the two screws (18), which moves within the intake hopper (24) between a raised position, in which the two screws remain accessible for introducing the mixture, and a lowered position, in which the inner surface (30a) of the plunger forms the upper part of the mixer (12).

3. The machine (10) of claim 1 or claim 2, further comprising one or more movable sleeves (34) arranged in a top-down pattern towards the outlet (25), each movable sleeve having a support surface with a predetermined surface area according to the elasticity of the mixture, and the movable sleeves (34) comprising movable elements that move by linear movement relative to the outlet (25) to adjust a predetermined space between the sleeves and the screw, the linear movement being defined between a closed position of the movable sleeves to facilitate mixing and an open position of the movable sleeves to facilitate flow of the mixture within the mixer.

4. A machine (10) as set forth in any of claims 1-3, wherein the screws (18) are mounted in the mixer (12) such that a crest of each screw flight is tangential to a surface of the opposing screw such that the screws remain substantially in contact with each other when the screws are rotated at an angle and center distance that promotes self-cleaning.

5. The machine (10) of claim 4, wherein the screw (18) is selected from the group consisting of an interpenetrating and a conjugate profile, including an interpenetrating conjugate profile having a conjugate profile.

6. The machine (10) of any of claims 1 to 5, wherein the sleeve (16) includes cooling channels to manage the temperature of the mixture during the mixing cycle.

7. A mixing method comprising the step of mixing and extruding a rubber mixture from the machine (10) of any one of claims 1 to 6, the method comprising the steps of:

a step of rotating the screw (18) forward with the sliding window panel (40) closed;

a step of introducing the mixture into the machine (10), during which the screw (18) continues to rotate and the sliding shutter (40) remains closed; and

a step of emptying of the machine (10) during which the sliding shutter (40) is opened to discharge the mixture from the outlet (25) of the machine towards the downstream process, and in which the screw continues to rotate until the mixer is emptied.

8. The method of claim 7, wherein the step of introducing the mixture into the machine (10) includes introducing raw materials to form the mixture.

9. The method of claim 7, wherein the step of introducing the mixture into the machine (10) includes introducing one or more masterbatches.

10. The method of any of claims 7 to 9, wherein:

the sliding shutter (40) is in the closed position at the beginning of the mixing cycle and in the open position at the end of the mixing cycle; and

the movable sleeve (34) is in an open position at the beginning of the mixing cycle and in a closed position at the end of the mixing cycle.

Technical Field

The invention relates to a mixer used in the field of production of rubber mixtures. More particularly, the present invention relates to the output mechanism of a mixer having a tapered conical screw to maintain the closure and sealing of the mixer.

Background

In the field of the production of rubber mixtures, screw mixing extrusion machines already exist. These machines include twin screw extruders, each having a frame with the usual assembly components. The assembly components may include, but are not limited to, a sheath screw assembly (with or without optional heating and cooling fittings), a drive unit (gearbox and coupling), a main motor, a material supply device (e.g., a gauge or hopper) or processing device (e.g., a degasser), a cutting or shaping device for the extruded material, and, if applicable, a control cabinet to which the motor's drives, start-up and safety devices, and control, command, display and measurement devices are connected. Examples of Twin-Screw extruders are described in the publication "Extrusion-Twin-Screen Extrusion Processes" by Bruno Vergnes and Marc Chapet (published by Techniques de l' Ing nieur, trail Plastic et compositions ("the Vergnes/Chapet reference"), 1, 10.2001).

The frame often includes a manual or auxiliary sleeve opening device to provide easy access to the screw for cleaning, inspection and/or maintenance. The most common opening systems include a sliding device (e.g., of the type commercially provided by Colmec and Pomini TDE) that slides a sleeve relative to a screw. There are also "combined" opening systems (commonly known as Farrel continuous mixers, or "FCMs") in which a sheath is hinged around a transverse hinge. The sleeve screw assembly is an active part, ensuring the handling of the material. The sheath is a housing. The sleeve is temperature regulated by a combination of a heating system (usually electric, controlled by a temperature control probe) and a cooling system (usually with water circulation). Within the sheath, two rotating screws eat the material and move it forward.

A commonly used screw mixing extrusion machine consists of a rotor (i.e. screw) and a stator (i.e. sleeve). Us patent 7,556,419 describes such a machine, which shows an example of a tapered conical twin screw machine with a movable door closing the outlet. This type of mixer makes it possible to combine the mixing phase of the raw materials with the discharge phase of the mixture thanks to a movable gate at the outlet, arranged at the end of the screw. The movable door closes and locks during the mixing cycle, preventing the mixture from leaving the machine. When the mixing cycle is complete, the movable door unlocks and opens. Rotation of the screw then moves the product forward in the machine.

To maintain the mixer closed and sealed, the disclosed invention combines the advantages of a tapered conical twin-screw mixer with the advantages of a movable door with sliding louvers. By using sliding louvers, the disclosed invention enables control of the shape and size of the product as soon as it leaves the mixer. This type of mixer can be equipped at the outlet with a roller-nose type system that will cause the discharge of the product in sheet form.

Disclosure of Invention

The present invention relates to a mixing and extrusion machine for producing rubber mixtures, said machine comprising: a tapered conical twin-screw mixer with a mount supporting a sleeve in which two screws are mounted angularly between an opening arranged upstream of the sleeve, where the introduction hopper of the machine feeds the screws, and an outlet downstream of the sleeve, where the mixer discharges the mixture at the end of the mixing cycle; one or more motors that rotate two screws in a barrel during a mixing cycle; and one or more movable gates disposed at the outlet to cause the rubber compound to be discharged and shaped during the mixing cycle. The screw is mounted in the sleeve with a movable door at the end, which conforms to the shape of the screw, the movable door being a sliding shutter mounted relative to the outlet such that the sliding shutter moves linearly between a closed position, in which it prevents the mixture from exiting the mixer, and an open position, in which it prevents the mixture from escaping from the sides of two counter-rotating rollers of a roller-nose system arranged immediately downstream of the outlet, to force the mixture to pass between the two rollers and form a sheet of mixture of predetermined thickness and width exiting the mixer.

In an embodiment of the machine, the machine further comprises a plunger having an inner surface of a shape complementary to the outer profile of the two screws, the plunger being movable within the introduction hopper between a raised position, in which the two screws remain accessible for introducing the mixture, and a lowered position, in which the inner surface of the plunger forms the upper part of the mixer.

In some embodiments of the machine, the machine further comprises one or more movable sleeves disposed above and below the outlet towards the outlet, each movable sleeve having a support surface with a predetermined surface area according to the elasticity of the mixture, and the movable sleeves comprising movable elements that move by linear movement relative to the outlet to adjust a predetermined space between the sleeve and the screw, the linear movement being defined between a closed position of the movable sleeve that facilitates mixing and an open position of the movable sleeve that facilitates flow of the mixture within the mixer.

In some embodiments of the machine, the screws are mounted in the mixer such that the crest of each thread of each screw tangentially contacts the surface of the opposing screw, such that the screws remain substantially in contact with each other when the screws are rotated at an angle and center distance that allows for self-cleaning. In one embodiment, the screw is selected from the group consisting of interpenetrating and conjugate profiles, including interpenetrating conjugate profiles having conjugate profiles.

In some embodiments of the machine, the sleeve includes cooling channels to manage the temperature of the mixture during the mixing cycle.

The invention also relates to a mixing method comprising the steps of mixing and extruding a rubber mixture from the disclosed machine. The method comprises the following steps:

-a step of rotating the screw forward with the sliding window panel closed;

-a step of introducing the mixture into the machine, during which the screw continues to rotate and the sliding shutter remains closed; and

-a step of machine emptying, during which the sliding shutter opens to release the mixture from the machine outlet towards the downstream process, and the screw continues to rotate until the mixer is emptied.

In an embodiment of the method, the step of introducing the mixture into the machine comprises introducing raw materials to form the mixture.

In an embodiment of the method, the step of introducing the mixture into the machine comprises introducing one or more masterbatches.

In some embodiments of the method, the sliding louvers are in a closed position at the beginning of the mixing cycle and in an open position at the end of the mixing cycle; the movable sleeve is in the open position at the beginning of the mixing cycle and in the closed position at the end of the mixing cycle.

Other aspects of the invention will become apparent from the detailed description below.

Drawings

The nature and various advantages of the present invention will become more apparent upon reading the following detailed description (in which like reference numerals refer to like elements throughout) in conjunction with the accompanying drawings, in which:

figure 1 shows a perspective view of the mixing and extrusion machine of the present invention.

Figure 2 shows a partial cross-sectional side view of the machine of figure 1 with a tapered conical twin screw mixer.

Figure 3 shows a partial cross-sectional front view of the plunger in the lowered position in the machine of the present invention.

Fig. 4 shows a partial cross-sectional side view of the mixer of fig. 2 including a movable sleeve.

Fig. 5 and 6 show partial front views of the machine of fig. 4 with the sliding louvers in a closed position and an open position, respectively.

Detailed Description

Referring now to the drawings, in which like numerals refer to like elements, FIGS. 1 and 2 illustrate a compounding screw extrusion machine (or "machine") 10 of the present invention. The machine 10 includes a tapered conical twin screw mixer (or "blender") 12 suitable for rubber materials. The mixer 12 includes a mount 14, the mount 14 supporting a stationary sleeve (or "sleeve") 16 in which two screws 18 are mounted. During the mixing cycle, one or more motors 20 rotate two screws in the barrel 16. The upper surface of the holder 14 comprises a guide (not shown) on which the sleeve 16 (without the screw 18) can move in a translational movement. The mixer 12 is selected from commercially available mixers, including mixers of the type disclosed by us patent 7,556,419 and proposed by Colmec s.p.a. In embodiments, this type of mixer achieves mixing and discharge by an archimedes-type screw.

Machine 10 may include an optional conveyor (e.g., conveyor belt 26 shown in fig. 2) known to the skilled artisan to introduce the components through an introduction hopper 24. The components are represented by a mixture M which is conveyed by a conveyor belt 26 (see arrow a in fig. 2). These components may include all types of components required to make a rubber product. During the mixing cycle, a conveyor belt 26 (or other equivalent means) is used to continuously introduce the raw materials and other necessary ingredients according to a predetermined recipe.

The screw 18 is mounted in the sleeve 16 at an angle between an opening 22 upstream of the sleeve, where an intake hopper 24 of the machine 10 feeds the screw 18, and an outlet 25 downstream of the sleeve, where the mixer 12 discharges the mixture at the end of the mixing cycle. The sleeve 16 may include known cooling channels for managing the temperature of the mixture. The profile of the inner surface 16a of the sleeve 16 is predetermined, which makes it possible to determine the distance between each thread and the inner surface of the respective sleeve, and thus the shear rate at the inner surface of the sleeve. Similarly, the crests of the screw threads tangentially contact the inner surface of the sleeve, preventing any retention of the mixed material on these surfaces.

In embodiments of the screw 18, the screw is selected from tooth profiles known for their self-cleaning properties, including interpenetrating and conjugate tooth profiles (especially interpenetrating, co-rotating tooth profiles with conjugate tooth profiles). In other words, the screws may substantially contact each other at an angle and center distance that achieves self-cleaning. Screws are considered to be "substantially in contact" when they can be cleaned by friction, or when the gap between two screws facing each other is so small that the extruded material cannot remain adhered to the surface of the screws. Screws are said to rub against each other or "self-clean" when material conveyed in a channel of one of the screws cannot stay in that channel for more than one revolution of the screw. The result is that the material moves more in the downstream direction parallel to the axis of the screw than in the transverse direction perpendicular to the axis. Patents EP0160124B1, EP0002131B1, US 4,300,839, US 4,131,371 and US 6,022,133 and publication WO2016/107527 disclose examples of self-cleaning screws.

With further reference to fig. 1 and 2 and 3, the machine 10 also includes a plunger (or equivalent movable presser) 30 that moves within the introduction hopper 24. The plunger 30 is similar to those used in mixing methods such as those implemented by banbury-type internal mixers (as disclosed by, for example, patents US1,370,398 and US7,404,664). As with these internal mixers, the ram 30 is used to extrude and apply pressure to the mixture during the manufacturing process. Thus, the plunger 30 allows more energy and shear to be imparted to the mixture, thereby improving the processing of the rubber.

The inner surface 30a of the plunger 30 has a shape complementary to the outer profile of the two screws 18. The guiding of the plunger 30 is achieved between a raised position (represented by fig. 2), in which the two screws 18 remain accessible for introducing the mixture, and a lowered position (represented by fig. 3), in which the inner surface 30a of the plunger 30 forms the upper part of the mixer 12. The guiding of the plunger 30 (e.g. driven by a cylinder which may be pneumatic, hydraulic or equivalent) is achieved by known sliding systems such as those used with banbury plungers. Thus, in the lowered position, the plunger 30 leaves only a very small clearance between the crests of the threads of the screw 18 and its inner surface 30 a.

Referring again to fig. 1 and 2, the machine 10 includes a roller nose type system. Patents FR1563077, FR2282993 and FR3001654 disclose examples of roller-nose type systems. Patents JP4294005 and US8,517,714 disclose examples of roller-nose type systems used at the outlet of tapered conical twin-screw extrusion machines.

The roller-nose type system of the present embodiment includes two counter-rotating rollers 32 disposed just downstream of the outlet 25 to form a sheet of the mixture exiting the mixer 12. The roller nose system may also include an optional control device (not shown) to control the rate at which the mixture is fed to the rollers. The rotation of the roller 32 is controlled (for example, detected by a proximity sensor, a pressure sensor or equivalent means) according to the quantity of mixture supplied by the mixer 12.

With further reference to fig. 1-3 and 4, the machine 10 combines the advantages of the screw 18 and plunger with one or more movable sleeves (such as the movable sleeve 34 shown in fig. 4). It will be appreciated that other modes of the movable sleeve known (e.g. side-to-side and angled modes) may be used (see also the examples disclosed in publications WO2009057753 and JPH 0550425). The movable sleeve 34 includes a movable element to adjust a predetermined space between the sleeve 16 and the screw 18. Each movable sleeve has a support surface with a predetermined surface area depending on the elasticity of the mixture. It will be appreciated that the removable sleeves having different surface areas are interchangeable to ensure use of the machine without having to replace it.

The illustrated embodiment includes two moveable sleeves 34, but it is understood that only one moveable sleeve (or other equivalent element) or multiple moveable sleeves (or other equivalent elements) may be integrated (e.g., in a top-down mode, a side-to-side mode, or an angular mode). The movable sleeve 34 adjusts the space between the sleeve and the screw to facilitate the flow of the mixture within the mixer 12 so that the duration and degree of mixing of the mixture can be adjusted.

The two screws 18 circulate the mixture from the upstream side (near the intake hopper 24) to the downstream side of the movable sleeve 34 where the machine 10 is mounted. The movable sleeve 34 is mounted relative to the outlet 25 of the mixer 12 such that in the open position, the movable sleeve 34 allows the mixture to be discharged to the roller 32 of the roller-nose system. The movable sleeve can be moved in an alternating or random manner in order to reduce the space between the screw and the support surface in a random manner, thus creating a mixing flow from downstream to upstream and preferably at the top or bottom. For example, in the manner in which machine 10 is used, when the mixture has a high viscosity, movable sleeve 34 is normally in an open position at the beginning of the mixing cycle (to facilitate mixture flow), and when the mixture has a lower viscosity, movable sleeve 34 is normally in a closed position at the end of the mixing cycle (to facilitate mixing). The guiding of the movable sleeve 34 is performed by known systems (for example actuated by a cylinder which may be pneumatic, hydraulic or equivalent). The linear movement of the movable sleeve 34 is controlled (for example, detected by a proximity sensor, pressure sensor or equivalent means) according to the amount of mixture supplied by the mixer 12.

The use of a movable sleeve allows a large air gap from the beginning of the mixing cycle and therefore a low pressure drop despite the high viscosity. The product to be extruded or mixed passes through the space left by the volume difference between the screw and its barrel. These spaces, and more particularly the spaces left between the crests of the screw thread and the crests of the sleeve thread (taking into account the minimum internal diameter if the sleeve is not threaded), are important for the product being worked, the speed of advance of the product and any pressure inside the machine. Products that are subjected to very high pressures at the end of the screw will attempt to move to areas of lower pressure. As the product moves through the machine, it is subjected to significant shear which promotes processing and homogenization of the product. The product can be put into the cycle from the beginning.

With further reference to fig. 1-4 and 5 and 6, fig. 5 and 6 show a cross-sectional view of the sliding louvers 40 perpendicular to the outlet 25 of the mixer 12. The screw is mounted to the sleeve 16 with a movable door at the end that conforms to the shape of the screw. To shape the product, the movable door includes a sliding window panel (or "door") 40 that is interposed between the roller 32 of the machine 10 and the front of the movable sleeve 34. The sliding shutter 40 comprises a movable element that regulates the outflow of the mixture from the mixer 12. The sliding louvers 40 are mounted relative to the mixer outlet 25 such that, in the closed position (see fig. 5), the sliding louvers 40 prevent the mixture from exiting the mixer 12 (e.g., to facilitate mixing when the mixture has a low viscosity). In the open position (see fig. 6), the sliding louvers act as "ears" for the roller 32, which prevent the mixture from escaping from the sides of the roller 32. In this way, the mixture is forced to pass between the two rolls and is calendered in the form of a thin sheet of predetermined width by opening the sliding shutter.

Sliding systems known to those skilled in the art allow the sliding window panel 40 to slide between a closed position (see arrow in fig. 5) and an open position (see arrow in fig. 6) without moving a rearward located cylinder. The illustrated embodiment includes two sliding louvers 40, but it is understood that only one sliding louver (or other equivalent element) or a plurality of sliding louvers (or other equivalent elements) may be integrated (e.g., in an up-down mode, a left-right mode, or an angular mode). The sliding window panel 40 is guided by known systems (e.g., actuated by a cylinder, which may be pneumatic, hydraulic, or their equivalents). The linear movement of the sliding shutter 40 is controlled (e.g., detected by a proximity sensor, pressure sensor, or equivalent device) in accordance with the amount of mixture supplied by the mixer 12. The sliding shutter 40 may be partially or fully opened during the mixing cycle.

In embodiments of the machine 10, locking systems known to the skilled person may be added to improve the closing of the sliding window panel 40 and thus the sealing thereof.

The use of rollers 32 to produce the sheet optimizes the emptying of the machine 10. In fact, both rollers exert a stretching force on the discharged product, both by adhesion of the product to the roller 32 and by the "angle of retraction" effect. The stretching potential of the rolls makes it possible to empty completely from the zone between the end of the screw and the roll gap even when the product is no longer pushed by the screw 18.

With reference to fig. 1 to 6, a detailed description is given as an example of the period of the hybrid method of the present invention. It should be understood that the method may be readily adapted to all of the various embodiments of machine 10.

After the start of the cycle of the mixing method of the present invention, the mixing method includes the step of rotating the screw 18 forward with the sliding shutter 40 closed (see fig. 5). During this step, once the mixture (or raw material) is introduced into the machine 10, the rotating screw moves the product downstream of the mixer. In all embodiments of machine 10, the rotational speed is variable during the cycle.

The mixing method comprises the step of introducing the mixture M into the machine 10 (conveyed by the conveyor belt 26 as indicated by the arrow a in figure 2). During this step, the screw 18 continues to rotate and the sliding window panel 40 remains closed. During this step, the plunger 30 remains in the raised position, the roller 32 remains inactive and the movable sleeve 34 remains in the open position (i.e. with the space between the sleeve and the screw at a maximum) (see fig. 4).

The step of introducing the mixture into the machine 10 may be carried out by: the various raw materials required to produce the product, including but not limited to elastomeric materials (e.g., natural rubber, synthetic elastomers, combinations thereof and equivalents) and one or more ingredients (e.g., one or more processing agents, protective agents and reinforcing loads) are introduced into the empty machine. The raw materials may also include one or more other ingredients such as carbon black, silica, oils, resins, and crosslinking or vulcanizing agents. All ingredients are introduced in different amounts depending on the desired properties of the product (e.g. a tyre) obtained from the mixing process.

The step of introducing the mixture into the machine 10 can also be accomplished by starting the cycle with a product that has been mixed but does not contain all the ingredients of the formulation (known as a "masterbatch"). For example, no resin and curing agent are present in the masterbatch. These ingredients that make mixing difficult can be added to mixer 12 to complete the mixing. In this case, the masterbatch is thermally recovered from an upstream mixer (such as a closed or open mixer), or the masterbatch is cold (as it has been made and packaged hours or even days in advance).

During the mixing cycle, machine 10 (or a system including machine 10) may be trained to identify and compare values (e.g., temperature and viscosity values) representative of the mixture exiting mixer 12 to target values. Such machine training includes identifying non-equal values between the compared values. Each step of training may include a classification generated by an autonomous learning approach. Such classifications may include, but are not limited to, parameters of the raw materials and masterbatches of the selected mixing recipe, screw configuration (archimedes screw or self-cleaning screw), process cycle time, and values expected at the end of the ongoing cycle (e.g., values of the space between the sleeve and the screw during the current mixing cycle, etc.).

During the step of introducing the mixture into the machine 10, the conveyor belt 26 (or other equivalent means) is used to continuously introduce the necessary raw materials and other ingredients according to a predetermined recipe. In one embodiment, the elastomeric material is introduced into the machine 10, followed by the reinforcing filler (e.g., carbon black or silica), oil, resin, and vulcanizing agent.

In one embodiment, the mixing method includes the step of lowering the plunger after the step of introducing the mixture into the machine 10. During this step, the screw 18 continues to rotate and the roller 32 remains inactive.

The mixing method comprises the step of partially closing the movable sleeve 34 (two movable elements at the same time or two movable elements alternated). Partial closure of the moveable sleeves may refer to their reciprocal or simultaneous movement. During this step, the screw continues to rotate and the plunger remains lowered.

In an embodiment, the mixing method comprises the step of raising the plunger. During this step, the roller 32 remains inactive and the movable sleeve 34 is in a partially closed position. During this step, the screw 18 continues to rotate.

The mixing method includes the step of reversing the screw 18 with the sliding window 40 closed (see fig. 5). During this step, the screw 18 rotates in the opposite direction to that assumed by the screw during the step of rotating the screw forward. The entire mixture located in the machine 10 moves downstream towards the upstream part of the machine, which causes additional distribution of the raw material. During this step, the plunger 30 remains raised, the roller 32 remains inactive and the movable sleeve 34 remains partially closed.

The mixing method includes the step of rotating the screw forward with the sliding window panel 40 closed. During this step, the screw 18 is rotated in the opposite direction to the step of reversing the rotation of the screw. During this step, the plunger 30 remains raised, the roller 32 remains inactive and the movable sleeve remains partially closed.

In one embodiment, the mixing method includes the step of lowering the plunger after the previous step of rotating the screw 18 forward. During this step, the screw 18 continues to rotate, the roller 32 remains inactive and the movable sleeve 34 remains partially closed.

The mixing method includes the step of fully closing the movable sleeve 34, thereby eliminating the gap between the sleeve 16 and the screw 18. This step comprises closing both movable elements simultaneously or alternately. During this step, the plunger 30 is raised again, the screw 18 continues to rotate and the roller 32 remains inactive. During this step, the sliding window panel 40 may be partially or fully opened so that some or all of the mixture is extruded in the form of a sheet. The extruded sheet may go to one or more conveying systems, such as those described in patent FR3045173, before being returned to the mixer 12 through the intake hopper 24 during the mixing cycle.

The mixing method includes a final step of emptying the machine 10. During this step, the sliding shutter 40 opens to discharge the mixture from the outlet 25 of the machine towards the downstream process (see fig. 6). In embodiments of machine 10 in which the sliding window panel comprises two or more movable elements, this step comprises opening the movable elements simultaneously or alternately. During this step, the plunger is lowered and the roller 32 is rotated so that the mixture is discharged in the form of a sheet. The movable sleeves 34 remain completely closed, but they can be adjusted according to the volume of mixture discharged from the mixer. During this step, the screw 18 continues to rotate to completely empty the machine 10 and take the mixture out in the form of sheets to downstream processes.

At the end of the mixing cycle, the product is completely mixed and available for downstream processing (e.g., may be a palletizing process, a forming process, and/or other mixing processes (e.g., an extrusion process)). After the step of emptying the machine 10 is finished, the mixing method cycle may be restarted.

The fact that only a portion of the mixture can be discharged makes it possible to improve the homogenization capacity of the mixer 12 by interrupting the internal flow of the machine and by promoting the contact between the portions of product during mixing. At the end of the mixing cycle, the sliding louvers may be fully opened so that the machine 10 may be completely emptied. The sheet form product may then be transported to downstream processes.

It will be appreciated that certain steps of the cycle, as well as the cycle itself, may be performed in an iterative manner depending on the mixture recipe selected.

It should also be understood that machine 10 may operate independently or it may be part of one or more systems that comprise a production plant.

It is contemplated that machine 10 may be capable of performing one or more processes involving the plasticizing of natural elastomers.

The method cycle may be performed by PLC control and may include pre-programming of control information. For example, method settings may be associated with the mix supplied to the mixer 12, including the characteristics of the screw 18, the characteristics of the mix entering the intake hopper 24, and the characteristics of the mix exiting the mixer. The adjustment may be, for example, opening (partially or fully) and closing (partially or fully) of the sliding window panel 40.

For all embodiments of machine 10, the monitoring system may be placed in a suitable location. At least a portion of the monitoring system may be disposed in a portable device, such as a mobile network device (e.g., a mobile phone, a portable computer, one or more networked portable devices (including augmented reality and/or virtual reality devices), networked portable apparel, and/or any combination and/or equivalent thereof).

In some embodiments of the present invention, machine 10 (and/or a system including machine 10) may receive voice instructions or other audio data indicative of, for example, the start or stop of rotation of screw 18. The request may include a request for a current state of the hybrid method cycle. The generated response may be represented in an audible, visual, tactile (e.g., using a tactile interface), and/or virtual or augmented manner.

In some embodiments of the present disclosure, machine 10 (and/or a system including machine 10) may receive voice instructions or other audio data indicative of, for example, a step or stop in the rotation of screw 18. The request may include a request for a current state of the hybrid method cycle. The generated response may be represented in an audible, visual, tactile (e.g., using a tactile interface), and/or virtual or augmented manner.

The invention maintains all the advantages of a mixer equipped with a tapered conical twin-screw mixer in order to obtain a mixture with the desired characteristics. At the same time, the present invention incorporates a sliding window panel solution to provide a single machine that is capable of handling multiple mixes without changing the equipment in the mixing facility.

The terms "at least one" and "one or more" are used interchangeably. The range denoted "between a and b" includes the value "a" and the value "b".

While particular embodiments of the disclosed apparatus have been illustrated and described, it will be appreciated that various changes, additions and modifications may be made without departing from the spirit and scope of the present disclosure. Accordingly, no limitation should be imposed on the scope of the described invention, other than that set forth in the appended claims.