SE1300556A1 - A multifunctional module - Google Patents

Abstract

The present invention relates to a multifunctional module comprising at least one unit, at least one inlet, and at least one outlet, wherein the at least one unit is selected from the group consisting of filter units, membrane units, reactor-separator units, extraction units, and mixing units, and wherein each unit in the group of units have at least one member having an active surface, on which active surface processes take place, which member rotates about an axis, one or more chambers rotate together with the rotating member and fluids from the active surface of the member are collected in one or more of the the co-rotating chambers, and the units in the module are connected in parallel, or in series or both and to each other.

Description

15 20 25 30 35 hoods.

The unit operations performed in the module can be a combination of mixing, combining, reaction, separation etc. or the module can be a combination of units within the same unit operation, the module can thus for example separate different fractions of a mixture within a module having different separation units . A module according to the invention can as an alternative carry out single-stage or multi-stage synthesis, i.e. be a combination of reactor units and separation units etc. The rotating multifunctional module according to the invention comprises units that work in different ways, e.g. a reactor unit in the module enables contacts between the reactants so that a reaction can take place. A filter unit is a unit where a filter is one of the components, a membrane unit is a similar unit. In a filter unit or a membrane unit, particles or molecules are separated from fluids. In a reactor-separator unit, reactions take place as well as separation of the product mixture.

A clarifying unit is a unit where a liquid is clarified from particles or sludge, and a purifying unit purifies, for example, a fluid. An extractor unit facilitates extraction of, for example, substances from one fluid to another or the extraction can take place to or from a gas or to or from a liquid. A contact unit can be a packed bed or a fluidized bed. A mixing unit can, for example, mix two immiscible fluids to produce, for example, an emulsion, but other kinds of mixing can also be carried out in a mixing unit.

The units of the multifunctional module according to the invention may have at least one member having a surface, which surface rotates with the member. The said surface is the surface on which the process takes place, therefore the surface is called the process surface or only the surface.

The processes can be mixing, reaction, separation, etc. The rotating member can be of the kind that rotates around an axis, such a member is for example a flat or flat disc is called here T-disc. Another example is a cone-shaped disc, which is a cone with an open end facing upwards, hereinafter referred to as a Y-disc. Yet another type of rotating member has a more complicated structure with extended surfaces, with two horizontal surfaces separated by a plurality of walls surrounding the axis of rotation and which walls diverging from a horizontal surface to the opposite horizontal surface, this kind of member is hereinafter referred to as Z-disc. Yet another kind of organ is the delta disc which has a shape like an upside down cone with the narrow end facing upwards, this kind of organ is hereinafter called the A-disc. The rotating member according to the invention can thus be selected from the group consisting of T-discs, Y-discs, Z-discs and A-discs. The active surface of the rotating member may be surfaces on the outside of the T-discs, the Y-discs, the Z-discs, or the A-discs, or the active surface may be integrated with the member in the form of one or more channels. The means which rotates about an axis during operation and works with centrifugal force, thus creating transport of products, mixing of products, separation of components, etc., and can be performed on a number of levels and with connections within the disks or between the disks. The centrifugal force causes heavier components to be transported out from the center of the organ to the circumferential edge or to only a part of the distance to the edge of the organ. The number of revolutions with which the body rotates can be adjusted to optimize the predetermined mode of operation. One or more chambers rotate together with the rotating member and collect material from the member. The chambers may surround the mantle surface of the organ, or the chamber may be below the mantle surface of the organ, or the chamber may be above the mantle surface of the organ, or the chamber may be at the mantle surface of the organ. In the chamber a stator can be arranged opposite to the rotating member according to an alternative of the invention.

The chambers may be shell chambers having one or more shell members, which may be shell discs, shell tubes or shell passages or combinations thereof. The shell passages may be closed or open, and the shell means are arranged relative to the chambers to define a surface of the fluids in the chamber at a certain predetermined level in the rotating shell chamber. The shell means can be connected to the shell chambers from below, which makes it possible to discharge fluids by means of gravity. The supply of fluids to the channels in the disc can also be arranged jointly in a shell tube, such an arrangement makes it possible to supply fluids at different levels in a disc which has several layers of channels in the disc. A shell tube for supply consists of two pipes, one for supplying fluids to the channel and one for defining the surface of the fluid to a predetermined level at an inlet part of the disc.

One or more shell discs may be centered on the axis of the rotating member and discharge fluids near the center of the surface or the shell disc may have a radius corresponding to the rotating member, and the shell disc may be a stator disposed opposite the rotating member. The shell disks can have any diameter depending on the fraction of the fluids to be discharged from the rotating disk.

The fluids can thus be pumped up through the shaft of the stator or by a rotating member of the shell discs. The module according to the present invention may also comprise one or more static separators connected to the units having rotating means. The static separators can be connected in parallel with the units, or in series, or both, to the units in the module. According to this alternative, the module may consist of one or more units having rotating members and one or more static separators. The static separators can be selected from clarification tanks, cyclones, coalescing units, contact units, filters, membranes, adsorbent means. According to a further alternative, one or more high-speed separators, or one or more decanter centrifuges, or combinations thereof, may be connected to the units in parallel, or in series, or both, to the units in the module.

The present invention also relates to a reactor unit or a mixing unit.

The reactor unit or mixing unit comprises at least one rotating member having a surface, which surface rotates with the member, and the member is selected from the group consisting of T-disks. Y-discs Z-discs, and A-discs. The rotating member of the unit rotates about an axis which causes the unit to operate by centrifugal force.

The reactor unit or mixing unit also includes one or more inlets for fluids across the member at the center of the disk at the axis or within a radial distance from the center of the disk, so that the fluids are mixed, or reacted or transported, or combinations thereof by the radial velocity to the peripheral edge of the member.

The unit further comprises one or more chambers for fluid which rotate together with the member. The chambers may surround the mantle surface of the organ, or the chambers may be below the mantle surface of the organ, or the chambers may be above the mantle surface of the organ, or the chambers may be at the mantle surface of the organ.

Alternatively, the reactor unit or mixing unit may also comprise one or more inlets for fluids at the shaft at the center of the disk which direct fluids into channels within the rotating member. The channels inside the disc go from the center to the circumference in the radial direction and lead incoming fluids to the mantle surface. This single or multiple channels may communicate with each other at one or more connection sites so that two or more fluids may mix and / or react with each other. As an alternative, the channels can be arranged on several levels in the disc. Channels at different levels can be connected so that two or more fluids can be mixed and / or react with each other. Alternatively, two or more channels at the same level may be connected so that two or more fluids are mixed and / or react with each other.

The present invention further relates to a filter unit or membrane unit comprising at least one member having a surface, which surface rotates together with the member, and the member is selected from the group consisting of T-discs, Y-discs, Z-discs or A-discs. The means rotates about an axis which causes the unit to operate under the influence of the centrifugal force, and the means comprises at least two compartments separated by a membrane or a filter or both. One or more inlets for fluids are connected across the disk surface at the shaft at the center of the disk or at a radial distance from the center, and some of the fluids pass through the filter or through the membrane and are transported by the radial velocity to the circumferential edge. The filter unit or membrane unit further comprises one or more chambers for fluids which rotate with the member. The chambers may surround the mantle surface of the organ, or the chambers may be below the mantle surface of the organ, or the chambers may be above the mantle surface of the organ or the chambers may be at the mantle surface of the organ.

As an alternative to the above-mentioned fluid chambers, the chambers may be shell chambers having one or more shell discs, shell tubes or shell passages, or combinations thereof, arranged at the surface of the fluids within one or more shell chambers. The shell passage can be closed or open. The shell plates, tubes or passages may be arranged to direct fluids out of the chambers, into one or more outlets in the radial direction from the member, into one or more outlets below the member, or into one or more outlets above the member, or through the upward axis. or downward, or combinations thereof.

The present invention also relates to a reactor-separator unit comprising at least one member having a surface, which surface rotates with the member, and the member is selected from the group consisting of T-discs, Y-discs, Z-discs, and A-discs. The member of the reactor-separator unit rotates about an axis which causes the unit to operate by centrifugal force. The unit may also include one or more inlets for fluids over the disks, but the inlets may also be below the disk. The reactor-separator unit comprises one or more shell chambers having shell tubes which shell chambers rotate with the means. The shell tubes are connected to chambers which define the surface of the fluids in the chambers. The rotating means and the co-rotating chambers are arranged on the same axis as a centrifugal separator, which may be of any kind and be arranged above, below or around the rotating means and the co-rotating chambers. The rotating member and the co-rotating chamber may be centered on the same axis as a centrifugal ball having a stack of insert plates inside the centrifugal rotor. The centrifugal rotor, the stack of insert plates, may be centered below or above the member on the same axis. The stack of insert plates and the centrifugal rotor rotate together with the body and the shell chambers. At least one of the shell tubes or shell passages may be connected between at least one of the shell chambers and the centrifugal rotor which directs fluids into the centrifugal rotor.

The present invention further relates to an extractor unit comprising at least one member having a surface, which surface rotates with the member, and the member is selected from a group consisting of T-discs, Y-discs, Z-discs, and A-discs. The body of the extractor rotates about an axis which causes the unit to work with centrifugal force.

The extractor unit comprises one or more shell chambers having shell tubes which shell chambers rotate together with the means. Inlets for fluids and gas, or liquids, are arranged so that the fluid flows with or against the flow through the unit. Alternatively, a centrifugal rotor may have a centrifugal ball and a stack of insert plates on the same axis as the rotating member and the co-rotating chambers.

The centrifugal rotor can thus surround the rotating member, be located on top of the rotating member or below. The insert plates may thus surround the rotating member and the co-rotating chamber, or the insert plates may be below or above the rotating member. A shell tube or shell disk can transport fluids to the centrifuge ball from the rotating member having a co-rotating chamber.

Alternatively, the units mentioned above may have a plate or housing centered on the shaft of the member attached to cover the surface of the member or attached to the same extent to the surface of the member and leave a gap between the plate or housing and the rotating member. The plate or housing may be stationary or may rotate at a different number of turns than the rotating member, and the plate or housing may rotate together with the rotating member or rotate counterclockwise towards the rotating member.

The housing or plate can be heat exchanged with heat exchanging fluids. As a further alternative, a shell disk may transport fluids through the outlet in the shaft of the stationary plate or stationary housing, or a pump may be connected to the inlet for pumping fluids out through the outlets in the shaft.

As a further alternative to the above-mentioned means according to the invention, the rotating means may be covered by a cover, and the cover may be provided with inlets and outlets for fluids, such as liquid fluids, sols, gases, fluidized particles, etc.

The cover may be sealed to contain a gaseous medium. The units can be hermetically sealed. Gas-tight gaskets can seal the parts and the rotating shaft at transition points between the different parts.

A further alternative to the present invention is that at least one surface of the members or at least a part of the surface of the members may be coated with one or more catalysts.

In the following, the present invention will be described by means of figures. Figures 1 to 15 are only examples of the invention which explain this and are not intended to limit the scope of the invention.

Brief description of the invention Figure 1 shows a rotating module according to the invention.

Figure 2 shows a T-disc according to the invention.

Figure 3 shows a T-disc with a stator according to the invention.

Figure 4 shows an inlet to a T-disc having channels according to the invention.

Figure 5 shows another view of a T-disc having channels.

Figure 6 shows yet another view of a T-disc having channels.

Figure 7 shows a membrane or filter unit according to the invention.

Figure 8 shows an A-disc inside a centrifugal separator according to the invention.

Figure 9 shows another A-disc inside a centrifugal separator according to the invention.

Figure 10 shows an A-disc unit according to the invention.

Figure 11 shows a hermetic unit according to the invention.

Figure 12 shows another hermetic unit according to the invention.

Figure 13 shows a Z-disc according to the invention.

Figure 14 shows a Y-disc according to the invention.

Figure 15 shows a detailed drawing of a shell tube located under a T-disc according to the invention.

Detailed description of the figures Figure 1 shows a multifunctional module that has four units 1, the units can have different sizes, different kinds of processes, etc. In figure 1, the units are under a hood 2 on a foundation 3. A supply pipe 4 and a product tube 5 out of the module is shown in the figure which illustrates that the process module is continuous. How the units are configured in the modules depends on space, what kind of processes and the sequence of processes, the units can be connected in series and the units can thus be in a row or the units can be placed in a square shown in the figure. A combination of units connected in series and in parallel with each other is an alternative to the module shown in Figure 1, another may be that all the units can be connected in parallel. All units in a module can be "rotating" or have parts that rotate around an axis, or some of the units can be stationary units.

Figure 2 shows two equipment according to the invention, figure 2 shows two different arrangements illustrated in figure one on each side of the shaft 6 A + B. A and B represent two different kinds of equipment, but A and B also represent two different supply inlets for reactants which will react with each other and form a product C. On the A-side of the equipment, a stator 7 is arranged over a T-disk 8. The stator 7 and the T-disk 8 are arranged so that a gap is formed between the stator 7 and the T-disk. the disc 8 to enable a space for reactions. The movement of the fluid is created by the stator. 7 and the disc 8 can enable better fluid movement to create better reactions between different components in the inlet flows. There is no stator on side B of the equipment and the reaction surface is open. Supply of reactants A and B is at an inlet at the center of the T-disc 8, but the reactants can also be supplied within a radial distance from the center, the reactants begin to react and mix to form a film or layer on the surface of the disc. Reactants and products are transported by the centrifugal force to the edge of the disc where a chamber 9 collects the material. The number of rotations with which the disk rotates depends on various properties such as the viscosity of the reaction mixture, reaction time, etc. The chamber 9 rotates together with the T-disk 8. In Figure 2, the disk is represented by a disk attached to a shaft 10, but according to the invention it is also included that the disc 8 is not attached to the shaft, the disc is instead mounted on the chamber 9 which chamber is connected to the driving force of the motor according to this alternative, this alternative is not shown in the figure. A shell tube 11 is connected from below with the disc to the chamber 9 for transporting the product mixture C out of the chamber 9. According to this location of the shell tube 11 it is possible to transport C by gravity from the chamber 9. The dynamic pressure forces the fluids out of the chamber.

Figure 3 shows a unit having a T-disc with a co-rotating chamber for 10 15 20 25 30 35 9 products. The process mixture is transported by the shell disk 12 from this process mixture is then pumped out through the stator shaft 13. A housing 14 closes the disk with the rotating chamber according to alternatives of the invention, and from the environment so that gas can be supplied. Figure 3 also shows how heat is transported to and from the units through heat-exchanging fluids. The heat exchanging fluids are transported in channels 15 through the rotating shaft 16 from below opposite to the process side of the disc 8. According to this alternative, the disc 8 is not attached to the rotating shaft 16 but the disc 8 is instead mounted to the co-rotating chamber. A stator 7, which may be a shell disk but not necessarily, is attached to the stator shaft 13.

Figures 4, 5 and 6 show a T-disc having integrated process channels 17. Inlet 18 supplies process fluids to the channels 17. In Figure 4 a shell pipe 19 secures the level of a flow path 20 of process fluid connected to the channels 17. Figure 6 shows the outlet pipe 21 which discharges process products from the co-rotating chambers inside the disc, which is not shown in detail in Figure 6.

Figure 7 shows a filter or a membrane unit according to the invention. Process fluids are led into the chamber 22 where a filter 23 or a membrane 23 divides the chamber 22 into two parts.

The process fluids are separated by the filter or membrane and both concentrate and filtrate, or permeate transported by the centrifugal force to be collected in co-rotating chambers, are not shown in detail in Figure 7. A shell tube 24 transports concentrate from the co-rotating chamber intended to collect concentrate through a stator shaft 13. The filtrate and permeate are transported by a shell tube 24 up through the stator shaft 13. A shell tube or shell disk will pump both concentrate and filtrate / permeate through the stator shaft. Shell discs can replace one or both shell tubes 24 or 25 according to an alternative.

Figure 8 shows an A-disc 26 inside a centrifugal ball 27 according to the invention. This option is without an extractor. Process fluid inlets 28 are centered on a stator shaft to supply process fluids into a space between the A-disc 26 and rotor body 29. The process fluids react and the product mixture is transported on the surface 26 of the A-disc to be collected in a co-rotating chamber 30 which according to this embodiment is a centrifugal ball 27. In the centifugal ball there is a stack of insert plates 31. The insert plates 31 have an extended surface for forming a separation equipment. The product mixture is separated and the different fractions of the product mixture are pumped out of the centrifuge ball by one or more shell discs 32. Heat exchanger fluids are transported from inlet 33a into the A-disc 26 and thus conduct heat to and from the process reactions. The heat exchanger fluids are collected in the chamber 34 and transported out of the shell tube 35.

Figure 9 shows an alternative A-disc with an extractor. According to this alternative, gas can be supplied through an inlet or outlet through the shaft 33c to or out of the space 36 between the A-disc 26 and the rotor body 29 and be connected to outlet or inlet 33b and the unit will function as an extractor.

Figure 10 shows an A disk having a shell tube 37 or a shell disk 37 at the bottom of the disk transporting the process fluids out of the chamber 38. The fluids are transported up through the stator shaft 39. Alternatively, a shell disk may transport fluids from the chamber 38 through the rotating shaft. shaft 40, is not shown in Figure 10. The supply inlets 41 supply process fluids into the A-disc and the fluids are transported by the centrifugal force down to the chamber 38 where the fluids are collected before further transport.

Figure 11 shows a hermetic unit having a T-disc 44. According to this version of the present invention, process fluids are supplied up through the axis of rotation 43 to the upper surface of the stator 42. The process fluids will be pumped down from the surface of the T-disc 44 through the rotating shaft 43 from the chamber. Heat exchanger fluids are transported up and down through the rotation shaft 43 for heat exchange to or from the T-disc 44. A housing 45 seals the T-disc from the environment. Figure 12 also shows a hermetic T-disc assembly. According to this alternative, process fluids are supplied through the inlet 46 into the housing 45. The process fluids are led out through the outlet 47 in the housing. A heat exchanger 48 is centered on the rotating shaft to heat exchange the heat exchanging fluids within itself to and from the T-disc.

Figure 13 shows a Z-plate having two horizontal surfaces 49 and 50 separated by a number of walls 51 and 52. Walls 51 and 52 surround the axis of rotation and extend diverging from a horizontal surface towards an opposite horizontal surface.

Figure 14 shows a Y-disc 53 according to the invention. The process fluids are supplied through inlet 54 from above the Y-disk. The process fluids are released at the bottom surface of the Y-disc.

By the centrifugal force, the fluids are forced onto the surface of the Y-disk and collected in the chamber 55. A shell disk 56 or a shell tube 56 transports the fluids from the chamber 55. The Y-disk is cold or heated by heat exchanger fluids, which are let in or out through the shaft 57 into a space 58 between the Y-disc and the rotor 59.

Figure 15 shows a more detailed figure of a unit having a shell tube 60 located below a T-disc for transporting fluids out of a shell chamber 62, there may be more than one shell tube 60 arranged below the disc. This figure shows how the shell tube 60 defines the fluid surface 63 at a predetermined level depending on the position of the shell tube 60 in the chamber 62. In this figure the T-disc 61 is mounted on the rotor body 64. The figure also shows that the shell chamber 62 is attached to the rotor body 64 with a or more bolts 65. A stator 66, according to this alternative, is placed over the T-disc 61 and leaves a gap 67 for fluids, which fluids are supplied through the inlet 68 in the stator shaft. According to another alternative, not shown in Figure 15, the stator may be superfluous and leave the rotating fluid surface open under the protective shell 69. According to another alternative, not shown in Figure 15, the stator may be a shell disk, but then the shell tube may 60 may be redundant in some applications, but not necessarily. If there is a shell disk, the T-disk 61 is mounted in such a way that the chamber 62 will cover the T-disk 61 and the shell disk. According to this alternative, the fluids from the chamber 62 will be pumped up through the protective cover 69 of the shell disk. Figure 15 shows inlet 70a and outlet 70b for heat exchanger fluids, which are arranged in the rotating shaft 71 and allow heat exchanger fluids to be pumped to the channels 72 under the T-disc 61 to heat or cool the disc. The design of the disc is, according to this alternative, as shown in Figure 15, a T-disc 61 in the form of a plate mounted on a rotor body 64, but according to other alternatives the shape of the disc may be a T-disc, a Y-disc, a Z-disc disc or an A-disc. The shape of the disc depends on the task of the unit and Figure 15 shows a T-disc but the invention is not limited to this version. When a T-disc, Y-disc, Z-disc or an A-disc is used, all these kinds of discs are mounted on a rotor body 64 and not on a rotating shaft, of course these discs can be mounted on a rotating shaft but not according to the alternatives in figure 15. The Y-disc can therefore be a cone-shaped bowl with the narrower end directed downwards, the A-disc can also have a cone-shaped but in this alternative the narrower ends are turned upwards. The Z-disc can be turned in both of these ways because the disc is symmetrical. The shell chamber 62 is mounted together with the selected disk on the rotor body 64 which covers the disk and the rotor body according to these alternatives of the invention. Depending on the disk used, the shell chamber 62 may have different sizes to cover both the disk and the rotor body. The housing 69 may have one or more inlets and / or one or more outlets, none of which are shown in Figure 15 except the inlet inlet 68 which is an alternative. As another alternative, not shown in Figure 15, a centrifugal rotor may have a centrifugal ball and a stack of insert plates may be centered on the same axis as the disk and shell chamber 62.

The centrifugal rotor may surround the disk, or be located above or below the disk. The insert plates may thus surround the disk, or the insert plates may be above or below the disk 61. A shell disk or a shell disk may transport fluids into the centrifuge ball from the chamber 62 when the centrifuge ball is below the disk 61. When the centrifuge ball is above the disk 61 the shell disk 62 pumps fluids from the shell chamber 62 in the centrifuge ball. According to the alternatives to the invention presented in Figure 15, the selection of the disc 61 can be flexible, which enables the unit to be assembled depending on the desired goal for use of the unit. The unit is thus very flexible and possible to change.

Claims (16)

10 15 20 25 30 13 Patent claims A multifunctional module comprising at least one unit, at least one inlet, and at least one outlet, wherein the at least one unit is the selected group of separator units, extraction units, and mixing units, and wherein each of consisting of filter units, membrane units, reactor unit in the group of units have at least one member having an active surface, on which active surface processes take place, which member rotates about an axis, one or more chambers rotate together with the rotating member and fluids from the active surface of the member are collected in one or more of the co-rotating members. the chambers, and the units in the module are connected in parallel, or in series or both and to each other. A multifunctional module according to claim 1, wherein the module also comprises one or more units selected from the group consisting of static separators, high speed separators, decanter centrifuges, contactors, clarification units, purification units, or any combination thereof, and the units are connected to the units in parallel. , or in series, or both, in the multifunction module. A multifunctional module according to claim 1 or 2, wherein the means is a disk selected from the group consisting of T-disks, Y-disks, Z-disks and A-disks, wherein the active surface is integrated with the disk so that the surface is over or below the T-disc, the Y-disc, the Z-disc, or the A-disc or the active surface is inside the disc in the form of one or more channels. A multifunctional module according to claim 1, 2 or 3, wherein one or more chambers are shell chambers having one or more shell members, and the shell chamber surrounds the shell surface of the disk, or the shell chamber is below the disk surface, or the shell chamber is above the disk surface, or the shell chamber is at the mantle surface of the disc. 10 15 20 25 30 14 A filter unit or a membrane unit comprises at least one disc having an effective surface, and the disc is selected from the group consisting of T-discs, Y-discs, Z-discs, and A-discs, said disc rotating about an axis, wherein the effective surface of the disc is at least two compartments divided by a membrane or a filter or both, and the filter unit or membrane unit comprises one or more inlets for fluids over the surface of the disc at the center of the disc at the axis or within a radial distance from the center, so that parts of the fluids pass through the filter or pass through the membrane and are transported by the radial force to the mantle surface, the unit also comprises one or more chambers for fluids rotating together with the disc, fluids from the active surface of the disc are collected in one or more of the co-rotating chambers, and the chamber surrounds the mantle surface of the disc, or the chamber is below the mantle surface of the disc, or the chamber is above the mantle surface of the disc, or the chamber is located at the mantle of the disc take. A reactor-separator unit comprising at least one disk having an effective area, and the disk being selected from the group consisting of T-disks, Y-disks, Z-disks and A-disks, the disk rotating about an axis, where the reactor the separator unit also comprises one or more inlets for fluids over the active surface of the discs, the unit also comprises one or more shell chambers for fluids rotating together with the disc, the fluids from the active surface of the disc are collected in one or more co-rotating chambers and one or more shell chambers have one or more shell tubes connected to the surface of the fluids in the shell chambers, and the reactor-separator unit also includes a stack of insert plates within a centrifugal rotor below the disk having the same axis as the disk, which stack of insert plates and centrifugal rotor rotates together with the disk and shell chambers. connected between at least one of the shell chambers and the centrifugal rotor. An extractor unit comprising at least one disc having an effective surface, the disc being selected from the group consisting of T-discs, Y-discs, Z-discs, and A-discs, said disc rotating about an axis, the extractor unit also comprising a or several inlets for fluids on both sides of the disc which cause the fluids to flow co-current or counter-current through the extractor unit, the various, supplied fluids are mixed, or reacted or transported, or combinations thereof by the radial force on the operative of the disc surface and transported to the mantle surface of the disc, and wherein the unit also includes one or more chambers for fluids rotating together with the disc, the fluids from the active surface of the disc are collected in one or more co-rotating chambers, and the chamber surrounds the mantle surface of the disc, or the chamber is below the disc surface. or the chamber is located above the mantle surface of the disc, or the chamber is located at the mantle surface of the disc. An assembly according to any one of claims 5 to 7, wherein the chambers for fluids are shell chambers having one or more shell means arranged to define fluid surfaces at predetermined levels in the one or more shell chambers, and the shell means arranged to direct the fluids out of the chambers, into one or more outlets in the radial direction from the disc, into one or more outlets below the disc or one or more outlets over the disc, or through the shaft upwards or downwards, or combinations thereof. An assembly according to any one of claims 5 to 8, wherein a plate or casing is centered on the shaft of the disk attached to cover the active surface of the disk or attached to have the same extent as the active surface of the disk and leaving a gap between the stationary the plate or stationary housing and disc, where the plate or housing is stationary attached to or rotates with or against the disc with a different number of rotations. An assembly according to claim 9, wherein one or more shell discs transport fluids through the outlet in the shaft of the stationary plate or stationary housing, or a pump is connected to the inlet for forcing the fluids out through the outlet in the shaft. An assembly according to any one of claims 5 to 10, wherein the channels or chambers for heat exchanging fluids are integrated with the discs or under the discs, which heat exchanging fluids are pumped from under the discs at or inside the shaft which provide heat exchange to or from the discs . A unit according to claim 11, wherein the heat exchanger fluids are passed through a heat exchanger centered on the shaft below the disc. A unit according to any one of claims 5 to 12, wherein the unit also comprises pumps for heat exchanger fluids, and for fluids from the chambers. An assembly according to any one of claims 5 to 13, wherein the disc is covered by a casing, and the casing is provided with inlets and outlets for fluids, such as liquid fluids, sols, gases, fluidized particles, etc. A device according to claim 14, wherein the device is hermetically sealed. A unit according to any one of claims 5 to 15, wherein at least a part of the active surface of the disc is covered with a catalyst.