EP3215244A1

EP3215244A1 - Device, system and method for extracting and filtering a suspension, preferably containing plant constituents, by means of rotating filter elements

Info

Publication number: EP3215244A1
Application number: EP15795126.0A
Authority: EP
Inventors: Klaus Gehrig; Klaus Karl Wasmuht; Tobias Becher; Konstantin Ziller
Original assignee: Ziemann Holvrieka GmbH
Current assignee: Ziemann Holvrieka GmbH
Priority date: 2014-11-03
Filing date: 2015-11-02
Publication date: 2017-09-13
Also published as: CN107109317B; EP3215595A1; BR112017008767A2; DE102014116308A1; DE102014116306A1; EP3215595B1; DE102014116305A9; WO2016071286A1; DE102014116305A1; BR112017008767B1; US10487299B2; CN107109317A; DE102014116304A1; US20170313963A1; WO2016071287A1; BR112017008758A2; US20170319981A1; US11104872B2; DE102014116307A1; DE102015105849A8

Abstract

The invention relates to a device, a system and a method for processing a suspension, preferably containing plant constituents, in particular to the separation of a liquid or a solid from said suspension in the fields of food-, pharmaceutical- and luxury goods production, and to corresponding uses. The device V for the continuous or discontinuous processing of a suspension MA, in particular for the separation of a liquid or a liquid phase WO, or a solid or a residual phase RM from the suspension MA, comprises at least: a receiving device AG for receiving the suspension MA; and at least one separation device T having a surface FA, the surface FA having a plurality of openings OP. The surface FA or part thereof can be brought into contact with the suspension MA, when the suspension MA is present in the receiving device AG for separation into the liquid phase WO and the solid phase RM. During the operation of the device V, the surface FA is moved or can be moved, or can be rotated relative to the suspension MA, the solid phase RM and/or the receiving device AG.

Description

description

DEVICE, SYSTEM AND METHOD FOR EXTRACTION AND FILTRATION OF A SUSPENSION, PREFERABLY CONTAINING PLANT COMPONENTS BY ROTATING FILTER ELEMENTS

The invention relates to a device, a system and a method for treating a suspension, preferably containing plant components, in particular the separation of a liquid or a solid thereof, in the field of food, drug and beverage production and corresponding uses.

introduction

In the treatment of suspensions, preferably containing plant components, in particular in the separation of a liquid (liquid phase, with or without solid residues) or a solid (residual phase, with or without residual liquid) therefrom, in the field of food, drug and beverage production, For example, after the separation device has been filled with the suspension, a filter layer of material originating from the suspension, in particular plant components, is often formed on the filter.

A disadvantage of the conventional procedure is that the plant components preferably contained in the suspension led to an early blocking or laying of the treatment and in particular separation device, which in turn had an extension of the required treatment or separation time result. Therefore, there has long been a desire to significantly shorten the process step of separation of the suspension or even to realize it as a continuous process step. In practice, a reduction in the separation times of plant-based suspensions has not been achieved so far, despite the recent development and optimization of existing separation systems. l definitions

For the purposes of the invention, the term "suspension" encompasses the meaning familiar to the person skilled in the art in the field of foodstuffs, pharmaceuticals and stimulants, although "suspension" may also include dilute suspensions, in particular mixtures of a suspension and water, and concentrated suspensions, i. Residual phases, ie suspensions from which a liquid phase has already been separated include. In addition, "suspension" may comprise all types of suspensions known to the person skilled in the art in the field of foodstuffs, pharmaceuticals and semi-luxury foods which contain plant components The suspension according to the invention may, in a particular embodiment, also be restricted to a suspension whose proportion of solids is from one In a particular embodiment, the suspension according to the invention may also be restricted to a suspension whose proportion of liquid consists of water The suspension according to the invention may in a further embodiment be limited to a suspension whose proportion of solids is one In a further embodiment, the suspension according to the invention may also be restricted to a suspension whose proportion of solid from a plant component or a mixture of plant zenbestanteilen and their share of liquid consists of water.

According to the invention, the term "plant constituent" is understood to mean any constituent of a plant, in particular fruits, seeds, leaves, flowers, branches, bark, wood or roots, which is directly obtainable or processed, in which case the plant may be in particular: a cereal, such as barley , Wheat, oats, spelled; a vegetable, or a herb or herb. Preferably the plant is selected from a group consisting of: tea, mint, cannabis, cassava, hops, tobacco, coca, ginko, aloe vera, opium poppy, Valerian, sage, hibiscus, lemon balm and chamomile.

The term "liquid phase" is understood according to the invention to mean a liquid which is obtained from the suspension by separating off solids or parts of the suspension. pension was won. In this case, the "liquid phase" may be a liquid or may also contain solids, in particular vegetable solids, in addition to a liquid When using a filter or sieve-like device for separating the suspension, the permeate typically forms the "liquid phase".

The term "residual phase" is understood according to the invention to mean a solid, a mixture of solids or a suspension which has been obtained from the above-defined "suspension" by separating off the "liquid phase." In this case, the "residual phase" may include solids, in particular vegetable solids , also contain liquid. The mass-related solids content of the "residual phase" is higher than that of the "liquid phase" resulting from the same separation step. When using a filter or sieve-like device for separating the suspension, the retentate typically forms the "residual phase." The term "separating device" is understood according to the invention to mean any device which is suitable for separating one or more constituents of a substance mixture. In particular, "separator" includes a filter, a sieve or the like.

When separating a suspension by means of the separation device according to the invention two fractions or phases, of which those with the higher liquid content or that which consists of liquid arise as "liquid phase", and those with the lower liquid content and higher solids content as "residual phase" in the frame this application is defined. By "mixing" is meant according to the invention the combination of two or more substances, but this may also include the homogenization of the resulting mixture.

In the context of this invention, the term "extractant" in the context of this invention includes the following substances and groups, including the associated subgroups, and, in particular, the term "extractant" in the context of this invention Modifications: water, preferably demineralised water, drinking water, and process water; Alcohols, preferably methanol, ethanol, propanol, isopropanol, butanol, isobutanol, pentanol, isopentanol; esters; Acids, preferably formic acid, citric acid and acetic acid; and hydrocarbons / oils, alkanes, alkenes, alkynes, benzene, aromatics having aliphatic and aromatic substituents, carboxylic acid esters, tetramethylsilane, carbon disulfide, carbon dioxide under pressure; Ether, diethyl ether and tetrahydrofuran; Ketones, acetone; Lactones, 4-butyrolactone; Nitriles, acetonitrile; Nitro compounds, nitromethane; tertiary carboxylic acid amides, dimethylformamide; Urea derivatives, tetramethylurea and dimethylpropyleneurea; Sulfoxides, dimethylsulfoxide; Sulfones, sulfolane; Carbonic acid esters, dimethyl carbonate, ethylene carbonate; Edible oils and edible fats.

For the purposes of the present application, a method or method step is defined as "continuous" if this method or method step is carried out or runs without interruptions According to the invention, however, the definition of "continuous" may additionally include methods or method steps which include one or more interruptions at a maximum of not more than 20%, preferably not more than 15%, preferably not more than 10%, preferably not more than 5%, in particular not more than 2%, of the total duration of the process or step in question; or one or more interruptions in an amount of the mass or volume flow rate of at most 20%, preferably at most 15%, preferably at most 10%, preferably at most 5%, in particular at most 2%, of the total mass or volume flow rate of the process or method step in question exhibit.

In the context of this application, all processes or process steps which do not fall into the above definition of "continuous" are defined as "discontinuous" or "batchwise." In this case, the definition of "discontinuous" can also include processes or process steps, although they are carried out without Interruption takes place, but the implementation of which is completed after a maximum of eight hours, preferably at most six hours, and in which a predetermined portion of a substrate is treated or processed. For the purposes of the present application, the term "surface" (FA, FA1, FA2,...) Of a separating device (T, T1, T2,...) Comprises the part of the entire, outer, that is, in contact with the environment - Or peripheral surface of the separation device having the openings OP for separating a suspension or residual phase and thus a separation or filtering function.

For the purposes of this application, the terms "about", "about" or the like mean a relative deviation from the respective reference value of at most 10%, preferably at most 5%, preferably at most 3%, in particular at most 1%.

It is an object of the invention to provide a device, a system and a method for treating a suspension, preferably a suspension containing plant constituents, in particular the separation of a liquid / liquid phase and / or a solid / a residual phase thereof in the region of Food, drug and beverage production and to provide appropriate uses that are suitable, the treatment of the suspension, preferably containing plant components, in particular the separation of a liquid or a solid thereof, to improve or simplify, in particular to shorten.

It is an aspect of the present invention to avoid or at least reduce the blocking or clogging of the surface of the separating agent used in treating the suspension, in particular when separating a liquid / liquid phase or a solid / a residual phase thereof.

Description of the invention

The object described above is achieved by the subject-matter of the claims and / or the objects described below (numbers 1 to 103). Device (V) for the continuous or discontinuous treatment of a suspension (MA), preferably containing plant components, in particular for separating a liquid or liquid phase (WO), or a solid or a residual phase (RM) from the suspension (MA), in the region of Food, pharmaceutical and luxury food production, at least with:

a receiving device (AG) for receiving the suspension (MA);

at least one separating device (T) having a surface (FA);

the surface (FA) having a plurality or plurality of openings (OP);

wherein the device (V) is preferably adapted to separate the suspension (MA) into the liquid phase (WO) and the residual phase (RM) by means of the surface (FA) of the separation device (T);

wherein the surface (FA) or a part thereof with the suspension (MA) is brought into contact when the suspension (MA) for separation into the liquid phase (WO) and the solid phase (RM) in the receiving device (AG) present is;

wherein the surface (FA) during the operation of the device (V) to the suspension (MA), the solid phase (RM) and / or the receiving device (AG) is arranged relatively movable or movable or rotatable.

Device according to number 1, characterized in that the separating device (T) is arranged in the device (V) in such a way that, by carrying out the relative movement or rotational movement, the contact of the surface (FA) or a partial surface thereof with that in the receiving device ( AG) existing suspension (MA) temporarily interruptible and can be restored after the interruption;

wherein the interruption and restoration of contact of the surface (FA) or a part thereof with the suspension (MA) is preferably repeatable. Device according to number 1 or 2, characterized in that the separating device (T) is arranged in the device (V) such that by carrying out the relative movement or rotational movement, the surface (FA) or a part surface thereof the suspension (MA) in Leaves the region of the mirror or the mirror of the suspension (MA) or in the region of the surface or on the surface of the suspension (MA), there emerges from the suspension (MA) or the contact with the suspension (MA) is interrupted there, wherein the direction of movement the surface (FA), viewed in the region of the level or liquid level of the suspension (MA) or on the level of the suspension (MA), with the level of the suspension (MA) or the surface of the suspension (MA) or the horizontal at an angle of 30 to 90 °, preferably 45 to 90 °, preferably 60 to 90 °, preferably 70 to 90 °, preferably 80 to 90 °, preferably 85 to 90 °, vorzugsw 87 to 90 °, in particular 90 °.

Device according to one of the numbers 1 to 3, characterized in that the device (V), in particular the separating device (T), by means of a control device (C) is controllable such that a relative movement or rotational movement of the surface (FA) during the entire Duration of the treatment of the suspension (MA), in particular the separation of a liquid or a solid from the suspension (MA), takes place.

Device according to one of the numbers 1 to 4, characterized in that the separating device (T) is arranged in such a manner to the receiving device (AG) that during operation of the device (V) for treating the suspension (MA), preferably containing plant components, in particular for separating a liquid or a solid from the suspension (MA), the surface (FA) in a proportion in the range of 1 to 95%, preferably from 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 10 to 90%, above preferably 15 to 80%, preferably 20 to 80%, preferably 20 to 70%, preferably 20 to 60%, preferably 20 to 50%, preferably 20 to 40%, preferably 30 to 40%, preferably 5 to 80%, preferably 5 to 40%, preferably 5 to 30%, preferably 5 to 25%, in particular 5 to 20%, preferably 5 to 15%, in particular 20 to 30%, of the suspension (MA) is covered or immersed in the suspension (MA) when the suspension (MA) is present in the receiving device (AG); and

the surface (FA) within the scope of the remaining portion is preferably arranged in or protrude into a gas-filled space (GR1) above the suspension (MA).

Device according to one of the numbers 1 to 5, characterized in that the openings (OP) a size or pore size or mesh size in the range of 5 to 10,000 μηι, preferably 10 to 1,000 μηι, preferably 10 to 500 μηι, preferably 20 to 400 μηι, preferably 25 to 500 μπι, preferably 30 to 300 μιη, preferably 40 to 250 μηι, preferably 45 to 350 μπι, preferably 45 to 200 μηι, preferably 45 to 100 μηι, preferably 55 to 300 μηι, in particular 65 to 250 μηι have.

Device according to one of the numbers 1 to 6, characterized in that the separating device (T) is designed as a separating device with a rotatably mounted shaft or with a rotatably mounted surface (FA) or as a rotatably mounted separating device or rotatably mounted filter; and / or the separating device (T) is formed in a disc-shaped or cylindrical shape, or in a substantially disc-shaped or cylindrical shape; and or

wherein the base surface and / or the lateral surface of the separating device (T) is partially or completely formed as a separating or filtering surface, in particular as the surface (FA); and or wherein the separating device (T) is arranged in the device (V) such that the center axis or a rotation axis of the separating device (T) or the surface (FA) is substantially parallel to the liquid level of a device (V) receiving device (AG). filled liquid is arranged, or the central axis or a rotation axis of the separator (T) or the surface (FA) with the liquid level of a in the receiving device (AG) of the device (V) filled liquid or with the horizontal an angle with an amount in the range from 0 to <90 °, preferably 0 to 45 °, preferably 0 to 30 °, preferably 0 to 20 °, preferably 0 to 15 °, preferably 0 to 10 °, in particular 0 to 5 °.

Device according to one of the numbers 1 to 7, characterized in that the relative movement or rotational movement of the surface (FA) takes place continuously or intermittently, in particular at regular time intervals.

Device according to one of the numbers 1 to 8, characterized in that the device (V) forms at least one flow path; and or

the at least one flow path from a liquid, in particular from the suspension (MA), can be flowed through by gravity only.

Device according to one of the numbers 1 to 9, characterized in that the surface (FA) is formed as a flat or planar surface or as a surface having a suspension to the (MA) convex or concave or wavy or zigzag-shaped contour ; and or

the separating device (T), preferably the surface (FA), has at least one projection (VO); wherein the at least one projection (VO) is arranged such that it can be brought into contact with the suspension (MA); wherein the at least one projection (VO) is adapted to move or take along from the suspension (MA) derived solid particles in the suspension (MA) and preferably from the suspension (MA) and / or from the receiving device (AG); wherein the at least one projection (VO) preferably has a shape in the manner of a web, paddle, star, a gutter or a pocket.

Device according to one of the numbers 1 to 10, characterized in that the device (V) has one or more, preferably two, separating devices (T; Tl, T2);

wherein the Trennvorri chtungen (Tl, T2) are each designed as a separator with a rotatably mounted shaft or as a rotatably mounted separator or rotatably mounted filter; and or

wherein the two separation devices (T1, T2) are each arranged in the device (V) such that the central axis or a rotation axis of each of the two separation devices (T1, T2) or their surfaces (FA1, FA2) is substantially parallel to the liquid level of one is arranged in the receiving device (AG) of the device (V) filled liquid, or the central axis or a rotation axis of each of the two separation devices (Tl, T2) or their surfaces (FA1, FA2) with the liquid level of a receiving device (AG) liquid filled with the device (V) or with the horizontal at an angle in the range of 0 to <90 °, preferably 0 to 45 °, preferably 0 to 30 °, preferably 0 to 20 °, preferably 0 to 15 °, preferably 0 to 10 °, especially 0 to 5 °, includes; and or

wherein the two separating devices (T1, T2) are arranged in the device (V) and in such a way that the central axes or a rotation axis of each of the two separating devices (T1, T2) or their surfaces (FA, FA2) makes an angle with an amount in Range from 0 to <90 °, preferably 0 to 45 °, preferably 0 to 30 °, preferably 0 to 20 °, preferably 0 to 15 °, preferably 0 to 10 °, especially 0 to 5 ° include; and or wherein the two separating devices (T1, T2) have an identical center axis or axis of rotation or their central axes or axes of rotation are arranged collinearly in the device (V); and or

wherein the two separation devices (Tl, T2) have a common rotation shaft; and or

wherein the two separating devices (Tl, T2) are arranged in the device (V), that the largest, preferably measured parallel to the rotary shaft or normal distance distance between the two surfaces (FA1, FA2) of the two separation devices (Tl, T2) in Range of> 2 cm to 100 cm, preferably 3 to 50 cm, preferably 4 to 30 cm, preferably 5 to 25 cm, preferably 10 to 30 cm, in particular 10 to 20 cm; and or

the smallest, preferably parallel to the rotation shaft or normal distance measured distance between the two surfaces (FA1, FA2) of the two separation devices (Tl, T2) in the range of> 2 cm to 100 cm, preferably 3 to 50 cm, preferably 4 to 30 cm , preferably 5 to 25 cm, preferably 10 to 30 cm, in particular 10 to 20 cm.

Device according to one of the numbers 1 to 1 1, characterized in that the at least one separating device (T; Tl, T2) is arranged in the device (V) such that the largest distance between the surface (FA), preferably measured as normal distance, and a wall of the device (V), preferably the receiving device (AG), in the range of> 2 cm to 100 cm, preferably 3 to 50 cm, preferably 4 to 30 cm, preferably 5 to 25 cm, preferably 10 to 30 cm, especially 10 to 20 cm, is; and or

the smallest distance, preferably measured as a normal distance, between the surface (FA) and a wall of the device (V), preferably the receiving device (AG), in the range of> 2 cm to 100 cm, preferably 3 to 50 cm, preferably 4 to 30 cm, preferably 5 to 25 cm, preferably 10 to 30 cm, in particular 10 to 20 cm. Device (V) for the continuous or discontinuous treatment of a suspension (MA), preferably containing plant components, in particular for separating a liquid or a solid from the suspension (MA), in the field of food, drug and beverage production, preferably device according to one of Numbers 1 to 12 or having a characteristic defined in one of the numbers 1 to 12, at least with:

a trough-like receiving device (AG) for receiving the suspension (MA);

at least one separating device (T), preferably two separating devices (T1, T2), each having a surface (FA, FA1, FA2);

wherein the at least one separating device (T; Tl, T2) is in each case designed as a rotatably mounted, disc-shaped or cylindrical filter;

wherein the surface (FA; FAl FA2) is in each case the base area of the at least one separating device (T; Tl, T2) or a part thereof;

wherein the surface (FA, FA1, FA2) is formed in each case as a flat or substantially flat filter surface with a plurality of openings (OP);

wherein the device (V) is preferably adapted to separate the suspension (MA) into a liquid phase (WO) and a residual phase (RM) by means of the surface (FA; FA1, FA2);

wherein the respective axis of rotation of the at least one separating device (T; Tl, T2) is arranged perpendicular or substantially perpendicular to the respective surface (FA; FAl, FA2);

wherein the respective axis of rotation of the at least one separating device (T; Tl, T2) with the liquid level of a liquid filled in the receiving device (AG) or with the horizontal an angle with an amount in the range of 0 to 20 °, preferably 0 to 15 °, preferably 0 to 10 °, especially 0 to 5 °;

wherein, in the presence of two separating devices (T1, T2), these are arranged in the device (V) such that the normal distance between the two surfaces (FA1, FA2) of the two separating devices (T1, T2) is in the range from 3 to 50 cm, preferably 4 to 30 cm, preferably 5 to 25 cm, preferably 10 to 30 cm, in particular 10 to 20 cm; and wherein the at least one separating device (T; Tl, T2) is arranged to the receiving device (AG) such that during operation of the device (V) for separating the suspension (MA), the surface (FA) in a proportion in the range of 1 to 95%, preferably from 5 to 95%, preferably from 15 to 80%, preferably 20 to 80%, preferably 20 to 70%, preferably 20 to 60%, preferably 20 to 50%, preferably 20 to 40%, preferably 30 to 40%, preferably 5 to 80%, preferably 5 to 40%, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, preferably 5 to 15%, in particular 20 to 30%, of the suspension (MA ) or immersed in the suspension (MA) when the suspension (MA) is present in the receiver (AG); and

the surface (FA) in the amount of the remaining portion is arranged in or protrudes into a gas-filled space (GR) above the suspension (MA); wherein the surface (FA) or a part thereof with the suspension (MA) is brought into contact when the suspension (MA) for separation into the liquid phase (WO) and the residual phase (RM) in the receiving device (AG) is present ;

wherein the surface (FA) during the operation of the device (V) to the suspension (MA), the residual phase (RM) and / or Aufnahmeeinri rect (AG) is arranged relatively movable or movable or rotatable.

Device (V) for the continuous or discontinuous treatment of a medium (M), preferably for separating solids from the medium (M), in the field of food, drug and beverage production, wherein the medium (M) is a suspension or a precursor thereof is;

wherein the device (V) comprises at least:

a receiving device (AG) for receiving the medium (M);

at least one separating device (T) having a surface (FA);

the surface (FA) having a plurality of openings (OP);

wherein the device (V) is preferably adapted to separate the medium (M) into two fractions by means of the surface (FA) of the separating device (T); wherein the surface (FA) or a part thereof is brought into contact with the medium (M) when the medium (M) is present in the receiving device (AG);

wherein the surface (FA) during the operation of the device (V) to the medium (M), to one of the resulting fractions and / or to the receiving device (AG) is arranged relatively movable or movable or rotatable.

Device (V) according to number 14, characterized in that the device (V) further comprises at least one of the features of the numbers 2 to 13.

Device according to one of the numbers 1 to 15, characterized in that the device (V) has a device (WZ) for supplying an extractant, preferably water.

A system for the continuous or discontinuous treatment of a suspension (MA), preferably containing plant constituents, in particular for separating a liquid or a solid from the suspension (MA), in the field of foodstuffs, medicaments and consumables, at least comprising:

a first device (VI), wherein the first device (VI) is preferably a device (V) according to one of the numbers 1 to 16;

wherein the first device (VI) comprises a first receiving means (AG1) for receiving the suspension (MA);

wherein the first device (VI) has at least one first separating device (T1) with a first surface (FA1);

wherein the first surface (FAI) has a plurality of openings (OP); wherein the first device (VI) is preferably suitable for separating a suspension (MA) into a first liquid phase (WO1) and a first residual phase (RM1) by means of the first surface (FA1) of the first separation device (T1); wherein the first surface (FA1) is in contact with the suspension (MA) when the suspension (MA) for separation into the first liquid phase (WOl) and the first residual phase (RM1) in the first receiving means (AG1) is present ;

wherein the first surface (FA1) during the operation of the first device (VI) to the suspension (MA), the first residual phase (RM1) and / or the first receiving device (AG1) is arranged relatively movable or movable or rotatable;

wherein the first device (VI), in particular the first separation device (T1), is preferably controllable by means of a first control device (Cl) such that a relative movement or rotational movement of the first surface (FA1) during the entire duration of separation of the suspension (MA ) he follows.

System according to number 20, characterized in that the first separation device (T1) is arranged to the first receiving device (AG 1), that during operation of the first device (VI) for separating the suspension (MA), the first surface (FA1) at a level in the range of 1 to 95%, preferably 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 5 to 80%, preferably 5 to 40%, preferably 5 to 30%, preferably 5 up to 25%, preferably 5 to 20%, especially 5 to 15%, of the suspension (MA) is covered or immersed in the suspension (MA) when the suspension (MA) in the first receiving device (AG1) is present; and the first surface (FA1) in the circumference of the remaining portion is preferably arranged in or protruding in a first gas-filled space (GR1) above the suspension (MA).

System according to number 20 or 21, characterized in that it further comprises:

a second device (V2), wherein the second device (V2) is preferably a device (V) according to one of the numbers 1 to 16; wherein the second device (V2) comprises a second receiving device (AG2), preferably a receptacle, for receiving the first residual phase (RMl) or a mixture containing the first residual phase (RMl);

wherein the second device (V2) has at least one second separating device (T2) with a second surface (FA2);

the second surface (FA2) having a plurality of openings (OP); wherein the second device (V2) is preferably adapted to separate a first residual phase (RM1) into a second liquid phase (W02) and a second residual phase (RM2) by means of the second surface (FA2) of the second separation device (T2);

wherein the second surface (FA2) is in contact with the first residual phase (RMl) when the first residual phase (RMl) for separating into the second liquid phase (W02) and the second residual phase (RM2) in the second receiving device (AG2) is available;

wherein the second surface (FA2) during operation of the second device (V2) to the first residual phase (RMl), the second residual phase (RM2) and / or the second receiving device (AG2) is arranged relatively movable or movable or rotatable; and

wherein the second device (V2), in particular the second separation device (T2), is preferably controllable by means of a second control device (C2) such that the relative movement of the second surface (FA2) during the entire duration of the separation of the first residual phase (RMl) continuously or intermittently, in particular at regular intervals.

System according to number 22, characterized in that the second separating device (T2) is arranged to the second receiving device (AG2) that the second surface (FA2) during operation of the second device (V2) for separating the first residual phase (RMl) a content in the range of 1 to 95%, preferably 5 to 95%, preferably 5 to 80%, preferably 5 to 75%, preferably 5 to 50%, preferably 5 to 40%, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, especially 5 to 15% is covered by the first residual phase (RM 1) or dips into the first residual phase (RM1) if the first residual phase (RM1) is present in the second receiving device (AG2); and

the remaining portion of the second surface (FA2) is preferably located in or protrude into a second gas-filled space (GR2), wherein the second gas-swept space (GR2) is disposed above or above the first residual phase (RM1).

System according to number 22 or 23, characterized in that it further comprises:

a third device (V3), wherein the third device (V3) is preferably a device (V) according to one of the numbers 1 to 16;

the third device (V3) having a third receiving device (AG3), preferably a receiving vessel, for receiving the second residual phase (RM2) or a mixture containing the second residual phase (RM2);

wherein the third device (V3) comprises at least one third separator (T3) having a third surface (FA3);

the third surface (FA3) having a plurality of openings (OP); wherein the third device (V3) is preferably adapted to separate the second residual phase (RM2) into a third liquid phase (W03) and a third residual phase (RM3) by means of the third surface (FA3) of the third separation device (T3); wherein the third surface (FA3) is brought into contact with the second residual phase (RM2) when the second residual phase (RM2) for separating into the third liquid phase (W03) and the third residual phase (RM3) in the third receiving device (AG3) is available; wherein the third surface (FA3) during the operation of the third device (V3) to the second residual phase (RM2), the third residual phase (RM3) and / or the third receiving means (AG3) is arranged relatively movable or movable or rotatable; and wherein the third device (V3), in particular the third separation device (T3), is preferably controllable by means of a third control device (C3) such that the relative movement of the third surface (FA3) during the entire duration of the separation of the second residual phase (RM2) continuously or intermittently, in particular at regular intervals.

System according to number 24, characterized in that the third separating device (T3) is arranged to the third receiving device (AG3) that the third surface (FA3) during operation of the third device (V3) for separating the second residual phase (RM2) a content in the range of 1 to 95%, preferably 5 to 95%, preferably 5 to 80%, preferably 5 to 75%, preferably 5 to 50%, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, in particular 5 to 15%, of the second residual phase (RM2) is covered or immersed in the second residual phase (RM2) when the second residual phase (RM2) in the third receiving means (AG3) is present; and

the remaining portion of the third surface (FA3) is preferably located in or protrude into a third gas-filled space (GR3), the third gas-filled space (GR3) being located above or above the second remaining phase (RM2).

System according to number 24 or 25, characterized in that it further comprises:

a fourth device (V4), wherein the fourth device (V4) is preferably a device (V) according to one of the numbers 1 to 16;

the fourth device (V4) having a fourth receiving device (AG4), preferably a receiving vessel, for receiving the third residual phase (RM3) or a mixture containing the third residual phase (RM3);

wherein the fourth device (V4) comprises at least a fourth separator (T4) having a fourth surface (FA4); wherein the fourth surface (FA4) has a plurality of openings (OP); wherein the fourth device (V4) is preferably adapted to separate the third residual phase (RM3) into a fourth liquid phase (W04) and a fourth residual phase (RM4) by means of the fourth surface (FA4) of the fourth separating device (T4); wherein the fourth surface (FA4) is brought into contact with the third residual phase (RM3) when the third residual phase (RM3) for separating into the fourth liquid phase (W04) and the fourth residual phase (RM4) in the fourth receiving device (AG4) is available;

wherein the fourth surface (FA4) during the operation of the fourth device (V4) to the third residual phase (RM3), the fourth residual phase (RM4) and / or the fourth receiving means (AG4) is arranged relatively movable or movable or rotatable; and

wherein the fourth device (V4), in particular the fourth separation device (T4), is preferably controllable by means of a fourth control device (C4) such that the relative movement of the fourth surface (FA4) during the entire duration of the separation of the third residual phase (RM3) continuously or intermittently, in particular at regular intervals.

System according to number 26, characterized in that the fourth separating device (T4) is arranged for the fourth receiving device (AG4) that the fourth surface (FA4) during operation of the fourth device (V4) for separating the third residual phase (RM3) a content in the range of 1 to 95%, preferably 5 to 95%, preferably 5 to 80%, preferably 5 to 75%, preferably 5 to 50%, preferably 5 to 40%, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, in particular 5 to 15%, of the third residual phase (RM3) is covered or immersed in the third residual phase (RM3), if the third residual phase (RM3) in the fourth receiving device (AG4) is available; and

the remaining portion of the fourth surface (FA4) is preferably located in or protrude into a fourth gas-filled space (GR4), the fourth Gas filled space (GR4) above or above the third residual phase (RM3) is arranged.

System according to one of the numbers 20 to 27, characterized in that at least one separating device (T) selected from the group consisting of the first separator (Tl), the second separator (T2), the third separator (T3) and the fourth separator (T4), as a separating device with a rotatably mounted separating or filtering surface, in particular with a rotatably mounted surface (FA1, FA2, FA3, FA4), or designed as a rotatably mounted separating device or rotatably mounted filter; and / or at least one separating device (T), selected from the group consisting of the first separating device (T1), the second separating device (T2), the third separating device (T3) and the fourth separating device (T4), in disc-shaped or cylindrical shape, or is formed in a substantially disc-shaped or cylindrical shape; and or

wherein the base surface and / or the lateral surface of the separating device or a part of the separating device is partially or completely formed as a separating or filtering surface, in particular as the surface (FA1, FA2, FA3, FA4); and or

wherein the at least one separation device (T) selected from the group consisting of the first separation device (T1), the second separation device (T2), the third separation device (T3) and the fourth separation device (T4) is arranged in the system such that the central axis or an axis of rotation of the separating device is arranged substantially parallel to the liquid level of a liquid filled into the respective receiving device (AG1, AG2, AG3, AG4) of the respective device (VI, V2, V3, V4) or the center axis or an axis of rotation of the separating device (T) or its respective surface (FA1, FA2, FA3, FA4) with the liquid level of a in the respective receiving device (AGl, AG2, AG3, AG4) of the respective device (VI, V2, V3, V4) filled liquid or with the Horizontal angle with an amount in the range of 0 to <90 °, preferably 0 to 45 °, preferably 0 to 30 °, preferably 0 to 20 °, preferably 0 to 15 °, preferably 0 to 10 °, in particular 0 to 5 °.

29. System according to one of the numbers 20 to 28, characterized in that the openings (OP) a size or pore size or mesh size in the range of 5 to 10,000 μηι, preferably 10 to 1,000 μηι, preferably 10 to 500 μηι, preferably 20 to 400 μιη, preferably 25 to 500 μπι, preferably 30 to 300 μπι, preferably 40 to 250 microns, preferably 45 to 350 μηι, preferably 45 to 200 μπι, preferably 55 to 300 microns, preferably 45 to 100 μπι, in particular 65 to 250 microns, exhibit.

System according to any one of the numbers 20 to 29, characterized in that the relative movement or rotation of the first surface (FA1), the second surface (FA2), the third surface (FA3) and / or the fourth surface (FA4) is continuous or intermittent , in particular at regular time intervals, takes place.

31. The system according to any one of the numbers 20 to 30, characterized in that during operation of the first device (VI) for separating the suspension (MA), preferably containing plant constituents, the first surface (FA1) in a proportion in the range of 1 to 95%, preferably from 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 10 to 90%, preferably 15 to 80%, preferably 20 to 80%, preferably 20 to 70%, preferably 20 to 60%, preferably 20 to 50%, preferably 20 to 40%, preferably 30 to 40%, preferably 20 to 30%, preferably 5 to 80%, preferably 5 to 40%, preferably 5 to 30%, preferably 5 to 25 %, preferably 5 to 20%, in particular 5 to 15%, of the suspension (MA) is covered or immersed in the suspension (MA). System according to one of the numbers 20 to 31, characterized in that the second surface (FA2) during operation of the second device (V2) for separating the first residual phase (RM1) to a proportion in the range of 1 to 95%, preferably from 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 20 to 90%, preferably 30 to 80%, preferably 35 to 70%, preferably 40 to 60%, preferably 5 to 80%, preferably 5 to 40 %, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, in particular 5 to 15%, of the first residual phase (RM1) is covered or immersed in the first residual phase (RM1).

System according to one of the numbers 20 to 32, characterized in that the third surface (FA3) during operation of the third device (V3) for separating the second residual phase (RM2) to a proportion in the range of 1 to 95%, preferably of 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 20 to 90%, preferably 30 to 80%, preferably 35 to 70%, preferably 40 to 60%, preferably 5 to 80%, preferably 5 to 40 %, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, in particular 5 to 15%, of the second residual phase (RM2) is covered or immersed in the second residual phase (RM2).

System according to one of the numbers 20 to 33, characterized in that the fourth surface (FA4) during operation of the fourth device (V4) for separating the third residual phase (RM3) to a proportion in the range of 1 to 95%, preferably 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 20 to 90%, preferably 30 to 80%, preferably 35 to 70%, preferably 40 to 60%, preferably 5 to 80%, preferably 5 to 40 %, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, in particular 5 to 15%, of the third residual phase (RM3) is covered or immersed in the third residual phase (RM3). System according to one of the numbers 20 to 34, characterized in that two, three, four or more, preferably up to ten, devices selected from the group consisting of the first device (VI), the second device (V2), the third device (V3) and the fourth device (V4) are connected in series or in parallel.

System according to one of the numbers 20 to 35, characterized in that two, three, four or more first devices (VI) are connected in parallel; and / or two, three, four or more second devices (V2) are connected in parallel; and or

two, three, four or more third devices (V3) are connected in parallel; and or

two, three, four or more fourth devices (V4) are connected in parallel; and the first devices (VI), the second devices (V2), the third devices (V3) and / or the fourth devices (V4) are connected in series.

System according to one of the numbers 20 to 36, characterized in that the system forms at least one flow path; and

the at least one flow path of a liquid or in particular of the suspension (MA), the first residual phase (RMl), the second residual phase (RM2), the third residual phase (RM3) and / or the fourth residual phase (RM4) is preferably permeable by gravity.

A system for the continuous or discontinuous treatment of a medium (M), preferably for separating solids from the medium (M), in the field of food, drug and beverage production, wherein the medium (M) is a suspension or a precursor thereof; the system at least with:

at least one first device (VI), wherein the first device (VI) is preferably a device (V) according to one of the numbers 1 to 16;

wherein the first device (VI) comprises a first receiving means (AGl) for receiving the medium (M);

wherein the first device (VI) has at least one first separation device (T1) with a first surface (FA1);

wherein the first surface (FA1) has a plurality of openings (OP); wherein the first device (VI) is preferably adapted to separate the medium (M) into two fractions by means of the first surface (FA1) of the first separation device (T1);

wherein the first surface (FA1) is contactable with the medium (M) when the medium (M) is present in the first receiving means (AGl); wherein the first surface (FA1) during operation of the first device (VI) to the medium (M), to one of the resulting fractions and / or to the receiving device (AG) is arranged relatively movable or movable or rotatable; and

wherein the first device (VI), in particular the first separation device (T1), is preferably controllable by means of a first control device (Cl) such that a relative movement or rotational movement of the first surface (FA1) during the entire duration of the separation, the medium (M ) he follows.

System according to number 38, characterized in that the system further comprises at least one of the features of the numbers 20 to 37.

System according to one of the numbers 20 to 39, characterized in that the first device (VI), in particular the first receiving device (AGl), a first means (WZ1) for supplying an extractant, preferably of water, has; and or the second device (V2), in particular the second receiving device (AG2), has a second device (WZ2) for supplying an extraction agent, preferably water; and or

the third device (V3), in particular the third recording device (AG3), has a third device (WZ3) for supplying an extraction agent, preferably water; and or

the fourth device (V4), in particular the fourth receiving device (AG4), a fourth device (WZ4) for supplying an extraction agent, preferably of water.

System according to one of the numbers 20 to 40, characterized in that the system comprises a first device (WZ1), a second device (WZ2) and / or a third device (WZ3) each for supplying an extractant, preferably water; and

wherein the first device (WZ1) is preferably arranged in the system such that the extraction agent in the first device (VI) and / or downstream of the first device (VI) and upstream of the second device (V2) and / or in the second device ( V2) is supplied; and or

wherein the second device (WZ2) is preferably arranged in the system such that the extraction agent in the second device (V2) and / or downstream of the second device (V2) and upstream of the third device (V3) and / or in the third device ( V3) is supplied; and / or wherein the third device (WZ3) is preferably arranged in the system such that the extraction agent in the third device (V3) and / or downstream of the third device (V3) and upstream to a fourth device (V4) and / or in the fourth device (V4) is supplied.

System according to one of the numbers 20 to 39, characterized in that a first device (WZ1) for supplying an extractant, preferably water, between the first device (VI), in particular the first Recording device (AG1), and the second device (V2), in particular the second receiving device (AG2), is arranged; and or

a second device (WZ2) for supplying an extraction agent, preferably water, between the second device (V2), in particular the second receiving device (AG2), and the third device (V3), in particular the third receiving device (AG3) is arranged; and / or a third device (WZ3) for supplying an extraction agent, preferably water, between the third device (V3), in particular the third recording device (AG3), and the fourth device (V4), in particular the fourth recording device (AG4), is arranged.

System according to one of the numbers 40 to 42, characterized in that the first device (WZ1), the second device (WZ2) and / or the third device (WZ3) each as an outlet, preferably as a nozzle, in particular as a flat jet nozzle, spray head, or Spray ball, are formed.

System according to one of the numbers 20 to 43, characterized in that the system comprises at least one damming element;

wherein preferably a first baffle element is arranged downstream of the first device (VI) and upstream of the second device (V2); and or

preferably a second baffle is disposed downstream of the second device (V2) and upstream of the third device (V3); and or

wherein preferably a third damming element is arranged downstream of the third device (V3) and upstream of the fourth device (V4).

Process for the continuous or discontinuous treatment of a medium (M), preferably for separating solids from the medium (M), im Field of food, drug and beverage production, wherein the medium (M) is a suspension or a precursor thereof;

Method with the steps:

(a) providing the medium (M);

(b) separating the medium (M) into a liquid phase (WO) and a residual phase (RM); characterized in that

Step (b) is carried out using the device (V) according to one of the numbers 1 to 16 or the system according to one of the numbers 20 to 44.

Process for the continuous or discontinuous treatment of a suspension (MA), preferably a suspension (MA) containing plant constituents, in particular for separating a liquid or a solid from the suspension (MA), in the field of foodstuffs, medicaments and stimulants, with the steps :

(A) feeding the suspension (MA) to a first receiving means (AG1) of a first device (VI), wherein the first device (VI) is preferably a device according to one of the numbers 1 to 16;

(b) separating the suspension (MA) in the first device (VI) by means of a first separation device (T1) into a first liquid phase (WO1) and a first residual phase (RM1);

wherein the suspension (MA) is brought into contact with a first surface (FA1) of the first separation device (T1),

wherein the filtrate or permeate is the first liquid phase (WOI) and the filter residue or retentate is the first residual phase (RM1);

wherein during the separation of the suspension (MA) into the first liquid phase (WOl) and the first residual phase (RM1) the first surface (FA1) for Suspension (MA), the first remaining phase (RM1) and / or the first receiving device (AG1) relatively moved or

during the separation of the suspension (MA) into the first liquid phase (WO1) and the first residual phase (RM1), the first surface (FA1) rotates about a first center axis or axis (AX1) of the first separation device (T1); and

wherein the relative movement or rotational movement of the first surface (FA1) takes place continuously or intermittently, preferably at regular time intervals, throughout the duration of separation of the suspension (MA).

(b) separating the suspension (MA) in the first device (VI) into a first liquid phase (WO1) and a first residual phase (RM1), by means of separating or filtering the suspension (MA) with the aid of a first surface (FA 1) a first separation device (T1); wherein the filtrate or permeate is the first liquid phase (WOI) and the filter residue or retentate is the first residual phase (RM1);

the separation being driven by the hydrostatic pressure of the suspension (MA) and / or another pressure acting on the suspension (MA) and / or a negative pressure acting on the first residual phase (RM1); wherein during the separation of the suspension (MA) into the first liquid phase (WO1) and the first residual phase (RM1), the first surface (FA1) to the suspension (MA) present in the device (VI), in the first device ( VI), the first remaining phase (RM1) and / or the first recording device (AG1) are relatively moved, or

the first surface (FA 1) rotates during the separation of the suspension (MA) about a first axis (AX1) of the first separation device (T1); and

wherein the relative movement or rotational movement of the first surface (FAl) takes place continuously or intermittently, preferably at regular time intervals, during the entire duration of the separation of the suspension (MA).

A method according to any one of 56, 58 or 59, further comprising the steps of:

(c) mixing a predefined volume of an extractant, preferably water or a liquid phase, preferably the third liquid phase (W03), with the first residual phase (RM1) obtained in the separation according to step (b), wherein a first mixture (MX1 ) is received;

(d) before step (c): supplies of the first residual phase (RMl) to the second receiving device (AG2) of the second device (V2); or

after step (c): feeding the first mixture (MX1) to the second receiving device (AG2) of the second device (V2);

the second device (V2) preferably being a device according to any of the numbers 1 to 16;

(e) separating the first mixture (MX1) thus obtained into a second liquid phase (W02) and a second residual phase (RM2), by means of a second separation device (T2) or by separating or filtering the first mixture (MX1) with the aid of a second one Surface (FA2) of the second Trennvorri rect (T2) in the second device (V2); wherein the filtrate or permeate is the second liquid phase (WO 2) and the filter residue or the retentate is the second residual phase (RM 2); wherein the separation is driven by the hydrostatic pressure of the first mixture (MX1) and / or another pressure acting on the first mixture (MX1) and / or a negative pressure acting on the second residual phase (RM2); wherein, during the separation of the first mixture (MX1) into the second liquid phase (W02) and the second residual phase (RM2), the second surface (FA2) relative to the first mixture (MX1) present in the second device (V2) in the second device (V2) existing second residual phase (RM2) and / or the second receiving device (AG2) moves or during the separation of the first mixture (MXl) in the second liquid phase (W02) and the second residual phase (RM2) the second surface (FA2) rotates about a second axis (AX2) of the second separator (T2); and wherein the relative movement or rotational movement of the second surface (FA2) takes place continuously or intermittently, preferably at regular time intervals, during the entire duration of the separation of the first mixture (MX1).

Method according to item 60, further comprising the steps of:

(f) mixing a predefined volume of an extracting agent, preferably water or a liquid phase, preferably the fourth liquid phase (W04), with the second residual phase (RM2) obtained in the separation according to step (e), a second mixture (MX2 ) is received;

(g) before step (f): supplying the second residual phase (RM2) to the third receiving device (AG3) of the third device (V3); or after step (f): supplying the second mixture (MX2) to the third receiving device (AG3) of the third device (V3);

the third device (V3) preferably being a device according to one of the numbers 1 to 16;

(h) separating the second mixture (MX2) thus obtained into a third liquid phase (W03) and a third residual phase (RM3), by means of a third separation device (T3) or by separating or filtering the second mixture (MX2) with the aid of a third one Surface (FA3) of the third separator (T3) in the third device (V3); wherein the filtrate or permeate is the third liquid phase (W03) and the filter residue or the retentate is the third residual phase (RM3); wherein the separation is driven by the hydrostatic pressure of the second mixture (MX2) and / or another pressure acting on the second mixture (MX2) and / or a negative pressure acting on the third residual phase (RM3); wherein during the separation of the second mixture (MX2) into the third liquid phase (W03) and the third residual phase (RM3), the third surface (FA3) to the second mixture (MX2) present in the third device (V3), in which Third device (V3) existing third residual phase (RM3) and / or to the third receiving device (AG3) relatively moved, or during the separation of the second mixture (MX2) in the third liquid phase (W03) and the third residual phase (RM3) the third surface (FA3) rotates about a third axis (AX3) of the third separator (T3); and

wherein the relative movement or rotation of the third surface (FA3) occurs continuously or intermittently, preferably at regular time intervals, throughout the duration of the separation of the second mixture (MX2). The method of paragraph 61, further comprising the steps of:

(i) mixing a predefined volume of an extractant, preferably water or a liquid phase, with the third residual phase (RM3) obtained in the separation of step (h) to obtain a third mixture (MX3);

(j) before step (i): supplying the third residual phase (RM3) to a fourth receiving device (AG4) of the fourth device (V4); or

after step (i): supplying the third mixture (MX3) to the fourth receiving device (AG4) of the fourth device (V4);

the fourth device (V4) preferably being a device (V) according to one of the numbers 1 to 16;

(k) separating the third mixture (MX3) thus obtained into a fourth liquid phase (W04) and a fourth residual phase (RM4) by means of a fourth separation device (T4) or by separating or filtering the third mixture (MX3) with the aid of a fourth one Surface (FA4) of the fourth separator (T4) in the fourth device (V4); wherein the filtrate or permeate is the fourth liquid phase (W04) and the filter residue or the retentate is the fourth residual phase (RM4);

wherein the separation is driven by the hydrostatic pressure of the third mixture (MX3) and / or another pressure acting on the third mixture (MX3) and / or a negative pressure acting on the fourth residual phase (RM4); wherein during the separation of the third mixture (MX3) into the fourth liquid phase (W04) and the fourth residual phase (RM4), the fourth surface (FA4) to the third mixture (MX3) present in the fourth device (V4), in which fourth device (V4) existing fourth residual phase (RM4) and / or to the fourth receiving device (AG4) relatively moved, or during the separation of the third mixture (MX3) into the fourth liquid phase (W04) and the fourth residual phase (RM4), the fourth surface (FA4) rotates about a fourth axis (AX4) of the fourth separator (T4); and

wherein the relative movement or rotation of the fourth surface (FA4) occurs continuously or intermittently, preferably at regular time intervals, throughout the duration of the third mixture (MX3) separation.

Method according to one of the numbers 56 or 58 to 62, characterized in that the relative movement is a rotational movement in the counterclockwise or counterclockwise direction, preferably in the counterclockwise direction, the direction of rotation being determined from the viewing direction at which the inflowing medium to be separated , Preferably, the suspension to be separated (MA) or residual phase (RM1, RM2, RM3) or the mixture (MX1, MX2, MX3) flows from the left into the device and the dissipated residual phase, the device (VI, V2, V3, V4) after leaves right; and or

the relative movement of the first surface (FA1), the second surface (FA2), the third surface (FA3) and / or the fourth surface (FA4) at a speed in the range of 0.01 to 2.5 m / s, in particular 0.01 to 1.8 m / s; and or

the rotational movement of the first surface (FA 1), the second surface (FA 2), the third surface (FA 3) and / or the fourth surface (FA 4) at a speed in the range of 1 to 60 U / min, preferably 1 to 40 U / min, preferably 1 to 30 U / min, preferably 1 to 20 U / min, in particular 1 to 12 U / min, takes place; and or

the rotational movement of the first surface (FA1), the second surface (FA2), the third surface (FA3) and / or the fourth surface (FA4) at a peripheral velocity or tip velocity in the range of 0.01 to <2, 0 m / s, preferably 0.05 to 1.8 m / s, preferably 0.1 to 1, 5 m / s, in particular 0.2 to 1, 5 m / s, takes place. Method according to one of the numbers 56 or 58 to 63, characterized in that the feeding of the suspension (MA) in step (a), the feeding of the first residual phase (RM1) or of the first mixture (MX1) in step (d), the Supplying the second residual phase (RM2) or the second mixture (MX2) in step (g) and / or supplying the third residual phase (RM3) or the third mixture (MX3) in step (j) in the range of 0.25 to < 2.0 m / s, preferably 0.3 to 1, 8 m / s, preferably 0.5 to 1, 5 m / s, in particular 0.8 to 1, 5 m / s, takes place.

Method according to one of the numbers 56 or 58 to 64, characterized in that it further comprises the step:

(1) using the first liquid phase (WO 1), the second liquid phase (W02), the third liquid phase (W03) or the fourth liquid phase (W04) for the production of a food, drug or beverage.

Method according to one of the numbers 56 or 58 to 65, characterized in that it further comprises the steps:

(M) producing a mixture of at least two arbitrary liquid phases, in particular from two, three or four arbitrary liquid phases selected from the group consisting of the first liquid phase (WOl), the second liquid phase (W02), the third liquid Phase (W03) and the fourth liquid phase (W04); and

(n) using the mixture (WOMX) resulting in step (j) for the manufacture of a foodstuff, pharmaceutical or beverage.

Method according to one of the numbers 56 or 58 to 66, characterized in that during the separation of the suspension (MA) the contact of the first surface che (FA1) or a partial surface thereof with the in the first receiving means (AG 1) existing suspension (MA) by the execution of the relative movement or rotational movement of the first surface (FA1) temporarily interrupted and restored after interruption;

wherein the interruption and restoration of the contact of the first surface (FA1) or a partial surface thereof with the suspension (MA) is preferably repeated.

Method according to one of the numbers 56 or 58 to 67, characterized in that, during the separation of the first residual phase (RM1), the contact of the second surface (FA2) or a partial surface thereof with the first residual phase (RM1) present in the second receiving device (AG2) ) is temporarily interrupted by the execution of the relative movement or rotational movement of the second surface (FA2) and restored after interruption; wherein the interruption and restoration of the contact of the second surface (FA2) or a partial surface thereof with the first residual phase (RM1) is preferably repeated.

Method according to one of the numbers 56 or 58 to 67 or 70, characterized in that during the separation of the second residual phase (RM2) the contact of the third surface (FA3) or a partial surface thereof with the second residual phase present in the third receiving device (AG3) (RM2) is temporarily interrupted by the execution of the relative movement or rotational movement of the third surface (FA3) and restored after interruption;

wherein the interruption and restoration of the contact of the third surface (FA3) or a partial surface thereof with the second residual phase (RM2) is preferably repeated. Method according to one of the numbers 56 or 58 to 67 or 70 or 71, characterized in that during the separation of the third residual phase (RM3) the contact of the fourth surface (FA4) or a partial surface thereof with that in the fourth receiving device (AG4) third residual phase (RM3) is temporarily interrupted by the execution of the relative movement or rotation of the fourth surface (FA4) and restored after the interruption;

wherein the interruption and restoration of the contact of the fourth surface (FA4) or a portion thereof with the third residual phase (RM3) is preferably repeated.

Method according to one of the numbers 56 or 58 to 67 or 70 to 72, characterized in that during the separation of the suspension (MA) according to step (b) the first surface (FA1) in a proportion in the range of 1 to 95%, preferably from 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 10 to 90%, preferably 15 to 80%, preferably 20 to 80%, preferably 20 to 70%, preferably 20 to 60%, preferably 20 to 50%, preferably 20 to 40%, preferably 30 to 40%, preferably 5 to 80%, preferably 5 to 40%, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, preferably 5 to 15 %, in particular 20 to 30%, of the suspension (MA) is covered or immersed in the suspension (MA), and the first surface (FA1) in the amount of the remaining portion preferably in a first gas-filled space (GR1) above or above the Suspension (MA) is arranged or protrudes in it.

Method according to one of the numbers 56 or 58 to 67 or 70 to 73, characterized in that during the separation of the first mixture (MXl) according to step (e) the second surface (FA2) is in a proportion in the range from 1 to 95%, preferably from 5 to 95%, preferably from 5 to 75%, preferably from 5 to 50%, preferably from 10 to 90%, preferably from 15 to 80%, preferably from 20 to 80%, preferably 20 to 90%, preferably 30 to 80%, preferably 35 to 70%, preferably 5 to 80%, preferably 5 to 40%, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20% , preferably 5 to 15%, in particular 40 to 60%, of the first mixture (MX1) is covered or immersed in the first mixture (MX1).

75. The method according to any of the numbers 56 or 58 to 67 or 70 to 74, characterized in that during the separation of the second mixture (MX2) according to step (h), the third surface (FA3) in a proportion in the range of 1 to 95

%, preferably from 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 10 to 90%, preferably 20 to 90%, preferably 30 to 80%, preferably 35 to 70%, preferably 5 to 80% , preferably 5 to 40%, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, preferably 5 to 15%, in particular 40 to 60%, of the second mixture

(MX2) is covered or immersed in the second mixture (MX2).

76. The method according to one of the numbers 56 or 58 to 67 or 70 to 75, characterized in that during the separation of the third mixture (MX3) according to

Step (k) the fourth surface (FA4) in an amount ranging from 1 to 95%, preferably from 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 10 to 90%, preferably 20 to 90 %, preferably 30 to 80%, preferably 35 to 70%, preferably 5 to 80%, preferably 5 to 40%, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, preferably 5 to 15%, in particular 40 to 60%, is covered by the third mixture (MX3) or immersed in the third mixture (MX3).

77. The method according to any of the numbers 56 or 58 to 67 or 70 to 76, characterized in that at least one medium selected from the group consisting of the suspension (MA), the first liquid phase (WOl), the second liquid phase W02), the third liquid phase (W03), the fourth liquid phase (W04), the first residual phase (RM1), the second residual phase (RM2), the third residual phase (RM3), the fourth residual phase (RM4), first mixture (MX1), the second mixture (MX2) and the third mixture (MX3), while at least one of the steps (a, b, d, e, g, h, j and k) is gravity-driven, in particular only gravitationally driven ,

Process for the continuous or discontinuous treatment of a medium (M), preferably for separating solids from the medium (M), in the field of foodstuffs, pharmaceuticals and luxury goods production, wherein the medium (M) is a suspension or a precursor thereof; Method with the steps:

(A) supplying the medium (M) to a first receiving means (AG1) of a first device (VI), wherein the first device (VI) is preferably a device according to one of the numbers 1 to 16;

(B) separating the medium (M) in the first device (VI) into two fractions by means of separating or filtering the medium (M) with the aid of a first surface (FAl) of a first separation device (Tl); wherein the separation is driven by the hydrostatic pressure of the medium (M) and / or another pressure acting on the medium (M) and / or a negative pressure acting on one of the fractions; wherein, during the separation of the medium (M), the first surface (FAl) relatively moves to the medium (M) present in the device (VI), to one of the resulting fractions and / or to the first receiving device (AG1), or

the first surface (FAI) rotates during the separation of the medium (M) about a first axis (AX1) of the first separation device (T1); and wherein the relative movement or rotation of the first surface (FA1) occurs continuously or intermittently, preferably at regular time intervals, throughout the period of separation of the medium (M).

79. Method according to number 78, characterized in that the method further comprises at least one of the features of Nos. 56 or 58 to 67 or 70 to 77.

100. Use of a device according to one of the numbers 1 to 16 or a system according to one of the numbers 20 to 44 for the continuous or discontinuous recovery of a liquid phase (WO) and / or a residual phase (RM) from a suspension (MA), preferably from a suspension (MA) containing plant components, preferably for separating the suspension (MA), preferably containing plant components, in the liquid phase (WO) and / or the residual phase (RM), in particular for separating a liquid or a solid from the suspension (MA ), in the field of food, drug and beverage production.

101. Use of a device according to one of the numbers 1 to 16 or a system according to one of the numbers 20 to 44 for the continuous or discontinuous treatment of a medium (M), preferably for separating a liquid and / or a solid from the medium (M), in the field of food, drug and beverage production;

wherein the medium (M) is a suspension or a precursor thereof.

102. Use of a separating device (T), preferably a filter, in particular a separating device (T; Tl, T2) according to one of the numbers 1 to 16, for the continuous obtaining a liquid phase (WO) from a suspension (MA) in the field of food, medicament and beverage production in a continuous or discontinuous manner;

wherein the separation device (T) has a surface (FA) with a plurality of openings with a size or pore size or mesh size in the range of 5 to 10,000 μπι, preferably 10 to 1000 μη, preferably 25 to 500 μπι, preferably 45 to 350 μπι, preferably 55 to 300 μιη, in particular 65 to 250 μηι, has;

wherein during the recovery of the liquid phase (WO), the surface (FA) is relatively moved to the suspension (MA);

wherein during the recovery of the liquid phase, the surface area (FA) is in an amount in the range of 1 to 95%, preferably 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 10 to 90%, preferably 15 to 80%, preferably 20 to 80%, preferably 20 to 70%, preferably 20 to 60%, preferably 20 to 50%, preferably 20 to 40%, preferably 30 to 40%, preferably 5 to 80%, preferably 5 to 40 %, preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, preferably 5 to 15%, in particular 20 to 30%, of the suspension (MA) is covered or immersed in the suspension (MA).

Use according to number 102, characterized in that the separating device is designed as a separating device with a rotatably mounted separating or filtering surface or as a rotatably mounted separating device or rotatably mounted filter; and or

the separator is formed in a disc-shaped or cylindrical shape or substantially disc-shaped or cylindrical shape; and / or wherein the base surface and / or the lateral surface of the separating device or a part of the base surface and / or the lateral surface is partially or completely formed as a separating or filtering surface; and or

wherein the separation device is arranged in the system such that the central axis or a rotation axis of the separation device is substantially parallel to a Liquid level (LL) of the existing in the vicinity of the separator suspension (MA) is arranged, or

the center axis or a rotation axis of the separation device with the liquid level (LL) of the existing in the vicinity of the separator suspension (MA) or with the horizontal angle with an amount in the range of 0.1 to 45 °, preferably 0.1 to 20 ° , preferably 0.5 to 10 °, preferably 0.5 to 8 °, preferably 0.5 to 6 °, in particular 0.5 to 4 ° includes.

The inventors of the present application have recognized that the process step of the treatment, in particular the separation of a suspension whose solids content preferably contains Pflanzenbestan parts or consists of Pflanzenbestanteilen, can be significantly shortened if in the treatment or separation of the structure of a solid layer, preferably consisting from plant components of the suspension, in particular plant leaves or their components, as far as possible or completely avoided. According to the inventors, this is realized by moving an apertured surface relative to the presented suspension during separation of the suspension.

Due to the relative movement between the suspension and the surface of a separating device, the structure of a solid layer, preferably of plant components of the suspension, is at least largely avoided. As a result, the flow channels are kept free in the apertured surface of the separator, so that the liquid content of the suspension as it flows through the surface of the separator experiences a lower flow resistance compared to the conventional treatment or separation methods.

In contrast to conventional separation devices, according to the invention, a relative movement of the separation device to the suspension surprisingly ensures that no appreciable solid layer, preferably of plant constituents, builds up on the surface of the separation device during the passage of the liquid particles while retaining solids. Because the suspension, due to the relative movement, permanently or at least temporarily a somewhat "fresh", to the Seeing suitable surface surface, the flow resistance remains when flowing through the liquid or liquid phase through the separator substantially unchanged in the course of the separation. The inventors suspect that on the one hand by the relative movement between the

Suspension and the apertured surface of the separator, the structure of a solid layer is prevented. On the other hand, it is assumed that the constituents of the suspension, in particular the herbal

Solid particles, in conjunction with the described relative movement have an abrasive effect on the surface of the separator, so that the suspension in the separation of the invention has an unexpectedly high cleaning effect on the surface of the separator. As a result, the separation efficiency is significantly increased, and the required separation time significantly shortened. Since, according to the invention, even at high volume throughputs of the suspension, if at all, only a minimal blockage or minimal clogging of the surface of the separation device occurs, the recovery of the liquid phase according to the invention can be carried out continuously or discontinuously, with high volume flows and with a long service life. In contrast to the separation processes hitherto carried out as batch processes, the invention, when designed in the form of a continuous process or a continuously operated device, achieves shorter separation times, smaller devices and other advantages associated with continuous processes. In the course of the relative movement relative to the suspension, the contact of the

Surface of the separator or a part surface thereof are temporarily interrupted with the suspension. If the relative movement during the separation from the suspension is, for example, a rotary movement of the separating device or its surface, the surface or at least a partial surface thereof can emerge from the suspension and reenter the suspension at a later time. When this surface element of the separation device emerges from the suspension, it acts on the solid particles which may be adhering to the surface element. Substances on the one hand gravity. At the moment of the escape of a particle from the suspension, ie at the moment of detachment of the particle from the liquid surface, the buoyancy which still counteracts the force of gravity in the liquid body of the suspension also ceases to act, so that in total one reaches the center of the earth. directed force outweighs. On the other hand, the surface tension of the suspension acts on exiting the liquid, so that the adhering particles are inclined to remain on the surface of the suspension or even in the suspension accumulated on the separation device when a surface element of the separation device emerges from the suspension.

Thus, forces acting on the solid particles of the suspension act on the liquid level of the suspension in the region of the interface with the surface or filter surface of the separator, whereby these forces can oppose the relative movement of the surface in the sum. Thus, solid particles entrained, entrained or temporarily adhering to the surface of the separator tend to develop a frictional action on the moving surface or filter surface of the separator on the surface, contrary to the relative movement.

It is believed that this further strengthens the above-described R eini effect tion and improved cleaning of the surface of the separator is achieved.

According to the invention, the surface of the separating device and / or the separating device can be made as such, for example, from stainless steel, copper, plastic, preferably polypropylene, or a fabric textile.

By the relative movement of the surface is carried out during the entire or at least predominantly duration of the separation, a permanent and thus temporally a maximum cleaning of the surface of the separator is achieved. The relatively moving surface of the separator may only be covered to a limited extent with the suspension or immersed in the suspension during the separation process. If the surface of the separating device is only partially covered with the suspension, solid particles which accumulate in the region of the mirror or the surface of the suspension due to the relative movement of the separating device can be surprisingly easily and effectively "carried along" by the moving surface of the separating device. It is also surprising that the discharged particles, ie the residual phase or a part thereof, are discharged relatively dry with a dry matter content of up to 75%. Such a dry discharge of the residual phase has not been achieved by the separation techniques used hitherto. The advantage of a high degree of coverage of the surface of the separation device with the suspension is a high filter area and thus a high throughput of suspension or residual phase and a high volume flow of recovered liquid phase.

The advantage of a medium to low degree of coverage of the surface of the separator with the suspension is that the space for enrichment and discharge, preferably as "dry" discharge, of solids from the suspension and ultimately from the device in the region of the surface of the separator above the level of the suspension is sufficiently available.

In view of the above-described circumstances, a degree of coverage or degree of immersion of the surface of the separator has been in the range of 1 to 60%, preferably 5 to 30%, preferably 5 to 20%, preferably 5 to 15%, preferably 5 to 10% proved particularly advantageous.

According to the invention, the gas-filled space of the device may contain a gas, the air or preferably an inert gas such as carbon dioxide, nitrogen or helium or mixtures thereof or consists thereof. Through the use of inert gases, a disadvantageous oxidation of the suspension or of the liquid phase and residual phase obtained therefrom can be prevented. By choosing the optimal pore size, depending on the composition of

Suspension of the volume flow of the recovered liquid phase and their properties can be set advantageously in terms of their material composition. Thus, at a pore size of at least 65 μι a satisfactory volume flow of the recovered liquid phase is achieved. If a pore diameter of greater than 350 μηι chosen, although a high volume flow of liquid phase is achieved, however, where appropriate, a sufficient separation of coarser particles no longer takes place.

Furthermore, the separation device can be designed as a rotatably mounted separating device or as a rotatably mounted filter. In particular, the axis of rotation of the separation device may include, with the liquid level of a liquid filled in the receiving device of the device, a small angular amount as described above. By this arrangement, in which the openings provided with the surface of the separating device is arranged perpendicularly or approximately perpendicularly to the mirror of the suspension, a high relative velocity of the suspension to the surface of the separating device is achieved when rotating the separating device. As a result, a good cleaning of the surface is achieved.

In the embodiment of the separation device in disk-shaped configuration in which the base surface is formed as a surface having the openings, or separating surface, a separator of compact design can be achieved with a high ratio of surface with a release effect to the total area.

By preferably selecting the spatial arrangement of the central axis or the axis of rotation of the separating device or its surface approximately parallel to the surface of the suspension, wherein deviations from the parallel orientation within certain limits to achieve the effects of the invention are quite possible, the relative movement of the surface, the partial covering of the surface or the partial immersion in the suspension, a good cleaning of the surface and a high solids discharge with a structurally simple device with easy handling can be achieved.

In addition, by a more or less vertical arrangement of the surface to the mirror of the suspension in combination with the only partial covering of the surface with the suspension and the rotational movement to the separation of a relatively "dry" residual phase, so a concentrated suspension, In the region where the surface of the separating device emerges from the surface of the suspension during the rotational movement, it is surprisingly even possible to discharge a relatively "thick" residual phase or even relatively dry solid particles from the suspension and finally from the separating device. It is particularly advantageous if the surface of the separating device is movable or movable relative to the suspension, the residual phase and / or the receiving device of the device such that a plurality of surface elements, the surface of the separating device, which are covered by the suspension during separation, emerge from the suspension in the course of the relative movement and are at least temporarily not covered by the suspension in order to submerge again into the suspension in the further course of the relative movement.

If the suspension or a residual phase can flow through the device according to the invention solely by gravity, the construction of the device according to the invention, for example by eliminating pumps, etc., becomes considerably simpler.

In addition, according to the invention, the energy consumption for operating the device is reduced by 40% or more compared with a conventional separating device. Furthermore, the power consumption peaks of the devices or systems according to the invention are reduced by the lower consumption and / or the smaller number of consumers. This can reduce the required installed power. Furthermore, the energy input into the suspension to be separated and thus des- lower heating, which has a gentle effect on the product. By eliminating the need for pumping, the inflow pressure of the inflowing suspension or residual phase is lower, whereby the surface of the separator is additionally protected against blocking.

The surface of the separator may have a diverse shape, which brings a high flexibility of the system design. Preferred contours of the surface, such as convex, concave, wavy, or zigzag contours, may cause additional flow effects or turbulence on the surface of the separator near the surface, which moves in the suspension or residual phase and relative to the suspension or residual phase. As a result, the cleaning of the surface is further improved.

The provision of projections, such as webs or paddles, which project from the surface of the separating device, and are preferably arranged perpendicularly or substantially perpendicular or obliquely to the direction of relative movement of the surface of the separating device, improve the solids discharge from the suspension or residual phase and from the device. Particularly preferred is the provision of two separation devices per device whose separation-effective surfaces are arranged substantially parallel to each other and have a distance of not more than 50 cm, more preferably not more than 30 cm, to each other. In this way, a device of high compactness at large effective interface by the presence of two (separation active) surfaces of the separation or separating surfaces. If both surfaces also have the same or approximately the same direction of relative movement, in particular the same direction of rotation in space, and the two surfaces of the separation devices are spaced sufficiently small, a particularly effective discharge of solids from the suspension or residual phase and from the device achieved wherein the discharged solids have a relatively high dry matter content.

Similar effects are achieved if, in the presence of at least one separating device in the device, the distance to a wall of the device or in particular of the receiving device is sufficiently low, preferably not more than 50 cm, more preferably not more than 30 cm.

According to the invention, the control devices can be designed as separate control devices. However, they can also be realized in a single control device which performs the functions of the first, second, third and / or fourth control device according to the invention.

The advantages of the device according to the invention apply analogously to the system according to the invention.

By connecting several, preferably two to four or more, in particular up to ten, inventive devices in series, a multi-stage separation of solids or residual phases can be realized. In a system with multi-stage separation, by adjusting the pore sizes of the openings of the surfaces of the individual devices, for example downstream ever smaller pore sizes, clogging or blocking of the release surface can be completely avoided or delayed at least longer. As a result, the achievable total volume flow of the medium to be separated through the system is high.

In addition, other parameters, such as the degree of coverage or degree of immersion of the surface of the separation device with respect to the suspension or a residual phase, the shape of the respective separation device and in particular their respective surface and the other parameters, in the context of this application Device according to the invention or the system are called, in each separation device in the cascade-like arrangement, the individual technological conditions and objectives individually. As a result, the total increase in xibility of the system according to the invention and its adaptability to the medium to be separated or obtained.

In each case one portion of an extractant, preferably water, can be added to the respective residual phase between two separation stages in the form of one apparatus according to the invention. In the following separation stage, a liquid phase is then recovered in a correspondingly high dilution. The more separation stages the system comprises, the more far-reaching leaching of the remaining phase can be achieved. Alternatively or additionally, however, the extractant may also be added to the suspension in the device according to the invention, in particular in the receiving device.

Particularly efficient in terms of a high extraction yield and avoiding an undesirably high dilution of the resulting liquid phase is when the extractant is passed in countercurrent to the flow of the suspension and / or the residual phase or residual phases. Thus, for example, at the end of the series or cascade of devices or of the system, water can be used as the extraction agent and the liquid phase obtained in the last stage can be used as extractant, etc. in the second-last stage. In this way, a gradual enrichment of the extractant takes place in countercurrent to the suspension or residual phase.

Alternatively, however, a "fresh" extractant, such as water or an alcohol, can be used in each extraction step (mixing step).) Advantageous here is that the leaching is more efficient than in the countercurrent mode described above due to the higher concentration difference less total separation steps required, which reduces the equipment and the cost.

The advantages of the device according to the invention and of the system according to the invention apply analogously to the method according to the invention. In particular, it is part of the invention that all devices according to the invention for treating and in particular separating the suspension and / or all devices according to the invention for treating a medium (above Nos. 1 to 16) and / or all systems based on these devices (above no. 20 to 42) and / or all processes according to the invention for treating and in particular separating the suspension and all processes according to the invention for treating a medium (above No. 56 or 58 to 67 or 70 to 79) can be combined with one another. Analogously, all the features and advantages disclosed for the devices and methods according to the invention can also be applied to the uses explicitly and implicitly disclosed in this application and are also regarded as disclosed for the uses.

By supplying an extraction agent, in particular water, to the residual phase of the respective separation step and providing a device for this, which is in each case arranged in a separation device or in particular downstream to a device and upstream of the subsequent device, a targeted washing out of the suspension is achieved.

By placing a baffle in the flow path downstream of a device according to the invention and upstream of the subsequent device, i. in the flow path of the residual phase or diluted with the extractant residual phase between two devices, the suspension is forced to overflow a weir-like obstacle. Here, a sedimentation of solid particles in the storage area upstream of the storage element can be achieved, whereby the clarification is improved.

Particularly advantageous in terms of a substantial separation of solids and efficient recovery of soluble substances is the combination of a storage element and a device for supplying extractant, which are both each arranged between two devices according to the invention. For the uses according to the invention (above Nos. 100 to 103), the above-described advantages and effects of the corresponding devices or systems according to the invention apply analogously.

All devices (V) according to the invention and the systems based thereon can be operated batchwise in a batch process. However, it is particularly advantageous if the devices (V) according to the invention and the systems based thereon are operated continuously. Accordingly, the processes according to the invention or the individual process steps described in this application can be operated batchwise, that is, batchwise, or particularly advantageously, continuously. If the method according to the invention consists of several steps, then all the steps can be carried out continuously and thus the entire process can be carried out continuously. Alternatively, however, all steps can be carried out batchwise and thus the entire process can be carried out batchwise. However, the invention is not limited thereto. Accordingly, it is also part of the invention that continuous and discontinuous process steps can be combined as desired within the scope of the process according to the invention. The same applies to the embodiment of the device according to the invention, of the system according to the invention and of the uses according to the invention.

To the knowledge of the inventors, there has hitherto been no continuous process or apparatus for treating or separating a suspension which would satisfy the requirements in practice.

Alternatives and further revelation

The process steps described in this application can each be configured either as continuous or batchwise or batchwise. This is especially true for the steps "Treat", "Feed", "Disconnect", "Mix". Preferably, all the process steps associated with a process according to the invention are either continuous or batchwise or batchwise. staltet. Accordingly, the devices described in this application or

Systems suitable for carrying out a corresponding, continuous or discontinuous process. The same applies to the uses described in this application.

DESCRIPTION OF THE FIGURES / DESCRIPTION OF PREFERRED EMBODIMENTS OF THE INVENTION FIG. 1 shows a vertical sectional view of an embodiment of the device (V) according to the invention. This has a receiving device (AG) for receiving the suspension (MA) and at least one separating device (T) with a surface (FA) (hatched shown). The surface (FA) has a plurality of openings (OP), which are indicated in the figure for the sake of simplicity only in a partial region of the surface (FA). Preferably, the surface (FA) is provided in all its faces with openings to provide the largest possible filter area. In this embodiment, the receiving device (AG) is designed as a trough-shaped vessel. The separating device (T) is designed as a circular, disk-shaped filter element, on whose base surface the surface (FA) is arranged. The separating device (T) is rotatably mounted about a central axis. In this case, the central axis is aligned substantially parallel to the horizontal. The separator (T) can rotate in the illustration of Fig. 1, both in the, and counterclockwise. However, the direction of rotation is "counterclockwise." In the figure, the suspension (MA) flows from the left into the receiving device (AG) and covers the separating device (T) and in particular the surface (FA) in part In this case, liquid particles pass through the filter layer and are removed on the filtrate side as liquid phase (WO) in or beyond the separation device (T) relative movement by turning counterclockwise (see the arrow in Fig. 1), the surface covered by the suspension (FA) is in relative motion to the Suspension (MA). In addition, parts of the surface (FA) due to the rotation constantly emerge from the suspension (right half of the surface (FA)), while other parts of the surface (FA) (left half of the surface (FA)) again under the mirror of the suspension submerge and thus be covered again by the suspension (MA). On the right side of the device, the residual phase (RM) resulting from the separation of the liquid phase (WO) passes out of the device (V) by overflow and / or assisted by the rotating separation device (T). During rotation, in the region of the occurrence of the surface (FA), solid particles (FS), in particular relatively "dry" solid particles, can also be discharged from the device (V) due to the relative movement.

The device (V) according to the invention is shown in a horizontal sectional view in FIG. Here again the entry of the suspension (MA) into the receiving device (AG) and the passage through the surface (FA) to obtain the liquid phase (WO) is shown. In this embodiment, the device (V) comprises two separation devices (T), which are arranged substantially parallel and can rotate about a common axis of rotation (AX) (preferably in the same direction). In a particular embodiment, which is shown in Fig. 3, the

Device (V) a separating device (T) in the form of a rotating cylinder, whose two base surfaces each configured as a surface (FA). In this case, the liquid phase (WO) penetrates from the outside through the filter layers into the interior of the separator (D), where it is collected and withdrawn.

Fig. 4 illustrates a system according to the invention, which is designed as a series circuit or cascade of three devices according to the invention (V). After separating the suspension (MA) into the first liquid phase (WO1) and into the first residual phase (RM1) in the first device (VI), as described, the first liquid phase (WO1) is drawn off. At the same time, the generated first residual phase (RM1) passes from the first device or is actively discharged by means of the separating device (T), depending on the filling level of the suspension (MA) in the separating device (T). The discharged First residual phase (RML), an extractant, such as preferably water or a liquid phase (eg W03) from a later process step, for extracting the extractable substances still present in the first residual phase (RML) is added. The resulting first mixture (MX1) is separated in the second device (V2) analogous to the suspension (MA) in the first device (VI). The resulting second liquid phase (W02) is withdrawn and the remaining second residual phase (RM2) discharged from the second device (V2). In the third device (V3), the above-mentioned steps are analogous. In this case, with each further stage, a further depletion of the residual phase produced.

Both in the device (V) according to FIG. 1 and in the system according to the invention with three devices (VI, V2, V3) according to FIG. 4, all the media involved essentially flow through the device or the system ,

The discharge of the respective residual phase (RM1, RM2, RM3,...) From the respective device (VI, V2, V3,...) Can be effected both by providing only one device and a cascade of at least two devices (VI, V2 , V3, ...) as a function of the level of the suspension or residual phase in the device (VI, V2, V3, ...) by overflow. Alternatively, the respective residual phase (RM1, RM2, RM3,...) Can be removed from the respective separating device at a filling level below the overflow level by active transport of the respective residual phase, preferably by means of the moving separating device (T) or by means of a conveying device independent therefrom.

Claims

claims

Device (V) for the continuous or discontinuous treatment of a

Suspension (MA), preferably containing plant components, in particular for separating a liquid or liquid phase (WO), or a solid or a residual phase (RM) from the suspension (MA), in the food,

Pharmaceutical and luxury food production, at least with:

a receiving device (AG) for receiving the suspension (MA);

at least one separating device (T) having a surface (FA);

the surface (FA) having a plurality of openings (OP);

wherein the device (V) is preferably suitable, by means of the surface (FA) of the separating device (T), the suspension (MA) in the liquid phase (WO) and the

To separate residual phase (RM);

Apparatus according to claim 1, characterized in that the device (V), in particular the separation device (T), by means of a control device (C) is controllable such that a relative movement or rotational movement of the surface (FA) during the entire duration of the treatment Suspension (MA), in particular the separation of a liquid or a solid from the suspension (MA), takes place. Apparatus according to claim 1 or 2, characterized in that the openings (OP) a size or pore size or mesh size in the range of 5 to 10,000 μη, preferably 10 to 1,000 μπι, preferably 10 to 500 μπι, preferably 20 to 400 μηι, preferably 25 up to 500 μηι, preferably 30 to 300 μηι, preferably 40 to 250 μηι, preferably 45 to 350 μηι, preferably 45 to 200 μηι, preferably 45 to 100 μπι, preferably 55 to 300 μιη, in particular 65 to 250 μηι have.

Device according to one of claims 1 to 3, characterized in that the device (V) forms at least one flow path; and or

the at least one flow path can be traversed by a liquid, in particular by the suspension (MA), driven by gravity.

Device according to one of claims 1 to 4, characterized in that the device (V) one or more, preferably two, separating devices (T; Tl, T2);

wherein the separating devices (Tl, T2) are each designed as a separator with a rotatably mounted shaft or as a rotatably mounted separator or rotatably mounted filter; and or

wherein the two separation devices (T1, T2) are respectively arranged in the device (V) such that the central axis or a rotation axis of each of the two separation devices (T1, T2) or their surfaces (FA1, FA2) is substantially parallel to the liquid level of one is arranged in the receiving device (AG) of the device (V) filled liquid, or the central axis or a rotation axis of each of the two separating devices (Tl, T2) or their surfaces (FAl, FA2) with the liquid level of a in the receiving device (AG ) of the device (V) filled liquid or with the horizontal an angle with an amount in the range of 0 to <90 °, preferably 0 to 45 °, preferably 0 to 30 °, preferably 0 to 20 °, preferably 0 to 15 °, preferably 0 to 10 °, especially 0 to 5 °, includes; and or

wherein the two separation devices (T1, T2) are arranged in the device (V) and in such a way that the central axes or a rotation axis of each of the two separation devices (T1, T2) or their surfaces (FA1, FA2) makes an angle with an amount in Range from 0 to <90 °, preferably 0 to 45 °, preferably 0 to 30 °, preferably 0 to 20 °, preferably 0 to 15 °, preferably 0 to 10 °, especially 0 to 5 ° include; and or

wherein the two separating devices (T1, T2) have an identical center axis or axis of rotation or their central axes or axes of rotation are arranged collinearly in the device (V); and or

wherein the two separation devices (Tl, T2) are arranged in the device (V) that the largest, preferably measured parallel to the rotary shaft or normal distance between the two surfaces (FAl, FA2) of the two separation devices (Tl, T2) in Range of> 2 cm to 100 cm, preferably 3 to 50 cm, preferably 4 to 30 cm, preferably 5 to 25 cm, preferably 10 to 30 cm, in particular 10 to 20 cm; and or

the smallest, preferably parallel to the rotary shaft or normal distance measured distance between the two surfaces (FAl, FA2) of the two separation devices (Tl, T2) in the range of> 2 cm to 100 cm, preferably 3 to 50 cm, preferably 4 to 30 cm , preferably 5 to 25 cm, preferably 10 to 30 cm, in particular 10 to 20 cm.

6. Device according to one of claims 1 to 5, characterized in that the device (V) comprises means (WZ) for supplying an extractant, preferably water. A system for the continuous or discontinuous treatment of a suspension (MA), preferably containing plant constituents, in particular for separating a liquid or a solid from the suspension (MA), in the field of food, drug and beverage production, comprising at least: a first device (VI ), wherein the first device (VI) is preferably a device (V) according to one of claims 1 to 6;

wherein the first surface (FAI) has a plurality of openings (OP); wherein the first device (VI) is preferably suitable for separating a suspension (MA) into a first liquid phase (WO1) and a first residual phase (RM1) by means of the first surface (FA1) of the first separation device (T1);

wherein the first surface (FAl) is in contact with the suspension (MA) when the suspension (MA) for separation into the first liquid phase (WOl) and the first residual phase (RM1) in the first receiving means (AG1) is present ; wherein the first surface (F A 1) during operation of the first device (VI) to the suspension (MA), the first residual phase (RM1) and / or the first receiving means (AG1) is arranged relatively movable or movable or rotatable;

wherein the first device (VI), in particular the first separation device (T1), is preferably controllable by means of a first control device (Cl) such that a relative movement or rotational movement of the first surface (FAl) during the entire duration of the separation of the suspension (MA ) he follows.

System according to claim 7, characterized in that it further comprises:

a second device (V2), wherein the second device (V2) is preferably a device (V) according to one of claims 1 to 6; wherein the second device (V2) has a second receiving device (AG2), preferably a receptacle, for receiving the first residual phase (RM1) or a mixture containing the first residual phase (RM1);

the second surface (FA2) having a plurality of openings (OP); wherein the second device (V2) is preferably adapted to separate a first residual phase (RM1) into a second liquid phase (W02) and a second residual phase (RM2) by means of the second surface (FA2) of the second separation device (T2); wherein the second surface (FA2) is in contact with the first residual phase (RM1) when the first residual phase (RM1) for separating into the second liquid phase (W02) and the second residual phase (RM2) in the second receiving device (AG2) is available;

wherein the second surface (FA2) during operation of the second device (V2) to the first residual phase (RM1), the second residual phase (RM2) and / or the second receiving device (AG2) is arranged relatively movable or movable or rotatable; and

wherein the second device (V2), in particular the second separation device (T2), is preferably controllable by means of a second control device (C2) such that the relative movement of the second surface (FA2) during the entire duration of the separation of the first residual phase (RM1) continuously or intermittently, in particular at regular intervals.

9. System according to claim 7 or 8, characterized in that two, three, four or more, preferably up to ten, devices selected from the group consisting of the first device (VI), the second device (V2), a third device (V3) and a fourth device (V4) are connected in series or in parallel.

10. System according to any one of claims 7 to 9, characterized in that the first device (VI), in particular the first receiving device (AG1), a first means (WZ1) for supplying an extractant, preferably of water, has; and or

the second device (V2), in particular the second receiving device (AG2), has a second device (WZ2) for supplying an extraction agent, preferably water; and or

11. System according to one of claims 7 to 10, characterized in that

a first device (WZ1) for supplying an extraction agent, preferably water, between the first device (VI), in particular the first receiving device (AG1), and the second device (V2), in particular the second receiving device (AG2) is arranged; and / or a second device (WZ2) for supplying an extraction agent, preferably water, between the second device (V2), in particular the second receiving device (AG2), and the third device (V3), in particular the third receiving device (AG3), is arranged; and / or a third device (WZ3) for supplying an extracting agent s, preferably water, between the third device (V3), in particular the third receiving device (AG3), and the fourth device (V4), in particular the fourth receiving device (AG4 ) is arranged.

System according to one of claims 7 to 1 1, characterized in that the first device (WZ1), the second device (WZ2) and / or the third Device (WZ3) in each case as an outlet, preferably as a nozzle, in particular as a flat jet nozzle, spray head, or spray ball, are formed.

13. System according to any one of claims 7 to 12, characterized in that the system comprises at least one baffle element;

14. A process for the continuous or discontinuous treatment of a suspension (MA), preferably a suspension (MA) containing plant components, in particular for separating a liquid or a solid from the suspension (MA), in the field of food, drug and beverage production, with the steps:

(A) feeding the suspension (MA) to a first receiving device (AG1) of a first device (VI), wherein the first device (VI) is preferably a device according to one of claims 1 to 6;

wherein the filtrate or permeate is the first liquid phase (WOI) and the filter residue or retentate is the first residual phase (RM1); wherein during the separation of the suspension (MA) into the first liquid phase (WO1) and the first residual phase (RM1), the first surface (FA1) to the suspension (MA), the first residual phase (RM1) and / or the first receiving device ( AG1) is relatively moved or

The method of claim 14, further comprising the steps of:

(c) mixing a predefined volume of an extractant, preferably water or a liquid phase, preferably the third liquid phase (W03), with the first residual phase (RM1) obtained in the separation according to step (b), wherein a first mixture (MXl ) is received;

(d) before step (c): supplying the first residual phase (RM1) to the second receiving device (AG2) of the second device (V2); or

after step (c): supplying the first mixture (MX1) to the second receiving device (AG2) of the second device (V2);

wherein the second device (V2) is preferably a device according to any one of claims 1 to 6;

(e) separating the first mixture (MX1) thus obtained into a second liquid phase (W02) and a second residual phase (RM2) by means of a second separation device (T2) or by separating or filtering the first mixture (MX1) with the aid of a second surface (FA2) of the second separator (T2) in the second device (V2); wherein the filtrate or permeate is the second liquid phase (WO 2) and the filter residue or the retentate is the second residual phase (RM 2); wherein the separation is driven by the hydrostatic pressure of the first mixture (MX1) and / or another pressure acting on the first mixture (MX1) and / or a negative pressure acting on the second residual phase (RM2); wherein during the separation of the first mixture (MX1) into the second liquid phase (W02) and the second residual phase (RM2), the second surface (FA2) relative to the first mixture (MX1) present in the second device (V2) in the second device (V2) existing second residual phase (RM2) and / or the second Aufnahmeei device (AG2) moves or

during the separation of the first mixture (MX1) into the second liquid phase (W02) and the second residual phase (RM2), the second surface (FA2) rotates about a second axis (AX2) of the second separation device (T2); and wherein the relative movement or rotation of the second surface (FA2) takes place continuously or intermittently, preferably at regular time intervals, during the entire duration of the separation of the first mixture (MX1).

Use of a device according to one of claims 1 to 6 or a system according to one of claims 7 to 13 for the continuous or discontinuous recovery of a liquid phase (WO) and / or a residual phase (RM) from a suspension (MA), preferably from a suspension (MA) containing plant components, preferably for separating the suspension (MA) containing plant constituents in the liquid phase (WO) and / or the residual phase (RM), in particular for separating a liquid or a solid from the suspension (MA), in the Food, drug and beverage production. Use of a separating device (T), preferably a filter, in particular a separating device (T; Tl, T2) according to one of claims 1 to 6, for the continuous or discontinuous recovery of a liquid phase (WO) from a suspension (MA) in the area of Nahrangs , Medicine and stimulant production;

wherein the separation device (T) has a surface (FA) with a plurality of openings having a size or pore size or mesh size in the range of 5 to 10,000 μπι, preferably 10 to 1,000 μηι, preferably 25 to 500 μη, preferably 45 to 350 μιη, preferably 55 to 300 μηι, in particular 65 to 250 μηι, has;

wherein, during the recovery of the liquid phase, the surface area (FA) is in an amount ranging from 1 to 95%, preferably 5 to 95%, preferably 5 to 75%, preferably 5 to 50%, preferably 10 to 90%, preferably 15 to 80%, preferably 20 to 80%, preferably 20 to 70%, preferably 20 to 60%, preferably 20 to 50%, preferably 20 to 40%, preferably 30 to 40%, preferably 5 to 80%, preferably 5 to 40% , preferably 5 to 30%, preferably 5 to 25%, preferably 5 to 20%, preferably 5 to 15%, preferably 5 to 10%, in particular 20 to 30%, of the suspension (MA) or in the suspension ( MA).