CAPSULE RECOGNITION SYSTEM

Abstract

The present invention relates to a capsule for a beverage production machine, the capsule comprising: —an ingredient enclosed within the capsule; and —an identifier; wherein the identifier is an area of conductive material incorporating a code pattern, the code pattern consisting of a predetermined arrangement of one or more discontinuities formed in the conductive material, and wherein the capsule comprises an orientation member for directing the alignment of the capsule within the beverage production machine.

Description

TECHNICAL FIELD OF THE INVENTION

The present invention relates to a recognition system for a capsule. In particular the invention relates to a coding system which allows the recognition of a capsule, for example in a beverage production machine.

BACKGROUND OF THE INVENTION

Automated beverage production machines which are designed to use portioned ingredients are already known. Often such machines use capsules containing a predetermined dose of beverage ingredient (e.g. ground coffee, cocoa powder, tea leaves). Such capsules are convenient to use and can facilitate the preparation of beverages that are consistent in terms of taste and quality.

The working parameters of beverage production machines may need to be varied according to the type of beverage being prepared. Several systems for identifying such capsules in order to control parameters in the beverage production machine have been proposed.

For example, international patent applications WO 2011/000723 and WO 2011/000724 (Nestec S.A.) describe beverage capsules comprising an identifier and a method for identifying such capsules in a beverage producing device. The identifier, which is preferably embedded within a beverage capsule, comprises a magnetically-responsive material enclosed in a plastic sheath. The magnetically-responsive material is capable of altering the voltage magnetic signal by producing at least one Barkhausen jump when excited by a magnetic field provided by an electromagnetic emitter. The composition of the magnetically-responsive material differs for each type of capsule but is identical for capsules of the same type. Hence the type of capsule can identified according to the alteration provided to the magnetic signal (e.g. by comparison with a number of reference magnetic patterns).

European patent application EP 0 451 980 (Kraft General Foods Limited) relates to packages containing comestibles for the preparation of beverages, which are preferably provided with a recognition means. Several possible systems are postulated, each comprising a particular recognition means and appropriate sensor. For example, the recognition means may comprise one or more surface features formed in the body of the package which can be identified by a mechanical sensor or an optical sensor; one or more strips of a magnetic material applied to the body of the package which can be read by an appropriate magnetic sensor; one or more shaped or divided areas of metal foil applied to the package body which cause an inductive effect on movement of the package in the machine, which inductive effect can be sensed; or one or more electrically conductive areas formed on the body of the package which can be sensed electronically.

International patent application WO 2011/141532 (Nestec S.A.) describes a capsule, system and method for preparing a beverage by centrifugation. The capsule comprises a code arranged to be read while the capsule is rotated around an axis of rotation traversing the capsule. Optical reading of a code that has been applied on the capsule by printing, embossing or Laser engraving is preferred. Inductive sensing of a code formed by reliefs or recesses provided on a circumferential metal rim of the capsule is also disclosed.

A problem with identifying a capsule in a beverage production machine is that retrieving or reading information from the capsule is not always reliable or convenient. For example, it is often necessary to use a coding system with a high level of redundancy in order to ensure that the capsule can be read in any orientation and/or in situations wherein the environment around the capsule is not clean (e.g. due to the presence of residual beverage material).

TESTS AND DEFINITIONS

As used herein the term “comprising” encompasses the terms “consisting essentially of” and “consisting of”. All percentages and ratios contained herein are calculated by weight unless otherwise indicated. It should be noted that in specifying any range of values or amount, any particular upper value or amount can be associated with any particular lower value or amount.

The disclosure of the invention as found herein is to be considered to cover all embodiments as found in the claims as being multiply dependent upon each other irrespective of the fact that claims may be found with multiple dependency or redundancy.

Beverage

As used herein the term “beverage” refers to a substantially aqueous drinkable composition suitable for human consumption. Preferably the beverage comprises at least 85% water by weight of the beverage, more preferably at least 90% and most preferably from 95 to 99.9%.

Beverage Ingredient

As used herein the term “beverage ingredient” refers to a food-grade substance than can be used to produce a beverage. Typically such an ingredient will be mixed with a liquid, preferably an aqueous liquid, in order to produce a beverage (e.g. by steeping, soaking, dissolution and/or suspension).

An “infusible beverage ingredient” refers to a beverage ingredient that when steeped or soaked in an aqueous liquid releases certain soluble substances into the liquid, e.g. flavour and/or aroma molecules. Preferred examples of infusible beverage ingredients are tea plant material, herb plant material and/or fruit pieces. Preferably the infusible beverage ingredient will be dried and have a moisture content of less than 30 wt %, preferably less than 20 wt % and most preferably from 0.1 to 10 wt %.

SUMMARY OF THE INVENTION

In a first aspect, the present invention relates to a capsule for a beverage production machine, the capsule comprising:

• • an ingredient enclosed within the capsule; and
  • an identifier;
    wherein the identifier is an area of conductive material incorporating a code pattern, the code pattern consisting of a predetermined arrangement of one or more discontinuities formed in the conductive material, and wherein the capsule comprises an orientation member for directing the alignment of the capsule within the beverage production machine.

The key to the present invention is the simplicity and reliability of the coding system. This permits recognition of the capsule over a wide range of tolerances without the need to build redundancy into the coding system and/or reduces the proportion of capsules rejected as void during the manufacturing process. The simplicity and reliability of the coding system is possible because the orientation member ensures that the capsule can only be aligned within the beverage production machine in one of a limited number of fixed orientations.

In a further aspect, the present invention relates to a method of recognising a capsule in a beverage production machine, the method comprising:

• • providing a capsule comprising:
    • an ingredient enclosed within the capsule;
    • an identifier, wherein the identifier is an area of conductive material incorporating a code pattern, the code pattern consisting of a predetermined arrangement of one or more discontinuities formed in the conductive material; and
  • an orientation member for directing the alignment of the capsule within the beverage production machine;
  • applying an alternating current to a coil, the coil being positioned in the beverage production machine such that it generates eddy currents within the identifier;
  • detecting a change in coil impedance;
  • generating a signal indicative of the change in coil impedance; and
  • identifying the capsule according to the signal.

This method provides a simple system for recognising a capsule within a beverage production machine. Such a system can have reduced complexity (e.g. by comprising fewer components) and/or be more economic to manufacture. This permits one or more working parameter of the beverage production machine to be varied according to the identity of the capsule, ultimately enabling a single beverage production machine to prepare a number of different beverages, each requiring distinct preparation conditions.

DETAILED DESCRIPTION

The present invention relates to a capsule for a beverage production machine. The capsule encloses an ingredient. Preferably this will be a beverage ingredient, although embodiments in which the capsule encloses a cleaning substance are also envisaged. Most preferably, the beverage ingredient comprises an infusible beverage ingredient (e.g. leaf tea).

The capsule can be of any suitable design. In order to facilitate efficient and cost-effective manufacture, it is preferred that the capsule is formed by injection moulding or by thermoforming. Preferably the capsule comprises a body part and a lid part, the lid part being attached to the body part so as to enclose the ingredient within the capsule. In this embodiment, the body part is preferably formed by injection moulding or by thermoforming, and the ingredient is subsequently enclosed within the capsule by attaching the lid part to the body part. In a particularly preferred embodiment, the body part comprises a rim, and the lid part is attached to the body part around the rim, e.g. by heat-sealing.

The capsule comprises an orientation member for directing the alignment of the capsule within the beverage production machine. The orientation member ensures that the capsule will be aligned within the beverage production machine in any one of n fixed orientations, wherein n is an integer. Preferably n is 1, 2, 3, 4, 5 or 6, more preferably n is 1, 2, 3 or 4, still more preferably n is 1 or 2 and most preferably n is 2. In certain preferred embodiments the capsule comprises a plurality of orientation members.

It is preferred that the orientation member(s) are integrally formed as part of the body part, more preferably as part of the rim. For example, the capsule base and/or rim may have fulcrum detents and/or protrusions of the rim perimeter to ensure that the capsule will be held any one of n fixed orientations within the beverage production machine.

In order to direct the alignment of the capsule holder within the beverage production machine, the beverage production machine comprises a capsule holder which can interact with the orientation member(s). For example, in embodiments wherein the orientation member is a protrusion, the capsule holder preferably comprises a corresponding recess adapted to receive the protrusion. Similarly, in embodiments wherein the orientation member is a recess, then the capsule holder preferably comprises a corresponding protrusion adapted to engage with the recess. An advantage of such arrangements is that the capsule is held in a fixed position within the beverage production machine. This ensures that the capsule is stationary during reading of the code pattern.

It should be noted that the orientation member is not necessarily a protrusion or an indent. In certain preferred embodiments the orientation member can consist of the shape of the capsule itself, wherein the shape of the capsule is adapted so as to limit the number of orientations of the capsule within the beverage production machine. This is most preferably achieved by providing a capsule wherein the base part is shaped such that it has a limited degree of rotational symmetry. For example, the capsule can be shaped such that the base part has 60° rotational symmetry (e.g. a substantially hexagonal base part), 72° rotational symmetry (e.g. a substantially pentagonal base part), 90° rotational symmetry (e.g. a substantially square base part), 120° rotational symmetry (e.g. a substantially triangular base portion), or 180° rotational symmetry (e.g. a substantially oval or substantially rectangular base portion).

In embodiments wherein the orientation member consists of the shape of the capsule, the capsule holder is adapted accordingly to ensure that it interacts with the shaped capsule and holds it in a stationary position within the beverage production machine (e.g. by preventing rotation of the capsule once it has been inserted therein). For example, if the base part of the capsule is substantially hexagonal in shape, the capsule holder will be adapted to receive such a capsule (preferably by providing the capsule holder with a substantially hexagonal recess, the recess being adapted to receive the substantially hexagonal capsule base).

The capsule comprises an identifier. The identifier is an area of conductive material incorporating a code pattern. The code pattern consists of a predetermined arrangement of one or more discontinuities formed in the conductive material. This coding system permits machine reading of the capsule, e.g. by a beverage production machine. Machine reading is also useful during capsule manufacture, particularly in relation to selection and/or packaging of the capsules.

The identifier may comprise any conductive material. Preferred examples of conductive materials include metallic foils, conductive inks and wire loops. In a particularly preferred embodiment the conductive material is metallic foil. In this embodiment the foil may be of any thickness, although metallic foil having a thickness of 10 to 100 μm is particularly preferred.

In certain preferred embodiments the capsule comprises a plurality of identifiers. The identifier(s) are arranged so as to enable detection of the capsule in any one of the fixed orientations dictated by the orientation member(s). In a preferred embodiment the capsule comprises a plurality of identifiers which are coded independently of one another.

The identifier(s) can be incorporated into the lid part or the base of the capsule or applied to the capsule as a label. For convenience of manufacture it is preferred that the lid part comprises the identifier(s). The code pattern can be located anywhere on the lid part. In a preferred embodiment each identifier is located towards the periphery of the lid part.

As described above, in certain embodiments the body part comprises a rim and the lid part is preferably attached to the body part around the rim. As such, the lid part consists of a peripheral rim portion and a central lidding portion. In these embodiments, is preferred that each identifier incorporated in the lid part. Preferably each identifier is located at least partially on the peripheral rim portion in order to minimise the likelihood of damaging the identifier during packaging and transport of the capsule. More preferably, each identifier is located wholly on the peripheral rim portion. However, it should be noted that it is also possible to locate the identifier wholly or partially on the central lidding portion, especially if the ingredient enclosed within the capsule is not air-sensitive.

In embodiments in which the lid part comprises the identifier(s), the lid part preferably comprises metallic foil, more preferably the lid part is a polymer/metallic foil laminate, most preferably a polymer/aluminium foil laminate. It is not necessary for the foil to be smooth prior to the incorporation of the code pattern. In fact, in order to allow sealing of the lid part to the body part to be controlled (e.g. in terms of seal strength), it is preferred that the foil is embossed.

It is preferred that the identifiers are arranged symmetrically. In particular, it is preferred that the identifiers have rotational symmetry. For example, the identifiers preferably have 60°, 72°90°, 120° or 180° rotational symmetry, more preferably 90°, 120° or 180° rotational symmetry, most preferably 180° rotational symmetry.

Recognition of the capsule is based on the principle of electromagnetic induction and metal detection. A coil carrying an alternating current and located close to the identifier induces eddy currents in the conductive material. The eddy currents produce an opposing electromagnetic flux that changes the impedance of the coil. The change in impedance is a function of the strength and freedom of the eddy currents to circulate in the conductive material.

Code patterns incorporated in the conductive material comprise discontinuities that constrain and weaken the strength of the eddy currents, and thereby affect the impedance of the coil. An electronic detection system (also referred to as an eddy current sensor) monitors the change in coil impedance in order to derive a signal. Further characteristics of the signal may be extracted by electronic and/or software processing. The processed signal can be associated with valid code patterns or invalid code patterns. For example, a valid code pattern may verify the integrity of the capsule or identify the capsule type (e.g. beverage variety, cleaning capsule), whereas an invalid code pattern can signify a void pattern, capsule reuse or simply that no capsule is present.

Each coil is excited with an alternating current (e.g. 10 mA, ˜200 kHz, and possibly phased/pulsed to avoid cross coupled interference). Although the diameter of the coil is not critical, it is preferably no more than 10 mm, more preferably no more than 8 mm. In one embodiment, the coil is configured in an electronic bridge circuit and the detection circuit includes an alternating waveform generator (oscillator, processor output etc), amplifier, filter, and further signal conditioning.

An advantage of this method of detection is that the coil and the eddy current sensor do not need to be in contact with the code pattern. This means that the recognition system works even if there is water and/or residual beverage ingredient between the coil and the code pattern. In order to ensure good signal differentiation, it is preferred that the coil and the code pattern are separated by a distance of 0 to 3 mm, more preferably 0 to 2 mm.

In order to function over a wide range of tolerances, it is preferable to have a low number of code patterns per coil and coarse pattern resolution. For example, 2 coils, each sensing 4 patterns per coil (A, B, C, D) provide 10 identification codes. This is sufficient to encode 9 different sets of machine parameters (e.g. 9 different brewing cycles and 1 cleaning cycle). In order to facilitate detection by a system comprising 2 coils, the code pattern is preferably symmetrical, and more preferably the code pattern has 180° rotational symmetry. The orientation member(s) in such an embodiment preferably ensure that the capsule will be aligned within the beverage production machine in either one of two possible orientations, wherein these orientations also have 180° rotational symmetry.

It should be noted that the code pattern does need to be exposed on the surface of the capsule. For example, the code pattern could be covered by a laminate. The laminate can be any material that does not support eddy currents. In order to protect the code pattern (e.g. during packaging of the capsule), it is preferred that the code pattern is wholly or partially covered by a layer of non-conductive material.

In a further aspect, the present invention relates to a method of recognising the capsule in a beverage production machine. The method comprises:

• • applying an alternating current to a coil, the coil being positioned in the beverage production machine such that it generates eddy currents within the identifier;
  • detecting a change in coil impedance;
  • generating a signal indicative of the change in coil impedance; and
  • identifying the capsule according to the signal.

This method enables a single beverage production machine to prepare a number of different beverages which require different preparation conditions. In a preferred embodiment, the capsule is identified by comparing the signal with a number of reference signals, each one corresponding to a certain type of capsule.

It is particularly preferred that identification of the capsule controls at least one parameter of the beverage production machine. For example, the at least one parameter can include modulating one or more of: temperature, pressure, volume and/or flow rate of a brewing liquid (which is preferably water). Additionally or alternatively, the at least one parameter can be air pressure or brewing time. It is also envisaged that identification of the capsule can determine which path(s) the brewing liquid follows within the beverage production machine.

The identifier and the coil are preferably stationary with respect to one another whilst the alternating current is being applied to the coil. This arrangement allows the capsule to be identified without requiring the capsule to be in motion. This reduces the time required to identify the capsule and/or increases the accuracy of the identification.

From the standpoint of hygiene, it is preferable that the capsules are disposable. In order to prevent capsule re-use, it is preferred that the code pattern is destroyed once the capsule has been identified. For example, destruction of the code pattern may be achieved by piercing the identifier(s).

FIGURES

By way of example, certain embodiments of the invention are illustrated by the figures, in which:

FIGS. 1a to 1c show a series of views of a capsule according to an embodiment of the invention.

FIG. 2 shows a cross-sectional side view of the capsule of FIG. 1 in a preferred reading mode.

FIG. 3 is a schematic diagram showing basic components of a beverage production machine.

FIGS. 4a to 4j illustrate a series of capsules according to an embodiment of the invention viewed from above, wherein each capsule is encoded with one of 10 possible identification codes.

FIGS. 5a to 5j illustrate a series of capsules according to an alternative embodiment of the invention viewed from above.

FIG. 6 illustrates a number of identifiers, wherein each identifier incorporates a possible code pattern.

FIGS. 1a to 1c show three different views of a capsule 1 for a beverage production machine according to an embodiment of the invention.

FIG. 1a is a cross-sectional side view of a capsule 1 comprising a body part 2 and a lid part 3. The lid part 3 is attached to the body part 2 around a flange-like rim 4. The body part 2 defines a compartment 5 which encloses an ingredient 6. The ingredient 6 is preferably a beverage ingredient, although it may also be a cleaning ingredient. The lid part 3 is attached to the body part 2 around the rim 4, thus sealing the ingredient 6 within the capsule 1. The capsule 1 comprises two orientation members 7a, 7b for directing the alignment of the capsule within the beverage production machine. In this embodiment, the orientation members 7a, 7b are fulcrum detents integrally formed in the underside of the rim 4.

FIG. 1b is a representation of the capsule of FIG. 1a viewed from above. In this embodiment the lid part 3 comprises perforations 8 along the inner edge of the rim 4 to facilitate release of the ingredient 6 from the capsule 1. The lid part 3 comprises two identifiers 9a, 9b which are arranged such that they have 180° rotational symmetry about a vertical axis through the centre of the capsule. Each identifier 9a, 9b is an area of conductive material incorporating a code pattern. In this embodiment, the lid part 3 comprises a conductive material (e.g. metallic foil, preferably in the form of a polymer/aluminium foil laminate) and the code patterns are formed in the lid part 3.

FIG. 1c is a representation of the capsule of FIG. 1a viewed from below. The body part 2 has a circular base 10 and a flange-like rim 4. As mentioned above, in this embodiment the orientation members 7a, 7b are integrally formed within the underside of the rim 4. In this embodiment, the orientation members 7a, 7b are arranged in a symmetrical manner, however this is not necessarily the case and other embodiments are envisaged wherein the capsule comprises only a single orientation member or a plurality of orientation members arranged in a symmetrical or non-symmetrical manner.

FIG. 2 shows a cross-sectional side view of the capsule of FIG. 1 in a preferred reading mode in the beverage production machine. In this embodiment, the capsule 1 comprises two orientation members 7a, 7b configured such that the capsule can only be inserted into the beverage production machine in one of two orientations. The beverage production machine comprises two coils 11a, 11b. On application of an alternating current to the coils eddy currents are generated in the conductive material. Each coil 11a, 11b is positioned such these eddy currents are generated within one of the identifiers. This leads to a change in coil impedance. Each coil provides a signal indicative of this change in impedance, allowing the capsule to be identified according to the signal.

FIG. 3 is a representation of the basic set up of a beverage production machine. The capsule 1, 21 of the present invention can be used in such a machine.

The beverage production machine comprises a capsule holder 20, which can receive a capsule 21. The capsule comprises one or more orientation members (not shown), and the capsule holder interacts with the orientation members so as to fix the position of the capsule within the beverage production machine (e.g. by preventing rotational movement of the capsule). The capsule additionally comprises one or more identifiers (not shown). Two coils 31a, 31b are positioned in close proximity (preferably 0 to 2 mm) to the identifiers. This arrangement facilitates recognition of the capsule as described above.

The beverage production machine preferably comprises a brewing chamber 22. Water from a reservoir 23 is fed to the brewing chamber 22 via a water filter 24, a water pump 25, a heater 26 and a valve 27. The valve 27 controls the route the water takes between the heater 25 and the brewing chamber 22. In order to produce a beverage, water from the reservoir 23 preferably enters the brewing chamber 22 via the capsule 21. An air pump 28 pumps air along with the water and thus facilitates the mixing of the capsule contents with the water. The beverage can subsequently be dispensed into a receptacle 29 (e.g. cup, mug) via a spout 30. In order to rinse and/or clean the brewing chamber 22, the valve 27 can re-direct the water such that it enters the brewing chamber 22 via a rinse head 32.

FIGS. 4a to 4j illustrate a series capsules according to an embodiment of the invention viewed from above. Each capsule 1 has a lid part 3 comprising two identifiers 9a, 9b arranged so as to have 180° rotational symmetry, wherein each identifier 9a, 9b is an area of conductive material incorporating one of four possible code patterns A, B, C or D. The capsule comprises orientation members 7a, 7b configured such that the capsule can only be inserted into the beverage production machine in two orientations, and is designed to be read by a beverage production machine comprising two coils. Thus code pattern #1 (sensed by coil #1) can be A, B, C or D and code pattern #2 (sensed by coil #2) can independently be A, B, C or D. Thus this embodiment is sufficient to encode 10 different identification codes, as summarised in FIGS. 4a to 4j and Table 1. Each identification code can be associated with a different set of machine parameters.

	TABLE 1
	Code pattern #1
	A	B	C	D
Code pattern #2	A	FIG. 4a	FIG. 4b	FIG. 4c	FIG. 4d
	B	FIG. 4b	FIG. 4e	FIG. 4f	FIG. 4g
	C	FIG. 4c	FIG. 4f	FIG. 4h	FIG. 4i
	D	FIG. 4d	FIG. 4g	FIG. 4i	FIG. 4j

FIGS. 5a to 5j illustrate a series of capsules according to an alternative embodiment of the invention, wherein the identification codes again have 180° rotational symmetry. The capsules differ from those shown in FIGS. 4a to 4j in that each capsule 1 comprises four identifiers 9a, 9b, 9c, 9d. Each identifier 9a, 9b, 9c, 9d is an area of conductive material incorporating one of four possible code patterns A, B, C or D. The identifiers have 180° rotational symmetry, with identifier 9a having the same code pattern as identifier 9c. Similarly, identifier 9b has the same code pattern as identifier 9d. Nevertheless, each pair of identifiers (9a, 9c; 9b, 9d) is coded independently of the other pair. Thus this embodiment is sufficient to encode 10 different identification codes in a similar manner to Table 1, each of which can be associated with a different set of machine parameters.

FIG. 6 illustrates a number of identifiers 39, wherein each identifier incorporates a possible code pattern. Each of the code patterns consist of a predetermined arrangement of one or more discontinuities formed in the conductive material 40. The discontinuities are preferably perforations 41, slits 42, holes 43, indentations (not shown), or a combination thereof.

For convenience, the code patterns are illustrated as 5 sets (set 1, set 2, set 3, set 4, set 5), with each set consisting of 4 code patterns (pattern A, pattern B, pattern C, pattern D). However, this is not meant to imply that these sets are in any way limiting. For example, a set of code patterns could be compiled by selecting all of patterns A, B, C and D from set 1, or by selecting patterns A from set 2, pattern B from set 3, pattern C from set 4 and pattern D from set 5. In fact any combination is possible, so long as each of pattern A, pattern B, pattern C and pattern D is associated with a unique and identifiable change in coil impedance.

Claims

1. A capsule (1, 21) for a beverage production machine, the capsule (1, 21) comprising: wherein the identifiers (9a, 9b, 9c, 9d, 39) are each areas of conductive material incorporating a code pattern, coded independently of one another, the code pattern consisting of a predetermined arrangement of one or more discontinuities (41, 42, 43) formed in the conductive material (40), and wherein the capsule comprises at least one orientation member (7a, 7b) for directing the alignment of the capsule within the beverage production machine, wherein the at least one orientation member (7a, 7b) directs the alignment of the capsule such that the capsule is aligned within the beverage production machine in any one of n fixed orientations, wherein n is 1, 2, 3, 4, 5 or 6, the identifiers being arranged with rotational symmetry, so as to enable detection of the capsule in any on of the fixed orientations dictated by the at least one orientation member.

an ingredient (6) enclosed within the capsule (1, 21); and

a plurality of identifiers (9a, 9b, 9c, 9d, 39);

2. A capsule as claimed in claim 1 wherein the capsule comprises a body part (2) and the orientation member (7a, 7b) is integrally formed as part of the body part (2).

3. A capsule as claimed in claim 1 wherein the conductive material (40) is metallic foil preferably having a thickness of 10 to 100 μm.

4. (canceled)

5. A capsule as claimed in claim 1 wherein the plurality of identifiers (9a, 9b, 9c, 9d, 39) are arranged so as to have 180 ° rotational symmetry.

6. A capsule as claimed in claim 1 wherein the capsule comprises a lid part (3) and the lid part (3) comprises the identifier(s) (9a, 9b, 9c, 9d, 39).

7. (canceled)

8. A capsule as claim 1 wherein the capsule encloses a beverage ingredient, preferably an infusible beverage ingredient.

9. A capsule as claimed in claim 1 wherein the capsule encloses a cleaning substance.

10. A capsule as claimed in claim 1 wherein the code pattern is wholly or partially covered by a layer of non-conductive material.

11. A method of recognising a capsule in a beverage production machine, the method comprising:

providing a capsule (1, 21) comprising: an ingredient (6) enclosed within the capsule; an identifier (9a, 9b, 9c, 9d, 39), wherein the identifier (9a, 9b, 9c, 9d, 39) is an area of conductive material incorporating a code pattern, the code pattern consisting of a predetermined arrangement of one or more discontinuities (41, 42, 43) formed in the conductive material (40); and an orientation member (7a, 7b) for directing the alignment of the capsule within the beverage production machine;

applying an alternating current to a coil (31a, 31b), the coil (31a, 31b) being positioned in the beverage production machine such that it generates eddy currents within the identifier (9a, 9b, 9c, 9d, 39);

detecting a change in coil impedance;

generating a signal indicative of the change in coil impedance; and

identifying the capsule (1, 21) according to the signal.

12. A method as claimed in claim 11 wherein the capsule is identified by comparing the signal with a number of reference signals, each one corresponding to a certain type of capsule.

13. A method as claimed in claim 11 wherein identification of the capsule controls at least one parameter of the beverage production machine.

14. A method as claimed in claim 11 wherein the identifier and the coil are stationary with respect to one another whilst the alternating current is applied to the coil.

15. A method as claimed in claim 11 wherein the method subsequently comprises destruction of the code pattern.