SE505114C2 - Method for continuous production of coffee extracts - Google Patents

Abstract

The disclosure relates to a method of producing a high-quality coffee extract. The roasted coffee beans are positively fed into water and are ground in a colloid mill (10) during simultaneous mixing to form a coffee suspension. The coffee suspension is extracted in at least one decanter centrifuge (21) to form a liquid coffee extract of high quality. The coffee concentrate possibly passes through a filter (28) before being cooled in, for example, a plate heat exchanger (29). The system for carrying the method into effect is a closed system (32) from the infeed of the coffee beans into water, and until the finished coffee extract has been cooled.

Description

15 50 25 30 35 IV 505 114 It is therefore desirable to be able to produce a coffee extract which has retained most of the flavorings present in the coffee beans and which develops during roasting.

The main purpose is to achieve a high-quality coffee extract, which, however, does not exclude a good quantitative return on the finished product.

This and other objects have been achieved according to the invention by the method of the type initially described, being given the characteristics that the roasted coffee beans are forcibly fed into water, after which they are ground into a coffee suspension, which is fed into at least one extraction device for continuous extraction, and the coffee suspension and the coffee extract are treated in a closed system until the finished extract is cooled.

Preferred embodiments of the invention have further been given the features set forth in the subclaims.

A preferred form of the invention will now be described in more detail, with reference to the accompanying drawings, of which: Fig. 1 shows a functional diagram of the method according to the invention. Fig. 2 shows a part of the functional diagram Fig. 3 shows the principle of a colloid mill Fig. 4. shows the principle of a decanter centrifuge Fig. 1 shows in a functional diagram the various components and process steps included in the method according to the invention. The roasted coffee beans are temporarily stored in a buffer tank 1, or alternatively fed directly from the roasting to the extraction process. In order to maintain a good quality from the outset, the ready-roasted coffee beans should be stored for as short a time as possible and should therefore be processed on the same day as the roasting takes place.

A simple principle of feeding from the buffer tank 1 is shown in Fig. 1, where a discharge pipe 2 from the tank 1 opens into a container or funnel 3. When the funnel 3 is filled to the desired level, the beans stop in the discharge pipe 3 until the level in the funnel 3 drops again. . The funnel 3 may be closed to reduce the exposure of the coffee beans to the ambient air.

The funnel 3 opens into a tube 4, in which a screw 5 is arranged, with an electric motor 6.

Since the roasted coffee beans are so light that they float in water, the beans must be force-fed by means of screw 5. By varying the amount of coffee beans that are dosed in, one can obtain coffee extracts with varied concentration.

Water of 10-10006, preferably about 75 ° C, is introduced into a vessel 7 with a level gauge 8, which regulates that the system always has the required amount of water.

Because the system is constantly filled with water, the air is prevented from gaining access, which minimizes the oxidation of the coffee's aromas while volatile substances are prevented from escaping. the temperature of the water, approx. 7506, is chosen so that the water can extract most of the aromas and flavors from the ground coffee beans, without adversely affecting these substances. The vessel 7 has open communication with the tube 9, to which the tube 4 also opens. Through the open communication between the tubes 9 and 4, the vessel 7 and the tube 4 will function as communicating vessels, so that the liquid level in the vessel 7 and the liquid level in the tube 4 will be at the same level. The tube 9 also forms an inlet to a colloid mill 10.

The colloid mill 10 is of conventional type, the working principle of which is shown in Fig. 3.

The colloid mill 10 basically consists of a stator 11 and a rotor 12. The float is caused to rotate by means of an electric motor 13. In the space 14 between the stator 11 and the rotor 12 there are two landed surfaces 15, 16 of which one 16 rotates at high speed . The coffee beans mixing with water are exposed in the mill 10 to high shear and frictional forces, but also a strong turbulence which contributes to the coffee beans being finely ground and mixed into a homogeneous coffee suspension. The degree of grinding of the mill 10 is adjusted by axial displacement of the stator 11 or the rotor 12.

Because the coffee beans are surrounded by water throughout the grinding process, this water will act as a cooling medium during grinding so that the finely ground coffee with its large exposure area cools down immediately, which reduces the release and impact of the volatile aromas.

The mixed coffee suspension leaves the mill 10 through the outlet 17.

The outlet pipe 17 has open communication with the pipe 9. The colloid mill 10 has such a large pumping action that an arrangement is required as shown in Figs. 1 and 2, where the pipes 4, 9 and 17 and the mill 10 together form a circulation circuit 18 of the type " feed-bleed ".

A capacity determining pump 19, of the gear or eccentric screw pump type, further transports a certain amount of coffee suspension through the pipeline 20. The other amount of coffee suspension is circulated in the circulation circuit 18. The tube 20 provides a certain holding time and forms an inlet to a continuous extraction device, which in the preferred embodiment, consists of a decanter centrifuge 21.

The function of a decanter centrifuge 21 is shown in Fig. 4. In a partly conical and partly cylindrical rotor 22 a screw conveyor 23 is arranged. The screw conveyor 23 rotates in the same direction as the rotor 22, but at a generally lower speed. The product, in this case the coffee suspension, is fed into the rotor 22 via the inlet 20. The liquid-mixed product, the coffee suspension, is forced to settle in the rotor 22, so that the solid material accumulates in the conical end 24 of the rotor 22, where the solid material leaves the decanter centrifuge through the outlet 25. The liquid is separated under pressure by means of shell discs 26 and leaves the centrifuge 21 via the outlet line 27. '114 114 f The extraction of coffee in a decanter centrifuge 21 is completely continuous. The process can be carried out in a Centrifuge 21 which, with special devices, can be made almost closed, to prevent access of air and loss of flavorings. The residence time in the process is furthermore very limited and the coffee extract will thus be processed in the shortest possible time. The liquid coffee extract which leaves the centrifuge 21 via the pipeline 27 is a very high quality coffee extract which has been exposed as little as possible to heat or air which can volatilize and oxidize the flavors.

The finished coffee extract is transported further, possibly via a filter 28 of conventional type, or alternatively a centrifuge. Depending on the desired type of coffee, with different amounts of suspended material, alternatively the finished coffee extract can be led directly to a cooler 29, by means of a conventional centrifugal pump 30. For e.g. For the manufacture of coffee extracts for the expresso type, no filter 28 is required, while such a filter may be desirable in the manufacture of extracts for clearer, brewed types of coffee.

The cooler 29 can, as in Fig. 1, consist of a plate heat exchanger with cold water as cooling medium. In the plate heat exchanger, the coffee extract is forced to circulate between the plates and on the opposite side of the plates, cold water is circulated so as to obtain a continuous cooling process.

The cooled finished coffee extract is transported further to some form of storage or buffer tank 31. The now cooled extract is not as sensitive to the action of air and the absence of heat means that the flavors are not so easily volatilized. The finished extract can now, possibly after some durability-increasing heat treatment, be packaged either in large aseptic containers for further transport to packaging in consumer packaging, or, after formulation, i.e. dilution and addition of ingredients such as sugar, milk or flavorings, are packaged directly in such consumer packaging.

The coffee extract resulting from the method described above maintains a high qualitative class in that the entire extraction of the coffee extract took place in a closed system 32. The closed system 32, where the air supply and aroma losses are reduced to a minimum, comprises the whole process described above, from feeding roasted coffee beans in hot water until the finished coffee extract is completely cooled.

To further increase the quantitative yield of the process, as shown in Fig. 1, an additional decanter centrifuge 33 can be used. To the, almost solid material leaving the first decanter centrifuge 21, via the outlet 25, water is added via the water line 34. This results in a new coffee suspension of considerably lower quality than that processed in the first centrifuge 21. The new suspension is optionally collected in a container 35 and then pumped by means of a centrifugal pump 36, into the pipeline 37 which forms the inlet to the second centrifuge 33. 15 20 5 505 114 The function of the second centrifuge 33 corresponds in principle to the function of the first centrifuge 21, which is described above. The solid material leaving the centrifuge 33 via the outlet 38 now contains very little of the coffee's flavors and aromas and this material is transported away for possible composting. The extracted liquid leaves the centrifuge 33 via the outlet 39. This liquid consists of an extract of considerably lower quality than the extract recovered by means of the first centrifuge 21. However, the liquid from the centrifuge 33 contains certain soluble flavors and aromas, which may contribute to quantitative yield of the whole process is increased.

Via the pipeline 40, this liquid is returned to the water vessel 7, where it will form part of the mixing medium for the freshly supplied coffee beans.

The second decanter centrifuge 33 with its pipelines 37 and 40 is not included in the closed system 32, as the result of the continuous extraction in this centrifuge 33, is an extract of lower quality.

As can be seen from the above description, the present invention provides a method of continuously producing a high quality coffee extract, which retains its aroma and flavor by not exposing the coffee to unnecessary heat or air exposure during the closed process, and to aroma - losses have been minimized. In addition, the concentration of the coffee extract can be varied by dosing different amounts of coffee coffee beans. This gives the opportunity to produce a concentrated extract without any extra process step such as. evaporation.

Claims (7)

10 15 20 25 30 35 505 114 6 PATENTKHAV Method for the continuous production of coffee extract, in which the roasted coffee beans are ground and mixed with water to a suspension, which is continuously extracted and cooled, characterized in that the roasted coffee beans are forcibly fed into water, after which they are ground into a coffee suspension, which is fed into at least one continuous extraction device (21) for extraction, and that the coffee suspension and the coffee extract are treated in a closed system (32) until the finished extract is cooled. Method according to claim 1, characterized in that the extraction of the coffee suspension takes place in two, successive extraction devices (21, 33), in order to increase the quantitative yield of the process. Method according to Claim 1, characterized in that the extraction device (21) consists of a decanter centrifuge. Method according to claim 1, characterized in that the cat beans are ground in a colloid mill (10). Method according to claim 1, characterized in that the water has a temperature of about 7500. Method according to claim 1, characterized in that the closed system (32) comprises a water vessel (7), the feed of coffee beans (3, 4, 5), the colloid mill (10) with pipelines (9, 17, 18) a capacity determining pump (19), the continuous extraction device (21) with pipelines (20, 27), a cooler (29), a centrifugal pump (30), and optionally a filter (28). Method according to claim 1, characterized in that the caffeine beans are forcibly fed into water by means of a screw (5) placed in a pipe (4), which pipe has free communication with the pipe (9) in which the water is supplied to the process.