EP2631580A1 - Drying of food, in particular pasta, with a fan blade containing plastic - Google Patents

Abstract

The dryer has treatment chamber that contains food. The air flow is applied to the food by a fan. The fan is provided with rotor (5) and blade (15). The blade is made up of polyamide and glass-fiber reinforced plastic. The blade is made up of glass fiber reinforced plastic and glass fiber reinforced polyamide. The rotor is located at six blades. An independent claim is included for method for drying food.

Description

The present invention relates to a food dryer, a method for drying food, a method for upgrading and / or converting a dryer for food and the use of a dryer for drying food. The foods may be, in particular, pasta.

For drying food, especially pasta, they are usually subjected to an air flow, which is generated by means of at least one fan. Such a fan includes a housing and a rotatable rotor disposed therein which has one or more vanes which generate the air flow upon rotation of the rotor. Such dryers for pasta are for example in the EP 551 464 B1 or the WO 92/17074 described.

Since the air flow flows around or through both the fan and the food, the fan and in particular its wings can contain only very specific materials for reasons of hygiene. Usually, the wings are made of a metal such as steel or aluminum. On the one hand, such metals have the required stability in order to generate a sufficient air flow even at high rotational speeds. On the other hand, they are also resistant to the usual in a food dryer temperatures and relative humidities. In addition, the materials mentioned do not tend even under these conditions to break off splinters that could get into the food with the air flow. In addition, metals do not absorb water or airborne constituents of the food where they could lead to contamination. This must be avoided for hygienic and health reasons.

However, rotor blades made of metal also have a number of disadvantages: on the one hand occur due to the large masses of the wings vibrations, which require a stable support structure. Sometimes the vibrations can even lead to damage to the bearings, resulting in time-consuming maintenance work. In addition, due to the moments of inertia and the friction losses a large drive power is required to achieve the required speeds. Such friction losses can occur when the drying air comes into contact with the metal blades, which have comparatively rough surfaces and imprecise geometries.

It is therefore an object of the present invention to overcome the disadvantages of the prior art, and in particular to provide a dryer with a fan, which requires less power at given dimensions and speeds of the rotor and also less prone to vibration than fans with metal wings. Nevertheless, the fan should as far as possible comply with the strict hygiene regulations governing the production of food.

This object is achieved on the one hand by a dryer for food, in particular for pasta, which contains at least one treatment room and at least one fan for generating an air flow. The treatment room is designed such that in it the food can be received and acted upon by the air flow. The fan contains a rotor with at least one wing.

According to the invention, the wing contains a plastic. Due to the lower densities of plastics compared to metals significantly lower drive power is required with the inventive wings, as is the case with metal wings with the same dimensions, which are driven at the same speeds. Conversely, with the same drive power, which are necessary for conventional metal wings, a larger air circulation are generated, which is particularly advantageous for long-goods dryer. For one thing, due to the lower moments of inertia, less energy is required for the acceleration when starting the fan. On the other hand, the lower mass also ensures smaller frictional forces. The bearings of the rotor are thereby less stressed, causing the fan has a longer life. In addition, due to the lower mass and the lower centrifugal forces significantly less vibrations than in metal wings arise. It therefore requires no expensive support structures for vibration reduction. Furthermore, plastic can be easily brought into the desired shape, for example by injection molding. By injection molding, a higher precision of the surface structure of the wings is possible; For example, in many cases, tolerances of less than 0.1 mm can be achieved, resulting inter alia in lower friction losses between the air and the vanes.

The plastic is preferably a polyamide. Polyamide has proven to be particularly suitable because it is easier to process than the metal of conventional wings. In particular, it can be formed particularly well by injection molding. In addition, polyamide has a low porosity; This can be avoided unwanted water retention in the wings. In addition, polyamide is particularly resistant to hydrolysis effects.

Furthermore, it is advantageous if the plastic is glass fiber reinforced. Such a glass fiber reinforcement gives the wing increased stability, which is required especially at high speeds. A reinforcement with glass fibers also prevents particularly effective breaking out of splinters from the wing, which could otherwise get into the food.

In preferred embodiments, the glass fibers are completely embedded in the plastic; The glass fibers thus run completely in the interior of the wing and do not emerge on its surface, which is particularly advantageous for short goods dryers. In this way, the surface of the wing can be made very smooth. In addition, we further reduce the risk of splintering.

With particular advantage, the wing of a glass fiber reinforced plastic, in particular a glass fiber reinforced polyamide.

It has been found that especially glass fiber reinforced polyamide is particularly resistant to the usual climatic conditions that prevail in a dryer for food, especially in a dryer for pasta. For example, temperatures of 95 ° C have no effect on the modulus of elasticity of the wing, and also relative humidities of up to 95% lead to no appreciable water absorption by the plastic, which could lead to its aging. In addition, it has been found that no plastic splinters break out of the wing and can get into the food.

Advantageously, the fan is designed as an axial fan. Such an axial fan allows a particularly space-saving design of the dryer.

The rotor of the fan may contain at least two, preferably at least three, more preferably at least four vanes. In advantageous embodiments, it contains at most six wings. The wings can be distributed uniformly in the circumferential direction around the rotor. However, it is also conceivable and within the scope of the invention that the wings are arranged at different angular distances from each other.

The rotor may have a diameter which is in the range from 200 mm to 1000 mm, preferably from 300 mm to 800 mm and particularly preferably from 400 mm to 630 mm.

The dryer can be a pasta dryer, in particular a long-goods dryer or a short-goods dryer. Such types of pasta dryers are known per se to those skilled in the art. The fan may also be arranged in a known per se position within the dryer.

Another aspect of the invention relates to a method for drying food, in particular pasta, with a dryer as described above. In this method, the food can be taken up or taken up in the treatment room of the dryer and there be acted upon by an air flow. The air flow can be generated by means of the fan, when the rotor rotates about a rotation axis. By means known per se, the air flow can be adjusted to a desired temperature and / or a desired relative humidity.

In many variants of the method, the rotor can be operated at a speed in the range of 1500 to 3000 rpm.

Furthermore, the invention also includes a method for upgrading and / or converting a dryer for food, in particular a dryer for pasta. The method includes a step of providing a fan that includes a rotor having at least one blade that includes plastic. In this way, an already existing dryer can be upgraded and / or converted in such a way that a dryer as described above results and the explained advantages are achieved - in particular a reduction vibration and a reduction in the drive power required for operation.

The method may include a further step in which a fan already contained in the dryer is removed and replaced by a fan with a rotor, the wing of which contains a glass fiber reinforced plastic in particular, preferably consists of a glass fiber reinforced plastic.

Finally, the invention also relates to the use of a dryer as described above for drying food, in particular pasta.

Figur 1

eine fotografische Darstellung einer ersten Ausführungsform eines Rotors mit Flügeln aus einem glasfaserverstärkten Kunststoff;

Figuren 2a und b

zwei Ansichten einer zweiten Ausführungsform eines Rotors mit Flügeln aus einem glasfaserverstärkten Kunststoff, welcher Teil eines Ventilators ist;

Figur 3

eine Skizze einer perspektivischen Ansicht eines erfindungsgemässen Trockners;

Figur 4

eine Skizze einer seitlichen Schnittansicht des Trockners.

In the following the invention will be explained with reference to exemplary embodiments and several drawings. Show

FIG. 1

a photographic representation of a first embodiment of a rotor with blades made of a glass fiber reinforced plastic;

FIGS. 2a and b

two views of a second embodiment of a rotor with blades made of a glass fiber reinforced plastic, which is part of a fan;

FIG. 3

a sketch of a perspective view of a dryer according to the invention;

FIG. 4

a sketch of a side sectional view of the dryer.

In FIG. 1 a rotor 5 of an axial fan for a dryer according to the invention is shown. The rotor 5 includes six blades 15 made of a glass fiber reinforced polyamide, which are attached to a hub 6 with an outer diameter of 255 mm. The hub 6 has a central opening 7, with which the rotor 5 can be attached to a drive shaft. The Wings 15 are arranged at an angular distance of 60 ° to each other uniformly around the outer circumference of the hub 6. Of course, it is also conceivable that the rotor 5 has a smaller or a larger number of vanes 15. The wings 15 have in the radial direction a length of 177.5 mm, which is measured from the outer periphery of the hub 6 to the outermost point of the wing 15; the rotor 5 thus has a total diameter of 610 mm. The width of the wings 15 measured perpendicular to the axis of rotation is about 130 mm at the innermost point and about 185 mm at the outermost point. The wings 15 are rotatably mounted on the hub 6. In this way, they can be fixed in different angles of attack relative to the axis of rotation. As is known per se to the person skilled in the art, the air flow and in particular the flow rate can thereby be adjusted.

The FIGS. 2a and 2b show an embodiment of an axial fan 3 with a substantially cylindrical housing 4 and a rotor 5 'arranged therein. This rotor 5 'contains in contrast to the rotor 5 off FIG. 1 only three wings 15, which are arranged uniformly in the circumferential direction. The number of wings 15, 15 'may, inter alia, be selected as a function of the power range in which the axial fan 3 is to be operated; this number of wings can be determined by the expert by routine experimentation. The wings 15 'of the rotor 5' are made of glass fiber reinforced polyamide and therefore have the advantages described above. Upon rotation of the rotor 5 'about its axis of rotation R, an airflow L can be generated. Like the wings 15 in FIG. 1 also have the wings 15 'in FIG. 2 in the radial direction a length of 177.5 mm. Its measured perpendicular to the axis of rotation R width is at the innermost point about 130 mm and at the outermost point about 185 mm.

In order to produce the highest possible flow rates, the outer diameter of the rotor should be 5 'only slightly smaller than the inner diameter of the housing 4. Due to their thermal Expansion of the wings 15 ', however, increases the diameter of the rotor 5' under operating conditions. Therefore, in many cases it is necessary that the diameter of the rotor 5 'be chosen correspondingly smaller at room temperature, so that the wings 15' do not come into contact with the inner wall of the housing 4 under operating conditions (for example at temperatures of about 95 ° C.). For example, the wings 15 'may be sized so that their distance from the inner wall of the housing at room temperature in the range of 2 mm to 4 mm. This distance then decreases under operating conditions.

In FIG. 3 a dryer 1 according to the invention for pasta is shown. The dryer 1 contains a plurality of segments 11, 11 ', 11 ", 11"', each of which contains a treatment space 2, 2. "The treatment spaces of adjacent segments are connected to one another FIG. 3 the two segments 11 'and 11 "are moved apart, these segments 11, 11' of course being connected to one another for the operation of the dryer 1. The pasta, not shown here, successively pass through the treatment rooms in the indicated conveying direction F. If long goods are concerned , These are transported, for example in a conventional manner hanging on rods.

FIG. 4 shows a side sectional view through one of the segments 11 perpendicular to the conveying direction F. On each side of the treatment chamber 2, a lateral chamber 12 is arranged, in each of which an axial fan 3 according to FIG. 2 located. By rotating the rotors at speeds in the range of 1500 to 3000 U / min 3 air streams L are generated by means of the axial fans. These move upwards in the lateral chambers 12, are then led laterally into an upper chamber 13 and subsequently introduced through a heat exchanger 9 into the treatment space 2. Below the treatment chamber 2, the air flow L passes into a lower chamber 14, from where he again enters the lateral chambers 12 and there again is sucked in by the axial fans 3.

The heat exchanger 9 can be traversed by warm water, whereby the air flow L is heated. The water can receive a portion of its heat energy directly or indirectly from a downstream in the conveying direction F segment of the dryer 1. For a detailed description, see the international application WO 2010/108806 directed.

The glass fiber reinforced polyamide, from which the wings 15 'of the axial fans 3 are made, on the one hand characterized by a density which is lower than that of metal. As a result, the required drive power compared to a rotor with metal wings with the same dimensions and at the same speed can be significantly reduced. In addition, occur due to the lower mass significantly less vibration during operation, which greatly simplifies storage.

Glass-fiber-reinforced polyamide has also proven particularly suitable for use in a pasta dryer 1. Because even at the temperatures usually used there of up to 95 ° C and relative humidities of up to 95%, the modulus of elasticity of the material hardly changed, and it takes up virtually no water. Furthermore, the break-out of splinters and penetration into the treatment room 2 can be practically excluded, so that the relevant hygiene regulations are met in the food production.

Claims (14)

Dryers (1) for food, in particular for pasta, containing - At least one treatment room (2, 2 ", ...), in which the food can be received and in which they are acted upon by an air flow (L); - At least one fan (3) for generating the air flow (L), wherein the fan (3) includes a rotor (5, 5 ') with at least one wing (15, 15');
characterized in that
the wing (15, 15 ') contains a plastic. Dryer (1) according to one of the preceding claims,
characterized in that
the plastic is a polyamide. Dryer (1) according to one of the preceding claims,
characterized in that
the plastic is glass fiber reinforced. Dryer (1) according to one of the preceding claims,
characterized in that
the wing (15, 15 ') consists of a glass fiber reinforced plastic, in particular a glass fiber reinforced polyamide. Dryer (1) according to one of the preceding claims,
characterized in that
the fan (3) is an axial fan. Dryer (1) according to one of the preceding claims,
characterized in that
the rotor (5; 5 ') at least two, preferably at least three, more preferably at least four wings (15, 15 ') contains. Dryer (1) according to one of the preceding claims,
characterized in that
the rotor (5; 5 ') contains at most six vanes (15; 15'). Dryer (1) according to one of the preceding claims,
characterized in that
the rotor (5, 5 ') has a diameter of 200 mm to 1000 mm, preferably of 300 mm to 800 mm, particularly preferably of 400 mm to 630 mm. Dryer (1) according to one of the preceding claims,
characterized in that
the dryer (1) is designed as a long goods dryer. Dryer (1) according to one of the preceding claims,
characterized in that
the dryer (1) is designed as a short goods dryer. Process for drying foods, in particular pasta, using a dryer (1) according to one of the preceding claims. Process according to claim 11,
characterized in that
the rotor (5, 5 ') is operated at a speed in the range of 1500 to 3000 rpm. Method for upgrading and / or converting a drier for food, in particular a drier for pasta, comprising a step of providing a fan (3) having a rotor (5; 5 ') with at least one vane (15; '), the plastic comprises, that a dryer (1) according to one of the preceding claims is obtained. Use of a dryer (1) according to one of claims 1 to 10 for drying food, in particular pasta.

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