EP1602887A2 - Device for producing ice crystals in an aqueous solution - Google Patents

Abstract

A method for producing ice crystals in an aqueous fluid has a double walled cooling cylinder (2, 3) with a rotor with radial scrapers to remove ice crystals formed on the inner wall of the chamber. The rotor drive (17) is located through the top flange of the chamber via an elastic seal (20) and is connected to the rotor via a claw coupling (14, 15) with one part (15) connected to the drive and the other part to the rotor. The coupling accommodates any non circular movements of the rotor and replaces costly bearings.

Description

The invention relates to a device for producing ice crystals in one aqueous solution.

They are devices for producing ice crystals in an aqueous mixture or solution (hereinafter referred to as "puddle"), in which water, the a freezing point depressant substance has been added (hereinafter this mixture is called "fluid") is cooled as far as ice crystals can form on a cooled wall. To a caking of the ice crystals at the To prevent wall, such walls are usually mechanical Scratches or wipers (hereinafter referred to as "scratches") equipped. such Designs are hereinafter referred to as "mechanical ice makers".

Such mechanical ice makers have a defined geometry, hence the scratch can have a defined intervention. The usual heat exchanger surfaces are usually designed as a tube, the inner surface of which acts on the fluid becomes. In this inner tube of the scratch runs around (it can of course also be several scratches). The cooling of this tube inner wall is expediently accomplished by evaporating refrigerant. This tube is in a Larger tube centric or eccentric introduced. This creates an annular gap. The tubes are closed at the ends so that the annular gap is a closed represents (hermetic) volume. Only the connections for the supply and discharge of refrigerant constitute a connection to the outside.

In such exported ice makers, the problem arises that the tubes in common Delivery quality is neither ideal nor ideal. This represents the Request for scratches that they must be able to follow the contour so far that Ice freedom is guaranteed.

In DE 101 13 395 C1 is a scratch together with a scratch-guiding rotor (hereinafter described as "rotor") which can follow the contour by the scratch elastic and the changing geometry in radial and axial Geometry adapts.

The rotor shown in DE 101 13 395 C1 has at the upper and lower end depending a shaft which guides the rotor largely concentrically in the inner tube. At one The end is a bearing, at the other end the shaft with a seal to the outside guided and stored there again. Both bearings are usually as ball bearings (Roller or needle roller bearings are also conceivable) executed. The wave is from a Motor driven, this engine also has bearings. To registration error as well as the "wobble" movement of the wave, caused by the not perfect Geometry of the inner tube to compensate, usually becomes a curved tooth coupling used.

The tumbling movements of the rotor are the result of multiple storage (two the shaft ends, usually two at the engine) and uneven geometry. Thereby the shafts, the seal and the bearings are heavily stressed, causing them On the one hand wear components quickly, on the other hand uneven loading the ice-forming surface takes place, which is the permissible cooling capacity of the ice maker adversely affected.

The omission of the bearing on the opposite side of the drive already has Improvements in bearing and shaft wear brought.

The outside of the outer tube is also affected by evaporating refrigerant cooled, a use for fluid cooling and / or ice production, however, so far not done, since a scratch design for this at least difficult, if not is impossible. Expensive surface remains so unused and becomes small - around losses hold - thermally insulated. So far, in tubular ice makers no cold technical use of the outside takes place.

The invention is therefore based on the object, a device of the aforementioned To create a type whose cooling capacity is improved.

According to the invention, these cold-performance-reducing defects are caused by the Characteristics of claim 1 solved.

Fig. 1

das Schema eines Eiserzeugers mit Rotor und Kratzern, die Ausgestaltung der - im Beispiel konzentrischen - Rohre, die Lagerung, die Wellenabdichtung sowie die Anbringung der Bogenzahnkupplung, und

Fig. 2

eine - in Fig. 1 als strichpunktierten Kreis begrenzte - Vergrößerung des Antriebsteiles des Eiserzeugers mit Bogenzahnkupplung, Lagerung und Wellenabdichtung.

The invention will be explained below with reference to a drawing. Showing:

Fig. 1

the scheme of an icemaker with rotor and scratches, the design of the - concentric in the example - pipes, the bearing, the shaft seal and the attachment of the gear coupling, and

Fig. 2

a - limited in Fig. 1 as a dotted circle - Enlargement of the drive part of the ice maker with curved tooth coupling, storage and shaft seal.

The operation of the ice maker is described in detail below. there For example, in FIG. 1, a vertical ice maker is shown. such However, ice makers may also be inclined or horizontally arranged. From the non-vertical arrangement resulting adjustments of the pipe connections not further described below, as they obey the laws of physics and thus are known to a person skilled in the art.

The inner tube 1 and the outer tube 2 (hereinafter referred to as "double tube") form an annular gap 3, which is closed on both sides and in which a refrigerant can evaporate. This refrigerant is in the annular gap 3 through a pipe socket 4 fed and leaves the annular gap 3 through a pipe socket. 5

At both ends of the double tube lids are attached and a "lower" Cover 6 and an "upper" cover 7. Both covers 6 and 7 are with the double tube tightly connected, e.g. by a flange connection (not shown in FIGS. 1 and 2). Through a pipe section 8 through the lower cover 6, the fluid in the interior 9 introduced the double tube and passes through another pipe section 10th cooled and possibly enriched with ice crystals.

The evaporating refrigerant in the annular gap 3 of the double tube cools the inside of the inner tube 1. This can be with sufficient cooling of the fluid in the Interior 9 of the ice maker on the surface of the inside of the inner tube. 1 Ice crystals form. Around the inside of the inner ear 1 in front of an increasingly thicker As the ice layer continues to grow, scratches 11 cover this area. The scratches 11 are connected to a rotor 12 in a manner that they are elastic the non-circular and / or not straight Kontor of the inner tube can react. The elastic connection is denoted by 13 and shown only schematically (it can e.g. to a resilient non-positive connection or a resilient form-fitting Compound - as indicated in DE 101 13 395 C1 - act).

In Fig. 1, the scratches 11 are exemplary in vertical 5 planes with two over the radius distributed scratches 11, with adjacent planes e.g. at each 90 ° offset. However, it can also have a different number of levels as well other arrangement and number of scratches 11 may be provided.

The rotor 12 has at the lower end no guided wave, i. there is no storage and no wave. At the upper end of the rotor 12, a stub shaft 14 is attached, which is connected to a gear tooth coupling 15. This curved tooth coupling is connected to a shaft 16, which in turn in bearings 17 of an electric motor 18 is clamped. The electric motor 18 is connected via a flange 19 with the upper lid 7 rigidly connected (It can also be a different number of bearings 17 and connections other than a flange 19 between the Electric motor 18 and the upper lid 7 are selected). One (usually as Seal seal running) seal 20 seals the shaft 16 to the upper lid 7 off.

By this construction it is achieved that the shaft 16 of the bearings 17 rigid to be led. Therefore, the mechanical seal 20 is stressed little, especially radial Movements do not occur or barely occur. Tumbling movements of the rotor 12, by geometrically induced deviations of the inner tube 1 in radial and axial direction are indeed communicated via the shaft 14, However, lying in the interior 9 curved tooth coupling 15 is mainly the radial Movements out.

The scratches 11 in their arrangement in the above-described levels and a expedient division can lack of restraint by a bearing of the rotor 12 follow the contour of the inner tube 1 very well and paint the surface thus better. This is the icing of the inside of the refrigerant-cooled inner tube 1 significantly reduced. It can - without risk of ice formation on the inside of the inner tube 1 - a higher cooling capacity are driven than in constructions of ice makers, in which the rotor 12 clamped on both sides by bearings is. The attempt was less wear of the scratches 11 and the mechanical seal 20 as well as additional services up to 40% related to ice cream production determined.

From the rotor 12 and the scratches 11 (including the resilient mount 13) existing assembly centered in the inner tube 1 so to speak itself and needed no forced operation, e.g. through additional storage. The inevitable tumbling movements - Especially in the radial direction - be through the curved tooth coupling 15 balanced.

Claims (1)

Device for producing ice crystals in an aqueous solution, characterized by at least one unit (27) consisting of a double tube (1, 2) formed by an inner tube (1) and an outer tube (2) and provided with pipe stubs (4, 5) for introducing and discharging a refrigerant, a rotor (12) arranged in the interior of the inner tube (1) and provided with a plurality of scratches (11) resting on the inner wall of the inner tube (1), a tube piece (8) introducing the fluid to be cooled into the interior of the inner tube (1), a tube piece (10) discharging the cooled fluid from the interior of the inner tube (1), a in the region of one of the ends of the double tube (1, 2) in the interior of the inner tube (1) arranged, the wobbling movements of the rotor (12) receiving the curved tooth coupling (15), one piece with the rotor (12) and the other piece with a by a double tube (1, 2) closing the lid (7) guided shaft (16) is connected, and a drive (18) acting on the shaft (16).

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