DE102011050836A1 - Centrifuge rotor has suspension holding portion for hanger, that is formed in recess shape, and extended from bottom portion to wall portion - Google Patents

Abstract

The centrifuge rotor (10) has an axle (14) and a bottom portion (16) formed in the end of a wall portion (18). The wall portion is parallel to the centrifuge axis. A suspension holding portion (20) for a hanger (12) is formed in the form of a recess, and extended from the bottom portion to the wall portion. The hanger is suspended in the region of the bottom portion, and passed through the wall portion into the recess. The centrifuge rotor is made of steel, aluminum or plastic. An independent claim is included for a method for manufacturing centrifuge rotor.

Description

The invention relates to a centrifuge rotor for a pivotable hanger according to the preamble of claim 1, and to a method for its production according to claim 7.

Centrifuge rotors connect a drive shaft of a centrifuge with a container for receiving the Zentrifugierguts. The containers can in principle be used detachably in the centrifuge rotor. In a particular embodiment of a centrifuge rotor, the containers are so-called hangers mounted in the centrifuge rotor, that they are used more or less parallel to the centrifuge axis and pivot during centrifugation in the horizontal, so are substantially orthogonal to the drive axis during centrifugation in an arm ,

According to the state of the art, as in US Pat. No. 6,811,351 B2 It is customary to manufacture centrifuge rotors in such a way that structures which are as light as possible and stable are produced. In this document, a centrifuge rotor is disclosed in which, hangers are used with a collar between horizontally extending struts. The struts terminate in a sidewall parallel to the rotor axis with the sidewall except in the hanger area. The hangers, guided over their collar, can tilt along the struts into the recess of the side wall during the centrifugation, which ultimately allows a centrifugation orthogonal to the axis of rotation. To meet the requirements for stability and weight, they have very complex shapes to meet them.

To manufacture these centrifuge rotors cost-effectively despite complex structures with many braces, the injection molding process is used. With the help of the injection molding process corresponding centrifuge rotors can be produced very inexpensively. However, this method has the disadvantage that it is only suitable for large numbers, since the production of the injection mold is extremely complicated and expensive.

It is an object of the invention to provide a centrifuge rotor for pivotable hangers, which is inexpensive to produce even for small quantities, and a method for producing.

The object is achieved for the centrifuge rotor by the characterizing features of claim 1 in conjunction with its generic features and for the method by the characterizing features of claim 7 in conjunction with its preamble features.

The dependent claims form advantageous developments of the invention.

In a known manner, a centrifuge rotor for a pivotable hanger, an axle receptacle for attachment to a drive axle of a centrifuge. The axle is followed by a floor that ends in a wall area. The wall region is in particular parallel to the centrifuge axis. Furthermore, at least one hanger receptacle in the form of a recess is introduced in the radial extent. This recess extends from the bottom into the wall section. A hanger can be hung in the ground. The hanger passes through the Zentriufgalkraft during centrifugation in the hangs of the wall area. The hanger to be inserted into the centrifuge rotor has in particular a collar for mounting in the centrifuge rotor. A hanger with a collar around the container represents a particularly simple and customary form. The collar is held in the centrifuge rotor via the collar and can be guided during pivoting.

According to the invention, the centrifuge rotor is configured in the shape of a cup, wherein, apart from the hanger receptacle and the axle receptacle, it is designed substantially over the entire surface. The substantially full-surface design of the centrifuge rotor has the advantage that it dispenses with the struts required in the prior art, which greatly facilitates both the production and the cleaning of the centrifuge rotor. Furthermore, the Ausgesteltung invention has the fact that the centrifuge rotor can not be made useful as the centrifuge rotors according to the prior art only by injection molding, but also forming or machining process can be used for the production.

As a result, on the one hand, a significantly larger choice of material is made available. On the other hand, the tools for producing the centrifuge rotor are significantly cheaper than the tools necessary for the injection molding process. Accordingly, centrifugal rotors designed according to the invention can also be produced inexpensively in small quantities. This allows a high degree of flexibility in adapting to user-specific requirements.

In a first advantageous embodiment, a specified edge is provided on the centrifuge rotor, wherein the edge at the end of the wall region extends circumferentially around the rotor. This edge provides for a stiffening of the centrifuge rotor, which by such a training before expansion of the cup shape by counteracting the centrifugal force acting during centrifugation. The edge can be at right angles be bent. This represents a particularly simple embodiment. Due to the molded edge, the functionality can be maintained, even at high speed and correspondingly high centrifugal force. As a result, the usual in the prior art struts that extend from the hub to the side wall to stabilize them omitted. The edge may preferably be designed according to raidal outwards in the case of forming processes, and also radially inwards in the case of machining.

In a further embodiment, the cup may have a polygonal basic shape. As a result, the stability of the centrifuge rotor is increased and the guidance of the inserted hanger takes place in an improved manner on a surface which is in particular trapezoidal.

In principle, the floor can also run at an angle of 90 ° or deviating from 90 ° with respect to the rotor axis. The floor can also run in different areas in different inclinations relative to the rotor axis. Preferably, the bottom may have an area which is 90 ° to the axis and an area which is at an angle of 60 ° to 70 ° with respect to the centrifuge axis. This has the advantage that the radial extent of the centrifuge rotor can be minimized, since the hanger used by the oblique orientation are still sufficiently spaced from a motor located below the centrifuge rotor. In addition, a smoother transition from the shooting position to the wall area is ensured since the angle between the floor and the wall area is increased. Nevertheless, the height of the rotor is reduced in order to improve the rotational properties.

In particular, the transition from the floor to the wall area is provided with a chamfer or rounded. A corresponding transition improves the Rückschwingverhalten of the hanger after centrifugation.

According to a further concept of the invention, reinforcing ribs can be introduced or formed in the ground in an individual case.

In a particularly advantageous embodiment, the centrifuge rotor can be made of a metallic material, in particular steel or aluminum or an alloy. By using a metallic material, the strength is increased, whereby the stability of the rotor is increased and this can thereby be operated at a higher speed.

Furthermore, the invention relates to a method for producing a centrifuge rotor described above. This is characterized by the fact that a cup-shaped structure is produced by a forming process or an exciting process. Due to the planar structure of the centrifuge rotor this can be prepared in a simple manner both as a forming part and in particular as a turned / milled part.

These methods allow a particularly cost-effective and specific production even for small quantities.

By this type of production in addition to plastics and metallic materials can be processed. Due to the greater choice of materials that are accessible to the manufacturing method according to the invention, cheap centrifuge rotors can be produced in small quantities.

Preferably, the recesses for receiving the hanger before forming a sheet material can be introduced to a cup-shaped centrifuge rotor in this. This has the advantage that it is much easier to machine recesses in a planar component than in an already formed component.

In a particularly advantageous embodiment, the centrifuge rotor can be produced by deep drawing. For this purpose, first recesses for the hanger shots are introduced in particular in a Ronde. Subsequently, the shape of the centrifuge rotor is formed from the blank due to the shape of the pressed-in punch. It can be formed at the end of the wall portion in a particularly advantageous manner, a circumferential edge / fold. This essentially supports the cup-shaped structure and prevents the centrifuge rotor from bending during centrifugation.

As an alternative to the deep-drawing process, the centrifuge rotor according to the invention can also be produced by thermoforming or deep-pressing or extruding. This has the advantage that now due to the shaping according to the invention and by the different methods, access to a large range of materials beyond plastic is created, resulting in a wider field of application.

Further advantages, features and possible applications of the present invention will become apparent from the following description in conjunction with the embodiments illustrated in the drawings.

In the specification, claims, and drawings, the terms and associated reference numerals used in the list of reference numerals below are used. In the drawing:

1 a centrifuge rotor according to the invention with inserted hangers in a perspective view;

2 a sectional view of a centrifuge rotor according to the invention, and

3 a plan view of a centrifuge rotor according to the invention.

1 shows a perspective view of a centrifuge rotor according to the invention 10 with six inserted hanger 12 , The illustration shows an operating state during centrifugation, in which the hangers are in a horizontal position. The centrifuge rotor 10 has an axle 14 for receiving the drive axle of the centrifuge, which is not shown for reasons of clarity, on. The axle is closed by a floor 16 on in a wall area 18 ends. The floor 16 is sheet-shaped and is only by the suspension shots 20 , which take the form of recesses in the ground 16 are introduced interrupted. The hanging pictures 20 also sit in the wall area 18 whereby a horizontal support of the hanger during centrifugation is ensured.

The centrifuge rotor 10 is thus cup-shaped and this has a dodecagonal basic shape. In addition, the cup wall is bent in the upper region and thus forms an edge surface 22 , which, however, has a round basic shape.

This cup-shaped configuration has the advantage that the centrifuge rotor 10 simply from one with the recesses for the hanger shots 20 provided Ronde finished in only a few steps by the deep-drawing or deep-pressing.

By this method, for the production of the centrifuge rotor 10 various materials are used. These may be, for example, sheets of steel or aluminum alloys or plastics. In this embodiment of the centrifuge rotor 10 is a section of the floor area 16 inclined by 25 ° with respect to the centrifuge axis. This allows an advantageous hanging the hanger 12 when loading the centrifuge, since the hangers due to the inclination space for centrifuge rotor 10 to let. The inclination of the ground area is in 2 shown more clearly.

2 shows the centrifuge rotor 10 in sectional view. Especially good is this representation of the course of the recesses, which the hanger shots 20 form, remove. Likewise, the sheet-like design of the soil 16 which, in twelve contiguous, essentially trapezoidal facets, the marginal area 18 the cup-shaped centrifuge rotor 10 with the axle 14 combines. The floor 16 runs, which is clearly visible in this illustration in the radially inner region first at an angle of 90 ° relative to the rotor axis, and then in a radially outward leigende range at an inclination angle b, from about 65 ° relative to the rotor axis, to the ground 16 to the wall area 18 followed. This has the advantage that, by a suitable choice of the angle of inclination of different soil areas, a centrifuge rotor optimized with regard to the reception of the hanger and the rotational properties can be produced.

3 shows the centrifuge rotor 10 in plan view. Particularly good here is the trapezoidal structure of the inclined cup base section as well as the fundamentally polygonal configuration of the centrifuge rotor 10 to recognize. This is particularly clear that the invisible wall area through the floor 16 except for the hanger shots 20 full surface with the axle 14 connected is. This means a significantly simplified production compared to the braced constructions in the prior art. The simplified production requires a significantly higher flexibility in the design of centrifuge rotors and pertinent adaptation to specific problems.

LIST OF REFERENCE NUMBERS

10

centrifuge rotor

12

hanger

14

axle mount

16

ground

18

wall area

20

suspension holding

22

edge

A

rotor axis

b

tilt angle

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 6811351 B2 [0003]

Claims (10)

Centrifuge rotor, which has an axle mount ( 14 ) for receiving a centrifuge axis and a bottom ( 16 ), which in a wall area ( 18 ), the wall area ( 18 ) is in particular parallel to the centrifuge axis, and in the radial extension at least one hanger receptacle ( 20 ) for a hanger ( 12 ) is introduced in the form of a recess, wherein the hanger receptacle ( 20 ) from the ground ( 16 ) into the wall area ( 18 ), wherein a hanger ( 12 ) in the area of the soil ( 16 ), and the hanger ( 12 ) by Zentriufgalkraft in the recess of the wall area ( 18 ), characterized in that the centrifuge rotor ( 10 ) is formed surface-shaped except for the recordings. Centrifuge rotor according to claim 1, characterized in that an edge ( 22 ) provided at the end of the wall area ( 18 ) extends circumferentially around the rotor in particular radially outward. Centrifuge rotor according to one of claims 1 or 2, characterized in that the bottom ( 16 ) has a bottom portion which extends at an angle (b) between 60 ° and 90 °, in particular at an angle of 60 ° to 70 °, to the rotor axis (A). Centrifuge rotor according to one of the preceding claims, characterized in that the bottom ( 16 ) is provided with reinforcing ribs. Centrifuge rotor according to one of the preceding claims, characterized in that the centrifuge rotor ( 10 ) is formed from a metal sheet. Centrifuge rotor according to one of the preceding claims, characterized in that a metal-safe material, steel or aluminum or another alloy or plastic is used as the material. Process for producing a centrifuge rotor according to one of the preceding claims, characterized in that the centrifuge rotor ( 10 ) is produced by means of a forming process or a cutting process. A method according to claim 7, characterized in that the recesses before the forming of the sheet material in a cup-shaped centrifuge rotor ( 10 ) are introduced. Method according to one of claims 7 or 8, characterized in that the recesses for guiding and holding the hanger ( 12 ) are introduced into the sheet raw material before it is formed. Method according to one of the preceding claims, characterized in that the forming by deep drawing or thermoforming or deep pressing or extrusion takes place.

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