阅读说明：本技术 对离心机设备的改进 (Improvements in or relating to centrifuge apparatus ) 是由 D·鲁克 C·布赖特 于 2019-10-16 设计创作，主要内容包括：本申请涉及的发明是一种设备,该设备用于允许从供应给设备的液体中分离一种或多种成分,并且然后在使用该设备之后,可以将一种或多种分离的成分用于进一步目的。该设备包括轴,该轴可旋转并且安装有一个或多个柱,所述柱与该轴一起旋转并且也绕着其自身的轴线旋转,并且液体通过该柱。所述柱(4)设置有来自跨接引导组件(6)的液体,并且本发明提供了在柱(4)和跨接引导组件(6)之间的改进的连接装置(2),以允许它们模块化。还公开了一种改进的冷却系统。(The invention to which this application relates is an apparatus for allowing one or more components to be separated from a liquid supplied to the apparatus and then, after use of the apparatus, the one or more separated components can be used for further purposes. The apparatus comprises a shaft which is rotatable and which mounts one or more columns which rotate with the shaft and also rotate about their own axis and through which the liquid passes. The column (4) is provided with liquid from the cross-over guide assembly (6) and the invention provides an improved connection arrangement (2) between the column (4) and the cross-over guide assembly (6) to allow them to be modular. An improved cooling system is also disclosed.)

1. A centrifuge device comprising a drive shaft and at least one column arranged to be rotated by the drive shaft about the drive shaft, the device further comprising a cross-over guide assembly to allow passage of a liquid introduced into the device and to allow separation of one or more components from the liquid, wherein connection means are provided for attaching the cross-over guide assembly to the column to allow modularisation of the cross-over guide assembly and/or column.

2. The apparatus of claim 1, wherein the cross-over guide assembly and column module are interchangeable with the rest of the apparatus.

3. The apparatus of claim 1, wherein the connection device forms and maintains a pathway for liquids and hydrodynamics between the cross-over guide assembly and the column.

4. Apparatus according to any preceding claim, wherein the connection means is arranged to enable connection with a series of differently shaped posts.

5. The apparatus according to any one of the preceding claims, wherein the connecting means is reusable.

6. A device according to any of claims 3-5, wherein the connection means comprises an insert member located in the liquid pathway.

7. The apparatus of claim 6, wherein the insert regulates a pressure of the liquid as it passes through the connection device.

8. The apparatus of claim 7, wherein the thickness of the insert is adapted to provide a particular pressure adjustment by a particular insert.

9. A device according to any of claims 6 to 8, wherein inserts of the same form are used in one or more other liquid paths of the device to balance the device in use.

10. Device according to any one of the preceding claims, characterized in that the connecting means comprise a locking mechanism to lock the connecting means when they are in the position of use on the device.

11. The apparatus of any one of the preceding claims, wherein the posts are square, oval or rectangular in cross-section and have smooth or corrugated side walls.

12. The apparatus of claim 11, wherein the interior of the post comprises perforated sheet material.

13. Apparatus according to any preceding claim, wherein a sleeve is provided in which the post is received and resin material is introduced between an inner surface of the sleeve and an outer surface of the post.

14. The apparatus of claim 1, wherein a conduit is provided for use with the post, and the post is formed by winding material in place relative to the conduit and maintaining the wound material at a substantially constant tension.

15. The apparatus of any one of the preceding claims, wherein a first post and a second post are provided in connection with the shaft and on substantially opposite sides of the shaft to rotate about a longitudinal axis of the shaft as the shaft is driven to rotate about the longitudinal axis.

16. The apparatus of claim 15, wherein the columns are rotatable about their respective axes to allow separation of at least one component from liquid passing through the columns.

17. Apparatus according to any preceding claim, comprising one or more fan assemblies arranged to rotate at least part of the time during which the shaft is rotating.

18. The apparatus of any one of the preceding claims, wherein rotation of the shaft is achieved by a motor connected to the shaft via a drive assembly.

19. The apparatus of claim 18, wherein the motor is located outside of a housing in which the shaft and post are located.

20. A centrifuge apparatus comprising a shaft and at least first and second columns, the shaft being driven to rotate about its longitudinal axis, the first and second columns being located on opposite sides of the shaft and attached to but offset from the shaft and rotating about the longitudinal axis, the columns being rotatable about their respective longitudinal axes to allow at least one component to be separated from liquid supplied to and passing through the columns from a cross-over guide assembly and connection means, and wherein the apparatus comprises one or more fan assemblies arranged to be rotated at least during part of the time the shaft is rotated.

21. The apparatus of claim 20, wherein the one or more fan assemblies continuously rotate during rotation of the shaft.

22. Apparatus according to claim 20 or 21, wherein the one or more fan assemblies are provided at or near the shaft and/or column of the apparatus.

23. The apparatus of any one of claims 20-22, wherein the one or more fan assemblies are positioned to urge air from outside of a housing in which the shaft and column are located and through the interior of the housing as an airflow that provides a cooling effect to the shaft as it rotates and thereby reduces the heat generated by the rotation of the shaft.

24. The apparatus of claim 23, wherein the walls, floor and/or top of the housing are provided with one or more inlets and/or vents to further encourage air to flow through the housing along a desired path and provide a cooling effect on the shaft.

Technical Field

The invention to which this application relates is an apparatus for allowing one or more components to be separated from a liquid supplied to the apparatus, which one or more separated components can then be used for further purposes after use of the apparatus.

Background

Devices of this type are known and the applicant describes one form of such a device in its co-pending patent application EP 2760589. The invention described herein relates to improvements to such apparatus which comprise a centrally mounted shaft upon which first and second columns are suspended for rotation about said shaft and which is typically driven for rotation by a motor which is typically located externally of the housing of the apparatus. The first and second columns have one or more guides, commonly referred to as "bridging guides", and through which the liquid to be treated is provided and rotation of the apparatus allows one or more components to be (separated) from the liquid.

The engagement between the post and the rest of the apparatus may be sealed and effected by use of a cross-over guide, or alternatively a rotary seal assembly may be provided. When a rotary seal is provided, the rotational movement of the components may be asynchronous, whereas when a cross-over guide is used, the rotation of the components is synchronous. Known problems are the engagement between the column and the cross-over guide assembly, and these problems have prevented the use of various column configurations that may improve component separation and processor efficiency.

It should be understood that the invention as described herein includes features that can be incorporated in both synchronous and asynchronous versions of a device.

The known apparatus, although effective to achieve separation of one or more components from a liquid, operates at a relatively small throughput rate (production rate), which may be defined, for example, as having the capacity to process 1 litre of liquid in a given time and is generally considered to be the production rate achievable using this type of apparatus. Although there are a number of reasons that limit the throughput of the apparatus, attempting to increase the capacity of the apparatus typically results in an increase in the size of at least some of the components of the apparatus and an increase in the rotational speed required to enable separation of at least one of the components. This in turn requires greater rotational speeds of the shaft of the device and has been found to result in significant heat build-up which, if not managed and reduced, can lead to failure of the shaft assembly and drive and/or other components of the device.

Another problem is that the equipment is relatively expensive, since it is relatively complex, and if it is manufactured incorrectly, any maintenance that must be subsequently performed on the equipment is difficult to achieve, and in fact may cause irreparable damage to the equipment.

Disclosure of Invention

It is therefore an object of the present invention to provide an apparatus whereby the capacity of equipment can be increased whilst ensuring that cooling of the equipment is maintained in use to allow the capacity of the equipment to be increased.

Another object of the present invention is to provide a device whereby the columns of the apparatus are formed in a manner that simplifies the construction of the apparatus and thus reduces subsequent problems and maintenance requirements.

In a first aspect of the invention there is provided a centrifuge apparatus comprising a drive shaft and at least one column arranged to be (driven) rotated about the shaft, the apparatus further comprising a cross-over guide assembly to allow passage of liquid introduced into the apparatus and separation of one or more components from the liquid, wherein connection means are provided for attaching the cross-over guide assembly to the column to allow modularisation of the cross-over guide assembly and/or column.

In one embodiment, the modularity of the cross-over guide assembly and/or the posts allows them to be interchangeable, preferably without requiring disassembly of the remainder of the apparatus and/or without requiring the use of tools.

In one embodiment, a connection means is provided in the form of a fluid passageway and thus fluid dynamics between the cross-over guide assembly and the column to which it is connected.

In one embodiment, the extent of the attachment means should be as large as possible so that the attachment means can be used to effect attachment to a range of differently shaped posts.

In one embodiment, the connection device is reusable and capable of connection and maintaining a liquid-tight seal under high pressure operation.

In one embodiment, the connection means comprises an insert member located in the liquid pathway.

In one embodiment, the insert allows the fluid pressure through the connection device to be adjusted at the time of manufacture by the design of the insert to adapt it with respect to the thickness of the insert.

In one embodiment, the insert is used in one or more other fluid paths of the device to balance the device in use.

Typically, the connection device includes a locking mechanism to lock the connection device in place for use.

In one embodiment, the provided posts have a square, oval or rectangular cross-section, and may have smooth walls, or corrugated or otherwise shaped walls.

In one embodiment, the interior of the column is filled with perforated sheet material.

In one embodiment, a sleeve for a post is provided, and a resin material is introduced and located between an inner surface of the sleeve and an outer surface of the post. In one embodiment, the cross-sectional shape of the column is selected to make a large portion of the column available to be packed and to minimize the use of resin.

In one embodiment, a spool is provided for use with the post and allows the post to be formed by winding material that is laid down at a constant tension to avoid plastic material deformation and stretching, or if stainless steel is used, damage and kinking of the tube, which can affect fluid dynamics.

Typically, the use of wound spools allows for improved dynamic balance as the weight difference between them will be minimized.

In one embodiment, first and second posts are provided connected to the shaft and on opposite sides of the shaft to rotate about the longitudinal axis of the shaft when the shaft is driven to rotate.

In another aspect of the invention there is provided a centrifuge apparatus comprising a shaft and at least first and second columns, the shaft being driven to rotate about its longitudinal axis and the first and second columns being located on opposite sides of the shaft and being attached to the shaft but offset from the shaft and rotating about the longitudinal axis, the columns being rotatable about their respective longitudinal axes to allow separation of at least one component from liquid supplied to and through the columns from a suspended guide assembly and connection means, and wherein the apparatus comprises one or more fan assemblies which rotate at least during part of the time the shaft is rotating.

In one embodiment, the fan assembly rotates continuously during rotation of the shaft.

In one embodiment, the fan assembly is disposed at or near the shaft and/or column of the device.

Typically, rotation of the shaft is effected by a motor connected to the shaft assembly, and preferably the motor is located outside of a housing in which the shaft and column are located, to avoid the motor generating heat in the housing.

Typically, one or more fan assemblies are positioned to urge air from outside the housing and through the housing as an airflow that provides a cooling effect to the shaft as it rotates, and thereby reduce the heat generated by the rotation of the shaft.

Typically, the housing is shaped relative to the components of the apparatus located therein to encourage airflow through the apparatus and to a desired location to provide maximum cooling effect.

In one embodiment, the walls, floor and/or top of the housing are provided with one or more inlets and/or vents to further encourage air to flow through the housing along a desired path and provide a cooling effect on the shaft.

Drawings

Specific embodiments of the present invention will now be described with reference to the accompanying drawings.

FIG. 1 illustrates a first embodiment of a coupling arrangement of an engagement between a column and a bridge guide assembly of a centrifuge apparatus;

FIG. 2 shows a cross-section along line AA of the connector of FIG. 1;

FIG. 3 shows a detailed view of the internal components of the connector of FIGS. 1 and 2;

FIG. 4 illustrates a centrifuge apparatus according to one embodiment; and

FIG. 5 illustrates a housing and air flow path of an apparatus according to one embodiment of the invention.

Detailed Description

Fig. 4 shows a centrifuge device 1 according to an embodiment in a front view. The apparatus comprises a body 3 in which body 3 a shaft 5 having a longitudinal axis 7 is located, which shaft 5 is connected to a motor which drives the shaft to rotate about the longitudinal axis 7.

Positioned in connection with the shaft 5 are first and second columns 4, 4 'which are positioned to rotate with the shaft 5 and also have their own respective longitudinal axes 9, 9', and the column 4 is also driven to rotate about the shaft 9 and the column 4 'is driven to rotate about the shaft 9'. As the rotation occurs, liquid is fed through the respective columns 4, 4' to allow one or more components to be separated from the liquid. Liquid is supplied to the column through a cross-over guide assembly 6, one of which is shown, and which includes a liquid passage or guide therein to allow liquid to be supplied and withdrawn from the column while allowing it to rotate.

One feature that allows the successful use of the centrifuge device is the design of the post 4, 4' configuration and the engagement between the cross-over guide assembly 6 and the post.

In particular, it would be desirable to be able to use columns of shapes other than circular in cross-section, for example using square/rectangular section extruded tubes, which would allow the capacity of the column, and therefore of the apparatus, to be increased. Another possibility is to use a bellows to form the wall of the column and thereby increase the mixing efficiency. Other forms of shape may include oval extrusions and various cross-sectional areas, but in each case the common problem is the engagement between the cross-over guide assembly and a column of any shape to transition from a column to a transition cross-over guide, requiring the connection means to be liquid-tight (fluid-tight) and wear-resistant.

The connecting means, the posts and/or the cross-over guide assembly are in a form that allows it to be modular in that they can be separated and replaced relatively easily, without interfering with the rest of the apparatus, and preferably without the use of tools.

According to the present invention, a connection device allowing these features to be achieved is provided, and an example of one embodiment is described with reference to the accompanying drawings.

A post according to the present invention may have an increased capacity of up to, for example, 20 liters or more, and it may be formed from selected materials, such as aluminum alloys, titanium, other alloys, carbon fibers, and/or by using 3D printing techniques.

According to the embodiment shown in fig. 1 and 2, a connection device 2 is shown, which connection device 2 is used for the transition between a rectangular cross-section of the column 4 and a circular cross-section of the bridging guide assembly 6. The connection device is provided with a channel 8, which channel 8 allows fluid to pass along it between the column 4 and the cross-over guide assembly 6, and has at a first end 10 an engagement structure shaped to receive an end 12 of the column 4 therein. At the opposite end 14, there is an engagement structure shaped to receive an end 16 of the jump guide assembly 6 therein. Intermediate the ends 10, 14 there is provided a transition portion 18 which allows for a smooth transition between the various cross-sectional shapes while minimizing the effect on the fluid flow along the passage 8. It will be appreciated that the connection means may be formed to allow transition between other cross-sectional shapes, for example from a square post to a circle, from a corrugated post to a circle, or from an oval post to a circle. Additionally, or alternatively, the connection means may be adapted to allow a transition between different materials used to form the post or cross-over guide, for example from a polymer to stainless steel.

It is desirable that the connecting device 2 allows it to be securely positioned with the jump guide assembly 6 and this is achieved by using a push fit locking device 20 as shown in figure 2 and which is shown in more detail in figure 3.

The locking device 20 includes a formation 22 on the end 14 of the connection device 2 and a formation 24 on a sleeve 26 located on the jump guide assembly. The first outer sleeve 28 and the second outer sleeve 30 cover the end 14 of the connecting device and the formations 22, 24 of the sleeve 26 and, when joined together, in combination act as an external securing mechanism for the locking device, holding it in place in a secure and fluid-tight manner. For ease of illustration, the first sleeve 28 and the second sleeve 30 are not shown in FIG. 3.

The outer structures 22, 24 each receive a retaining ring therein that secures the respective component 14, 26 in place, and the inner structures 22, 24 are located on the jump guide assembly 6.

The insert 34 is positioned and located around an inner wall 36 of the cross-over guide assembly 6 and an inner wall 38 of the end 14 of the connection device such that the insert extends along the joint between the components 14 and 26 to enable a relatively smooth and seamless fluid path at the joint to avoid interruption of fluid flow. Additionally, the insert may be selectively formed to allow it to act as a regulator with respect to the fluid. For example, if different materials and/or cross-sectional patterns are used for the columns and/or have different volumes and sizes, the pressure across the columns and at the cross-over guides may be different. Thus, the insert may be used as a means for adjustment by forming it with appropriate dimensions to standardize (unify) the upstream and downstream fluid channels.

For example, the pressure may be balanced by using different insert sizes (typically their thicknesses).

In addition to the above features, the apparatus may also include an air cooling system as shown in FIG. 5, in which a housing 40 is shown, in which the centrifuge apparatus 1 is located as shown. The housing is usually provided with a door which is closed during operation of the centrifuge apparatus and heat can build up during use of the centrifuge apparatus, and in particular at the rotating shaft 5. According to this embodiment, a fan assembly 42, in this case two assemblies, is provided, which in this embodiment is located adjacent vents 44, 46 in the housing 40. The fan assembly may be selected and positioned so as to create an air flow path 48 that is created and controlled to allow cooling air to enter the housing from the exterior of the housing at vent 44, and pass through the apparatus, particularly around shaft 5, to cool it, and then exit the housing through vent 46. The number and location of the fan assemblies and vents may be selected based on the desired cooling effect and/or the size of the housing. In one embodiment, an external cooling air source may be provided that enters the inlet connection to the housing.