EP1278593A1

EP1278593A1 - Static mixing element

Info

Publication number: EP1278593A1
Application number: EP01940350A
Authority: EP
Inventors: Manfred Schauerte
Original assignee: Tracto Technik GmbH and Co KG
Current assignee: Tracto Technik GmbH and Co KG
Priority date: 2000-04-20
Filing date: 2001-04-20
Publication date: 2003-01-29
Anticipated expiration: 2021-04-20
Also published as: EP1278593B1; AU2001273957B2; DE10019759A1; US20040100864A1; AU7395701A; US7878705B2; US20070211570A1; ATE291486T1; DE50105692D1; DE10019759C2; WO2001080985A1

Abstract

Static mixer element for homogenizing media and methods of mixing a drilling liquid are disclosed. The static mixer includes a housing and a deflection surface arranged within the housing at a selected angle with respect to the flow direction.

Description

"Static mixing element"

The invention relates to a static mixing system for homogenizing and dispersing liquid, gaseous or powdery media and claims the priority of German patent application 100 19 759.0-23, to which reference is made in terms of content.

Homogenizing and dispersing media of the same or different aggregate states as a prerequisite for a large number of process steps in chemical or engineering technology are subject to increasingly stringent requirements, which are usually met with the help of complex static or dynamic mixing systems.

Horizontal drilling also requires the mixing of a liquid with a powdery substance or a liquid or a suspension if, for example, a bentonite-water suspension is to be used as drilling or rinsing liquid to facilitate and improve the drilling process. Such a suspension keeps the cuttings in suspension, lubricates the pipe string when it is pulled in and protects it against the surrounding soil after a certain hardening phase. Additives such as soda ash or polymers can be added to vary the property of the suspension. Usually drilling fluids are mixed in a separate storage tank by an agitator working in this tank, i.e. a dynamic mixer, or by a high-speed pump.

These mixing systems require more space and lead to delays in the drilling process if a new batch has to be prepared after a batch of drilling fluid has been used up. They do not allow a compact construction of the entire drilling system.

Static mixing systems are also known which, in contrast to dynamic systems, have no agitator and require less space.

The use of static mixers in mixing plants for producing drilling fluid for horizontal drilling processes is known from German patent application 199 18 775.4. In the method for producing a drilling fluid described therein, the addition medium, for example bentonite, is fed to the water in powder form upstream or downstream of a hydraulic pump which transports the drilling fluid to the drilling system. A static mixing section can be arranged behind the pump, which homogenizes the addition material and the water.

A static mixer, as it is known, for example, from "Weighing + dosing" 3/1997 pages 23 to 26, usually consists of a plurality of different individual mixing elements connected in series, which are used with the aid of an adapter in a supply or discharge system can. Each of these mixing elements has one or more deflection surfaces, which are possibly measured by one or more passages. The deflecting surfaces following one another either within a mixing element or in downstream mixing elements are always inclined at small angles to one another and also point with respect to the direction of flow of the flow in the line Medium coincidentally a small one; of 90 ° different inclination angles.

The deflecting surfaces, which are at a special axis angle to one another and to the direction of flow, produce a positive guidance of the flow, so that its direction of flow rotates several times. The passages which possibly pass through the deflecting surfaces also run at an angle to one another and to the deflecting surfaces, so that both a distribution of the flow and a multiple change in the flow direction take place. The individual flows are brought together again at other deflection surfaces.

This multiple division, deflection and merging of the media brings about their homogenization or dispersion.

Different mixer geometries are selected depending on the Reynolds number, which as a quotient of the inertial forces and the frictional forces depends, among other things, on the material properties of the media. At a critical flow velocity, the inertial forces exceed a characteristic value compared to the friction forces, so that the flow becomes turbulent.

The choice of mixer geometries and the size of the entire mixing system, i.e. the number of mixing elements connected in series is also dependent on the permissible pressure loss in the flow, which is to be assessed above all with regard to the critical speed required for turbulence and the requirements of the subsequent process steps.

Furthermore, the geometry of the deflecting surfaces and through openings and their arrangement relative to one another and to the direction of flow must be arranged in such a way that the absence of dead zones can be ensured as far as possible, since these prevent homogeneous mixing. A considerable disadvantage of the known static mixers is that the mixing elements manufactured in complex geometry have to be produced in complex production processes, which cause considerable expenditure of time and money. Above all, the sometimes massive design of the mixers with differently aligned outlets requires a high amount of material.

Another disadvantage of known mixers is that cleaning the mixers is made considerably more difficult by the deflecting surfaces which are at different angles to one another. Reliable, simple cleaning, for example by a cleaning liquid flowing only through the mixer, is inadequate.

The invention is therefore based on the object of providing a static mixer which enables efficient homogenization and dispersion of different media with structurally simple mixing elements which are also inexpensive to produce and easy to clean.

The object is achieved with a mixing element with at least one deflection surface, which is oriented at an angle of 70 to 110 ° to the main flow direction of the media in the flowed-through line.

The invention is based on the idea that when the media collide with the deflection surface that is only slightly inclined to the direction of flow and the edges flow around it, shear forces arise which cause the media to swirl and mix.

The particular advantage of the mixing element according to the invention lies in its simple construction, which can be manufactured inexpensively and without special machines. Another advantage is that due to the special orientation of the deflecting surface there are no acute angles between the surface and the surrounding housing or the wall. This makes cleaning the mixing element considerably easier.

Surprisingly, the deflection surface, which is only slightly inclined to the direction of flow, enables very good homogenization of the media to be mixed, which can be further improved by a plurality of deflection surfaces connected in series.

In a particularly preferred embodiment, the deflection surface is arranged at an angle of 90 ° to the direction of flow of the media, i.e. it is perpendicular to the direction of flow.

The result obtained, which was particularly good, could not be presumed due to the well-known considerations of the average person skilled in the art, that due to the assumed requirements of the pressure drop to be minimized as far as possible, the forced flow of the flow as varied as possible and the avoidance of dead zones, this was only slightly inclined to the flow direction or one that was vertical deflection surface for particularly unsuitable. A deflection surface arranged in this way allows dead zones lying behind it to emerge and "brakes" the currents impinging on them to a considerable extent. This leads to a significant reduction in the pressure and the speed of the liquid. Furthermore, the deflection surface according to the invention dispenses with directional positive guidance, which leads to a multiple targeted rotation of the flow direction of the medium.

In the mixing element according to the invention, the shape of the cross section of the deflecting surface can essentially correspond to the cross sectional outline of the flow through the line. However, their diameter is advantageously smaller than that of the line, so that between the line and the Deflection surface creates at least one passage for the medium deflected from the deflection surface.

The deflection surface can be fastened directly to the flow through the line or to a housing of a mixing element to be inserted into the line via fastening means.

In a special embodiment, it can also be advantageous to insert the mixing element into the line via an adapter.

The housing of the mixing element can advantageously be designed such that the side surfaces of the housing lying behind the deflection surface in the direction of flow are used to guide the medium.

For example, they can run in a funnel-like manner in order to narrow to a passage opening leading to a deflection surface of a downstream deflection surface or located in the same mixing system.

Due to the narrowing, the pressure energy of the electricity is partially converted into kinetic energy. This increases the shear forces that favor the homogenization upon impact on the deflection surface.

In a further advantageous embodiment, the deflection surface can be provided with openings which enable the medium striking the surface to be divided. An improvement in the homogenization can thus be achieved without, however, cleaning the system being considerably more difficult.

The individual mixing elements can be connected in series in a mixing system. It can also be advantageous Mixing elements in parallel next to each other if, for example, the flow rate of media is to be increased.

The mixing element according to the invention can be used for homogenizing and mixing gases, liquids, suspensions or dispersions. It can thus be used in a variety of different methods and devices, e.g. from the areas of chemical or process engineering as well as in the plastics industry, water treatment or in the food industry.

In particular, it can be used to mix drilling fluids, e.g. Bentonite-water suspensions can be used, for example, for horizontal or vertical drilling.

In the following the invention will be explained with reference to an embodiment shown in the drawings.

The drawings show:

Fig. 1 shows a longitudinal section through a mixing system consisting of several individual elements according to the invention connected in series and

FIG. 2 shows a cross section through a mixing element in plane A-A of FIG. 1.

A single element 1 of the mixing system consists of a housing 2 with two inclined surfaces 3 and 4, which narrow in a funnel shape to a through opening 5. They allow the medium flowing in the direction of the arrow through the inlet opening 6 into the mixing system.

The deflection surface 9, which is perpendicular to the outer surfaces 7, 8 of the housing, is between the housings 2 via three tongues 10a, 10b, 10c clamped. It has a smaller radius compared to the housing, so that passages 11a, 11b, 11c remain free between the housing 2 and the deflection surface 9. Parts 13a to d represent tie rods which pull the head piece 12 and the end piece 17 against one another and thus clamp the deflection surfaces 9 through the housing 2.

In the exemplary embodiment, a mixing system is composed of 3 individual elements, each with a deflection surface and a head piece 12 and an end piece 17. These are sealed off from one another by seals 20. This arrangement can be supplemented with other mixing elements.

The head piece has an input opening 6 which opens onto the first deflection surface worked as part of the head piece. The opening is funnel-shaped.

The end piece 17, on the other hand, does not have a deflecting surface, but rather releases the medium through the outlet opening 16. End piece 17 and head piece 12 are provided with a thread (not shown here) into which common pipe screw connections can be screwed.

The media flow into the head piece 12 via the inlet opening 6 and impact on the deflection surface 9. There they are deflected and flow through the passages 11a, 11b, 11c into the mixing space 19. They are partly guided along the inclined surfaces 3 and 4 , The media then flow through the passage opening 5 onto a further deflection surface. They flow through a second mixing element in the manner just described.

After flowing through the last mixing element, they reach the outlet opening 16 of the end piece 17 and leave the mixing system.

Claims

Protection claims:

1. Static mixing element (1) for mixing media with a housing (2), characterized by at least one arranged at an angle of 70 to 110 ° to the direction of flow of the media

Deflection surface (9).

2. Static mixing system (1) according to claim 1, characterized in that the deflecting surface is arranged at an angle of 90 ° to the direction of flow of the media.

3. Static mixing element according to one of claims 1 or 2, characterized by at least one passage (11a, 11 b, 11c) between the deflection surface (9) and the housing (2).

4. Static mixing element according to one of claims 1 to 3, characterized by funnel-shaped inclined surfaces (3, 4) of the housing (2).

5. Mixing system with at least one of the static mixing elements according to one of claims 1 to 4.

6. Mixing system according to claim 4, characterized by at least two parallel static mixing elements according to one of claims 1 to 4.

7. Mixing system according to one of claims 5 or 6, characterized in that a head piece (12) and an end piece (17) are tensioned together via traction means (13a, 13b, 13c, 13d).

8. Use of the static mixing element according to one of claims 1 to 4 or the mixing system according to claims 5 to 7 for producing a drilling fluid.

9. A method for mixing at least two media, characterized in that the media are guided at an angle of 70 to 1 10 ° on a deflection surface (9) arranged in their flow direction.

10. The method according to claim 9, characterized in that the media are guided at an angle of 90 ° to a deflection surface arranged in their flow direction (9).

11. The method according to any one of claims 9 or 10, characterized in that the media are divided and / or brought together by a positive guide.