In many chemical reactions involving two or more immiscible fluid phases, the rate of conversion of reactants to products is limited by the amount of surface area generated between the phases. For example, in the nitration of benzene to form mononitrobenzene using a plug flow reactor, it is important to keep the organic phase and the aqueous phase well mixed and avoid phase separation. Effective mixing elements produce fine dispersions of the reactants to maximize surface area and therefore reaction rate.
Tabbed mixing devices are effective in mixing fluids and solids. Some devices employ three tabs in a staggered arrangement that creates a counter-rotating vortex pair, which is highly effective in mixing fluids. For example, U.S. Pat. No. 4,758,098 (Meyer) describes a tabbed mixing device used to mix solid particles without clogging. U.S. Pat. No. 6,811,302 (Fleischi) and U.S. Pat. No. 7,316,503 (Mathys) disclose that an additive is immediately mixed by a device including three tabs oriented to create a pair of counter-rotating vortices. U.S. Pat. No. 9,403,133 (Baron) discloses three pairs of overlapping tabs arranged around the circumference of a pipe so as to induce a pair of counter-rotating vortices.
Mixing devices formed by folding metal sheets are known in the art. U.S. Pat. No. 6,595,682 (Mathys) discloses a device in which a sheet of metal is folded such that two sets of tabs form two planes that intersect downstream of the flange in which the device is clamped. One embodiment of the device incorporates three tabs oriented to create a pair of counter-rotating vortices.
Mixing devices have been used in conjunction with a piping bend. However, these are designed to reduce or eliminate turbulence and are not effective in preventing phase separation. U.S. Pat. No. 5,323,661 (Cheng) and U.S. Pat. No. 7,730,907 (Richter) disclose devices in which the fluid is spun to create a single, full diameter vortex before being passed through the elbow. US 2011/0174407 (Lundberg) discloses a mixing device installed downstream of a pipe bend to create a uniform flow field downstream of the device.
There is a need for a mixing element that is simple to fabricate as well as effective in mixing the reactants and preventing phase separation, particularly in pipe bends.
According to one aspect of the invention, there is provided a mixing device for mixing fluids flowing through a pipe, comprising a plate having a flowpath therethrough and two or more tabs extending from the plate into the flowpath at an angle from the plane of the plate, the tabs being formed by first folds in the plate, at least two of the tabs having a second fold therein, the tabs and first and second folds being arranged to produce two counter-rotating vortices in the fluids passing through the pipe.
According to a further aspect of the invention, the mixing device has a plane of symmetry perpendicular to the plane of the plate and the tabs and first folds and second folds form a pattern that is symmetrical about the plane of symmetry.
According to a further aspect of the invention, there is provided a method of mixing fluids flowing through a pipe having a mixing device upstream of a pipe bend, the mixing device comprising a plate having a flowpath therethrough and two or more tabs extending from the plate into the flowpath at an angle from the plane of the plate, the tabs being formed by first folds in the plate, at least two of the tabs having a second fold therein, the tabs and first folds and second folds being arranged to produce two counter-rotating vortices in a fluid passing through the pipe, the method comprising: (a) flowing the fluids through the pipe in a direction from the mixing device to the pipe bend; (b) forming the counter-rotating vortices in the fluids as the fluids flow past the mixing device; and (c) flowing the fluids past the pipe bend and thereby inducing counter-rotating Dean vortices in the fluids, the Dean vortices being reinforced by the counter-rotating vortices formed by the mixing device.
According to a further aspect of the invention, there is provided a method of reducing phase separation in a flow through a pipe of a mixture of immiscible fluids, the pipe having a mixing device upstream of a pipe bend, the mixing device comprising a plate having a flowpath therethrough and two or more tabs extending from the plate into the flowpath at an angle from the plane of the plate, the tabs being formed by first folds in the plate, at least two of the tabs having a second fold therein, the tabs and first folds and the second folds being arranged to produce two counter-rotating vortices in the fluids passing through the pipe, the method comprising: (a) flowing the fluids through the pipe in a direction from the mixing device to the pipe bend; (b) forming the counter-rotating vortices in the fluids as the fluids flow past the mixing device; and (c) flowing the fluids past the pipe bend and thereby inducing counter-rotating Dean vortices in the fluids, the Dean vortices being reinforced by the counter-rotating vortices formed by the mixing device.
Further aspects of the invention and features of specific embodiments of the invention are described below.
A key concern in the design of reactors processing immiscible fluids is fluid flow stability. Published investigations of two phase flow such as T. J. Crawford, C. B. Weinberger and J. Wesiman, ‘Two-Phase Flow Patterns and Void Fractions in Downward Flow Part 1’, Int J. Multiphase Flow, Vol. 11, No. 6 pp. 761-782, 1985 generally categorize observed flow patterns as follows:
An analysis of experimental observations made of the stability of two phase down flow in a reactor model produced a new dimensionless stability parameter (0) that can be used to predict if a section of downflow pipe will operate in a stable bubbly or dispersed flow regime based on three classic dimensionless parameters: Richardson Number (Ri), Void Fraction (β), and and Eötvös Number (Eo). These parameters are defined as follows:
where: Ri=Richardson Number
A support vector machine (SVM) algorithm was used to separate desirable ‘Dispersed’ and ‘Bubbly’ flow regimes from unstable or unsafe ‘Churn’ and ‘Annular’ flow regimes. A new dimensionless parameter (0) was discovered based on the output of the SVM algorithm that allows the transition from unstable to stable flow regimes to be reliably predicted in extended regions of downward flow.
The parameter ϕ is defined as:
where: ϕ=Stability Parameter
Pipe bends in reactors processing two or more immiscible fluids present particular challenges in avoiding phase separation. In the development of the present invention, phase separation was observed as the fluids passed through pipe bends. This separation is attributed to differences in fluid momentum tending to separate the different fluids. Changes in fluid direction are known to separate fluids and particles with different densities. In fact, it is known to use this effect to remove small particles and droplets from gas and liquid flows. However, bulk phase separation would negatively affect the performance of a chemical reactor.
Phase separation is more likely to occur when external forces such as gravity reinforce the changes in fluid momentum. For instance, in a system with a heavy continuous phase and a light dispersed phase, the transition from downward to horizontal flow is more likely to result in phase separation than the transition from upward flow to horizontal flow. Similarly, in a system with a light continuous phase and a heavy dispersed phase, the transition from upward flow to horizontal flow is more likely to cause phase separation. This is illustrated in the flow maps of
Pipe bends are also known to induce a secondary flow pattern consisting of one or more pairs of counter-rotating vortices known as Dean vortex flow. The Dean Number (De=Re (d/Ri)0.5) (W. R. Dean, M. A., ‘Fluid motion in a curved channel’, proceedings of the royal society, Vol. 121, Issue 787, pp. 402-420, 1928) is used to characterize this behavior, where Re is the commonly known flow Reynold's Number. Dean vortex flow becomes stable when De exceeds 64 and can exist in fluid conduits having round, square or rectangular cross-section (‘Phillip M. Ligrani, ‘A Study of Dean Vortex Development and Structure in a Curved Rectangular Channel With Aspect Ratio of 40 at Dean Numbers up to 430’, NASA Contractor Report 46047, 1994).
During testing, it was determined that a fluid momentum effect similar to Dean vortices persisted even when bulk phase separation occurred around the pipe bend. A mixing device as disclosed herein can be used to reinforce the Dean vortices and thereby prevent or delay bulk phase separation.
Referring to
The mixing device 10 has a plane of symmetry 28 perpendicular to the plane of the plate. The plate 12 is cut and folded about this plane 28 in a geometrically symmetrical manner to form the mixing device. This induces formation of a pair of counter-rotating vortices 30 (shown in
The cutting pattern may create voids 36 in the plate, as in
The pipe 16 in which the mixing device is used may be a tubular conduit with round cross-section, or a tubular conduit of arbitrary cross-section.
At least two tabs 20 of the mixing device incorporate a fold 26 in the tab body. Each fold in the plate or in the tab (i.e., the folds 32 in the plate that form the tabs and the folds 26 within the tab bodies) may be between 0 and 90 degrees and they may be identical or different. Different tabs may have differing fold angles. Tabs may be folded so as to angle the tab upstream (see folds 32A, 26A in
The tabs 20 and folds 26, 32 are arranged in a manner that produces two counter-rotating vortices 30. This is depicted in
Hydraulic tests on the mixing device showed that it is highly effective in preventing phase separation. When installed in a transition from vertically-downward to horizontal flow with a heavy continuous phase, the device effectively eliminated phase separation at any operating point between 0<ϕ≤1.5. Use of the mixing device provides stable fluid behavior in pipe bends at any operating point that would be expected to produce stable bubbly or dispersed flow regimes in sections of straight pipe in downward flow, as shown in
The results in
References in this disclosure to “vertically-downward” or ‘vertically-upward” flowpaths and the like mean flows that are at an angle of greater than 45 degrees. In practice, the flows are substantially vertical. Likewise, references to “horizontal” flows means flows that are at an angle of less than 45 degrees.
The mixing device 10 may be adapted to prevent phase separation in a conduit with a non-circular cross-section which is also known to produce Dean vortices. Again, the mixing device is particularly effective between 0 and 15 hydraulic diameters from the pipe bend.
The pressure drop of the mixing device 10 is low, typically having a loss coefficient of between 1 and 10, depending on the configuration. For example, the device depicted in
Alternatively, the device may also be installed in a straight section of pipe and used to improve mixing of immisible phases. The device is particularly suited to improving mixing of immiscible phases in vertical flow applications producing bubbly or dispersed flow regimes where bulk flow separation does not occur, but it is also effective in horizontal applications.
Visual comparison of the dispersions present in pipe flow with and without the mixing device 10 indicated that it is highly effective in increasing surface area in flow regimes where the phases are already largely mixed, such as in bubbly and dispersed flow regimes. The improvement in mixing and phase dispersion is seen in
Throughout the foregoing description and the drawings, in which corresponding and like parts are identified by the same reference characters, specific details have been set forth in order to provide a more thorough understanding to persons skilled in the art. However, well known elements may not have been shown or described in detail to avoid unnecessarily obscuring the disclosure. Accordingly, the description and drawings are to be regarded in an illustrative, rather than a restrictive, sense.
As will be apparent to those skilled in the art in the light of the foregoing disclosure, many alterations and modifications are possible in the practice of this invention without departing from the scope thereof. Accordingly, the scope of the invention is to be construed in accordance with the following claims.
Filing Document | Filing Date | Country | Kind |
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PCT/IB2018/059010 | 11/15/2018 | WO | 00 |
Number | Date | Country | |
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62734056 | Sep 2018 | US |