The core elements of conventional water treatment include the sequential process steps of coagulation, flocculation, sedimentation and physical filtration. Typically, chemical coagulants are used to screen Coulomb repulsion and promote aggregation of sub-micron particulates into pin flocs.
Flocculants in the form of long chain polymers can then be added to anchor the flocs to form larger entities that settle faster in the sedimentation basin. The hydraulic retention time through the first 3 stages may be 5-10 hours, depending on the input water quality and the facility.
A transformative approach to the practice of conventional water treatment has been taught in the two related applications noted above. Features of this approach include: high scalability, modularity, small footprint, high throughput, purely fluidic, continuous flow, membrane-less, size selective cut-off, and accelerated agglomeration kinetics. The system will work with particulates of any density, including those with neutral buoyancy. These features allow reduced coagulant dosage by 50% to achieve the same turbidity reduction; which may be attributed to the compact and self-limiting narrow size distribution of pin flocs resulting from fluid shear effects. The combined effects allow for extraction of micron sized pin flocs in fluidic structures to potentially eliminate flocculation and sedimentation steps, resulting in significant savings through reduced land and chemical cost, operational overhead, and faster processing time from raw to finished water.
A major design consideration is the aggregation time to grow the pin flocs compared to the hydraulic retention time of the system. For in-line pin floc formation and subsequent removal with the spiral separator, it would be preferred that the two time scales be comparable or at least the difference between these two time scales be minimized.
As shown, process 10 is illustrated wherein water is injected into the system (at 12) and then coagulant is added (at 14). From this combination, primary particles are formed to which micro-sand is added (at 16). Polymer material is then added (at 18) to form the floc (at 20). It should be appreciated that the particles or floc in this conventional system are attached to the micro-sand. As will be illustrated in greater detail in
In this regard, with reference to
The advantage of this known technology is that process time and foot print are reduced. The disadvantages are the need to recover the micro-sand, which is granular and insoluble, using hydrocyclones and the need for additional power for the micro-sand pumps.
This application is related to commonly assigned U.S. Publication No. 2008/0128331 A1, having U.S. Ser. No. 11/606,460, filed on Nov. 20, 1006 and entitled “Particle Separation and Concentration System,” U.S. Ser. No. 11/936,729, filed on Nov. 7, 2007 and entitled “Fluidic Device and Method for Separation of Neutrally Buoyant Particles,” and U.S. Ser. No. 11/936,753, filed on Nov. 7, 2007 and entitled “Device and Method for Dynamic Processing in Water Purification,” all of which are incorporated herein in their entirety by this reference.
In one aspect of the presently described embodiments, the system comprises an inlet operative to receive source water having particles therein, a mixer operative to mix the source water with coagulant material, a buffer tank operative to receive an output of the mixer and receive mature floc (e.g. that are preferably at least of the cut-off size of the spiral separator), wherein the mature floc is operative to promote growth of particles in the source water (e.g. into aggregates that are at least of the cut-off size of the spiral separator), a spiral separator operative to segregate the mixture from the buffer tank into effluent and waste water having aggregated particles therein and an outlet operative to provide a first path for the effluent and a second path for the waste water having aggregated particles.
In another aspect of the presently described embodiments, the inlet comprises a mesh filter.
In another aspect of the presently described embodiments, the mixer is a spiral mixer.
In another aspect of the presently described embodiments, the system further comprises a tank for forming the mature floc.
In another aspect of the presently described embodiments, the age of the mature floc is minimized to allow optimal aggregation of small particles which is controlled by both size and concentration of the aged floc.
In another aspect of the presently described embodiments, the system further comprises a feedback line between the second path and the buffer tank.
In another aspect of the presently described embodiments, the system further comprises a filter device operative to receive and filter the effluent.
In another aspect of the presently described embodiments, the method comprises receiving source water having particles therein, adding alkalinity, mixing the source water with coagulant material, injecting mature floc into the mixture of the source water and the coagulant material, the mature floc promoting aggregation of the particles in the source water and separating the source water into effluent and waste water having aggregated particles.
In another aspect of the presently described embodiments, the mixing is spiral mixing.
In another aspect of the presently described embodiments, the mature floc is injected from a tank wherein the mature floc is generated.
In another aspect of the presently described embodiments, the separation is spiral separation.
In another aspect of the presently described embodiments, the method further comprises feeding the waste water back into the buffer tank to be injected as mature floc in the injecting step.
In another aspect of the presently described embodiments, a means is provided to implement the method.
The presently described embodiments are directed to a system and method that circumvent the micro-sand used by the previously described system by introducing mature floc (such as floc that is processed, e.g., for approximately 30 minutes or less) as seed particles to promote aggregation of smaller pin flocs, which are formed soon after mixing of source water and coagulant. It should be understood that the mature floc typically are large aggregates that are either extracted or recycled from the waste stream of the spiral separator or generated in another tank from coagulant and organic and/or inorganic nano-particles, for example, those that are naturally occurring in source waters. As such, the seed particles do not need to be recovered as they separate out with the waste stream after spiral separation. The additional chemicals to form the seed floc can be off-set by the 50% reduction in chemical dosage for coagulation. One implementation method is to prepare the mature floc off-line and inject periodically into the buffer tank as needed. Another embodiment is to feedback the more mature downstream floc as needed to the buffer tank. Mature floc may take a variety of forms as it is a function of relative age and the system into which it is implemented. In one form contemplated herein, mature floc has a size above the cut-off size of a spiral separator used in the process. As a point of reference, flocs above the cut-off size have dimensions such that they will be taken out of the separator in the waste stream. Also, for at least some applications contemplated herein, 30 minutes of maturing is sufficient; however, shorter durations are obtainable and often desired. For example, floc maturing for 4 minutes is sufficient for some applications. In this regard, in at least some forms, the age of the mature floc is minimized to allow optimal aggregation of small particles which is controlled by both size and concentration of aged floc.
In this regard, an exemplary system 100 according to the presently described embodiments is illustrated. The system 100 receives source water at a suitable inlet (shown representatively) from an input water source 102 that is, in one form, flowed through a mesh filter 104. It should be appreciated that the mesh filter 104 is designed to filter out relatively large particles from the input water. In this regard, the filter 104 may be formed of a 2 mm-5 mm mesh material. In at least one form, alkalinity is added in the form of a base to the input water after filtering by the mesh filter 104 to adjust for the pH. Any suitable base may be used. In at least one form, coagulant may be added to the input water after the base is added. Any suitable coagulant may be used.
The system 104 also includes a mixer 108, e.g. a spiral mixer that receives the input water and the coagulant. The spiral mixer shown in
The output of the buffer tank 110 is connected to a spiral separator 112 which has an effluent output 114. The effluent output 114 directs effluent separated out from the fluid input to the spiral separator to further filtering mechanism 116. The output of the mechanism 116 typically comprises the treated water that may be used in a variety of ways. The spiral separator 112 has a second output line 118 upon which waste water travels. The waste water can be disposed of in appropriate manners or recirculated within the system along a feedback line 120. It should be appreciated that the feedback line 120 is optional to the system; however, in one form, the feedback line 120 provides feedback of the waste water to be reinjected into the system as mature floc. As an alternative to the feedback line 120, mature floc can be generated in a tank 122 and injected into the buffer tank 110. It should also be appreciated that a combination of these approaches can be implemented in any one system.
The spiral separator 112 may take a variety of forms, However, in at least some forms, the separator operates as the spiral separator described, for example, in U.S. Publication No. 2008/0128331 A1, having U.S. Ser. No. 11/606,460, filed on Nov. 20, 1006 and entitled “Particle Separation and Concentration System,” U.S. Ser. No. 11/936,729, filed on Nov. 7, 2007 and entitled “Fluidic Device and Method for Separation of Neutrally Buoyant Particles,” and U.S. Ser. No. 11/936,753, filed on Nov. 7, 2007 and entitled “Device and Method for Dynamic Processing in Water Purification,” all of which are incorporated herein in their entirety by this reference.
In this regard, the presently described embodiments use a spiral separator that uses the curved channel of a spiral device to introduce a centrifugal force upon particles such as neutrally buoyant particles (e.g. particles having substantially the same density as water, or the fluid in which the particles reside) flowing in a fluid, e.g. water, to facilitate improved separation of such particles from the fluid. It should be understood that, because the mature floc is organic, soluble, and non-granular in nature the techniques for separating neutrally buoyant particles are particularly useful here. However, other separation techniques are contemplated as well. For example, some of these techniques utilize various forces generated in the flow of the fluid in the spiral channel to separate particles as a function of, for example, geometry of the channel and velocity. These forces include centrifugal forces and pressure driven forces, among others.
In the case of neutrally buoyant particles, as such particles flow through the channel, a tubular pinch effect causes the particles to flow in a tubular band. The introduced centrifugal force perturbs the tubular band (e.g. forces the tubular band to flow in a manner offset from a center of the channel), resulting in an asymmetric inertial migration of the band toward the inner wall of the channel. This force balance allows for focusing and compaction of suspended particulates into a narrow band for extraction. The separation principle contemplated herein implements a balance of the centrifugal and fluidic forces to achieve asymmetric inertial equilibrium near the inner sidewall. Angled impingement of the inlet stream towards the inner wall also allow for earlier band formation due to a Coanda effect where wall friction is used to attach the impinging flow. The migration could also be directed to the outer wall based on the selected operating regime.
With reference to
Likewise, the spiral mixer 108 may take a variety of forms, including that described in U.S. Ser. No. 11/936,753, filed on Nov. 7, 2007, entitled “Device and Method for Dynamic Processing in Water Purification,” which is incorporated herein by reference. In this regard, the spiral mixer may take a physical form substantially similar to that of a spiral separator, with some minor and/or functional modifications. So, with reference to
In operation, with reference back to
The maturing of the floc and its benefits as described herein can be explained in terms of aggregations kinetics. Aggregation kinetics describes the evolution of aggregates of different sizes over time. If we assume an initial dispersion of identical particles (primary particles of size a0), we can describe the time evolution of the number density Nk of aggregates containing k primary particles by
where τ is the characteristic time scale of the process and the kernel K(i, j) denotes the efficiency with which particles of size i and j collide with each other. A particle of size i is an aggregate that consist of i primary particles. The number density Nk is defined as the concentration of particles of size k divided by the total concentration of particles at time t=0. The first term on the right hand side of (1) describes the formation of an aggregate of size k through the collision of two smaller particles of sizes i and k−i. The second term describes the loss of aggregates of size k through collisions with other aggregates. The collision kernels K(i, j) depend on the physical driving force that brings the particles together.
For small (sub-micron) particles diffusion driven (perikinetic) aggregation dominates. For this type of kinetics, the collision frequency is determined by the rate with which two diffusing particles find each other and the collision kernel and time scale are given by
Here, ai (aj) is the radius of an aggregate of size i (j), kB is the Boltzman factor, T is absolute temperature, η is the viscosity of the fluid, and N0 is the total initial particle number density.
Stirring of the colloidal suspension adds a shear induced (orthokinetic) aggregation kinetics. In this case, the collision frequency is calculated as the rate of particles of size i that move through a circle with radius ai+aj, giving the collision kernel and time scale
where {dot over (γ)} is the shear rate, and φ is the solids volume fraction.
As can be seen from Eqn. (3b), the rate for orthokinetic aggregation increases with the size of the particles, and for a typical shear rate of 1/s exceeds the perikinetic aggregation rate for particles in excess of 1 μm.
In a situation where a species of large particles (>1 μm) is mixed together with small particles (<1 μm), we observe two competing aggregation kinetics. The small particles will grow together at the perikinetic aggregation rate. At the same time, the larger particles will “sweep up” the smaller particles at the orthokinetic aggregation rate. The second process is described by
where τls=π/{dot over (γ)}φl, and φl is the volume fraction of the larger particles. If we neglect aggregation between large particles (i.e. we assume Nl to be constant), we can integrate Eqn (4) to obtain the number density for the smaller particles
s(t)=Ns(t=0)e−t/τ
Here, the time scale τls is independent of the size and/or concentration of the smaller particles, but solely given by the volume fraction of the larger particles and the stirring rate.
Table 1 shows typical time scales for perikinetic and orthokinetic aggregation. As expected, the perikinetic aggregation rate is faster for sub-micron particles. Since in this aggregation mode many particle-particle collisions have to occur before the aggregates reach a size for easy removal (i.e. before they are larger than a few μm), these aggregation times are very low bounds for the actual aggregation time required in a water treatment process.
Table 2 shows typical time scales for “sweep” aggregation for different sizes and concentrations of the sweep particles. Even at low concentrations of the sweep particles, time scales are comparable to those of perikinetic aggregation. Combined with the fact that in sweep mode a single collision of a small particle with a large one results in an aggregate that is easily separated out, this results in a much higher removal efficiency for sweep mode aggregation.
Two sets of experiments were performed to validate the presently described embodiments: (1) Jar Test; and (2) in-line floc separation.
Jar Test—The Jar Test is a standard method used in the water industry to determine chemical dosage for clarification of source waters. Typical test volumes are 2 L with determined dosage being scaled up for the operational flow rates. The protocol for a standard Jar Test includes:
2 minute rapid mix;
2.3 ml of 1 N NaOH (as base) and 110 mg/L of 1% Alum (as coagulant) added to source water with starting turbidity of 26 NTU;
28 minutes slow mix; and,
Mixing stopped at 30 min and flocs allowed to settle out.
A modified Jar Test Protocol to test the presently described embodiments includes:
2 minute rapid mix;
2.3 ml of 1 N NaOH (as base) and 110 mg/L of 1% Alum (as coagulant) added to source water with starting turbidity of 26 NTU;
28 minutes slow mix; and,
First batch of 30 min floc added at 2 min (100 ml) and second batch is added at 6 min (50 ml). All flocs are injected in the slow mixing regime. A total of 150 ml of 30 min flocs are added to the jar; and,
Mixing stopped at 30 min and flocs allowed to settle.
In-line Floc Separation—The schematic for in-line floc separation is shown in
Measured turbidity in the collected effluent and waste streams for 4 minute floc are shown in
Additional experiments were performed to demonstrate separation of both 30 minute and 4 minute floc. A setup where 30 minute floc was separated using gravity by placing the flocs on the shelf some 4 feet above the plane of the spiral separator was conducted. The collected effluent was clear compared to that of the waste stream. Comparisons of separated and collected effluent and waste streams for both 30 minute and 4 minute flocs shows that collected effluent is clearer using 30 minute floc. Table 3 summarizes the comparison of process times for conventional water treatment compared to the proposed spiral system.
Particle concentrations for range of particles sizes for seeded and unseeded cases are shown. The seeded case results in lower concentrations of small particles due to enhanced aggregation with larger seed particles. The seeded case also shows a peak in the 25-30 um rang; indicating the average size of flocs immediately after mixing is stopped.
By assuming that NTU is proportional to volume fraction and that shear induced motion is dominant to sedimentation during mixing, we can infer that particles will not sediment if tsed>tmix. This gives a criterion for the largest particle to stay in solution during mixing:
where G is the shear rate and Δρ is the difference between the particle and water density. Parameter α is estimated from empirical data in the time interval between the end of mixing and the first NTU measurement. The volume fraction is given by:
Particle size as a function of time, R(t), decreases as particles sediment, and is derived as:
The corresponding particle density is estimated as:
The particle size distributions extracted from fit to empirical data in the 32-45 min time interval is shown in
The presently described embodiments result in at least the following advantages:
It will be appreciated that several of the above-disclosed and other features and functions, or alternatives thereof, may be desirably combined into many other different systems or applications. Also that various presently unforeseen or unanticipated alternatives, modifications, variations or improvements therein may be subsequently made by those skilled in the art which are also intended to be encompassed by the following claims.
This application is related to commonly assigned U.S. Publication No. 2008/0128331 A1, having U.S. Ser. No. 11/606,460, filed on Nov. 20, 1006 and entitled “Particle Separation and Concentration System,” U.S. Ser. No. 11/936,729, filed on Nov. 7, 2007 and entitled “Fluidic Device and Method for Separation of Neutrally Buoyant Particles,” and U.S. Ser. No. 11/936,753, filed on Nov. 7, 2007 and entitled “Device and Method for Dynamic Processing in Water Purification,” all of which are incorporated herein in their entirety by this reference.