A PROCESS AND A PLANT FOR PURIFYING OF A LIQUID
The present invention is related to a process and a plant for purification of a liquid, said liquid being contaminated by gas, other liquids and/or solid materials.
It is known to use methods like centrifuges, hydrocyclones, and flotation systems to treat wastewater containing oil or other contaminants. Centrifuges are big, heavy, energy demanding, and expensive especially for treating flows of above 100 m3/h. Hydrocyclones have been used extensively for treating oil containing waste waters, and they have proven reliable under steady conditions. However, hydrocyclones have their disadvantages as they can not give very low outlet contaminant values, e.g. usually not under 25 mg/1 dispersed oil, and if larger capacities are required a plurality of hydrocyclones is needed in parallel. A degassing tank is often used downstream of the hydrocyclones. Hydrocyclones geometrical shape leads to high production costs. A common flotation system requires big space, and usually it is not separately a high efficiency device.
By flotation a substance, e.g. in the form of droplets or particles, is removed from another directly or indirectly by means of buoyancy forces, such as when gas bubbles are supplied to one of the substances, the gas bubbles thereby attaching to the substance to be removed, respectively by natural flotation and gas or air flotation.
Flotation is performed as dissolved gas flotation when the entire or part of the liquid flow is pressurized in such a way that a desired amount of gas is dissolved in the liquid, whereafter the pressure is released and the gas releases as gas bubbles, or as induced gas flotation where gas is supplied directly to the liquid flow in such a way that many gas bubbles are created.
To achieve a high efficiency, a complete flotation process comprises destabi- lisation, precipitation and flocculation, addition of gas and flotation, respectively. There are many different system solutions for these unit processes in use.
By dissolved gas flotation the complete or a part of the input flow or output flow is pressurized to add gas. Separation is performed in a tank whereby main portion of the particle/droplets float to the surface of the liquid or to the upper portion of
the tank. From here the particles are skimmed, drained or pumped away. A small fraction of the particles sink to the bottom where it is scraped and pumped away.
WO/96/12678 describes a process for purification of a liquid, where the liquid is contaminated by other liquids or solid materials, thereby for example removing oil from oil contaminated water. The process comprises a flocculation device, a bubble generator, and a flotation device or a sedimentation device. The flocculation device comprises a pipe loop of one or more vertically arranged pipe elements with built-in agitators providing turbulence and plug-type flow through the loop. Each pipe element has a built-in agitator comprising a shaft that extends through the element and being provided with propeller elements. A motor drives the agitator. The bubbles and floe containing liquid pass through a static mixer and a diffusor arranged between the flocculation device and the flotation device. The diffusor is connected to the flotation inlet at the lower part of the flotation device. The diffusor results in a speed reduction of the liquid before it enters a flotation chamber of the flotation device. As the static mixer generates the bubbles in the liquid from added gas, the process is based on induced gas flotation. This system has several disadvantages over the present invention as external energy is used to build up floes with agitators and gas is added rather than using existing gas. Another disadvantage is that large shearing forces in the mixer can destroy the already built up floes. The known processes have further disadvantages such as floe destruction by large shearing forces in pumps, cyclone inlets and valves downstream of the flocculation process. Known processes based on recirculation have the disadvantage that the recirculation as such increases the loading on the separation process and the requirement of a recirculation pump. This leads to larger tanks and consumption of ex- ternal energy by the pump. Agitators in flocculation processes consume energy and gives high operating expenses.
The above mentioned disadvantages with prior art processes and designs are avoided and further advantages are achieved with the process and the plant according to the present invention as defined by the features stated in the claims.
The objective of the present invention is to achieve a process and a plant for purification of a liquid by only using the energy of the liquid flow that eliminates the disadvantages of the above described prior art.
The drawing discloses in figure 1 schematically a process and a plant for per- forming the process according to the present invention; figure 2 discloses a side view of a mixing and coagulation device; figure 3 discloses a cross section III-III of figure 2; figure 4 discloses schematically a flotation and separation device and figure 5 discloses an isometric view of a complete plant for performing the method according to the invention. As can be seen in figure 1 a plant for performing a process according to the present invention comprises a degassing tank 10, a mixing and coagulation device 30 and a flotation and separation device 40.
The degassing tank or pre-treatment tank 10 comprises a tank having equipment and means internally, possibly externally. The input flow to the plant as such is directed through an input 14 to the degassing tank. It mainly consists of gas, oil and water as well as some small grains of sand. In the degassing tank 10, gas, liquid and possibly sand are separated.
The gas exits the tank through a gas outlet 15 and the liquid, the water and the oil exit through a liquid outlet to line 16. When sand separation is performed, the sand together with a small amount of the liquid exits through a bottom outlet 17, preferably comprising of a line and valve 13. The gas and the sand flow thereafter exit the system. The liquid flow is directed to the mixing step 30 of the plant.
The sand separation executed in the degasser is important for the final oil separation result, when the target is very low oil concentration in the outlet. This is due to the following.
Sand grains have less probability for being separated in the flotation process than oil droplets. Oil droplets float up by themselves because their density usually is lower than the water density, while sand grains settles down because their density is higher than water. Sand grains can be forced to float up in a flotation process. The function is to combine the flotation gas bubble with the sand grains or oil droplets. The combined aggregate will float up. The floating speed is dependent on the aggre-
gate density. Aggregates with sand particles will have a higher density than aggregates with oil. Thus they will have a slower rising velocity and hence, they have a greater chance to escape separation.
Sand can contain up to 20 % of oil. Thus sand can be considered as an oil s carrier. Sand escaping separation will then contribute to the oil content in the outlet water from the system. In the plant according to the present invention this is to a great extent avoided because an efficient sand separation is executed in the degasser. This is one of the important advantages of the system.
The degassing tank 10 operates with a pressure, which is higher than in the to mixing step 30 and the flotation tank 40. If the pressure is higher or substantially higher in the degassing tank 10 than in the mixing step 30, the liquid flowing from the degassing tank to the mixing step has to pass through a valve 12 where the pressure is released. This pressure release causes the dissolved gas in the liquid to be released as many small gas bubbles. These gas bubbles promote flotation in the flota- i5 tion tank 40. The amount of released gas and the bubble size is dependent on the pressure difference between the degassing tank 10 and the mixing step 30. An increased differential pressure increases the amount of released gas and decreases the bubble size.
The pressure in the degassing vessel is controlled by valve 11. The opening
20 of valve 1 1 is set by a control system that measures the pressure in the degassing vessel. The control system action is increased pressure - increased opening. The degassing vessel has a liquid level that is controlled by valve 12. A level measuring and control system opens valve 12 when the level increases and vice versa. Separated sand that accumulates in the vessel bottom is flushed out of the vessel through line 17
25 on a preferably intermittent basis and controlled by valve 13. A timer process variable or an operator opens and closes valve 13.
The purpose with the degassing tank 10 is to function as a separator for gas, liquid and sand on one hand, and on the other hand to ensure that the liquid contains dissolved gas which is released to flotation gas after a pressure release over a down-
30 stream valve.
The mixing step, agitation step or coagulation step 30 may comprise one or more tanks or compartments 31 in series. Each tank or compartment in this case has a specific geometric shape and may have internal equipment and means. The mixing step 30 also may be a long pipe arranged geometrically in a specific way. The inlet flow from the degassing tank 10 passes through the mixing step 30 and it is directed to the flotation tank 40 through an outlet to line 35. It is possible to increase the plant flow capacity by having two or more mixing steps in parallel. This will in addition increase the flow turndown capacity of the plant.
The geometrical arrangement 30 and the means of the mixing step 30 provide establishment of a specific flow pattern and a specific agitation intensity in the mixing step. The agitation intensity is provided and the flow pattern is initiated only by using the energy contained in the inlet flow to the mixing step. The conversion of the inlet stream energy to agitation energy is done according to the overall mechanical energy balance over an agitated volume with fixed solid boundaries, steady state conditions, constant mass flow through a single planar inlet and single planar outlet, incompressible flow and in accordance with:
2 Λ + V2 2 + Z2 - p - g + p - Ea +AF (1)
Where: p = pressure (Pa)
V = average stream velocity (m/s)
Z = distance from a selected reference level (m) p = fluid density (kg/m3) g = gravity acceleration or other acceleration due to system movement (m/s ) Ea = agitation energy per unit mass inside the vessel/compartment (J/kg)
ΔF = viscous energy dissipation to internal energy or friction loss through the system (Pa) subscription 1 indicates inlet 33 subscription 2 indicates outlet 35
The term Ea in equation 1 represents the agitation energy inside the volume that is agitated. Since agitation is equivalent with motion, it represents only the kinetic energy of the fluid moving around inside the agitated volume. The amount of agitation energy is usually larger than the energy amount required for the transport of liquid through the agitated volume. This means that the flow pattern has to have some kind of rotational behaviour. The construction of the mixing step has to reflect the fundamentals stated above. This means that the construction must create a con- tinuos rotational behaviour of the liquid inside the agitated volume, by using some of the energy in the inlet stream. The agitation intensity is the energy expressed by the term p • Ea per unit time (seconds). The agitation intensity is important for the coagulation and flocculation processes. The agitation intensity shall neither be too high nor too low. Too high agitation intensity will cause oil droplet, floe or aggregate break up. Too low agitation intensity gives a slow coagulation/flocculation rate. The agitating intensity is de- creasing from the inlet of the line 33 to the outlet to line 35 in the mixing step. This is important since droplets, floes or aggregates are more susceptible to break up as they grow. A larger droplet requires a lower agitation intensity not to break up, compared to a small one. Thus as the droplets, floes or aggregates grow through the mixing step, the agitation intensity should decrease through the mixing step, to prevent break up. The construction of the mixing step as described above promotes coagulation and flocculation of small oil droplets and particles to larger oil droplets and particles. The creation of aggregates between the oil droplet/particles and the gas bubbles is also promoted.
The coagulation, the flocculation and the establishment of oil-gas-aggregates may be improved by adding chemicals through an injection line 32 before the mixing device and on chosen places in the mixing step 30 through one or more injection lines as indicated by 34. Adding chemicals is, however, not always necessary.
The purpose of the mixing step 30 is to ensure coagulation and flocculation of particles and oil droplets, to ensure creation of aggregates between particles re- spectively oil droplets and gas bubbles. It is substantial in connection with the present
invention that this is achieved by using only the energy from the inlet flow for agitation and mixing.
An example of mixing step design is shown in figure 2 and 3. The mixing step is built as a cylindrical vessel or pipe with flat or curved end caps. The vessel is divided into four compartments 31 by three partition walls 36. Each partition wall 36 has a hole or slot 37 that allows the liquid to flow through the mixing step. The inlet 33 is located in the first compartment at one of the vessel ends. The outlet 35 is positioned at the opposite vessel end in the final compartment. The general design measures of the mixing step preferably being; the distance between the partition walls 36 is minimum one quarter of or maximum ten times the outside cylinder diameter; the length of the cylindrical part being approximately equal to four times the distance between the partition walls. The inlet 33 preferably has a position and direction that is parallel to the tangent of the vessel cylinder. The preferred tangential inlet sets up a main rotational flow pattern with the rotation axis substantially equal to the cylinder centre axis through the whole mixing step. This flow pattern is disturbed when the stream passes the partition wall holes 37. This disturbance creates additional eddy currents in the second, third and fourth compartments and so on in addition to the main rotational flow pattern. This is good for the mixing. In the final compartment, the stream exits the mixing step through the outlet to line 35. The outlet for line 35 is preferably positioned at the centre of the vessel end cap, and it has a direction that is parallel to the centre axis of the vessel cylinder. The outlet for line 35 might have a vortex breaker at the inside to break up the main rotation in the mixing step. The correct agitation intensity in the different parts of the mixing step is determined by selecting the correct diameters of the inlet 33, partition wall holes 37 and the outlet to line 35.
The mixing step design shown in the example has managed to grow oil droplets from a mean diameter of 10 microns up to a mean diameter of 100 to 400 microns. This has been done in laboratory tests with the use of a coagulation chemical injected immediately upstream of the inlet of line 33. In the tests the retention time in the mixing step was 10 seconds.
The flotation tank, the separation step or the separation tank 40 is a tank equipped with internal structural packing material 52. The packing material functions as a lamella separator. This provides a large separation area and a compact design of the flotation tank. On the inlet side of the tank there is a compartment 51. There is also a compartment 53 on the outlet side of the tank. The tank may also have a storage volume/compartment 54 on the outside. The storage volume/compartment 54 might be connected to the flotation vessel 40 by a line or pipe. The inlet flow from the mixing step is directed into the tank inlet compartment 51 before the packing material 52. From here the liquid flows through the packing material 52 out on the other side and exits through the outlet 50.
On the way through the packing material oil droplets, particles, gas bubbles and aggregates of oil, particles and gas are separated according to the flotation or the sedimentation principle. The packing material is such that separated oil, particles and gas are transported to the upper part of the tank and into a storage volume 54. The storage volume might be an outside compartment placed on the upper side of or outside the vessel or it might be the very upper part of the vessel. It is important to shield the storage volume from contact with the outlet compartment 53. The shielding shall prevent separated oil or particles to be dragged into the main outlet line 50. The transportation of separated material upwards through the packing material and into the storage volume results in a dewatering of the separated material. The storage volume then contains a pure gas phase and phase of separated material that contains small amount of water. These phases can then be tapped off separately from the flotation vessel. Gas from the storage volume exits the system through line 48. Separated oil/particles preferably exits the system through line 49. The pressure in the flotation vessel is controlled by valve 42. A control system measuring the pressure in the vessel adjusts the opening on valve 42. The control system has an increased pressure-increase opening action. It is important to maintain a constant pressure in the flotation vessel since the size of the gas bubbles in the floating aggregates of bubbles and particles is dependent on the pressure. A pressure increase will reduce the bubble sizes and likewise the buoyancy of the aggregates. The pressure then has direct effect on the separation performance.
The storage volume has a liquid level that has to be controlled. Valve 44 on the main outlet 50 controls this level. A control system that measures the level in the storage volume adjusts the opening of valve 44 by increased level - increased opening action. The removal of dewatered separated material is controlled by valve 43. The removal is preferably intermittent.
The construction of the flotation vessel with the packing material is preferably done as described below to optimise the separation in the structural packing material. The flow in the packing material channels should preferably be laminar. This means that the Reynolds number shall be in the laminar range. In addition the flow should preferably be stable. A stable flow will not be disturbed by acceleration forces and forces from separating gas and materials. The laminar flow requirement returns a low flow velocity in the channels. A too low velocity can give unstable flow condi- tions. To maintain a stable flow the Froudes number in the packing channels must be greater than 4-10"5 at the maximum acceleration force the separation step can experience.
The packing material should preferably not have construction details or be installed in such way that accumulation of large volumes of gas and other separated material is retained inside the packing. If the accumulated gas/material suddenly is released from the accumulation spot, it can disturb the flow and the separation. The flotation tank together with the inlet compartment 51 before the packing material is constructed in such a way that mixing and flocculation occur in the inlet compartment without using external energy. The construction criteria for optimum mixing and flocculation are equal to those stated for the mixing step. In addition to those criteria the following two criteria should preferably be fulfilled: first the agitation intensity in the inlet compartment must be lower than in the last mixing step compartment.
Secondly the inlet flow from the mixing step 30 contains many small gas bubbles. These bubbles should preferably be evenly distributed through the whole compartment 51. Gas bubbles distributed through the whole compartment will
maximise the probability for formation of aggregates of gas bubbles, oil droplets and other particles. This will in turn enhance the separation efficiency.
Chemicals may be added to the inlet 46 of the flotation tank 40, through an injection line 45 to improve the flocculation and separation in the tank. A small frac-
5 tion of the particles entering the tank settles down to the lower part of the tank and of the packing material. The tank may be equipped with flushing means to remove this material through a specific outlet 47 below the packing material.
The flotation tank 40 performs the final flocculation in the inlet compartment 51 of the flotation tank 40, separation of oil droplets, particles and gas as well as de- o watering i.e. removal of water, from the separated material. Clean water is removed from the flotation tank 40 through the outlet 50.
The flow into the packing material in the flotation vessel is distributed across the whole cross section of the packing. The upward flow of gas and separated material in the packing material develops a downward flow of water. The bulk flow of s water is forced down to the lower part of the packing at the flotation tank outlet side 53. The preferable position for the water to exit the outlet compartment of the flotation vessel is at the lower half of the end cap or the lower side at the end. The outlet 50 should then preferably be positioned in this area to maintain the overall flow pattern through the packing in the flotation vessel. 0 An example of a flotation vessel design is shown in figure 4.
The inlet 46 of the flotation tank is preferably positioned at the top of the vessel. The inlet flow is pointing downwards into the inlet compartment 51. When the size of the inlet is made according to the desired inlet compartment design criteria, this construction will create several large eddy currents between the inlet jet and 5 the compartment walls. This creates good mixing with correct agitation intensity. Because of the downward flow at the inlet, gas bubbles are distributed throughout the entire inlet compartment.
The outlet 50 is positioned just below the centre line of the vessel. This position will not set up a flow pattern in the outlet compartment 53 that will disturb the o overall flow pattern in the packing.
The position of the storage volume 54 of separated oil and gas is shielded from the outlet compartment 53. The packing prevents a direct contact between the oil in the storage volume 54 and the water in the outlet compartment 53.
The plant including equipment, means and functional qualities as described above comprises properties as described in the following, which also characterizes the present invention over prior art.
With the method according to the present invention, degassing of the inlet flow and removal of sand are made as a pre-treatment. Because sand is an oil carrier, removal of sand as pre-treatment is important when very low oil outlet concentration is a target. Furthermore, existing dissolved gas in the inlet flow is utilized to produce small gas bubbles used for the flotation. This means that existing gas in the inlet liquid is used as flotation gas and there is no use of any external energy source for the supply of this utility.
The coagulation and flocculation made in the mixing step is performed with- out external energy and special equipment such as an agitator or pump for creating agitation. The geometry, the design of the mixing step and the existing energy in the inlet flow are used to create a specific flow pattern and a specific agitation intensity promoting coagulation and flocculation.
The agitation intensity is decreasing through the entire plant, which is ad- vantageous for coagulation, flocculation as well as separation.
The flotation tank 40 comprises a specific compartment for the final flocculation immediately upstream of the structural packing where the separation is performed. The arrangement and performance of the inlet to the compartment creates a flow pattern which increases building of aggregates between gas bubbles and parti- cles as well as oil droplets. These advantages are favourable and increase the efficiency of the separation.
As the packing material in the flotation tank functions according to the lamella principle, a large separation area is achieved, which makes the flotation tank very compact. The tank and the lamella packing are designed in such a way that laminar and stable flow is achieved in the lamella package.
Due to the design of the flotation tank 40, water is removed from the separated material and a concentration of this material, i.e. the sludge thickening, is achieved.
The process has very low if any consumption of external energy in relation to prior art. The plant according to the invention is very compact, and it has a low weight compared to prior art plants. This provides low investment cost and low total lifetime cost.
An example of a plant for treatment of produced water according to the present invention is shown in figure 5. The figure shows a plant with a design capacity of 700 m3/h or 105 700 BPD. The skid measures for the plant are LxWxH: 7m x 8m x 7,8m. The energy consumed for this plant is only energy used by the instrumentation. The process and plant purifying the water is capable of removing oil down to a concentration of 10 ppm or even lower, and it executes full degassing of the water.
The example above clearly shows that the method according to the invention is competitive and has advantages compared to prior art technology of produced water treatment.