The HydroFlo Tech, DynaPac™ Cross Corrugated Coalescing Media is an effective media suitable for a number of different applications.
• Oil Water Separators: DynaPac™ Coalescing media is the industry standard for high efficiency oil water separators and separation systems. DynaPac™ coalescing media is ideal for new installations or replacement of existing media. Configurations are available for retrofitting any manufactures separator.
• Trickling filters, bio-towers, nitrification towers: For new installations or replacement of existing media.
• Demisters: Horizontal Coalescing media is available with demister fillings. Existing vessels can be refurbished with demister packs if a lower separating efficiency is accepted.
• Ideal replacement for random pack media: Increases retention time and wastewater biomass contact; Improves wastewater distribution and ventilation.
• Excellent for submerged fixed-film biological systems: Suitable for either aerobic or anaerobic modes. The DynaPac's high mixing/redistribution rates and 95% void to volume ratio promotes air and liquid mixing without impeding flow.
DynaPac™ Series Cross Corrugated "Coalescing" media is used in our line of Oil Water Separators.
Hydro-Flo manufactures custom packs to fit any existing separator
There are many separators out there that were manufactured by companies that are now out-of business. Great Lakes Environmental, Enprotech, Clow, WRG, to name a few. We can supply replacement media for any size shape or configuration of OWS. Not only cam we supply media for companies which are now defunct, but we can also supply media for any separator currently in manufacture today.
• General Arrangement
• Standard Engineering
• Standard IO&M Manual
HydroFlo Tech offers systems to separate liquid hydrocarbons (oils) from water by means of coalescing plate pack systems, down to 5 ppm. This page will explain the function and technical aspects of the DynaPac™Cross Corrugated Coalescing Plate Pack.
The high efficiency of the Coalescing Plate Pack system is based on a limited rise distance of 6 mm or 12 mm for the oil droplets. For example, an oil droplet of 20 micron diameter at a density of 850 kg/m³ and a temperature of 20° has a rise velocity of 2 mm/min. After 3 min. retention time within the plate pack, the oil droplet will be captured by the underside of the next plate, ensuring separation.
The configuration of the plates will force hydrodynamic coalescence. The merging of very small oil droplets into larger ones will create extremely enhanced coalescence. Rising oil droplets are captured by the next higher plate. The oliophilic material of the plates ensures that oil droplets will never reach the separator outlet. They are concentrated at the top of the corrugated plates and will rise through the weep holes to the developed oil layer above the plate packs. The rise velocity is a function of the square of the oil droplet diameter. A twice as large oil droplet will rise four times faster, a triple size oil droplet will rise nine times faster etc. An oil droplet of 3 mm will rise with a velocity of 0,74 m/s through the weep holes (when the density is 850 kg/m³ and the temperature is 20°C).
In 1845, an English mathematician named George Stokes first described the physical relationship that governs the settling solid particles in a liquid (Stokes 1845). This same relationship also governs the rising of light liquid droplets within a different, heavier liquid. This function, simply stated is:
Where: Vp = particle rising or settling velocity, cm/sec
G = gravitational constant, 980 cm/sec2
h = absolute viscosity of continuous fluid, poise
dp = density of particle (or droplet), gm/cm2
dc = density of continuous fluid, gm/cm2
D = diameter of particle, cm
A negative velocity is referred to as the particle (or droplet) rise velocity.
Assumptions Stokes made in this calculation are:
1) Particles are spherical
2) Particles are the same size
3) Flow is laminar, both horizontally and vertically.
Laminar flow, in this context, means flowing gently, smoothly, and without turbulence.
From the above it may be seen that the variables are the viscosity of the continuous liquid, specific gravity difference between the continuous liquid and the particle, and the particle size.
The rise rate of oil droplets is also governed by Stokes' law. If the droplet size, specific gravity, and viscosity of the continuous liquid are known, the rise rate may be calculated.
To calculate the size of an empty vessel gravity separator, it is first necessary to calculate by the use of Stokes' Law the rise velocity of the oil droplets. The size of the separator is then calculated by considering the path of a droplet entering at the bottom of one end of the separator and exiting from the other end of the separator. Sufficient volume (residence time) must be provided in the separator so that an oil droplet entering the separator at the bottom of the inlet end of the separator has time to rise to the surface, before the water carrying the droplet exits the opposite end of the separator.
Calculation of rise rate by this method is a gross simplification of actual field conditions because oil droplets are not all the same size, and they tend to coalesce into larger droplets. Furthermore, turbulence within a separator makes an orderly rise of very small droplets impossible. Droplets will rise following Stokes' law so long as laminar flow conditions prevail.
When the particle size exceeds that which causes a rise rate greater than the velocity of laminar flow, the flow around them as they rise begins to be turbulent. Particles of this size and larger do not rise as rapidly as would be expected from calculations based on Stokes' law because of the hydrodynamic drag. They do, however, rise very quickly in relationship to smaller droplets, and so are removed by a properly designed separator.
Very small particles such as those of 8 microns (micrometers) and less in diameter do not rise according to Stokes’ law (or hardly at all) because the random motion of the molecules of the water is sufficient to overcome the force of gravity, and therefore they move in random directions. This random motion is known as Brownian Motion. Fortunately, the volume of a droplet decreases according to the cube of the diameter, so these very small droplets tend to contain very little oil by volume, and unless there are very large quantities of very small droplets (such as would be created by using a centrifugal pump to pump the water) they contain negligible amounts of oil.
When the droplets coalesce, they do not form flocs as the solid particles can, but coalesce into larger droplets. Interfacial tension, (sometimes referred to as surface tension), of the liquid tends to make the droplets assume spherical shapes, since this is the smallest possible shape for a given mass. This is convenient for a separator designer because it is one of the conditions of Stokes’ Law. Several types of separators that utilize this principle have been designed, including API Separators, and Corrugated Plate Interceptors (CPI), and others. In general, the most efficient and predictable of these systems are the Coalescing Plate Module type.
Contact us for the efficient and economical solution of your oil-in-water problem.