Essential disposal solutions

Suru Nathwani, managing director of Kee Process, comments on a practical approach to industrial wastewater disposal and treatment


There are many industries that use large amounts of water, including brewing, wine making, soft drinks manufacture, food preparation production and packaging (baking, ready convenience meals, abattoir, meat, poultry and vegetable), dairy (milk processing, cream, cheese and yoghurt production), commercial laundries, pharmaceutical, petrochemical and many others. This results in large quantities of heavily polluted wastewater for disposal.

UK water companies and the public bodies responsible for collection, drainage and treatment of wastewater have strict controls on the quantity and quality of industrial and trade wastewater being discharged into public sewers. Legislation supports them in this. Direct discharge to a watercourse is even stricter and is normally monitored by the Environment Agency (EA) in the UK.

Penalties for transgression can include prosecution, fines, financial loss and can, in some cases, prohibit operations. It is advisable to carry out an evaluation of the processes involved in the core business of an organisation to identify sources of wastewater. An audit would help reduce waste/wastewater and disposal costs, quantify flow rates, solids and organic loads and characterise the wastewater to provide the necessary data for analysing the available disposal options and optimise the design of any on-site treatment plant.

It is useful to be subjective when carrying out an audit to ensure good housekeeping practices are identified to reduce unnecessary waste, which would add to the costs of disposing wastewater generated on-site. Process audits should be aimed at identifying the waste, excess use of water and energy. Simple actions, such as installations of energy-saving devices or taps and hose controls and careful disposal of solid waste, can produce both financial and environmental benefits. Also it would help to reduce the size of an on-site treatment plant if one was planned, this would result in capital cost-savings.

An audit would lead to evaluation of volumetric and organic mass loads for design purposes and would aid in characterising the nature of the waste to optimise the design for on-site treatment plants. Public sewers are convenient for disposal if nearby.

Quantity, strength and characteristics of the wastewater need to be considered and consented by the EA or the water company. If approval is granted and the wastewater meets the criteria set, then sewer disposal would be an obvious choice, but this comes at a cost. High chemical oxygen demand (COD) and suspended solids would lead to high costs in discharging to sewer and reducing these parameters could make significant savings.

Partial or full on-site treatment would bring about cost-savings to sewer discharge but needs justifying through quantification. With the food processing, beverage and dairy industry, hygiene is of paramount importance. On-site wastewater treatment may be perceived by management as presenting problems, although the risks are small.

It is vital the operatives normally involved in the process part of the industry do not need to visit the WwTW and the risks to main operation therefore are contained, and the operation of the WwTW becomes one of non-core features. This can be achieved by having the plant operation undertaken by the maintenance department of the industry or independent operators such as Kee Process, which would provide a turnkey solution for designing, supplying, installing and operating a plant for a client. Where the decision to treat on-site has been made, the appropriate choice of plant has to be determined.

Whether partial treatment or full treatment is installed is usually a matter of economics. A capital outlay is necessary and this must have an acceptable payback period. The treatment options available are physical, physical/chemical, biological or a combination of all or any of these. On-site treatment could involve simple physical treatment to remove materials such as gross solids, fat, oil and grease (FOG) and can include pH correction.

The equipment may include manual or mechanical screens, grease separators or the newly introduced dispersed air flotation, which is simple, economical, efficient and effective. A component of COD associated with these materials would also be removed by the physical treatment. With dispersed air flotation up to 30% BOD, 50% COD, 60% TSS and more than 90% FOG can be removed physically without the use of chemicals. Better performance can be achieved by using coagulant, flocculants and ploy-electrolytes. In most cases, partial treatment using dispersed air flotation would achieve the reduction in pollution loads necessary to substantially reduce the cost of discharge of effluent to public sewer.

The ownership costs (capital expenditure, servicing, maintenance and operation costs) associated with dispersed air flotation are usually low. The benefits of cost-savings in effluent disposal are high and the financial justification of proving on-site partial treatment are justified against the ownership costs.
Given these benefits it may be sufficient not to invest in further on-site treatment for the effluent to be discharged into public sewer. However, it may still be necessary or desirable for the wastewater to be treated further for direct discharge to a watercourse or re-used for non-process operations within the industry. In such a case, full on-site treatment would often justify the capital and operations cost. Cost analysis must also take into account the valuable space required for location of the plant on the core business site. For disposal to watercourse, consent from the EA will be necessary. The full treatment options could include anaerobic fixed film technology. This is particularly suitable for high-strength wastewater requiring initial partial treatment prior to sewer disposal or further aerobic treatment to produce effluent suitable for direct discharge to a watercourse. The aerobic process could include:

  • suspended growth activated sludge process options through extended aeration, sequencing batch reactor (SBR) or even oxidation ditch,
  • fixed film process through rotating biological contactors (RBC), submerged aerated filter (SAF).

The most suitable process selection would depend on many factors such as:

  • initial mechanical/electrical capital plant cost,
  • installation cost,
  • operating cost including on-site attendance/labour costs, energy costs, consumables and plant operation complexities. Disposal costs of physically separated pollutants, for example, FOG, TSS and sludge in case of full biological treatment plant,
  • servicing, spares and maintenance cost,
  • space and land requirements for location of the on-site treatment plant.

All these factors should be taken into account and a discounted cash flow calculated on a 10, 15 or a 20-year replacement cycle. This should be weighed against the cost of disposal to sewer or partial treatment followed by disposal to sewer. When evaluating the disposal costs to public sewer it is necessary to liaise with the authorities or provider of the central WwTW to establish initial capital cost contribution expected and the potential annual costs associated with sewer discharge over the next 10,15 or 20 years.

Armed with this financial data the overall cost of various disposal options should be evaluated and the financial disposal option chosen justified on a payback period or the net discounted cash flow or the simple approach of evaluating the cost of disposing a unit volume (say 1 m3) of effluent.

With so many factors to consider, such as type of treatment, if any, the process selection for partial or full on-site treatment and cost analysis to justify the most appropriate option for disposal of the effluent, it may be beneficial to use the services of a professional.

An experienced independent consultant with a wide knowledge of industrial wastewater treatment processes would be the obvious choice. Some companies offer a wide spectrum of process options and have the necessary experience to offer turnkey solutions using the most optimised process. Such companies may have a bias towards their own technology and process if they have a limited range of process options to offer. All this should be balanced against their ability to provide project management, process design, site civil work, mechanical or electrical erection commissioning and, more importantly, on-site operation with process warranties.


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