EA018896B1 - System for purification an utilization of waste waters heat - Google Patents

Abstract

The present invention relates to purification of waste waters, to heat utilization and can be used for heating buildings located nearby treatment plant, for water heating and for improving environment. According to the invention a system for purification and utilization of waste waters heat comprises a heat exchanger-utilizer filled with a coolant, evaporator and a compressor forming a heat pump. The evaporator has a heat contact with a waste water drainage pipe at its outlet section downstream the waste water purification block. An oxygen saturating chamber of waste waters is arranged downstream the outlet section of the drainage pipe. The obtained result provides enhancement the purification efficiency and utilization of waste water heat.

Description

The present invention relates to the field of wastewater treatment and to the field of heat recovery and can be used to heat buildings located near treatment plants, water heating, as well as to improve the environment.

A known system for cleaning and utilizing wastewater heat (see patent for the invention of the Russian Federation No. 2161763, publ. 2001), made in the form of a filter-heat exchanger, including a cylindrical body filled with coolant, a coil for a heated medium with inlet and outlet pipes connected to the lower part of the housing, characterized in that a layer of loose filter material is placed in the housing, into which at least four tubular coils are concentrically located one inside the other, while input the tubes of two external and two internal coils are connected in pairs to the lower part of the housing, and the outlet pipes are likewise located at the upper level of the bulk filter material.

The disadvantage of this system is the insufficient efficiency of heat recovery of wastewater associated with a low temperature drop in the cooling of the wastewater, as well as the low environmental friendliness associated with the fact that the purification unit, made in the form of a filtering embankment, does not sufficiently treat wastewater, as well as wastewater at the outlet have a low percentage of oxygen and, when discharged into a pond, violate its biological oxygen balance.

Also known from the prior art is a system for treating and utilizing wastewater heat, including a wastewater drain pipe, a wastewater treatment unit, a heat exchanger-utilizer (see RF patent for invention No. 2418251, publ. 2011)

This system is taken as a prototype of the invention.

In this system, the wastewater treatment unit is made in the form of a filtering embankment containing a horizontal system for distributing wastewater over the surface of the embankment made of drainage pipes perforated from above, one or more layers of filter material arranged from top to bottom in descending order of filtration coefficient material and separated by a film of permeable material, which prevents the mutual penetration of layers of filter material.

One or several heat exchangers of low potential heat exchangers of treated wastewater are installed in the thickness of the filter materials, and the heat exchangers of the heat exchangers are located at the boundaries of the layers of filter materials, where due to the difference in the filtration coefficients of the materials, a backwater and accumulation of filtered wastewater is formed, which ensures intensification of heat transfer.

The disadvantage of the prototype is the lack of efficiency of heat recovery of wastewater associated with a low temperature drop in the cooling of the wastewater, as well as low environmental friendliness due to the fact that the purification unit, made in the form of a filtering embankment, does not sufficiently treat wastewater, and the wastewater at the outlet a low percentage of oxygen and when discharged into a reservoir disrupt its biological oxygen balance.

Based on this original observation, the present invention mainly aims to propose a system for cleaning and utilizing heat, which allows at least to alleviate the above disadvantages, namely, to increase the efficiency of treatment and utilization of waste water heat.

To achieve this goal, the system for cleaning and utilizing wastewater heat comprises a heat exchanger-heat exchanger that is filled with refrigerant and connected in series with a thermostat, evaporator and compressor, forming a heat pump. The evaporator has thermal contact with the sewage discharge pipe at its outlet section located after the wastewater treatment unit.

Thanks to this characteristic, it becomes possible to increase the efficiency of heat extraction of wastewater due to a heat pump containing circulating refrigerant. The wastewater treatment unit, made, for example, in the form of a biological treatment station, provides heating of wastewater, and the heat pump is able to cool water to almost 0 ° C. At the same time, environmental friendliness is increased, since the wastewater treatment unit allows wastewater to be cleaned to sanitary standards. And also with a decrease in the temperature of wastewater, the ability to saturate wastewater with oxygen increases.

There is an embodiment of the invention in which a wastewater saturation chamber with oxygen is located at the outlet of the sewage discharge pipe after the evaporator.

Due to this characteristic, the environmental friendliness of the system is increased due to the fact that the wastewater is saturated with oxygen to the limit value, which is especially important for maintaining the biological oxygen balance of the reservoir during the discharge of wastewater into the reservoir. This characteristic leads to the improvement of the reservoir.

Other features and advantages of the invention clearly follow from the description below for illustration and not limiting, with reference to the accompanying drawings, in which FIG. 1 schematically depicts a functional diagram of a system for treating and recovering wastewater heat according to the invention; FIG. 2 - stages of purification and heat recovery of wastewater according to the invention.

According to FIG. 1 wastewater heat treatment and recovery system includes a sewage treatment unit

- 1 018896 water 1 and heat pump 2, which includes a series-connected evaporator 3, compressor 4, heat exchanger-heat exchanger 5 and temperature controller 6. The evaporator has thermal contact with the sewage drain pipe 7.

The sewage discharge pipe 7 includes sections of the AECS. Sewage treatment unit 1 is located in section AB, heat pump 2 in section BC, and oxygen saturation chamber 8 for oxygen in section CO.

As a sewage treatment unit, you can use the station for deep biochemical treatment of domestic and industrial wastewater containing the following elements:

three-chamber sump, bioreactor with submerged loading (biofilter), laminar sump, coagulation system, sludge disinfection system, clean water removal system, hydraulic sludge collection and return system.

The heat pump is a separate closed circuit designed to transfer heat from the portion of the sewage water drain pipe to the heat exchanger-heat exchanger 5. Inside this circuit is a refrigerant, namely a liquid with a low boiling point, such as freon, ammonia.

The evaporator 3 of the heat pump 2 has thermal contact with the sewage drain pipe, for which the evaporator 3 can be designed as a coil wrapped around the sewage drain pipe section BC, or it can be directly inside the sewage drain pipe section BC.

The heat exchanger-utilizer 5 allows you to remove heat from the system, which can be used to heat directly the house or premises or several houses or rooms; for heating hot water used in the plumbing and heating system; in the boiler room, which is involved in providing heat to one or more houses.

The oxygen saturation chamber 8 is connected to a compressed air supply station. The device of the saturation of wastewater with oxygen 8 is a plastic container, on the bottom of which there are aerators (plastic pipes taken into the film membrane elements of aeration).

A high-tech method of microperforation of the aerator membrane ensures the formation of small bubbles, prevents the return penetration of liquid during technological or emergency pauses in air supply and, therefore, eliminates its pollution. The membrane material is flexible and chemically resistant to hydrolysis and the influence of microorganisms.

Film aerators have a high degree of oxygen saturation and have a service life of 5-15 years.

Air is supplied by a compressor or blower. The aeration system has the ability to adjust and calibrate the intensity and volume of the air supply to achieve the optimal level of oxygen saturation of the drain.

Discharged sewage can be discharged into a reservoir, onto terrain (into a ditch) or into the ground. Each of these methods has its own cleaning standards, but they are much stricter for discharge into a reservoir. Therefore, we will consider as an example the most complex version of the system for cleaning and utilizing wastewater heat, in which it is drained into a natural body of water.

A system for treating and utilizing wastewater heat operates as follows (see FIG. 2).

Stage P1. Flow discharge. Untreated wastewater through a sewage drain pipe 7 is supplied to the wastewater treatment unit 1

Stage P2. Cleaning up. It is produced in a wastewater treatment unit: wastewater occurs coarse, fine filtration, sludge, several stages of biological treatment. Wastewater is treated to the requirements of sanitary standards, namely, the content of suspended solids is not more than 3 mg / l, the content of petroleum products is not more than 0.05 mg / l. The temperature of the wastewater rises to 20-40 ° C.

Stage P3. Cooling. After wastewater treatment to sanitary standards, water enters the aircraft section of the wastewater discharge pipe, in which it is in thermal contact with the evaporator 3 of the heat pump 2. Here, the wastewater temperature decreases to a value range from 0.1 to 10 ° C, less 0.1 ° C water freezes, more - the system ceases to be effective. But the optimal range of values is 3-5 ° C. At a temperature of about 4 ° C, water has a maximum density, which is why this temperature is near the bottom layers of any natural reservoirs. In this case, compliance with environmental standards is achieved.

Stage P4. Oxygen saturation. Wastewater at low temperature is able to be saturated with oxygen as much as possible. At 4 ° C, the wastewater can be saturated with oxygen to a value of 12 mg / L. In this case, compliance with environmental standards is achieved. The discharge of warm water, and even more hot water into the reservoir, due to the low oxygen content in it, violates the oxygen balance of the reservoir, which leads to the gradual biological extinction of the reservoir.

Stage P5. Discharge of treated wastewater into a pond.

In accordance with the proposed invention, the applicant made a prototype system

- 2 018896 for the treatment and utilization of waste water heat.

As a purification unit, the biological wastewater treatment unit Λίτ Мagnetet РКО 15 was used with the following parameters:

productivity - 15 m ³ / day .;

station height - 2500 mm;

dimensions: base area - 8.7 m ² , module width - 2.16 m, number / length of modules - 1/4 m, height - 2.5 m;

Shipping weight - 1.7 tons;

maximum working weight - 15.3 tons;

the number of compressors (blowers) / pumps - 2-3 pcs .;

power of compressors (blowers) / pumps - 1.21 kW;

power consumption - 0.29 kWh;

voltage - 220 V.

The water parameters at the outlet of such a station comply with accepted sanitary standards, namely: suspended solids content of not more than 3 mg / l, oil products content of not more than 0.05 mg / l.

As a chamber for saturation of wastewater with oxygen, the L11a Λίτ Mayet Rgo 35 was used.

Tests of the prototype showed the following characteristics:

the possibility of using the system for heating residential, industrial and commercial premises, the preparation of hot water;

high reliability of the system;

high environmental friendliness: the waste water at the outlet has a temperature of 4 ° C and the oxygen content in the water is 12 mg / l.

Thus, in this invention the goal is achieved - increasing the efficiency of treatment and heat recovery of wastewater.

At the same time, an unexpected advantage of the invention is high profitability:

for transferring 1 kWhh of thermal energy to the heating system, the system needs to spend only 0.2-0.35 kWhh of electricity; we remove heat from 100 m ³ per day to heat 750 m ^{2 of} production and storage facilities;

the system does not require operating costs, except for the cost of electricity necessary for the operation of the equipment;

system reliability; during operation, the system does not require special maintenance; possible manipulations do not require special skills;

the heat pump is compact and virtually silent;

the system is practically explosion and fireproof. No fuel and open flame, no exhaust pipes, no dangerous gases or mixtures, i.e. there is nothing to explode. Not a single detail is heated to temperatures that can cause ignition of combustible materials;

stopping the functioning of system components does not lead to breakdowns or freezing of liquids.

The proposed system for the treatment and utilization of wastewater heat can be used to purify runoff from residential complexes, hotels, boarding houses, sanatoriums, cottage villages, housing estates, settlements, etc., as well as industrial facilities, dairies; poultry farms, meat procuring and processing enterprises, fish factories, food industry enterprises.

Claims (1)

CLAIM A system for treating and utilizing wastewater heat, including a wastewater drain pipe, a wastewater treatment unit, a heat exchanger-heat exchanger, characterized in that the heat exchanger is filled with refrigerant, connected in series with a thermostat, evaporator and compressor, forming a heat pump, the evaporator has thermal contact with a sewage discharge pipe at its outlet located after the wastewater treatment unit, and a sewage saturation chamber is located at the outlet of the sewage drain after the evaporator water with oxygen.