RU2338969C1 - Method of impure sewage water heat utilisation - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: method of impure sewage water heat utilisation and preparation of hot coolant by means of sewage water heat utilisation, on the one hand, as a result of intermediate coolant heating by 6-9°C in heat exchanger immersed into header of main flow under the level of sewage water, on the other hand, as a result of heating system water heating in condenser of heat pump up to the temperature based on temperature schedule, but not exceeding 50-55°C, at which the highest transformation ratio is provided, as well as more efficient operation of heat pump installation together with traditional source of heat supply. At that mode of intermediate heat exchanger surface washing is organised so that flow rate of sewage water amounts to the volume, when sewage water cooling takes place at the level of 1°C. Optimal geometric parameters of intermediate heat exchanger modules are selected, as well as their location in the main flow of sewage water, which provide such flow rate of sewage water through the modules of intermediate heat exchanger, at which intense heat supply is provided to intermediate coolant with its heating by 6-9°C.

EFFECT: increase of heat supply efficiency.

3 cl, 1 dwg

Description

The invention relates to the field of energy. The invention can be used in heating systems of housing and communal and urban energy.

A well-known heat supply system, consisting of a cogeneration power plant, including a main steam-power circuit, a cooling water circuit, a primary network water circuit with hot water and heating water heaters, and a heating system circuit with elevators, which is equipped with a heat pump installation located at heating stations, is used along the return path primary water supply network is connected to the input-output of the evaporator, and along the return water path of the heating system to the input-output of the condenser with the installation of regulating x valves on the respective paths. According to this scheme, the highest efficiency of heat recovery of the spent steam is achieved due to cooling of the return primary network water, which leads to the need for increased steam extraction for heating the return network water and thereby reduce the steam consumption in the condenser of the steam turbine. As a result, losses in a cold source are reduced, which leads to an increase in the thermal efficiency of the TPP and TPP when working together with heat pumps located at heat points (see patent RU 2095581 C1, cl. 6 F01K 17/02, bull. No. 31, 1997).

There is a method of utilizing the heat of exhaust steam in the built-in heat-exchange beams of the main condenser of a steam turbine, in which the network water supplied from consumers is heated in the built-in additional bundles and then in regular network heaters and boilers (in accordance with the temperature schedule of the heating load).

The disadvantage of these methods is the dependence on seasonal fluctuations in heat loads, when the amount of heat of the exhaust steam becomes minimal in the winter, and in the summer is redundant, and for this reason, the role in utilizing the heat of the exhaust steam using heat pumps is minimized in winter and in limited sizes in the summer, when the need for heat is sharply reduced.

The aforementioned patents cannot be applied to involve third-party external sources of low-grade heat, such as wastewater of various origins in the urban sewage system and water supply.

Closest to this technical solution is a method of utilizing the heat of untreated wastewater and producing hot coolant (see patent RU 2249125, class F03D 9/00, 03/27/2005) by cooling wastewater, which occurs as a result of heating an intermediate working coolant (in according to the present invention, water is indicated as an intermediate heat carrier) in a heat exchanger immersed in a sewage receiving well of a sewage network, while the heated intermediate water flows into the heat pump evaporator, where Heat is taken from the intermediate circuit water to the low boiling fluid (NKRT) of the heat pump, the vapors of which are heated in the compressor and then transferred to the condenser, in which, on the one hand, NKRT vapors are condensed, on the other hand, the heating water is heated for heating and hot water supply, implemented using distribution and prefabricated combs, the latter is an analogue of the corresponding collectors.

The disadvantages of this method are the mismatch between the temperatures of hot water supply (50-60 ° C) and heating (95/105 ° C). In this case, inevitably there is an increased energy consumption for the compressor drive, since the temperature of the network water consumed for the needs of hot water supply (DHW) is higher than that required for DHW, which leads to increased entropy losses and, as a result, to a decrease in the heat efficiency of the heat supply installation as a whole.

Placing a submerged heat exchanger in a wastewater well is one of the ways to expand the technical feasibility of involving the heat of wastewater using heat pump technology, however, the problem of preventing contamination of heat transfer surfaces and maintenance becomes an insurmountable task and do not always allow you to get rid of deposits without having to mechanically clean the heat transfer surfaces. As a result of biological processes, the formation of such deposits on the surfaces of the heat exchanger, which lead to increased corrosion wear and premature decommissioning of heat exchangers.

When heating network water to 55-70 ° C at an initial temperature of wastewater of 15-20 ° C, it is impossible to obtain a conversion coefficient (COP) of 5-6 and thus it is impossible to extract 4-5 kWh of low potential heat from wastewater. In the best case, the CPC will be 2.7-3.5, then the extracted low-grade heat will be at the level of 1.7-2.5 kWh (t).

The above disadvantages are inevitable when utilizing the heat of contaminated wastewater using heat pumps. Therefore, the invention is aimed at improving the efficiency of a heat pump installation in the wastewater of a water supply system.

The technical result, which the invention is directed to, is to increase the efficiency of heat supply by placing an intermediate heat exchanger directly in the collector under the level of wastewater. In this case, the temperature of the wastewater as a result of washing off the heat exchange surface is cooled within 0.5-1 ° C and can be assumed to be constant during the calculations, which does not distort the performance indicators of the heat exchanger. In this regard, the main attention is focused on the choice of the range of variation of the parameters of the coolant of the intermediate circuit and network water along the path of the heat consumer circuit, in which the use of heat pumps provides the greatest effect from the involvement of low-grade heat of wastewater in the heat supply process.

The specified technical result in the proposed method of heat recovery of wastewater is achieved by heating the intermediate heat carrier at 6-9 ° C in a heat exchanger immersed in the collector under the level of the main stream of wastewater. In this case, the intermediate heat carrier is cooled in the evaporator of the heat pump to the same 6-9 ° C and returned to re-heating in the heat exchanger. In turn, the network water is heated in the condenser of the heat pump to 50-55 ° C and, if necessary, followed by heating in the network heaters according to the traditional heat supply scheme.

To ensure the efficient operation of the immersed heat exchanger, a protective device is installed in front of it from pollution, for example, bumpers or mechanical combs. The waste water purified from coarse mechanical impurities washes the surfaces of the heat exchanger, while due to the external longitudinal helical finning of the heat exchange tubes, the water flow swirls, which intensifies the heat exchange and thereby allows heating of the intermediate heat carrier by 6-9 ° C, and only then the heated intermediate the coolant enters the evaporator of the heat pump. In the indicated temperature range along the heat carrier paths (wastewater, intermediate heat carrier), the greatest effect of the utilization of the heat of sewage sewage when using heat pump units is achievable.

The drawing shows a structural diagram of an installation for implementing a method of utilizing the heat of untreated wastewater and producing hot heat transfer medium with an intermediate heat exchanger placed in the collector of the main wastewater stream under its lower level.

Installation for implementing the method of utilizing the heat of untreated wastewater and producing hot coolant comprises a protective device 1 for preliminary wastewater treatment (source of NTP), an intermediate circuit 2; pump 3 for pumping an intermediate coolant; intermediate heat exchanger 4; installation penetrations for the circulation pipes of the intermediate coolant 5; a heat pump 6, including an evaporator And and a condenser K; circulation circuit of heat supply network water 7; network water pump 8; heat consumer circuit 9; wastewater collector fragment 10.

The method of utilization of the heat of untreated wastewater and obtaining hot coolant is as follows.

Wastewater (from the water supply system) passes through the device 1 and then along the main channel of the sewage collector, pump 3 delivers an intermediate coolant to the evaporator And the heat pump 6 and returns for re-heating to the heat exchanger 4.

In turn, the intermediate coolant pump 3 after the heat exchanger 4 is fed to the evaporator (I) of the heat pump 6, where the heat is supplied to the low-boiling working coolant (NKRT). The cooled intermediate fluid after the evaporator AND heat pump 6 is returned back to the heat exchanger 4 for re-heating. Thus, the intermediate coolant is circulated along circuit 8 through the evaporator And and the heat exchanger 4.

In the evaporator And of the heat pump 6, the formed NKRT vapor enters the compressor, where, as a result of the compression of the NKRT vapors, they are heated to a temperature of about 110 ° C (depending on the thermophysical properties of the NKRT). The heated NKRT steam enters the condenser K of the heat pump 6, where heat is supplied to the network water of the heat consumer circuit, the NKRT condensate is returned to re-heating in the evaporator AND of the heat pump 6.

The heat consumer 9 along the path of the circuit 7 of the working fluid (network water) is connected to the output of the condenser K of the heat pump 6, and the input of the condenser K is connected to the output of the consumer 9.

Thus, the circulation of network water through the path of the working fluid of the heat consumer 9.

Mains water heated in the condenser ТНУ to 50-55 ° С is used for the needs of hot water supply. For heating, it must be warmed up in traditional boilers of network water and then supplied to the heat consumer 9. With pump 9, the network water is returned to re-heat to the heat pump 6. According to this scheme, the conversion coefficient (COP) is achieved at a level of 4-5, i.e. utilization of the heat of wastewater will occur with the greatest thermodynamic efficiency. In principle, at the outlet of the heat pump, it is possible to obtain network water with a temperature at the level of 80-90 ° С, but in this case the CPC will not exceed 2.5-3.5.

Structurally submerged heat exchanger 4 is a device made up of one or more modules, each consisting of a bundle of flexible fluoropolymer tubes with external longitudinal fins tubes helical shape with an overall surface of the heat exchange module in the range of 5-10 m ^2.

Recommended heat exchanger parameters:

- number of tubes up to 100 pcs;

- tube length up to 4500 mm;

- the inner diameter of the tubes is 4 mm with a wall thickness of 0.6 mm;

- heat transfer surface up to 10 m ² ;

- heat transfer coefficient at the level of 200 W / m ² ° С.

The most suitable heat exchanger design solution for such an environment is a fluoroplastic tubular heat exchanger with an external longitudinal finning of a screw-shaped heat exchanger tube. Tubular fluoroplastic heat exchangers can be used as coolers, heaters, condensers, etc.

The anti-adhesive properties of the fluoroplastic exclude overgrowing of the working surfaces of the heat exchanger, which allows the heat transfer process with a high heat transfer coefficient to be carried out. Permissible internal pressure of the working medium depends on its final temperature, but not higher than 0.9 MPa.

Installation penetrations can be heat-insulated support rings in sizes not less than the diameter of the main pipelines of the intermediate wastewater circulation circuit.

The above-described scheme for the utilization of low-grade heat of wastewater is recommended for all cases where it is easy to directly select the heat of wastewater as a result of placing the heat exchanger in the main stream under the level of wastewater.

Claims (3)

1. The method of utilizing the heat of untreated wastewater and producing hot network water with a temperature based on the heating schedule by cooling the wastewater as a result of heating the intermediate heat carrier in an immersed heat exchanger, characterized in that the collector has wastewater washing the surface of the immersed heat exchanger to a level wastewater into the collector through installation penetrations is cooled by 0.5-1 ° C, in which, in turn, the intermediate heat carrier is heated by 6-9 ° C and then enters the evaporator heat pump, where it is cooled to the same 6-9 ° C, while the mains water is heated to 50-55 ° C in the heat pump condenser. 2. The method of heat recovery of untreated wastewater according to claim 1, characterized in that the immersed heat exchanger is made in the form of several modules, each consisting of a bundle of thin-walled flexible fluoroplastic tubes with an external longitudinal finning of helical tubes with a common module heat exchange surface in the range of 5-10 m ² . 3. The method of utilizing the heat of untreated wastewater according to claim 1, characterized in that the installation penetrations are heat-insulated support rings in sizes not less than the diameter of the main pipelines of the wastewater circulation intermediate circuit.