RU2163703C1 - Centralized heat supply system - Google Patents

Abstract

FIELD: power engineering; warm and hot water supply systems. SUBSTANCE: proposed system includes warm and hot water consumers, central thermal station (thermoelectric plant) connected with remote thermal station by means of direct heating-system water supply pipe line; remote thermal stations are equipment with thermal pump; inlet of evaporator of this pump is connected to pipe line and outlet is connected with hot water consumer; heat consumer inlet is connected to outlet of thermal pump condenser; heat consumer outlet is connected to inlet of thermal pump absorber and absorber outlet is connected with inlet of thermal pump condenser. EFFECT: enhanced economical efficiency. 2 cl, 1 dwg

Description

 The invention relates to the field of energy and can be used to supply consumers with heat and hot water.

 A known district heating system comprising sequential heating of direct network water in a central heating center (CHP), peak heater or boiler room and a remote heating station (G.S.Ruzavina, patent N 2002169 C1, RU), which includes a heat exchanger of hot water supply of the first and second stages with heating and heating lines, pipelines of hot, circulating and cold water, heat pumps, control and check valves, gate valves, storage tank, two additional bypass pipelines, and Sator first heat pump installed in the line of heated water after the first stage heat exchanger, the evaporator and the condenser of the second heat pump are respectively arranged on pipelines cold and hot water. Transportation of network water is carried out through direct and return pipelines of network water.

The disadvantages of the known district heating systems are:
the presence of two main pipelines of direct and reverse network water, which leads to an increase in the capital and operational component of the cost of heating networks;
the presence of a built-in steam turbine condenser beam, network heaters of the lower and upper taps and a peak heater or boiler room for heating the coolant to temperatures due to the coating of the peak part of the heat load schedule, which are sequentially connected to the return network water path at the central heating center (CHP), which leads to high heat losses in the direct network water pipeline and to high specific consumption of equivalent fuel for heat supply at the central heating station (CHP);
the presence of two heat pumps, two additional bypass pipelines, a large number of shut-off and control valves, which leads to an increase in the capital and operational component of costs in a remote heat point.

 Closest to the proposed one is a district heating system (a.s. N 1800235 A1, SU, MKI F 24 D 11/02), which includes the main and peak heat sources and the consumer, which are remote from each other, consisting in the supply of direct network water through the supply line from the main heat source to the peak and heat consumer and return the return network water through the return line. The remote heat source is equipped with a heat pump containing at least an evaporator and a condenser. In the heat pump, part of the heat of the direct mains water is used to produce steam of the working fluid (in the evaporator), and the condensation of the exhausted steam of the working fluid is carried out by reverse mains water (in the condenser), while the heated water is mixed with direct mains water. In this system, the input and output of the heat pump evaporator are connected to the direct network water pipe, the condenser input of the heat pump is connected to the reverse network water pipe, and the condenser output is connected to the direct network water pipe.

The disadvantages of the known district heating systems are:
the presence of two main pipelines of direct and reverse network water, which leads to an increase in the capital and operational component of the cost of heating networks;
the presence of a built-in steam turbine condenser beam, network heaters of the lower and upper taps for heating the coolant to temperatures determined by the schedule of the heating load, which is consequently high heat losses in the direct network water pipe and to high specific consumption of equivalent fuel for heat supply at the central heating center (CHP);
the need for the presence of a peak hot water boiler (PVC) in addition to the heat pump in the remote heat point to cover the peak part of the heat load schedule, which leads to an increase in the capital and operational cost component of the remote heat point.

 The objective of the invention is the creation of a district heating system, which is more economical.

 The task is achieved by the fact that in the well-known district heating system, including consumers of heat and hot water, a central heating station connected by a direct network water supply pipe to a remote heating station equipped with a heat pump, which in turn contains at least an evaporator and a condenser, moreover, the input of the heat pump evaporator is connected to the direct network water pipe, the output of the heat pump evaporator is connected to the hot water consumer, and the input and output of the condenser heat pump connected to the input of the consumer of heat.

 The heat pump can be made of lithium bromide absorption.

 The drawing schematically shows one of the possible district heating systems that implements the proposed method.

 The system comprises a pipeline 1 of direct network water of a heating network from a central heating station (CHP) to a remote (e.g., intra-quarter) heating station. The remote heat station contains a heat pump, which consists of a generator 2, a condenser 3, a regenerative heat exchanger 4, an evaporator 5, an absorber 6, a lithium bromide path 7, a working agent circuit 8 and a heating water circuit 9 providing heat to the consumer 10. In addition to Moreover, the remote heating unit is equipped with a highly reactive fuel combustion chamber 11 and a chimney 12 to remove combustion products. The system also includes a consumer of hot water 13. In this case, the input of the heat pump evaporator 5 is connected to the direct network water pipe 1, the output of the heat pump evaporator 5 is connected to the hot water consumer 13, the input of heat consumer 10 is connected to the output of the heat pump condenser 3, output the heat consumer 10 is connected to the input of the heat pump absorber 6, and the output of the absorber 6 is connected to the input of the condenser 3. The condenser 3 and the heat pump absorber 6 connected to each other and the heat consumer 10 form a heating circuit ur 9 circulating water.

 This system works as follows.

 From the central heat point (CHP), network water with a temperature determined by the heat supply mode “hot water supply” is fed through a direct network water pipe 1 to a remote (for example, intra-quarter) heat station equipped with a lithium-bromide absorption heat pump. The low-grade heat of direct network water is transferred to the water circulating in the heating circuit 9 in the evaporator 5 and the absorber 6 of the heat pump. The temperature of the water circulating in the heating circuit is increased to a temperature determined by the heat consumption schedule by consumer 10 during the heating period, in the condenser 3 of the heat pump.

 The process of increasing the temperature in the heating circuit is carried out due to the circulation of the absorbent and the working agent in the lithium bromide path 7 and the working agent circuit 8, respectively. To evaporate the working agent, hot gases generated by burning highly reactive fuel, for example natural gas in the combustion chamber 11, are supplied to the heat pump generator 2, which are then removed through the chimney 12. The working agent steam is activated in the condenser 3 of the heat pump to transfer heat to the circulating water heating circuit 9. In the regenerative heat exchanger 4 of the heat pump, regenerative heating of the absorbent (lithium bromide) is carried out.

 Network water, cooled to a temperature determined by the schedule of "hot water" in the evaporator 5 of the heat pump, is supplied directly to the hot water system to the consumer 13 of hot water.

 At the same time, the process of heating the network water at the central heating station (CHP) is carried out only in the network heater of the lower heating selection to a temperature determined by the load schedule for "hot water supply".

Thus, the described district heating system has a higher efficiency due to the fact that:
1. The system contains only one main pipeline of direct network water, which reduces losses in heating networks and costs in heating networks.

 2. The process of heating network water at a central heating point (CHP) is carried out only in the network heater of the lower heating selection to temperatures determined by the load schedule of "hot water", which, in turn, reduces the temperature of direct network water and, as a result, the heat loss in pipeline direct network water.

 3. Reducing the temperature of direct network water leads to an increase in the generation of electricity from heat consumption by increasing the passage of steam into the condenser of a steam turbine at a thermal power plant.

 4. Reducing the temperature of direct network water leads to a decrease in the volumetric flow rate of network water and, as a result, to a decrease in the diameters of pipelines, which reduces investment and heat losses in them.

 5. Reducing the temperature of direct network water leads to the abandonment of the use of peak hot water boilers (PVCs) and network heaters of the upper heating selection at the central heating point (CHP), which reduces fuel consumption for heat generation at CHPs and reduces investment in CHPs.

 6. The absence of a peak hot water boiler at a remote heating point simplifies the circuit and structural-layout solutions of the latter and reduces the capital and operational component of the costs in it.

Claims (2)

 1. A district heating system, including consumers of heat and hot water, a central heat point connected by a direct network water supply pipe to a remote heat station equipped with a heat pump containing at least an evaporator and a condenser, the heat pump evaporator inlet being connected to a direct network pipe water, characterized in that the output of the heat pump evaporator is connected to the hot water consumer, and the output and input of the heat pump condenser are connected to the consumer w heat.  2. The district heating system according to claim 1, characterized in that the heat pump is made of lithium bromide absorption.