RU78907U1 - CENTRALIZED HEAT SUPPLY SYSTEM - Google Patents

Abstract

A district heating system containing a CHP, a supply pipe, consumers and a return pipe, the consumers being connected to the main pipeline through heat exchangers of the peak load heat supply subsystems, and each of the subsystems includes a heat carrier supercharger, a gas-fired heat generator to which a gas supply regulator is connected, the first regulator of the coolant, three temperature sensors and a controller, the inputs of which are connected to temperature sensors, and the outputs - to the first regulating with a heat-transfer agent and with a gas supply regulator, while the output of the heat exchanger from the side of the peak load subsystem is connected through the heat carrier supercharger and the heat generator to the consumers input, the outputs of which are connected through the first heat carrier regulator to the heat exchanger input from the peak load subsystem and to the additional input of the heat carrier supercharger moreover, the first temperature sensor is installed in the pipeline at the output of the heat generator of the peak load subsystem, the second temperature sensor tours are installed in the pipeline at the inlet of the first coolant regulator, and the third temperature sensor is installed outside the building, characterized in that a second coolant regulator is installed in the heat supply subsystem of the peak load, installed in the pipeline between the coolant supercharger and the heat generator so that it faces the input to the coolant supercharger, the first outlet to the heat generator, and the second outlet is connected through an additional section of the pipeline to the outlet of the heat generator

Description

A useful model of a district heating system belongs to the field of heat energy and can be used in cogeneration heat supply systems (in particular, heat supply from a thermal power plant).

Known heat supply system (patent RU 2304254 C1, F24D 3/02, 02.20.2006) containing a thermal power plant, a direct pipeline, consumers, a return pipe, the circuit of which includes an element of the heat supply subsystem of the peak load in the form of a heat exchanger, the input of which is from the heat supply subsystem of the peak load connected to the return pipe of the heat supply subsystem of the peak load through the regulator, the second output of which together with the heat exchanger output from the heat supply subsystem of the peak load is connected to the input of the generator heat output of the peak load heat supply subsystem, and its output is connected to consumers of the peak load heat supply subsystem, while the regulator is connected to the output of the control device, the inputs of which are connected to temperature sensors located on the return pipe of the cogeneration heating system and on the return pipe of the peak heat supply subsystem load.

The disadvantage of this system is the fact that the change in the temperature of the coolant from changes in the external temperature of the consumers in the heat supply system of the peak load is delayed, that is, the temperature schedule is violated, because in the heat exchanger of the heat supply subsystem of the peak load, the change in the temperature of the coolant from the CHPP occurs with a large delay in

due to the large length of the pipeline of the district heating system.

Closest to the proposed utility model is a cogeneration heat supply system (patent RU 72748 U1 F24D 3/02 12/17/2007) containing a thermal power plant, a supply pipe, consumers, a return pipe, the circuit of which includes an element of the heat supply subsystem of the peak load in the form of a heat exchanger, the input of which from the heat supply subsystem of the peak load is connected to the return pipe of the heat supply subsystem of the peak load through the regulator, the second output of which together with the heat exchanger peak load is connected to the input of the heat energy generator of the peak load heat supply subsystem, and its output is connected to consumers of the peak load heat supply subsystem, while the regulatory body is connected to the output of the first control device, the inputs of which are connected to two temperature sensors located on the return pipe of the centralized heat supply system and on the return pipe of the heat supply subsystem of the peak load, while the inputs of the second control device are connected to a third a temperature sensor installed in the supply pipe of the heat source of the peak heat supply subsystem, and a fourth temperature sensor installed outside the building, in which the heat source of the peak heat supply subsystem is located, and a heat generator is used as the heat source in the heat supply subsystem of the peak load operating on gas, to which a gas supply regulator is connected, the input of which is connected to the output of the second control unit royals. This system is adopted as a prototype.

The disadvantage of this system is that with a sequential version of connecting peak loads to the district heating system, their mutual influence on each other occurs, and when

accidental shutdown of consumers, a heat carrier with an increased temperature enters the return peak flow pipe, which is partially compensated by a decrease in the gas supply in the heat generator, but it remains in working condition, i.e. in the described case, excessive gas consumption occurs.

The problem solved in the utility model is to reduce the influence of the heat supply subsystems of peak loads on each other and to save the gas consumed by the heat generator of the corresponding heat supply system of the peak load if the temperature rises above the temperature set in the pipeline at the inlet of consumers of the peak load.

The solution to the problem is achieved in that in a centralized heat supply system containing a thermal power plant, a supply pipe, consumers and a return pipe, and consumers are connected to the main pipeline through heat exchangers of the peak load heat supply subsystems, and each of the subsystems includes a heat carrier supercharger, a gas-fired heat generator, to which is connected to the gas supply regulator, the first regulating body of the coolant, three temperature sensors, and a controller whose inputs are connected to temperature sensors rounds, and exits with the first regulating body of the heat carrier and with a gas supply regulator, while the output of the heat exchanger from the side of the peak load subsystem is connected through the supercharger and heat generator to the consumers inlet, the outputs of which are connected through the first regulating body of the heat carrier to the inlet of the heat exchanger from the peak subsystem load and to the additional input of the coolant supercharger, and the first temperature sensor is installed in the pipeline at the output of the heat generator of the pi subsystem oic load, a second temperature sensor installed in the pipeline at the inlet of the first coolant regulator body and a third temperature sensor is installed outside the building, and the peak in the heating subsystem

of the load, a second coolant regulating body is installed, located in the pipeline between the coolant supercharger and the heat generator so that it faces the input of the coolant supercharger, the first output to the heat generator, and the second output is connected through an additional section of the pipeline to the output of the heat generator, while in the pipelines reverse action valves are installed in front of the connection point, and the second regulatory body is connected to the third output of the controller by its control input, and in The moves of the heat exchangers of each heat supply subsystem of the peak load from the centralized heat supply system are connected directly to the supply and return pipes of the centralized heat supply system, and a portion controller is installed at one of the heat exchanger inlets.

Figure 1 presents a functional diagram of a utility model of a district heating system, explaining the operation of a utility model.

A useful model of a district heating system contains a CHPP 1, a supply pipe 2, consumers 22 and a return pipe 3 with a coolant supercharger 4, and consumers are connected to the main pipeline through heat exchangers 7 of the peak load heat supply subsystems, and each of the subsystems includes a heat transfer supercharger 11, a heat generator 14 running on gas, to which the gas supply regulator 13 is connected, the first regulatory body of the coolant 10, three temperature sensors 17, 20, 21, and a controller 18, the inputs of which connected with temperature sensors, and the outputs with the first regulating body of the coolant 10 (output c) and with the gas supply regulator 13 (output d), while the output of the heat exchanger from the peak load subsystem is connected through the coolant supercharger and heat generator to the consumer input, the outputs of which connected through the first regulatory body of the coolant 10 to the input of the heat exchanger 8b

from the side of the peak load subsystem and to the additional input of the coolant supercharger 8a, whereby the first temperature sensor 17 is installed in the pipeline 16 at the output of the heat generator of the peak load subsystem, the second temperature sensor 21 is installed in the pipeline at the inlet of the first regulator of the coolant 10, and the third temperature sensor 20 installed outside the building. The second regulating body of the coolant 12, installed in the pipeline between the coolant supercharger 11 and the heat generator 14 in such a way that it faces the coolant supercharger with the input, the first output to the heat generator, and the second output is connected through an additional section of the pipeline to the output of the heat generator, while In the pipelines in front of the connection point, reverse valves 9, 15 and 19 are installed, and the second regulatory body 12 is connected to the output b of the controller 20 by its control input, and the heat inputs 7 exchangers each peak load heat supply subsystem from the district heating system are directly connected to the feed conduit 5 and reverse the district heating system, the heat exchanger on one of the inputs 7 installed batch controller 6 steps.

A utility model of a district heating system works as follows. From the supply pipe 2 of the CHP 1 with the help of the portion control 6, the heat supply quota of the peak load receives a quota of heat energy at the input of the heat exchanger 7 from the CHP side. The controller 18 generates a control signal at the output "a" to the supercharger of the heat carrier 11 and at the same time generates a second control signal at the output "b" to the second regulatory body 12, while the supercharger of the heat carrier 11 supplies the heat carrier to the heat source of the heat supply subsystem of the peak load - heat boiler 14, where it is slightly heated and served to consumers 22 of the peak heat supply subsystem. AT

In the steady state, the hot stream after the consumer of the heat supply subsystem of the peak load is divided into two streams, one of which is directed through the pipe 8b to the coolant supercharger through an additional input of the heating circuit of the heat exchanger 7, and the second directly to the coolant supercharger through the pipe 8a. Separation of the hot stream is carried out using the regulator 10 of the controller 18, the input of which receives a signal from the temperature sensors of the coolant 21. The controller generates a control signal of the regulator 10 at the output of the controller "c" in accordance with the value of the temperature sensor 21 and the temperature of the coolant stored in the memory the controller in accordance with the temperature graph so that if the temperature value of the sensor 21 is greater than or equal to the value of the temperature of the coolant stored in the memory If the controller is in accordance with the temperature schedule, then the regulating body 10 directs the heat carrier flow after the consumer of the peak load heat supply subsystem directly to the heat carrier supercharger 11 via pipeline 8a and at the same time the controller 18 generates a signal at the output "b" to the second regulatory body 12 to let the heat carrier pass "bypassing" "of the heat generator 14 of the peak load, while the output controller d turns off the gas supply to 14. Otherwise, the flow is directed to the coolant supercharger through a pipe Gadfly 86 through an additional input of heat exchanger circuit 7 and the controller 18 generates a signal to the second regulator 12 to let the coolant through the heat generator 14.

With a sharp change in the ambient temperature from the CHP 1 in the direct pipe 2, the coolant with the changed temperature begins to flow in accordance with the temperature schedule, however, the change in the coolant temperature in the heat exchanger 7 of the peak load heat supply subsystem will come with a delay due to the length of the pipelines. In this case, the controller 18, which

generates a control signal at the output "d" to the gas regulator 13 to increase or decrease the gas supply to the heat boiler 14 depending on the readings of the temperature sensors 17 and 20. The temperature sensor 17, located in the supply pipe 16 of the peak heat supply subsystem, measures the temperature of the coolant and gives a signal to the input of the controller 18. At the same time, its second input receives the outdoor temperature from the temperature sensor 20. If the temperature of the coolant in the supply pipe 16 of the heat supply peak the new load is greater than that which must correspond to the temperature schedule stored in the memory of the controller 18 at the corresponding outdoor temperature, the controller 18 gives a signal to the gas supply controller 12 to reduce the gas supply to the heat source of the heat supply subsystem of the peak load 14 or to completely shut off the supply gas, otherwise the gas supply is increased. Upon receipt of the coolant with a changed temperature from the CHPP to the heat exchanger 7 of the heat supply subsystem of the peak load, the controller 18 will react by supplying gas in the opposite direction, i.e. consumers in the peak heat supply subsystem will not feel sudden changes in temperature comfort conditions.

The introduction of the second regulatory body 12, installed between the coolant supercharger and the source of thermal energy of the peak load, its outputs associated respectively with the input and output of the thermal energy source, while the control input of the regulatory body is connected to the corresponding output of the controller, allows to reduce gas consumption by the heat generator 14 due to the fact that a sufficiently hot heat carrier after the consumer is not heated additionally, but is supplied to consumers with a peak heat supply subsystem load "bypassing" the heat generator. And connecting the heat exchangers of the subsystems of the peak loads in parallel to the supply and return pipes

centralized heat supply systems with heat transfer quotas by portion-controlled regulators 6 reduces the influence of the peak load subsystems on each other.

Claims (1)

A district heating system containing a CHP, a supply pipe, consumers and a return pipe, the consumers being connected to the main pipeline through heat exchangers of the peak load heat supply subsystems, and each of the subsystems includes a heat carrier supercharger, a gas-fired heat generator to which a gas supply regulator is connected, the first regulator of the coolant, three temperature sensors and a controller, the inputs of which are connected to temperature sensors, and the outputs - to the first regulating with a heat-transfer agent and with a gas supply regulator, while the output of the heat exchanger from the side of the peak load subsystem is connected through the heat carrier supercharger and the heat generator to the consumers input, the outputs of which are connected through the first heat carrier regulator to the heat exchanger input from the peak load subsystem and to the additional input of the heat carrier supercharger moreover, the first temperature sensor is installed in the pipeline at the output of the heat generator of the peak load subsystem, the second temperature sensor tours are installed in the pipeline at the inlet of the first coolant regulator, and the third temperature sensor is installed outside the building, characterized in that a second coolant regulator is installed in the heat supply subsystem of the peak load, installed in the pipeline between the coolant supercharger and the heat generator so that it faces the input to the coolant supercharger, the first outlet to the heat generator, and the second outlet is connected through an additional section of the pipeline to the outlet of the heat generator at the same time, in the pipelines in front of the connection point, reverse-acting valves are installed, the second regulatory body being connected to the third output of the controller by its control input, and the heat exchanger inputs of each peak heat supply subsystem from the district heating system are connected directly to the supply and return pipes of the district heating system at the same time, at one of the inputs of each heat exchanger a batch action regulator is installed.