RU2485408C1 - Method to provide heating load in systems of centralised heat supply - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: when connected to primary heating networks operating with temperature curves of 120-70°C, 130-70°C, 140-70°C and 150-70°C without use of mixing pumps, two heating subsystems formed as a result of division of a subscriber's heating system into two circulating circuits with identical thermal loads, are connected in series via a recuperative heat exchanger, which reduces temperature of network water upstream the first (along with network water flow) subsystem due to supply of return water in it from the same (first) subsystem, which, in its turn, is heated and supplied into the second subsystem. As a result of serial connection of two subsystems to a main heating network via a recuperative heat exchanger, specific flow rate doubles in terms of 1 Gcal/hr of heating load in each of serially connected heating subsystems, and separate regulation of temperature in supply pipelines of each subsystem makes it possible to optimise temperature mode of operation of each heating subsystem.

EFFECT: provision of required temperature and hydraulic modes of heating system operation.

Description

The method is intended for use in district heating systems.

The closest technical solution to the invention is a method of providing a heating load in district heating systems by heating network water at a heat source, transporting it to consumers, supplying network water to the supply pipelines of heat-using plants, connected in parallel through valves of flow regulators to the supply mains of the heating networks and, in including through the valve of the heating controller to the supply pipe of the heating system with heating devices, a return pipe oestriasis and mixing pump to the control valve differential pressure regulator at its discharge line connected to the flow line of the heating system, which also is removed through a check valve in other heat-cooled grid units after supplying water into it via mains water heating regulator valve. Moreover, the excess of this chilled water is discharged through the valve of the differential pressure regulator into the return heating line [1].

The disadvantage of this method is the need to use a mixing pump to provide the required circulating flow in the heating system and, therefore, additional energy consumption for its drive.

In addition, when implementing this method, it is not possible to carry out facade control or to connect heating systems operating with different temperature graphs in parallel.

The aim of the invention is the implementation of the heating system solely due to the pressure drop in the supply and return heating mains, i.e. without the use of mixing pumps and, therefore, without the consumption of electricity for their drive.

This goal is achieved by the fact that in a water district heating system containing a supply and return pipes, to which heat-consuming installations and, in particular, heating systems are connected, is carried out by the fact that two heating subsystems are formed as a result of dividing the subscriber’s heating system into two circulation circuits with equal heat loads are connected to the supply line of the heating network sequentially through a recuperative heat exchanger, lowering the temperature of the networks water before the first (along the mains water) subsystem, by supplying reverse water to it from the same (first) subsystem, which, in turn, is heated and fed to the second subsystem. At the same time, the flow rate of chilled water discharged from heat-using plants through a non-return valve to the supply pipe of the heating main after supplying network water to it through the valve of the return water temperature regulator after the first heating subsystem is controlled by the temperature controller in the supply pipe of the first subsystem, with which excess chilled water is discharged water to the return heating line, and the regulation of the water temperature in the supply pipe of the second subsystem is It wishes to set up three-way valve mounted on the return pipe of the first subsystem by controlling water flow through the regenerative heat exchanger of the heating side via its bypass line.

Figure 1 presents a schematic diagram of the implementation of the proposed method for providing a heating load. It contains the supply pipe of the heating network 1, connected to it through the valve 2 of the flow regulator 3, the heat-using installation 4, the return pipe 5, which through the check valve 6 is connected to the supply pipe 7, which, in turn, through the recuperative heat exchanger 8 (on the cooling side ) is connected to the supply pipe 9 of the first (along the mains water) heating subsystem 10 with heating devices 11. Moreover, the return pipe of the first heating subsystem 12 through a three-way valve 13, regenerative heat ennik 8 (on the side of heating) and the bypass line 14 is connected to the second supply line 15 (in the direction of network water) heating subsystem 16, a heater 17 and return line 18, connected to the heating system return pipe 19.

In this case, the return pipe 5 of the heat-using installation 4 is connected through the control valve 20 of the temperature controller 21 with a temperature sensor 22 on the supply pipe 9 of the first heating subsystem to the return heating pipe 18, and the supply pipe of the heating network 1 is connected by a connecting pipe 23 with a temperature controller valve 24 installed thereon 25 return water of the first heating subsystem 10 with a temperature sensor 26 on the return pipe 12 of the first subsystem 10.

In turn, the three-way valve 13 is connected to a temperature controller 27, the temperature sensor 28 of which is installed on the supply pipe 15 of the second heating subsystem 16.

It should be noted that all temperature controllers 21, 25, and 27 are equipped with sensors for outside air temperature (not shown in FIG. 1), by a signal from which the controllers maintain the set temperature in the indicated pipelines.

The system operates as follows.

The mains water through the supply pipe of the heating network 1 enters through the valve 2 of the flow regulator 3 to the heat-using installation 4, and then through the return pipe 5 and the check valve 6 to the supply heating line 7, and then through the heat exchanger 8 (on the cooling side) enters the supply pipe 9 of the first (along the network water) heating subsystem 10 and through the heating devices 11 to the return pipe 12. Through the pipe 12, the network water cooled in the heating devices partially or completely flows through a three-way to valve in the heat exchanger 8 (on the heating side). In this case, the return water flow from the first subsystem can partially pass through the bypass line 14 of the heat exchanger 8. The latter is necessary to control the heat capacity of the heat exchanger under off-design conditions, since the active surface of the heat exchanger, calculated under design conditions (for the lowest outdoor temperatures during the heating period), higher temperatures may be overpriced. And at the same time, using a three-way control valve 13, controlled by a temperature controller 27 with a temperature sensor 28, it is possible to optimize the temperature of the water supplied to the supply pipe 17 of the second heating subsystem 16. Moreover, in the supply pipe 9 of the first heating subsystem 10 according to a predetermined temperature schedule the temperature is maintained by supplying network water to it through the valve 24 of the temperature controller 25 with a temperature sensor 26 in the return pipe of the first heating subsystem 10 and adding to the network water de passed through the valve 24 of the heating controller 25; through the non-return valve 6, the return water cooled in the heat-using installations 4, the flow rate of which is adjusted by regulating the temperature in the supply pipe 9 of the first heating subsystem 10 according to the set temperature graph, by the temperature controller 21, the control valve 20. Accordingly, if the water temperature in the supply pipe 9 is the first heating subsystem 10 exceeds the value set by the temperature graph, the temperature controller 21 transmits a signal to close valve 20, which leads to an increase in cooling flow REPRESENTATIONS water after heat-setting 4 through a check valve 6 in the supply line of the heating pipe 7. On the contrary, when the temperature drops in the supply line 9 of the first heating subsystem 10 temperature controller 21 provides a signal to open the valve 20. This flow of chilled water through the check valve is reduced. Thus, the operation of the heating devices of the first heating subsystem is regulated by the temperatures in the supply and return pipelines, which guarantees a high-quality mode of their operation. As for the operating mode of the heating devices of the second heating subsystem, it is sufficient to regulate the temperature of the water in the supply pipe 15 according to the set temperature schedule, since the second heating subsystem will work exactly at the same flow rate of the network water as the first subsystem. Moreover, the temperature conditions of the first and second heating subsystems can be selected individually. This allows you to use this method of providing a heating load for facade control, as well as in the case of connecting heating subsystems operating with different temperature schedules, and in some cases with different heating loads.

An important distinguishing feature of the proposed method for providing a heating load is that the series connection of two subsystems to the main heating network through a heat exchanger creates the effect of increasing the specific consumption in the heating subsystems. For example, if in the heating line 7 (in front of the inlet pipe of the heat exchanger 8) the temperature is maintained according to the heating schedule of 120-70 ° C with the total heating load of the two heating subsystems 1 Gcal / h, the flow rate in the heating line 7 will be 20 m ³ / h, respectively, specific consumption will be 20 m ³ / cal / h of heating load. Passing successively through the first and second subsystems, the load of each of which is 0.5 Gcal / h, respectively, the specific consumption in each of the subsystems will be 20 / 0.5 = 40 m ³ / Gcal / h. Moreover, under design conditions, the temperature in the heating supply pipe 7 in front of the heat exchanger 8 must be maintained at 120 ° C, in the supply pipe of the first subsystem - 95 ° C, in the return pipe of this subsystem - 70 ° C in front of the heat exchanger 8 (on the heating side), in the flow line of the pipeline 15 of the second subsystem - 95 ° C and in the return pipe - 70 ° C.

Thus, for two-pipe heating systems, when using the proposed method for connecting heating systems, it is advisable to maintain the temperature in the supply heating line 7 according to the heating schedule of 120-70 ° C.

Accordingly, for single-pipe systems with a calculated temperature in the supply pipelines of heating systems of 105 ° C and in return 70 ° C, it is required to maintain the temperature in heating line 7 according to the heating schedule 140-70 ° C. The temperature in this case will have the following values in the calculated conditions: heating line 7-140 ° C, after the recuperative heat exchanger 8 in the supply pipe 9 of the first subsystem - 105 ° C, in the return pipe - 70 ° C and, respectively, 105 and 70 ° C in the supply and return pipes of the second subsystem from captivity.

Thus, in comparison with the prototype in the proposed method, in order to achieve the required temperature in the heating main 7 according to the heating schedule 120-70 ° C during operation of the primary heating networks according to the typical temperature schedule 150-70 ° C, it is required to add to the mains water through the check valve 6, passed through valve 24 into the heating supply line 7, only 60% of the cooling water (or 7.5 t / h to 12.5 t / h for one Gcal / h of the connected heating load of the two heating subsystems). That is, in this case, the load of the heat-using installation 4 for the removal of cooling water from it in the amount necessary to maintain the temperature in the supply line 7 according to the heating schedule 120-70 ° C, should be 60% of the total load of the two heating subsystems. Accordingly, in order to maintain the water temperature in heating line 7 according to the heating schedule 140-70 C and the operation of primary heating networks according to the schedule 150-70 ° C, the load of the heat-using installation 4 should be only 12.5% of the total rated load of the two heating subsystems 10 and 16 .

First of all, we are talking about the use of water after being mixed through a non-return valve 6 into the heating line 7 after heat-using plants operating directly on primary network water, including ventilation systems, air curtains, dryers, etc., the percentage of which is usually loaded , in modern buildings and buildings of the old buildings for public and cultural purposes, kindergartens and pre-schools, schools, hospitals, clinics and, especially, industrial enterprises significantly exceeds the decree The above values, and in some cases exceed the loads of heating systems.

Thus, in comparison with the prototype, in order to abandon the mixing pumps, the load of heat-using plants 4 should be from the required in the prototype, respectively, for the implementation of the temperature schedule 120-70 ° C - 27.2%, and when implementing the temperature schedule 140 -70 ° C only 11.2%.

In this regard, the proposed method allows in the vast majority of cases to abandon mixing pumps, since modern buildings and old buildings of public and cultural purposes, as well as kindergartens, schools, hospitals, clinics and industrial enterprises have significantly greater heating and ventilation values loads.

Thus, the proposed method for connecting loads of heating systems significantly expands the scale of pump-less connection of heating systems for buildings for various purposes. It should be noted that in some cases, for connecting subscribers with exclusively heating load, it may be necessary to use mixing pumps, as in the prototype, but their performance compared to the pumps used in the prototype will be almost 4 times less for two-pipe heating systems and 9 times less for single pipe heating systems. At the same time, theoretical and experimental studies performed by numerous experts confirm the possibility of using qualitative and quantitative regulation in heating systems. The latter allows you to further expand the scope of the pump-less method of connecting heating systems.

Literature

1. Patent No. 2117857. Yakimov V.L., Kashcheev V.P., Podstavkin N.E., Paskov V.V., Skrynnikov B.C., Tikhonov M.Yu., Smirnov V.A.

Claims (1)

A method of providing a heating load in district heating systems by heating mains water at a heat source, transporting it to consumers, supplying mains water to supply pipelines of heat-using plants, connected in parallel through valves of flow regulators to supply mains of heating networks and, including, through a valve of heating regulator in the supply pipe of the heating system with heating devices, a return pipe and a heat exchanger, characterized in that there are two subsystems heating formed as a result of dividing the subscriber’s heating system into two subsystems with approximately equal heat loads are connected to the supply network of the heating network sequentially through a recuperative heat exchanger, lowering the temperature of the supply water before the first subsystem along the supply water by supplying return water to it from the same (first) subsystem, which, in turn, is heated and fed into the second subsystem, moreover, the regulation of the flow rate of chilled water discharged from heat-using plants The wok through the non-return valve to the supply pipe of the heating main after supplying network water through the valve of the heating controller is carried out by the temperature controller in the supply pipe of the first subsystem, and the water temperature in the supply pipe of the second subsystem is controlled by a three-way valve installed on the return pipe of the first subsystem, regulation of water flow through the recuperative heat exchanger on the heating side and along the bypass line of this heat exchanger.