EA012942B1 - The method of modernization of double-pipeline heat supply system - Google Patents

Abstract

The invention relates to double-pipeline system modernization when re-constructing single buildings and a group of buildings combined by location by means of broadening and/or increasing of number of floors of existing and new buildings in order to increase house density in existing infrastructure. According to the invention when modernizing double-pipeline systems redistribution of coolant delivery is conducted between heat using equipments joint with one branch of the heat supply network in such a way that in order to convert heating and hot water supply to gas for a part of gas-fired buildings hooked up to one branch of the heat supply network, they are further equipped with apartment or house gas heat and hot water supply sources and released heat power of the network is directed for heating of reconstructed and/or new buildings joint with this very branch of the heat supply network.

Description

The invention relates to the field of modernization of heating systems in the reconstruction of individual buildings and united by the location of groups of buildings by broadening and / or increasing the height of existing and building new buildings in order to compact buildings with the existing infrastructure.

A possible increase in the area and volume of a residential building during its reconstruction can be 2-4 times. With such an increase in area and volume, additional warming of the enclosing structures of the old part of the building becomes completely insufficient to compensate for the growth of heat consumption to ensure normal heating of the reconstructed building and there is a need for additional thermal energy.

Provided that the old heat distribution network is maintained, additional heat for the reconstructed house can be obtained at the expense of other consumers and, in particular, due to the thermal rehabilitation of neighboring old houses that are not planned for reconstruction for various reasons.

However, the redistribution of heat loads between heat consumers with the universal use of quality regulation and dependent connection (via hydraulic elevators) of consumers leads to a change in the hydraulic mode of the heat supply system. To compensate for the change in the hydraulic mode of the heat supply system and preserve the necessary heat supply to each consumer with a significant redistribution of heat loads, it is necessary to apply not only qualitative but also quantitative control, which is associated with the need to change the operating mode of pumping units. The latter, in order to preserve high efficiency of pumping installations, requires adjustment of the speed of electric drives, which requires additional equipment. In addition, the change in the hydraulic mode by increasing the pressure in the old heating system is undesirable because of the possible increase in the accident rate of the system.

Therefore, it is necessary to use such a method of reconstruction of the two-pipe heating system, in which the operation mode of pumping installations without increasing the pressure in the system remains unchanged.

There is a method of regulating the pressure of a fluid [2], relating to pipeline transport, in particular for the supply of a large number of consumers with a fluid medium with elevated pressure. To provide all consumers with the necessary fluid, in particular the coolant, they adopt an adjustment characteristic that is set between the minimum and maximum in such a way that, in the direction of increasing pressure, the characteristic lies above the straight line connecting the points of minimum pressure and maximum pressure. The pressure regulator is constantly given a signal proportional to the amount of flowing medium or the speed of its flow. When the actual value of the quantity or velocity of the medium and the corresponding pressure deviates from the set value, the engine speed is adjusted to compensate for the deviation. The technical result of this invention, as stated in the description [2], is to reduce the load on the pipe system with the existing units. The negative factors of this method include the complication of the heating system due to the introduction of a special pressure regulator with a control device, excessive energy consumption for pumping coolant with a negative valve control and the need for an engine speed control system. Therefore, this method is not very suitable for the implementation of the purpose of adjusting the redistribution of heat supply to consumers.

As a prototype, a method of controlling the distribution of the coolant in the heat supply system using the main and additional heat sources and a system for its implementation have been adopted [3]. This invention deals with the case when at the end of one of the branches of the heat network an additional source appears with a constant heat release. The objective of this invention was the rational use of this heat source without major reworking of the existing heating system, which is achieved by regulating the flow of coolant in the heating system by periodically and alternately connecting some consumers closest to the additional heat source and connected to the main pipeline, and, accordingly, disconnecting these consumers from main heat source.

At the same time, in the system at the site of consumers connected to the additional heat source, they maintain the required pressure in the return pipeline by feeding pumps from the main return pipeline connected to the main heat source. In the heating system to regulate the distribution of the coolant according to the prototype, sectional plugs or valves are installed to connect (or disconnect) them to an additional heat source or disconnect (or connect) from the main heat source, and bypass pipes are connected to both sides of the sectional plugs on the return pipe pipelines associated with make-up pumps.

Thus, the modernization of the two-pipe heating system in the prototype of the invention is that in order to obtain additional heat and control the heat load between the main and additional heat sources, an additional heat source and a substantial constructive reconstruction of the existing heat supply network are provided. Such a principle is not economically and technologically rational for use in the modernization of two

- 1 012942 of the piped heat supply system for the reconstruction of the existing housing stock and the provision of heat for new buildings built on vacant spaces of a given quarter and / or microdistrict.

The objectives of the proposed method for the reconstruction of the two-pipe heating system are: the release of part of the heat capacity of the heating network for its use in reconstructed (superstructured and / or expandable) and / or new buildings;

maintaining the constant hydraulic mode of the heat supply network in order to eliminate the need for its reconstruction;

regulation of the operating parameters of the heating system by changing the hydraulic resistance of individual sections;

increase of economic and material indicators in the reconstruction of energy supply systems for buildings.

The achievement of the technical result in accordance with these objectives is provided by the proposed method of reconstruction of the two-pipe heating system, including the preservation of the existing heating network and heating mode, the difference in which, according to the invention, redistribute the coolant supply between heat consumers connected to one branch of the heating network, so that to convert heating and hot heat of a part of gasified buildings to gas, Connected to one branch of the heat supply network, they are additionally equipped with apartment or house gas sources of heating and hot water, and the heat capacity of the network released at the same time is directed to heat supply of the reconstructed and / or new buildings connected to the same branch of the heating network.

Local branches are connected to the heat points of the reconstructed or new buildings or groups of buildings from the external heat supply network mainly before the hot coolant branches to the buildings that are additionally equipped with residential or house gas sources of heating and hot water, i.e. transferred to gas.

At each redistribution of heat between consumers, an additional additional hydraulic linkage is made of the parameters of the heating system operation.

The heat capacity of the heat supply system is released due to the replacement of the centralized heating system and hot water supply for part of the gasified buildings, which are supplied from one branch of the heat supply network, by apartment or house heating using gas-fired or residential heating appliances. Further redistribution of the released thermal power is in its use in heating and hot water supply of buildings under reconstruction or under construction, connected to the same branch of the heating network. Modern gas roof heaters that have a high thermal efficiency (92-93%), corresponding to large boiler installations, and safe combustion chambers with a high level of automation can be used as home or house gas sources of heating and hot water. These heaters are currently recognized as the most economical sources of heat.

It is also necessary to take into account the amount of heat transport losses in the main heat pipelines and branches to buildings and central heating stations or transformer substations. The use of locally located house heaters is often more effective than centralized heating systems.

The invention is illustrated using FIG. 1 and 2.

FIG. 1 shows a graphic representation of the hydraulic mode of operation of a two-pipe heating system, and FIG. 2 - the conditional scheme of connection of consumers and pressure diagrams for it under the normal and new modes of the supply system for three consumers of heat and hot water.

The two-pipe heat supply system, in particular, centralized, is an extensive heating network emanating from a central heat source (urban or district CHP or boiler house) with branches equipped with relevant central heat points (CHP) belonging to groups of houses and with local branches from them separate heat points (TP) buildings. The main feature of the two-pipe heating system is the parallel connection of consumers, due to the need to output the spent coolant in the return line.

The hydraulic mode of operation of a two-pipe heating system is in principle determined by the intersection point of the dependency curve:

H = k, o, ² .

where H ₁ is the pressure produced by the turbo pump, m (m. water line), B, is the hydraulic resistance of the heat supply system under turbulent motion, O, is the coolant flow rate, m ³ / s;

and a turbomachine characteristic curve, as shown in FIG. 1, points В ₁ , В ₂ , В ₃ for different values В ₁ , moreover В ₃ <В ₁ <В ₂ . In this case, such a turbomachine is a pump.

Therefore, any change in hydraulic resistance In ₁ network, on which the pump operates, leads to a change in pressure and coolant flow (point B ₃ - while reducing the resistance and

- 2 012 942 points K ₂ - with its increase). It follows that in order to maintain the constancy of the hydraulic regime it is necessary to ensure the constancy of the value of the hydraulic resistance of the heat supply system.

The scheme of the water network of the heating system (see Fig. 2) is presented in a form similar to that given in [4, Fig. 6.3]. It conditionally shows the consumers of 1, 2, 3 heat supply, the corresponding sections 4 of heat supply and pressure schedules for the water network of the heat supply system, in normal mode - curve 5, in the new mode - curve 6.

When converting to a gas heat source, one of the consumers (buildings) produces its disconnection from the central heating network. Any disconnection of one of the consumers of heat supply (1, 2 or 3), meaning K yes, leads to a change in the overall hydraulic resistance K.

Turning off one of the sites should lead to an increase in K! and the offset (fig. 1) of the point K ₁ to the position K ₂ , and the pressure H and the flow C must change to H ₂ and ^ ₂ . However, an increase in pressure at the beginning of the heat supply system should lead to a slight change in pressure throughout the entire system, and a change in the coolant flow rate can adversely affect the heating conditions of buildings connected to the heat supply system in a dependent pattern, i.e. through hydraulic elevators.

With an independent scheme of connecting the house heating system to the heating network (i.e., in the presence of house heat exchangers), fluctuations in the hydraulic parameters in the latter affect its operation to a lesser extent.

To preserve the unchanged hydraulic mode in the absence of one of the consumers in the heating system, it is necessary to change the hydraulic resistance accordingly. Therefore, disconnecting one or more houses from the centralized heat supply and / or turning on other consumers requires an appropriate hydraulic linkage.

As an example, the calculation of the parameters of a water network with three consumers is given, during which it is necessary to determine the water consumption of consumers and build a graph of pressure when consumer 2 is disconnected due to the transfer of its hot water supply from centralized to local using gas-fired or household heating appliances. When calculating it is necessary to accept that the pressure generated by the pump station, for both modes remains constant and equal to 40 m.

The scheme of the water network with three consumers and the pressure chart for it in normal mode — curve 5, when the water consumption of each consumer is Y ' ₁ = Y' ₂ = Y ' ₃ = 0.1 m ³ / s, is shown in FIG. 2, where V '= consumption of water at the consumer, m ³ / s.

For this calculation, the resistances of individual sections 4 (Fig. 2) of the network (sections I - III) for the normal mode (Table 1) and the conductivity of consumers 1-3 are determined from known values of 5H and V. Here δΗ is the pressure loss [m] equal to 5H = ZU ² , where V is the water flow, m ³ / s; 3 - the resistance of the pipeline section or network, m ² / m ⁶ . In turn, = Λ ₈ (ί + 1e) / H ⁵ , ²⁵ , where 1 and 1 _e are the length of the pipeline and the equivalent length of local resistances, m; b - internal diameter of the pipeline, m;

And ₈ is a constant coefficient depending on the absolute equivalent roughness of the pipeline and on the system of units.

Table 1. Resistance of sections of the IP network and the conductance of consumers 1-3 for the normal mode

Plot V m ³ / s δΗ, m 8 = 0Н1У \ м с ² / м ^б a = U1 <5Y, m ³ / (cm ' ⁵ ) I 0.3 ten 111 0,0182 II 0.2 ten 250 III 0.1 ten 1000 ^one 0.1 thirty 3000 2 0.1 20 2000 3 0.1 ten 1000

Next, determine the resistance and conductivity of sections 4 of the network after disconnecting consumer 2:

5ts.z = 5ts +% + & = 250 +1000 +1000 ~ 2250 m-s ² / m ⁶ ; aiz = 1/7 ^ 7 = 1/72250 = 0.0210 m ³ / (s-m ° ⁵ );

= * 1 + "of = 0,0182 + 0.0210" 0.0392 m ³ / (s * m ° ⁵ );

Jaz == 1 / a ?. ₃ ~ 1 / 0.0392 ² - 652 m ² / m ⁶ , where a is the conductivity of the corresponding section of the pipeline, m ³ / (cm ^0.5 ). The total resistance of the network after disconnecting the consumer 2

5 _GZ = № ι, 3 = 111 +652 = 763 m ² / m ⁶ .

Total water consumption after switching off the consumer 2

7 = = 740/763 = 0.229 m ³ / s.

Water consumption at consumers 1 and 3

- 3 012942 η = = 0.229 7652/3000 = 0.107 m ³ / s;

Γ ₃ = K- AND * = 0.229 - 0.107 = 0.122 m ³ / s.

Loss of pressure on network sections and at consumers:

OD = 5 / ^ = 3000 0.107 ² = 34.3 m

Sc = 250 0.122 ² = 3.7 m;

ΔΗ ^ Ηι-δΗ ^, 3-3.7 = 30.6 m;

LND = 1000 0.122 ² = 14.9 m;

Based on the obtained values, we construct a graph of pressures for the new regime (curve 6 in Fig. 2).

As can be seen from the above calculations, the total network resistance after disconnecting consumer 2 increased from 625 to 763 ms ² / m ⁶ , and the total water consumption decreased from 0.3 to 0.229 m ³ / s. At the same time, for consumer No. 1, water consumption changed from 0.1 to 0.107 m ³ / s, i.e. by 7%, but at consumer # 3 the change in water consumption is 3 times more (from 0.1 to 0.122 m / s). Therefore, a significant reduction in water consumption at the consumer has a significantly greater impact on other consumers located downstream of the coolant.

According to the information given in [1] in the Khoroshevo-Mnevniki district of Moscow, with a slight increase in the construction area as a result of the reconstruction of a 5-storey building, its total area should increase from 3,500 m to 11,000 m ² , i.e. 3.6 times. In this case, the estimated cost of reconstruction will be 10% lower than the construction of a new similar house. The elaboration of options for the modernization of the brick 80-apartment residential building of the series 480-29B, carried out by the problem research laboratory of the Kiev State Technical University of Construction, showed the effectiveness of its superstructure up to 10-16 floors. The width of the above floors is more than the existing ones (15 m instead of 10.9 m). Therefore, the total area as a result of reconstruction may increase by about 4 times. In St. Petersburg, the company JSC “Construction Trust No. 5”, together with specialists from LenNIIproekt, carried out an experiment on the reconstruction of a 5-storey building that is in disrepair. The reconstruction of such a house makes it possible to preserve the fixed assets (walls, foundation) and reduce costs, as well as to obtain additional housing in the former building plot. With the addition of 4 floors, the living area increased from 2,730 to 4,280 m ² , i.e. 1.6 times, and the construction volume - from 16591 to 39658 m ³ , i.e. 2.4 times.

Economic calculations show that the use of the presented invention makes it possible to further reduce the cost of 1 m ^{2 of} reconstructed housing by about 10%.

Information sources

1. The patent KP number 2224172, cl. Ε17Ώ 3/01, Ε04Ώ 15/00. Pressure control method for fluid pressure (Hennel Ewald, Mike Hennel, country of priority ΏΕ), 2001.

2. Ci patent number 2089790, cl. Ε24Ώ 10/00. The method of regulating the distribution of the coolant in the heating system. (Skornyakov V.V., Lagutin V.A., Khoroshikh B.A.), 1994.

3. Pilipenko V.M. Domestic and foreign experience in the reconstruction of industrial residential buildings. Mn .: RUE "Belstroycenter", Construction Science and Technology, No. 4 (1), 2006, p. 74-79.

4. Safonov A.P. Collection of tasks for district heating and typical networks. M .: Energostroyizdat, 1985, 232 p.

Claims (2)

CLAIM 1. A method of modernizing a two-pipe heating system for reconstructed and new buildings of a microdistrict or residential area, which consists in the fact that in order to preserve the existing network and heating supply mode, the heat carrier supply is redistributed between heat consumers connected to one branch of the heating network by supplying heat and with hot water, parts of gasified buildings connected to one branch of the heating network are converted to gas by means of their additional equipment residential and domestic gas sources of heating and hot water, and the heat capacity of the network released at the same time is directed to supply heat to the reconstructed and / or new buildings connected to the same branch of the heating network, characterized in that at each redistribution of coolant supply between heat consumers to save the constancy of the hydraulic mode of operation of the heat supply system additionally produce a hydraulic linking of its parameters as follows: on the basis of To determine the resistance of network sections and consumer conductivity for a normal heat supply mode, using known values of pressure loss and water flow and subsequent determination of the resistance and conductivity of network sections after transferring one or several consumers to a gas source of heat and disconnecting them from the central heating network, calculate the total hydraulic resistances of the heat supply system and make up the pressure graphs for the specified modes and then change the hydraulic resistance accordingly. Lenie heating network towards ensuring its permanence. 2. The method according to claim 1, characterized in that the local branches to the heat points of the reconstructed or new buildings from the external heat supply network are connected before the branches in the direction of the hot heat carrier to the buildings with the heat supply converted to gas. - 4 012942