RU2748956C1 - Method for heat power control in heating system with solid fuel boiler - Google Patents

Abstract

FIELD: heating.SUBSTANCE: invention relates to heat power engineering, namely to heating systems with solid fuel boilers. Proposed is a method of heat power control in a heating system by a solid fuel boiler. A heat carrying agent is heated in the boiler and pumped through the heating system. The temperature of the heat carrying agent is changed by adjusting the volume of air which changes the intensity of fuel combustion. The heat carrying agent is heated to a nominal or maximum temperature of 80 to 95°C. The volume of the heat carrying agent passing through the heating system is changed by changing the speed of heat carrying agent pumping or changing the flow passage of the pipeline. The temperature of the heat carrying agent is maintained at a value close to the initial value by changing the generated power.EFFECT: expanded range of power tuning and improved operating characteristics.2 cl, 3 dwg

Description

The invention relates to heat power engineering, namely to heating systems with solid fuel boilers, and can be used to create heating systems with improved technical and operational characteristics and expanded functionality.

There is a known heating and hot water supply system based on a gas boiler (RF patent No. 2452906, No. 2652974), which implements a method for controlling thermal power based on heating the coolant in the boiler to a temperature corresponding to the required power, supplying a given volume of coolant to the heating system, changing coolant temperature by changing the volume of gas burned in the boiler. The disadvantage of the described method is the limited possibility of implementation due to the inaccessibility of connection to gas networks in many regions of the country, the high cost of thermal energy with an autonomous gas supply system, the explosion hazard of the heating system, the minimum power is limited by the temperature of the coolant below the dew point.

A well-known heating system based on a solid fuel boiler (Yu.L. Gusev. Basics of designing boiler plants. M., Stroyizdat, 1973, S. 239-241), which implements a method for controlling the thermal power in the heating and hot water supply system, including heating the coolant (water) to the required temperature, transfer of a given volume of coolant to the heating system, mixing the water cooled in the heating system with heated water until the temperature supplied to the boiler reaches a few degrees above the dew point and heating the water to a temperature corresponding to the required power supplied into the heating system. The disadvantage of the described method is the complexity of its implementation and the high cost of the heating system.

Known heating system with forced circulation of the coolant (patent for a useful model of the Russian Federation No. 143360), selected as a prototype, which implements a method for controlling thermal power, including heating the coolant to a temperature (above the dew point) corresponding to the heat consumed in the heating system and hot water supply power, supply of a given volume of coolant to the heating system, changing the temperature of the coolant to a temperature corresponding to the power consumption, by changing the volume of inlet air in the boiler, which changes the intensity of fuel combustion.

The disadvantages of this method are:

- a small range of power adjustment, typical for solid fuel boilers, which is due to the fact that high power is limited by acceptable heat losses, which increase with an increase in the temperature of flue gases, and the minimum power is limited by the permissible temperature of flue gases, at which there is no rapid growth of deposits on heat exchange surfaces and chimney;

- rapid growth of deposits on heat exchange surfaces at low capacities, which leads to the need for frequent boiler maintenance and low performance of the heating system;

- the possibility of condensate formation in the boiler when generating low power and the temperature of the coolant below the dew point;

- at low capacities, due to the low smoldering temperature of the fuel, its chemical underburning sharply increases, in connection with which the overall efficiency of the boiler decreases and the likelihood of its extinction increases.

The technical result consists in expanding the range of power tuning and improving performance.

The technical result is achieved by the fact that the method of controlling the thermal power in the heating system from a solid fuel boiler, in which the coolant is heated in the boiler, pumped through the heating system, the temperature of the coolant is changed by adjusting the volume of air that changes the intensity of fuel combustion, the coolant is heated to the nominal or maximum temperature (80-95 ° C), change the volume of the coolant passing through the heating system by changing the rate of pumping the coolant and / or changing the flow area of the pipeline and maintain the temperature of the coolant close to the initial value by changing the generated power.

- операции прототипа, 1 - нагрев теплоносителя твердотопливного котла до температуры, соответствующей требуемой мощности, но выше точки росы, 2 - подача заданного объема теплоносителя в систему отопления, 3 - повышение температуры теплоносителя до температуры, соответствующей требуемой мощности, путем изменения объема воздуха, изменяющего интенсивность горения топлива. На фиг 2 обозначено:

- операции, отличающиеся от прототипа режимом их проведения, 4 - нагрев теплоносителя в твердотопливном котле до температуры (80-95°С), соответствующей номинальной или максимальной мощности, 5 - изменение объема теплоносителя, подаваемого в систему отопления, в соответствии с требуемой мощностью, путем изменения скорости прокачки теплоносителя и/или изменения сечения трубопровода, 6 -поддерживают температуру теплоносителя, близкой к исходному значению, путем изменения генерируемой мощности за счет изменения объема воздуха подаваемого в котел. На фиг. 3 приведен один из возможных вариантов системы отопления и горячего водоснабжения, где обозначено: 7 - твердотопливный котел, 8 - входной воздуховод, 9 - заслонка, 10 - привод заслонки, 11 - терморегулятор, 12 - дымоход, 13 - радиаторы отопления, 14 - трехходовой кран, 15 - циркуляционный насос, 16 - регулировочный кран, 17 - расширительный бак, 18 - ввод водоснабжения, 19 - контур водонагревателя, 20 - проходной кран, 21 - кран умывальника, 22 - ванна.The essence of the invention is illustrated in FIG. 1-3 using the example of a heating system based on a solid fuel boiler. FIG. 1 shows the operations of the prototype; FIG. 2 shows the operations of the invention, and FIG. 3 is an example of a heating system that implements the proposed method. FIG. 1 indicates:

- prototype operations, 1 - heating the coolant of a solid fuel boiler to a temperature corresponding to the required power, but above the dew point, 2 - supplying a given volume of coolant to the heating system, 3 - increasing the temperature of the coolant to a temperature corresponding to the required power by changing the volume of air that changes the intensity of fuel combustion. Figure 2 indicates:

- operations that differ from the prototype by the mode of their conduct, 4 - heating the coolant in a solid fuel boiler to a temperature (80-95 ° C) corresponding to the nominal or maximum power, 5 - changing the volume of the coolant supplied to the heating system, in accordance with the required power, by changing the rate of pumping the coolant and / or changing the cross-section of the pipeline, 6 - maintain the temperature of the coolant close to the initial value by changing the generated power by changing the volume of air supplied to the boiler. FIG. 3 shows one of the possible options for the heating and hot water supply system, where it is indicated: 7 - solid fuel boiler, 8 - inlet duct, 9 - damper, 10 - damper actuator, 11 - thermostat, 12 - chimney, 13 - heating radiators, 14 - three-way tap, 15 - circulation pump, 16 - control tap, 17 - expansion tank, 18 - water supply input, 19 - water heater circuit, 20 - straight-through tap, 21 - washbasin tap, 22 - bathtub.

To implement the proposed method for controlling thermal power in a heating system with a solid fuel boiler, as a solid fuel boiler 7, it is necessary to use a long-burning boiler, for example, a shaft type, in which a relatively small volume of fuel is burned in the lower part of the feed hopper. The input air volume control device must be highly accurate, for example, based on a non-volatile two-stage damper 9 (RF patent No. 2651393) with a temperature controller 11 based on a bimetallic spiral or, for example, an electromechanical temperature controller (RF utility model patent No. 174496). Heating radiators 13 have no fundamental features, and their number depends on the size and number of storeys of the heated room. The three-way valve 14 also has no features and is used for its intended purpose. When the temperature of the coolant is higher than the dew point, valve 14 switches the coolant flow from the short circuit to the heating circuit. The circulating pump 15 can have a smooth adjustment of performance from zero to maximum or in a narrower range, which provides pumping of the coolant through the radiators for output from minimum to maximum thermal power. The pump 15 can have a built-in control unit or be connected via an external electronically controlled frequency converter. Pump 15 can be controlled from a room temperature sensor, including taking into account the temperature outside the room and the dynamics of its change, or according to a given program from a programmable control unit. If the circulation pump has a limited range of performance adjustment or in a system with natural circulation of the coolant (without a circulation pump), a control valve 16 is used, which is designed to change the flow area of the pipeline in order to change its hydraulic resistance and change the rate of pumping or flow of the coolant. The valve 16 can be made manually or electronically based on a servo drive and depending on the complexity of the heating system, its configuration and composition, and can be used in conjunction with the pump 15 in a system with forced circulation of the coolant or separately in a system with gravitational (natural) circulation. The expansion tank 17 has no peculiarities and its volume is selected at least 1:10 of the volume of the coolant in the heating system. The water supply input 18 can be connected to an individual pumping station from a well or to a centralized water supply line. The water heater circuit 19 can be built into the boiler 7 or installed in a separate heat exchange tank. The circuit 19 is connected to the inlet 18 through the straight-through tap 20. The hot water consumption points can be, for example, a washbasin 21 and a bathtub 22.

The heating system works according to the proposed method as follows. After loading the boiler 7 with fuel (wood, briquettes, etc.), it is ignited, the damper 9 is opened by the drive 10 of the thermostat 11 by turning it to the appropriate angle. The circulation pump 15 is turned on, while the coolant is pumped through the three-way valve 14 in a small circle. The temperature of the coolant gradually increases and when the temperature of the coolant corresponding to the nominal or maximum power (80-95 ° C) is reached, the three-way valve 14 switches and the coolant passes in a large circle through the control valve 16 and radiators 13. In this case, the rate of circulation of the coolant by the circulation pump 15 is selected corresponding to the required heat output delivered to the heating system, which can be significantly less than the maximum. If the consumed heat power turns out to be significantly less than the maximum power, and the circulation pump 15 has a limited range of performance adjustment, then the hydraulic resistance of the system increases with the control valve 16 and, thereby, the volume of the pumped heat carrier is reduced and the heat output to the heating system is reduced to the required one. At the same time, at the same time when cold water is heated in the water heater circuit 19 and hot water consumers 21, 22 are turned on, additional heat energy can be removed from the boiler 7. When the heat output is taken from the boiler 7, the temperature of the coolant begins to decrease, the damper 9 opens slightly, more air begins to flow into the boiler and the combustion intensity increases. An increase in the generated power occurs, and the temperature of the coolant rises to close to the initial value. In this case, the damper remains open to a small angle, and as much air enters the boiler as is necessary to generate the consumed power. If the consumption of thermal energy remains approximately constant, then the boiler 7 generates the consumed energy with small fluctuations in the temperature of the coolant. In the event that the consumption of thermal energy by the heating system and the water consumption system ceases, for example, by forcibly shutting off the circulation pump 15 (in manual mode or by the control system according to a given program) or its failure or power outage, the boiler 7 goes into standby mode. In this mode, a small power (hundreds of watts) is generated in the boiler, due to the use of a high-precision control system for the inlet air and smoldering of a relatively small volume of fuel, which is equal to the heat losses of the boiler through the heat-insulating casing. In this mode, boiler 7 can operate for a long time (tens - hundreds of hours, depending on the volume of fuel loaded into the boiler and the boiler design) and at any time is transferred or can automatically switch to the mode of generating the required thermal energy. In particular, the standby mode of the boiler can be used to periodically obtain hot water, for example, in the summer, when there is no need for the heating system to operate. In this mode, the boiler can operate even when the electricity is cut off, but in this case a high-precision non-volatile input air control system must be used in the boiler, for example, a two-stage damper in conjunction with a mechanical thermostat. At the same time, the use of electronically controlled elements with a backup power source in a heating system with a solid fuel boiler allows for programmable and remote control of the heating system.

Thus, the implementation of the proposed method in the heating system has the following advantages over the prototype and other analogues:

- increasing the power tuning range many times by reducing the minimum power;

- the ability to work for a long time in standby mode, with automatic transition to it (including when the electricity is cut off) and exit from it to the mode of generating the required power, which increases the safety of the boiler in various conditions;

- expansion of operational capabilities due to the operation of the boiler in a pulse mode, for example, to periodically obtain a limited amount of hot water, including when the heating system is not working;

- the possibility of electronic control of the heating system, including remote control or programmable for a long period of time;

- the possibility of obtaining a high peak power due to the high temperature of the coolant with a large supply of thermal energy;

- reduction of deposits on heat exchange surfaces, including when working at low power, due to the high temperature of these surfaces;

- elimination of the formation of condensate when generating small capacities.

The efficiency of the proposed method was tested in a heating system based on a mine boiler with a non-volatile high-precision inlet air control system based on a two-stage damper. The claimed characteristics of the described method have been tested and confirmed experimentally with an instrumental assessment of the parameters.

Claims (2)

1. A method of controlling the thermal power in the heating system from a solid fuel boiler, in which the coolant is heated in the boiler, pumped through the heating system, the temperature of the coolant is changed by adjusting the volume of air that changes the intensity of fuel combustion, characterized in that the coolant is heated to the nominal or maximum temperature 80-95 ° C, change the volume of the coolant passing through the heating system by changing the rate of pumping the coolant and / or changing the flow area of the pipeline and maintain the coolant temperature close to the initial value by changing the generated power. 2. The control method according to claim 1, characterized in that the volume of the coolant passing through the heating system is changed by changing the rate of pumping the coolant and changing the flow area of the pipeline.

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