RU2599707C1 - Method for automatic control of heat consumption of building in central heat supply system - Google Patents

Abstract

FIELD: heat engineering.

SUBSTANCE: invention relates to heat engineering and can be used to perform weather-dependent heat flow control in central heating systems of buildings and structures. In method of controlling operating mode of heating system, which comprises periodic supply of heat carrier in building heating system in form of a pulse whose duration is shorter than or equal to a preset period of heat carrier flow control in building heating system, in measurement of heat carrier temperature in return line of building heating system and in measurement of ambient air temperature, as well as in correction of pulse duration of heat carrier, specified value of heat carrier temperature in return line is functionally linked with temperature of ambient air, minimum step is introduced and its multiple step of change of pulse duration of heat carrier is set in each period of control, and a step change of heat carrier temperature in return line is predetermined for period of heat carrier flow control at minimum value of pulse duration of heat carrier, equal to minimum step of change of pulse duration of heat carrier in control period, wherein at beginning of each period of control, specified value of heat carrier temperature in return line is compared with heat carrier temperature in return line, determining rounded value k_i - coefficient of frequency of correction off step of change of pulse duration of heat carrier in said period of heat carrier flow rate control and correcting value of pulse duration of heat carrier in i-th period of heat carrier flow rate control.

EFFECT: higher reliability, efficiency and accuracy of control of heat consumption of building included in central heat supply system.

1 cl, 1 dwg

Description

The invention relates to the field of heat engineering and can be used to implement weather-dependent regulation of heat consumption in central heating systems of buildings and structures.

A known method of regulating the mode of operation of a water heating system (USSR Author's Certificate No. 1241029, F24D 3/00, 3/02, 1986), which consists in periodically supplying and stopping the flow of coolant into the heating system depending on the ratio of the set temperature and the actual air temperature in a heated room.

The disadvantage of this method is the occurrence in the heating system of uncontrolled self-oscillations of air temperature in a heated room, which reduces its reliability due to the need to regularly check and adjust the settings of the relay control bodies for air temperature in a heated room. In addition, the use of a circulation pump significantly complicates and increases the cost of implementing this method, and also does not take into account the effect of changes in outdoor temperature on the regulation process.

Closest to the claimed, is the "Method of regulating the operating mode of the heating system" (Patent for the invention of the Russian Federation No. 2474764, F24D 3/00, 2013), adopted as a prototype, which consists in the periodic supply of coolant to the building heating system in the form of pulses of duration less than or equal to the pre-established period for regulating the flow of coolant in the heating system of the building, as well as in measuring the temperature of the coolant in the return pipe of the heating system of the building and in measuring the temperature of the outside air.

The disadvantage of this method lies in the complexity of its implementation, which reduces reliability and increases the cost of the entire heat management system of the building, as well as its low speed, due to the presence of significant thermal inertia in the air temperature control loop inside the building.

The technical result of the proposed method is to increase the reliability, efficiency and accuracy of heat management of a building included in the central heating system.

The technical result is achieved by the fact that in the method of regulating the operating mode of the heating system, which consists in periodically supplying the coolant to the building heating system in the form of an impulse of a duration shorter than or equal to the pre-set period for regulating the flow of coolant in the building heating system, in measuring the temperature of the coolant in the heating system return line buildings and in measuring the temperature of the outside air, as well as in correcting the duration of the coolant pulse, the set value the temperature of the coolant in the return line is functionally associated with the temperature of the outside air, a minimum step is introduced and the step of changing the duration of the coolant pulse in each period of regulating the flow of the coolant, multiple of the minimum step, is set, and the sign of the step of changing the duration of the coolant pulse depends on the ratio of the set value of the temperature of the coolant in the return line and the temperature of the coolant in the return line, and also determine the step of changing the temperature of the coolant eating in the return line for the period of regulation of the flow rate of the coolant with a minimum value of the duration of the pulse of the coolant equal to the minimum step of changing the duration of the pulse of the coolant in the period of regulation of the flow of coolant, while at the beginning of each period of regulation of the flow of coolant compare the set value of the temperature of the coolant in the return line with the temperature of the coolant in the return line, determine the rounded value of the coefficient of the coefficient of correction of the step changes the duration of the coolant pulse in a given period of regulation of the coolant flow as:

,

,

where i is the serial number of the period of regulation of the flow of coolant;

k _i is the coefficient of correction factor for the step of changing the duration of the coolant pulse in the i-th period of regulation of the coolant flow;

T _oz - the set value of the temperature of the coolant in the return line, ° C;

T _about - the temperature of the coolant in the return line, ° C;

ΔТ _о - step of changing the temperature of the coolant in the return line for the period of regulating the flow of the coolant with a minimum value of the duration of the pulse of the coolant equal to the minimum step of changing the duration of the pulse of the coolant in the period of regulating the flow of the coolant, ° C;

and adjust the magnitude of the pulse duration of the coolant in the i-th period of regulation of the flow of coolant in accordance with the expression:

,

,

where t and _i - the duration of the coolant pulse in the i-th period of regulation of the flow of the coolant, s;

Δt _and is the step of changing the duration of the coolant pulse in the period of regulating the flow of coolant, s;

at the same time, the correction factor k _i = 0 is set at

,

,

where δ is the dead zone, ° C.

In FIG. 1 shows a block diagram of a device that implements the proposed method for automatically controlling the heat consumption of a building in a central heating system.

The device contains a heat source 1, the output of which through the heat regulator 2, the heating system of building 3 and the unit for measuring the temperature of the coolant in the return pipe 4 of the heating system of the building 3 is connected to the input of the heat source 1. The second output of the unit for measuring the temperature of the coolant in the return pipe 4 through the control unit 5 connected by the second input to the output of the outdoor temperature measuring unit 6 is connected to the second input of the heat regulator 2.

The heat regulator 2 is based on a normally open solenoid valve.

The method is as follows.

In the initial state, the heat carrier from the heat source 1 is connected through a series-connected heat regulator 2 with a normally open solenoid valve, the heating system of the building 3 and the temperature block of the coolant in the return pipe 4 to the heat source 1. The control unit 5 controls the operation of the heat regulator 2 based on temperature information outdoor air T _n and the temperature of the coolant T _about in the return line 4.

Preliminarily, in the control unit 5, a period for regulating the flow of coolant in the heating system of the building 3 is set depending on the permissible switching frequency of the normally open solenoid valve of the heat regulator 2 and the thermal inertia of the heating system of the building 3, and a functional dependence (for example, tabular) of the set value of the temperature of the coolant T is introduced _Lake in the return flow of external air of the building 3 from the heating temperature T _n T _Lake = φ (T _n).

In addition, a dynamic parameter is entered into the control unit 5 that determines the speed of the device: step ΔТ _about changing the temperature T _{о of the} coolant in the return pipe of the heating system of building 3 for the period of regulating the coolant flow with a minimum pulse duration t _{andmin of} coolant equal to the minimum step Δt _{andmin of} change pulse duration t _and period of coolant in the coolant flow control.

At the beginning of each (i-th) coolant flow control period, the temperature T _{о of the} coolant in the return pipe of the heating system of building 3 is measured and compared with the set value of the coolant temperature T _oz in the return pipe of the heating system of building 3, obtained from the dependence T _oz = φ (T _n) to calculate the difference (T _Lake -T _o) for setting the pulse duration changes sign t _ANDi coolant in the i-th period coolant flow control, as well as for entering the increment Δt calculation _and considering District ennogo multiplicity factor correction values k _i Δt step _and varying the duration t pulse _ANDi coolant in i-th period coolant flow rate control according to the relation:

According to the correction factor k _i , the duration t and _i of the coolant pulse is _refined in the i-th period of the coolant flow control in accordance with the expression:

which provides accelerated compensation for large errors in temperature control of T _{about the} coolant in the return pipe of the heating system of building 3, since at (T _oz -T _o ) / ΔT _o ≥2, the correction factor is k _i ≥2.

The required accuracy of temperature control Т _{о of the} coolant in the return pipe of the building 3 heating system is achieved when:

where δ is the dead zone.

за пределы зоны нечувствительности δ.In this case, the value of the coefficient of correction factor k _i = 0 is set and the regulation of the pulse duration t _{and the} coolant is suspended until the output

outside the dead zone δ.

When T _oz > T _o, the control unit 5 provides an increase in the pulse duration t _{and the} coolant, which leads to an increase in the temperature T _{o of the} coolant in the return line of the heating system of building 3, and when T _oz <T _o, by analogy, the temperature T _{o of the} coolant in the return heating system heating pipes 3.

As a result, the temperature T _{о of the} coolant is stabilized in the return line of the heating system of the building 3 with a given accuracy and high speed, and therefore, the required thermal regime in the premises of the building is ensured.

If the device that implements the proposed method for automatically controlling the building’s heat consumption in the central heating system is inoperative, the coolant supply to the heating system of building 3 will be saved through the normally open solenoid valve of the heat regulator 2 with the maximum flow rate of the coolant.

Thus, taking into account the low energy consumption of the electromagnetic valve and the control unit, as well as the ease of implementation and the accuracy of the technical solution, the implementation of the proposed method allows for high accuracy, reliability and cost-effectiveness of automatic control of heat consumption of the building in the central heating system.

Claims (1)

A method for automatically controlling the heat consumption of a building in a central heating system, which consists in periodically supplying heat to the building heating system in the form of a pulse with a duration shorter than or equal to a pre-set period for controlling the flow of heat in the building heating system, in measuring the temperature of the coolant in the return pipe of the building heating system and in measuring outdoor temperature, as well as in the correction of the duration of the coolant pulse, characterized in then the set value of the temperature of the coolant in the return line is functionally associated with the temperature of the outside air, enter the minimum step and set a multiple of the minimum step of the step of changing the duration of the coolant pulse in each period of regulating the flow of coolant, and the sign of the step of changing the duration of the coolant pulse depends on the ratio of the set value of the coolant temperature in the return line and the temperature of the coolant in the return line, and also determine the step of changing t the temperature of the coolant in the return line for the period of regulation of the flow of the coolant with a minimum value of the duration of the pulse of the coolant equal to the minimum step of changing the duration of the pulse of the coolant in the period of control of the flow of coolant, while at the beginning of each period of control of the flow of coolant compare the set value of the temperature of the coolant in the return line with the temperature of the coolant in the return line, determine the rounded value of the coefficient of multiplicity of the core of the step of changing the duration of the coolant pulse in a given period of regulating the coolant flow as:
k _i = INT [(T _oz -T _o ) / ΔT _o ],
where i is the serial number of the period of regulation of the flow of coolant;
k _i is the coefficient of correction factor for the step of changing the duration of the coolant pulse in the i-th period of regulation of the coolant flow;
T _oz - the set value of the temperature of the coolant in the return pipe, ° C;
T _about - the temperature of the coolant in the return pipe, ° C;
ΔТ _о - step of changing the temperature of the coolant in the return line for the period of regulating the flow of the coolant with a minimum value of the pulse width of the coolant equal to the minimum step of changing the duration of the pulse of the coolant in the period of regulating the flow of the coolant, ° C;
and adjust the magnitude of the pulse duration of the coolant in the i-th period of regulation of the flow of coolant in accordance with the expression:
_ANDi t = t _{and a (i-1)} + k _i · Δt _and
where t and _i - the duration of the coolant pulse in the i-th period of regulation of the flow of the coolant, s;
Δt _and is the step of changing the duration of the coolant pulse in the period of regulating the flow of coolant, s;
at the same time, the correction factor k _i = 0 is set at
| T _oz -T _o | <δ,
where δ is the dead zone, ° C.

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