CZ176796A3 - Method of pulse regulation of heating and apparatus for making the same - Google Patents

Abstract

This method of the pulse regulation of heating is used mainly for regulating distance or local warm-water heating of buildings. The nature of this method is based on the fact that first of all in the introductory time section of the heating (testing regime) - from the beginning of heating up to the moment tm1 - the heating medium is continually supplied while keeping a constant temperature difference (Tn) in the leading branch and the temperature (Tv) in the reverse branch of the heating conduit and in the tm1 time the outside temperature (Ta) is measured in the surrounds of the heated building and the temperature of the heating medium - temperature (Tn) in the leading branch and temperature (Tv) in the reverse branch of the heating conduit. On the basis of results of these measurements the regulating radius (Rp1) is stated for the first cycle of the regulating regime and this regulating ratio should be in the interval 0 to 1 and is increased with a decrease of the outside temperature (Ta) and temperature (Tn, Tv) of the medium. Then the supply of heating medium into the leading branch of the conduit is interrupted and its further supply is performed in its own regulating regime - non-continuously in time periods. At the moment (tmi) of the termination of each of these periods there is a repeated measurement of the value of the outside temperature (Ta) in the surrounds of the heated building and the temperature of the heating medium - temperature (Tn) in the leading branch and temperature (Tv) in the reverse branch of the heating conduit and on the basis of the measured values using the same principle as for the initial heating time interval a new regulating ratio (Rpi + 1) is stated which will influence the time of the heating next period (t0i+1), i.e. the time after which the heating medium delivered into the leading branch of the conduit and/or the time of the interruption of the supply of the heating medium after this period stated by the time difference <IMAGE>, where tr+1 is the total time of i+1 regulating cycle which includes the respective period of heating and the time of interruption of the supply of the heating medium to the leading branch of the conduit.

Description

Method of pulse heating control and apparatus for carrying out this

buildings (dwelling houses, apartments, office space, business premises, etc.). The invention also relates to an apparatus for carrying out this method.

BACKGROUND OF THE INVENTION

Several methods of heating control are currently known. In the case of district heating, this is primarily a dispatching system for district heating control based on the equithermal regulation of the heating water temperature in the heat exchanger stations. Since the heat exchanger station does not normally receive feedback on the actual heat demand in the individual heating objects connected to it, this control method often causes unnecessary overheating of these objects, resulting in unnecessarily high energy consumption. At present, it is technically and financially demanding to solve this deficiency by remote transmission of information about the actual state of the heated buildings to the heat exchanger stations.

The way of regulation of heating, which takes into account the actual state in the heated buildings, is eg equithermal (continuous) regulation with the help of so called object transfer stations. In the case of local heating, the principal equivalent of the latter method of control is the classical continuous heating water regulation. A more technically complex and sophisticated way of control is adaptive continuous equithermal heating control.

A common drawback of the known methods of heating regulation (whether remote or local) is their not always sufficient possibility to optimize heating in terms of the most efficient use of consumed thermal energy. For example, in the current regulation methods it is difficult to suppress the influence of the distance of the heated object from the source and to take into account the influence of the thermal insulating properties of the heated object.

SUMMARY OF THE INVENTION

The pulse control method of the present invention contributes to overcoming the above drawbacks of the known heating control methods. It is a method of regulation designed especially for hot-water district or local heating of buildings, which is based on the fact that first - in the initial heating period (in test mode) the heat transfer medium is continuously supplied while maintaining constant difference between its flow temperature and flow temperature. in the return branch of the heat pipe. At the time of termination of this initial heating section (test mode), the outdoor temperature around the heated object and the temperature of the heat transfer medium - flow temperature and return flow temperature are simultaneously measured. Based on the results of these measurements, the control ratio for the first control mode cic is determined, the control ratio being in the range of 0 to 1 and the higher the lower the outdoor and medium temperatures. Thereafter, the heat transfer medium supply to the hot-water supply line is interrupted and its further supply to it is performed in its own control mode.

- discounted in time periods, at which time the outdoor temperature around the heated object and the temperature of the heat transfer medium are repeatedly measured at the end of each of these periods

- flow temperature and return flow temperature. On the basis of the measured values, a new control ratio is determined by the same principle as after the initial heating period, on which the time of the next heating period, ie. the time during which the heat transfer medium is supplied to the hot-water flow branch and / or the time of interruption of the heat transfer medium supply after this period.

Accordingly, the heating control method according to the invention may have two preferred more specific variants. In the first one, the time of the i-th heating period (toi) in the control mode is determined as a function to i = Rp i. tr, where Rpi is the control ratio, determined on the basis of the outdoor temperature (Ta) around the object to be heated and the temperature of the heat transfer medium - the flow temperature (T _n ) and the flow temperature (T _v ) measured at the moment. i at the end of the previous i-1 heating period and t _r is the control cycle time constant throughout the control period.

In this variant of the control method according to the invention, the time of interruption of the supply of the heat transfer medium after the i-th heating period is given by the edge of the heating element.

In the second variant of the control method according to the invention, during each of the heating periods in the control mode, the flow temperature (Tn) in the flow branch and the flow temperature (T _v ) in the flow return line are continuously measured and their variation <5 (T _n - T _v ). The time of each of the heating periods (toi) is then limited by the moment when the magnitude of this change á (Tn-Tv) = O. At this time (t _m i) the outdoor temperature (T _a ) values around the heated object and the heat exchange temperatures are measured. medium - temperatures (T _n ) in the flow line and temperatures (T _v ) in the return line of the heat pipe to evaluate the control ratio Rpi + i for the next control cycle. At the same time, the supply of the heat transfer medium to the hot-water branch of the hot-water pipeline is interrupted for a period of time determined by (1-Rpi) .toi, which is followed by an i + 1 control cycle.

A control system for the control of the controller by means of which the inputs of the outdoor temperature sensor in the vicinity of the heated object and the temperature sensor of the heat transfer medium - namely the flow temperature of the heat transfer pipe and the temperature in the return flow pipe. The regulator output is connected in the control circuit of the three-way valve actuator, which is mounted in the flow line of the heat pipe, at the point where the overflow pipe leading to the flow pipe of the heat pipe is connected to this flow line.

A regulating valve can be installed in the overflow pipe to hydrodynamically balance the heating system or the heating system. When the heating medium is discharged from the flow branch directly into the method according to the invention, return temperature sensors are connected to the heating circuit. from the point of view of the control mode in the mode of interruption of the supply of medium to the flow branch of the heat pipe leading to the heated object.

The control system can also be equipped with an air temperature sensor in the heated object, connected to the controller input and possibly with time-dependent temperature setting elements during the weekly cycle.

The main benefit of the pulse heating method according to the invention and the associated control system is the highly efficient optimization of the heating of individual buildings in district heating regardless of the distance of the building from the heat source (heat exchanger stations). Another, no less substantial benefit of the method according to the invention is the possibility of taking into account the thermal insulation properties of the heated object.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a control system for performing the pulse control method of the present invention;

Fig. 2 - time course of pulse heating control with constant control period;

Fig. 3 - Time course of pulse heating control with variable control period.

DETAILED DESCRIPTION OF THE INVENTION

Example 1 (pulse heating control with constant cycle time) - the course of the control cycle is shown in Fig. 2.

In this variant of the pulse heating control method according to the invention, the heat transfer medium - water is continuously fed in continuously during the initial heating period (test mode) - from the start of heating up to the time tmi - while maintaining a constant difference in its flow temperature T _n and T _v in the return line 2 of the heat pipe (see Fig. 1)

At time tmi, the outdoor temperature Ta in the vicinity of the heated object and the water temperature are simultaneously measured - the temperature Tn in the inlet branch and the temperature T _{in the} return branch of the heat pipe. On the basis of the results of these measurements, the control ratio Rpi for the first control mode cic is determined, the control ratio being in the range of 0 to 1 and the higher the lower the outdoor temperature Ta and the temperatures Tn, Ty medium i.

At the same time, the water supply to the hot-water supply line 11 is interrupted and its further supply to the hot-water supply line 1 is then carried out already in its own control mode - discounted in time periods. At the time tm of each of these periods, the outdoor temperature Ta in the vicinity of the heated object and the water temperatures Tn in the inlet branch 1 and in the return temperature 2 of the heat pipe are repeatedly measured and based on the measured values. of the heating section is determined by the new control ratio Rpi + i.

The time of the following heating period toi + i, ie. the time during which water is supplied to the flow line 7 of the hot-water duct is determined as a function of i + 1 = Rpi + i .tr, where Rpi + i is the control ratio determined based on outdoor temperature Ta in the vicinity of the heated object and water temperatures ie. the temperature Tn in the inlet branch 1 and the temperature T _{in the} return branch 2 of the heat pipe, measured at the time tmi at the end of the preceding, i.e., the heating period and tr, is the control cycle period time constant throughout the control.

The time of interruption of the water supply to the flow line t_ after i_ + 1 of the heating period is given by the difference i.

The same method of heating control is then applied in other periods of the control cycle.

Example 2 (pulse heating control with variable cycle cycle time) - the cycle of the control cycle is shown in Fig. 3.

In this variant of the pulse heating control method according to the invention, as in the previous variant according to example 1, the heat exchange medium - water is continuously fed in continuously during the initial heating period (test mode) - from the start of heating to the moment tmi - while maintaining a constant difference. temperature Tn in the flow line 1 and temperature Tv in the return line 2 of the hot water pipe (see Fig. 1)

At time tmi, the outdoor temperature Ta in the vicinity of the object to be heated and the water temperature are simultaneously measured - the temperature Tn in the inlet branch 7 and the temperature Tv in the return branch 2 of the heat pipe. Based on the results of these measurements, the control ratio Rpi for the first control mode cic is determined, again, the control ratio being in the range of 0 to 1 and the higher the lower the outdoor temperature Ta and the temperature Tn, Ty of the medium.

At the same time, the water supply to the hot-water supply line 7 is interrupted and its further supply to the hot-water supply line 1 is then carried out in its own control mode - discounted in time periods. At the end of each of these periods, outdoor temperature Ta in the vicinity of the heated object and water temperatures - temperature T _n in the flow branch 1 and temperature Tv in the return branch 2 of the heat pipe are repeatedly measured and then based on the measured values the new regulation ratio Rpi + i.

In contrast to the variant in Example 1, during each of the heating periods in the control mode, the flow temperature Tn in the flow line 7 and the water temperature Tv in the flow return line 2 are continuously measured and the change in their difference α (Tn-Tv) is evaluated.

The time of each of the periods of heating toi is then limited by the moment the magnitude of this change

S (Tn-Tv) = 0.

At this point tmi, the outdoor temperature Ta in the vicinity of the heated object and the water temperature Tn in the flow branch are measured.

1. and the temperatures Tv in the return line 2 of the heat pipe to evaluate the control ratio Rpi + i for the following control cycle.

At the same time, the water supply to the hot-water supply line 7 is interrupted for a period of time determined by the formula (1-Rpi). After this time has elapsed, a controlled + 1 period of the control cycle follows.

Example 3

The control system (see Fig. 1) for carrying out the method according to the previous two examples consists of a controller R, the inputs of which are connected temperature sensors, namely an outdoor temperature sensor Ta environment around the heated object, and water temperature sensors - specifically temperature T _n and the temperature Tv in the return branch 2 of the heat pipe.

The output of the regulator R is connected in the actuator control circuit S of the three-way valve Vt, which three-way valve Vt is mounted in the flow line 7 of the heat pipe, at the point where the transfer line 3 is connected to this flow line 3.

A control valve V _r can be mounted in the overflow pipe 3 for hydrodynamic balancing of the heating system. of the heating circuit when the heating medium is transferred from the flow line 7 directly to the return line 2.

The control system can also be equipped with an air temperature sensor in the heated object, connected to the inlet of the controller R and possibly also temperature-dependent elements during the weekly cycle.

Regarding the function of the control system, two basic modes of operation can be defined in accordance with the requirements of the above-described pulse control method according to the invention:

1) in heating mode, the three-way valve Vt is opened in the direction of the flow line 1 of the hot water line, the heated water passes in the direction A from the heat source through the flow line 7 of the hot water line to the heated object and returns back to the flow line 2;

2) in the mode of interruption of heating (interruption of hot water supply to the heated object), on the other hand, the three-way valve Vt closes the inlet branch 7 and the hot water passes through the overflow pipe 3 (in direction B) directly to the return line 2 of the hot water pipeline without entering the heated object.

The setting of the functional element of the control system - three-way valve Vt is controlled via the actuator S with the regulator R depending on the data of the temperature sensors and the respective variant of the control method.

Claims (6)

Claims 9 6. L Z l 01500 ΐ κ i fr fr o • f’3 A method of pulse heating control, in particular a hot-water or district heating of buildings, characterized in that the heat exchange medium is continuously fed continuously in the initial heating period (test mode) - from the start of heating to the moment of tmi - while maintaining a constant the difference in temperature (Tn) in the inlet branch and the temperature _(T) in the return flow, heat pipe, and then the time TMI simultaneously measured outside temperature (Ta) in the vicinity of the heated object and the heat transfer medium - temperature (T _n) in the inlet branch and temperature (T _v ) in the return line of the heat pipe, based on the results of these measurements, determine the control ratio (R _P i) for the first control cycle cic, this control ratio being in the range of 0 to 1 and the higher the the outside temperature (T _a ) and the temperature (T _n , T _v ) of the medium are lower, then the heat exchanger interruption of the heat pipe and its further feeding into it is then carried out in its own control mode - discontinuously in time periods, while at the moment (tmi) of each of these periods repeatedly measured outdoor temperature (Ta) around the heated object and temperature of the heat transfer medium - temperature (T _n ) in the flow branch and temperature (T _v ) in the return branch of the hot-water pipeline and based on the measured values the new regulation ratio (Rpi + i) then either the time of the next heating period (toi + ι) depends directly, ie. the time for which the heat transfer medium is supplied and / or the time of interruption of supply to the heat transfer medium heat transfer duct after this period, determined by the time difference t ^ + i- toi + i, where t _r + i is the total time i + 1 of the control cycle, including the respective heating period and the time of interruption of the heat transfer medium supply to the hot-water flow branch. Method according to claim 1, characterized in that the period of the i-th heating period (i) in the control mode is determined as a function of ΙΟ toi = Rpi.t _r , where Rpi is the control ratio based on the outdoor temperature (Ta) around the object to be heated and the temperature of the heat transfer medium - the flow temperature (Tn) and the flow temperature (T _v ) measured at the time tai-i at the end of the previous, including _1-year period of heating at the time of the regulatory cycle, constant throughout the regulation and that the time of interruption of the heat exchange medium after the ith heating period is the difference t _r - even Method according to claim 1, characterized in that during each of the heating periods in the control mode, the flow temperature (Tn) in the flow branch and the flow temperature (T _v ) in the flow return line are continuously measured and the change in their difference á is evaluated. (Tn-Tv), where the time of each of the heating periods (to i) is limited to the moment when the magnitude of this change <5 (T _n -Tv) = 0, at which time (tni) the outdoor temperature (Ta) is then measured. ) around the heated object and temperatures of the heat transfer medium - temperature (T _n ) in the flow branch and temperature (T _v ) in the return branch of the heat pipe to evaluate the control ratio Rpi + i for the next control cycle and time elapsed from (1-Rpi) .toi, followed by an i + 1 controlled cycle in the same manner. A control system for carrying out the method according to claim 1, characterized in that it comprises a controller (R), to the inputs of which temperature sensors are connected, i.e. an ambient temperature sensor (Ta) of the environment in the vicinity of the heated object. in particular, the temperature (T _n ) in the flow line (1) of the heat pipe and the temperature (T _v ) in the return line (2) of the heat pipe and whose output is connected in the actuator control circuit (S) of the three-way valve (Vt); ) is mounted in the flow line (1) of the heat pipe, at the point where the flow line (3) is connected to this flow line (1), leading to the return line (2) of the heat pipe. Control system according to claim 4, characterized in that an air temperature sensor (Tp) in the heated object is further connected to the input of the controller (R). Control system according to claim 4, characterized in that a control valve is mounted in the transfer line (3)