KR101866799B1 - Method for controlling heating with temperature controller for each room and ditial direct controller in machine room of each household of group heat supply facility - Google Patents

Abstract

The present invention relates to a heating control method. When intermittent heating is performed in accordance with the intermittent heating operation cycle (Hp) without continuous operation in the machine room during the summer (including summer), when heating is performed in any household, the heating is immediately performed and the operation is performed according to the intermittent heating operation cycle (Hs) of heating for each of the households of all the households in the intermittent heating operation cycle, and then the heating start time (Hs) corresponds to the heating period and it is possible to perform heating by the heating time for each household room and to heat the household in which the heating time of the household exceeding the facility capacity that can be supplied at the time of insufficient supply of heat at the winter peak load is shortest. It is possible to efficiently supply heat even in a small heat supply facility, and the digital temperature controller in each household of the mass heat supply facility that interlocks with the digital direct controller of the machine room is interlocked so that the user can set and save the charge for this month in advance.

Description

TECHNICAL FIELD [0001] The present invention relates to a heating control method and a heating control method, and more particularly, to a heating control method in which a room temperature controller and a digital direct controller of a machine room are interlocked with each other in a collective heat supply facility,

The present invention relates to a heating control method, and more particularly, to a method of controlling heating in an arbitrary household when intermittent heating is performed in accordance with an intermittent heating operation cycle (Hp) without operating continuously in a machine room in a summer The heating of the remaining households, which are operated according to the intermittent heating operation cycle, is immediately performed by applying the heating correction time (Hm), and thereafter, the heating starts for each generation of all the households in the intermittent heating operation cycle The heating time of the generation that exceeds the facility capacity that can be supplied in the period when the amount of supplied heat is insufficient at the winter peak load is the shortest heating time Heat generation can be carried out efficiently in a small heat supply facility. It can hurry, to a thermostat and silbyeol heating control method where the direct digital controller in the machine room interlocking in each generation of the collective heat supply facilities to save the user to pre-set the rates to use for this month.

Generally, the district heating (central heating) is not economical in large-scale heat source facilities (cogeneration plant, heat-only boiler, garbage incinerator, etc.) instead of various buildings such as apartments, houses, shops, offices, schools, Is an efficient heating system that contributes to the heating and hot water supply to the entire area by using the heat generated by the heat generated by the user and creates a pleasant urban environment and contributes to energy conservation and improvement of the environment and environment. .

In other words, district heating does not have individual heating facilities such as houses, commercial buildings, offices, schools, hospitals, factories, etc. in a single city or a certain area, and a large-scale heat production facility, that is, a cogeneration power plant, (110 ° C or higher) and supplies it to each customer through a hot water pipe at a high pressure (16 bar).

On the other hand, a cogeneration system is required to utilize this district heating. A cogeneration system is a system that can produce two or more usable energy (electric energy and thermal energy) from one energy source (fuel).

On the other hand, the district heating system stores boilers that produce hot water (over 110 ° C) and surplus hot water produced by the boiler at a time when the heat load is low or the electricity sale price is high, A heat storage tank which is a hot water storage tank for daily peak load, a heat exchanger which is produced in a boiler or stores hot water stored in a heat storage tank, and a circulation pump which circulates heat-exchanged hot water at a high pressure. A circulation pump is connected to a heat transfer pipe composed of a double heat insulating and heat insulating pipe and a heat pipe to heat and recover heat to the heat supply target region through a user heat exchanger.

On the other hand, in each generation, a temperature controller is installed to control the temperature, and the temperature of each room and the living room is controlled. In the machine room of the district heating, 24-hour heating is mainly supplied. It is controlled according to each temperature.

However, there is a problem that the idling loss and the low load loss are very large because the heating is required to be supplied in an extremely low load state in the summer or summer.

In order to solve such a problem, Korean Patent Registration No. 10-1469045 filed a heating control method was filed and registered.

In the actual heating control method, when the opening of each heating valve is controlled by varying the heating start point of the room according to each heating operation signal of the room temperature controller, the heating valve is operated while matching the heating start point of the room in the next heating operation cycle So that the heating of the room can be controlled.

However, even if the actual heating control method is operated in the temperature controller of each household, if the heating time is not matched with the time of supplying the heating in the machine room, the user may not receive heating heat once a day.

Korean Patent Registration No. 10-1469045

SUMMARY OF THE INVENTION [0006] The present invention has been made to solve the above problems, and it is an object of the present invention to provide a method and apparatus for performing intermittent heating in accordance with an intermittent heating operation cycle (Hp) The heating of the remaining households, which are operated according to the intermittent heating operation cycle, is immediately performed by applying the heating correction time (Hm), and thereafter, the heating starts for each generation of all the households in the intermittent heating operation cycle The present invention provides a heating control method in which a room temperature controller and a digital direct controller of a machine room are interlocked with each other in a household heat supply facility in which heating is performed for each heating room for each household room after matching all the time points have.

In addition, the present invention relates to a system and method for controlling the temperature of a room, including a room thermostat and a room temperature controller in each household of a collective heat supply facility capable of communicating between a digital direct controller (DDC) of a machine room and a household temperature controller, Another object is to provide a heating control method in which a digital direct controller is interlocked.

In addition, the present invention relates to a heating control method in which a room temperature controller in each household of a collective heat supply facility, which calculates the outside air temperature and an expected load by time in the machine room, and a digital direct controller of the machine room are interlocked There is another purpose.

In addition, since the present invention enables heating after the generation of the shortest heating time of households exceeding the facility capacity that can be supplied at a time when the amount of supplied heat is insufficient at the peak load during the winter season, it is possible to heat efficiently in a small heat supply facility Another object of the present invention is to provide a heating control method in which a room temperature controller and a digital direct controller of a machine room are interlocked with each other in a collective heat supply facility that enables a user to set and save a fee for use in the month.

According to an aspect of the present invention,

A real heating control system including a room temperature controller (RT), a heating valve controller (VC) and a heating meter (FM) in each household to be applied to a district heating or central heating heating facility, a digital direct controller (RT) in an arbitrary generation while performing heating in accordance with an arbitrary intermittent heating operation cycle (Hp) in a method of controlling heating in accordance with an arbitrary intermittent heating operation cycle (Hp) The heating control valve is instantly opened in an arbitrary generation according to the set temperature value and the current room temperature value and the electric heating control valve is immediately opened in the digital direct controller (DDC) in cooperation with the digital direct controller (DDC) The pressure independent control valve (PICV) and the circulation pump are immediately activated, and at the same time, In order to prevent the case where the heating is immediately performed by applying the fixed time Hm and the load is all burnt in the first intermittent heating operation period Hp, The heating start time (Hs) of the actual temperature regulator (RT) of the generation exceeding the facility capacity is started at the end of the generation at which the heating is supplied at the shortest time, and the heating of the household The controller (VC) controls the actual temperature controller (RT) to measure whether a flow rate designed in communication with the heating metering system (FM) within the household is flowing, and transmits the measured flow rate to the digital direct controller (DDC) through a gateway (PICV) and the number of rotations of the circulation pump are adjusted by transferring the respective data.

In this case, Hp is the intermittent heating operation cycle, Hs is the heating start time of each generation in the previous intermittent heating cycle, and Hb is the heating time of each household according to? T.

Here, the digital direct controller (DDC) receives the ambient temperature from an external sheet of paper, calculates a required heat amount from an external server in accordance with a basic pattern of an existing heating period, and calculates the heat supply expected time and the intermittent heating operation cycle (PICV) and the circulation pump are operated in accordance with the temperature difference Δt between the indoor set temperature of the room temperature regulator (RT) in each household and the present room temperature After calculating the heating time, the heating start time (Hs) for each household is matched in the intermittent heating operation cycle (Hp), and heating is performed for each heating room for each household room.

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The room temperature controller RT calculates a calorie value to be inputted based on the outside temperature, the room temperature, and the set temperature according to the user's set monthly charge, So that the calorie value measured by the user does not exceed the initial charge.

According to the heating control method in which the room temperature controller in each household of the present invention and the digital direct controller of the machine room are interlocked, the circulation pump of the machine room is intermittently operated to reduce the power consumption and improve the energy efficiency And the maintenance cost can be reduced.

According to the present invention, it is possible to effectively operate the circulation pump flow rate in the machine room to a value that is much smaller (50% or more) than the existing design flow rate value, and the calorific value (49 psi / ), And the system efficiency is very low due to continuous operation under low load condition. By interlocking operation, it is possible to avoid low-load operation very effectively and minimize heating cost due to pipe loss can do.

According to the present invention, it is possible to heat the heating point of the generation exceeding the facility capacity that can be supplied at the time when the amount of supplied heat is insufficient at the peak load of the winter season, in the shortest heating period, And the user can set and save the charge for this month.

In addition, according to the present invention, it is possible to know quickly whether the heating meter is malfunctioning and whether the valve is malfunctioning, and it is possible to preliminarily respond to the heat demand by predictive operation according to the outside air temperature, day of week, and time zone.

1 is a block diagram showing a configuration of a heating control system in which a room temperature controller in each household of a collective heat supply facility according to the present invention is interlocked with a digital direct controller of a machine room.
FIG. 2 is a systematic diagram showing the construction of each household in a heating control system in which a room temperature controller in each household of a group heat supply facility according to the present invention is interlocked with a digital direct controller in a machine room.
FIG. 3 is a flowchart illustrating a heating control method in which a room thermostat in each household of a collective heat supply facility according to the present invention is interlocked with a digital direct controller in a machine room.
FIG. 4 is a graph showing the relationship between the operation time and the flow rate in order to lower the simultaneous load rate among the heating control methods in which the digital thermostat controller in the machine room is interlocked with the thermostatic thermostat in each household of the collective heat supply facilities according to the present invention.
FIG. 5 is a UI image showing the monthly charge and the monthly charge set by the user according to the heating control method in which the room temperature controller in each household of the collective heat supply facility according to the present invention is interlocked with the digital direct controller of the machine room.

Hereinafter, a configuration of a heating control system in which a room thermostat in each household of the collective heat supply facility according to the present invention is interlocked with a digital direct controller of a machine room will be described in detail with reference to the accompanying drawings.

In the following description of the present invention, detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

FIG. 1 is a system diagram showing a constitution of an intermittent heating control system for a local heating in accordance with the present invention, and FIG. 2 is a systematic diagram showing the constitution of each household in the intermittent heating control system for a local heating according to the present invention.

Referring to FIGS. 1 and 2, the intermittent heating control system 1 for the district heating according to the present invention is roughly divided into a machine room and each household.

First, the machine room is provided with a heat pipe L1 of a district heating and a heating heat exchanger EX connected to the primary side, a circulation pump P is installed on the secondary side of the heat exchanger EX, And connected to the user-side heat pipe (L2).

In addition, a pressure independent control valve (PICV) is installed in the user-side heat pipe (L2) connected to each of the motors. An electric combined valve (PICV) can be replaced by a differential pressure control valve (PDCV) (PICV) is applied so that it can more actively respond to the heating of the household, and the inverter type which can move the pump P more actively to the heating load is preferably applied, and the digital direct controller (DDC) (50% or more) than the existing design flow rate because it is operated according to the load according to the control of the controller.

The digital direct controller (DDC) of the machine room includes first and second temperature sensors T1 and T2 provided on the secondary side of the heating heat exchanger EX, first and second pressure sensors P1 and P2, And third and fourth temperature sensors T3 and T4 respectively installed on the side of the user side heat pipe L2 connected to the first and second pressure sensors P3 and P4 and the temperature and pressure values through the third and fourth pressure sensors P3 and P4, (PICV) and circulation pump (P) to provide a 24-hour heating mode and an intermittent heating mode. When entering the intermittent heating mode, control is passed to the room temperature controllers (RT1 to RTN) Signal.

At this time, the digital direct controller DDC receives the indoor heating temperature value Ts and the current indoor temperature value Tc from the room temperature regulators RT1 to RTN in each household, receives the outdoor temperature value from the outside, The total required heat quantity, the heat supply expected time, and the intermittent heating operation cycle (Hp) are calculated. Here, the digital direct controller (DDC) performs RS-485 communication with the room temperature controllers (RT1 to RTN) in each household or performs communication via the wired / wireless Internet and receives the outside temperature from the external sheet leaves (not shown) , A basic pattern for an existing heating cycle is received from an external district heating central server (not shown), the required heat quantity is calculated, the estimated time of heat supply and the intermittent heating operation cycle (Hp) can be calculated, It is also possible to backup operation data.

Next, the digital direct controller (DDC) operates the room temperature controllers (RT1 to RTN) by arbitrary generation users in a state in which intermittent heating is performed in accordance with the intermittent heating operation cycle (Hp) If set to a high value, heating is immediately performed to the household irrespective of the intermittent heating operation cycle (Hp), and heating is performed immediately in the existing household in the heating standby. At this time, when the electric combined type valve (PICV) and the circulation pump (P) are not operated, they are operated to perform heating.

 The digital direct controller (DDC) calculates the heat supply expected time, and then calculates the heat supply estimated time in each of the room temperature control units (RT1 to RTN) in order to prevent the load from being mixed into the first intermittent heating operation cycle (Hp) And the heating of the generation exceeding the heating start point (Hs) of the household temperature controllers (RT1 to RTN) exceeding the facility capacity at the end of the shortest generation heating is restarted and the simultaneous load ratio It is preferable to lower the temperature. In another embodiment, the digital direct controller (DDC) sequentially activates the respective electric combined valves (PICV) provided for each of the heaters in the case where heating is simultaneously performed in the household in an arbitrary intermittent heating operation period (Hp) The deficient flow rate of the circulation pump P or the limit capacity of the heating heat exchanger EX may be supplemented.

Each household is provided with a user-side heat pipe L2, a hot water distributor HD connected thereto, and a heating pipe L3 distributed to the rooms L1 through LN from the hot water distributor HD, Each heating pipe L3 is provided with heating solenoid valves V1 to VN and each of the heating solenoid valves V1 to VN is opened and closed under the control of the heating valve controller VC.

The heating valve controller VC is electrically connected to the room temperature regulators RT1 to RTN provided for each of the rooms L1 to LN and is connected between the user side heat pipe L2 and the hot water distributor HD through a heating meter FM , And the heating meter FM is electrically connected to the heating valve controller VC and transmits the measured value to the room temperature controllers RT1 to RTN. At this time, the heating valve controller (VC) in each household controls the room temperature controller (RT1 ~ RTN) and measures the flow rate designed by communication with the heating meter (FM) The data is transmitted through the gateway or wired / wireless communication, so that the opening amount of the electric combined valve (PICV) and the number of revolutions of the circulating pump (P) are adjusted to the optimum value to have the optimum flow rate value.

In addition, each of the household temperature controllers RT1 to RTN performs wired / wireless communication with a digital direct controller (DDC) through a communication terminal or a gateway.

The room temperature regulators RT1 to RTN within each household are operated in accordance with the intermittent heating operation cycle Hp provided from the digital direct controller DDC and the heating start time Hs ) Are different for each household, the heating start time Hs of each household is matched in the next intermittent heating operation cycle Hp.

In addition, the actual temperature controllers RT1 to RTN within the respective generations can calculate the heating correction time (Hm) according to Equation (1) below when the room temperature controller is operated in an arbitrary generation while performing heating according to the intermittent heating operation cycle Hp ) To apply heating immediately.

In this case, Hp is the intermittent heating operation cycle, Hs is the heating start time of each generation in the previous intermittent heating cycle, and Hb is the heating time of each household according to? T.

Next, each of the household temperature regulators RT1 to RTN communicates with a heating meter FM installed in the household, and when a failure occurs, it is transmitted to the digital direct controller (DDC) in real time so that the manager can confirm the failure , When all the water is to be drained into the pipes (L2, L3) to improve water quality in the machine room, the heating solenoid valves (V1 to VN) are all opened to drain the water regardless of the user's will.

Meanwhile, as shown in FIG. 5, the room temperature controllers RT1 to RTN of the respective households are set based on the outside temperature, the room temperature, and the set temperature in accordance with the service charge of the month set by the user The calorific value to be measured is calculated so that the calorific value measured by the heating meter (FM) within the household does not exceed the originally set rate.

Hereinafter, a method of intermittent heating control of the local heating according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 3 is a flowchart illustrating a heating control method in which a room temperature controller and a digital direct controller of a machine room cooperate with each other in a household heat supply facility according to the present invention. FIG. 4 is a flowchart FIG. 5 is a graph showing the relationship between the operating time and the flow rate in order to reduce the simultaneous load factor among the heating control methods in which the digital temperature controller of the room temperature and the digital direct controller of the machine room are interlocked. Is a UI image indicating the monthly rate set by the user and the usage rate set for this month according to the heating control method in which the digital direct controller of the machine room is interlocked.

Referring to FIG. 3, the intermittent heating control method of the local heating according to the present invention includes an intermittent heating period calculation step (S10), an immediate heating step (S20) and an intermittent heating step (S30).

"Intermittent Heating Cycle Estimation Step-S10"

First, the digital direct controller (DDC) receives the indoor heating temperature value Ts and the current indoor temperature value Tc from the household temperature controllers RT1 to RTN of each household, And calculates the total required heat quantity, the heat supply expectation time and the intermittent heating operation cycle (Hp) by using these values, and transmits the estimated heat quantity and the intermittent heating operation cycle (Hp) to each of the generation temperature controllers (RT1 to RTN) Share this information. At this time, the total required heat quantity, the heat supply expected time, and the intermittent heating operation cycle (Hp) are calculated by a general calculation method.

On the other hand, the digital direct controller (DDC) estimates the time required for the supply of heat, and then, in order to prevent the load from being all buried in the first intermittent heating operation period (Hp) And the heating of the generation exceeding the heating start point (Hs) of the household temperature controllers (RT1 to RTN) exceeding the facility capacity at the end of the shortest generation heating is restarted and the simultaneous load ratio Can be lowered.

A method for lowering the simultaneous load factor will be described in more detail with reference to FIG.

4 is a graph showing the relationship between the operation time and the flow rate in order to lower the simultaneous load factor in the intermittent heating control method of the local heating according to the present invention.

First, if the total number of A motions is 20 generations and the flow rate per generation is 6 lpm, the maximum design flow value of the electric combined valve (PICV) installed in A is 120 lpm, and when the simultaneous load ratio is 50%, the maximum design flow value is 60 lpm .

If the 13th generation starts heating, it does not matter because the first intermittent heating operation cycle Hp does not operate at the same time as shown in FIG. 4. However, when the second intermittent heating operation cycle Hp is performed, The maximum design flow value is exceeded.

Thus, when the digital direct controller (DDC) exceeds the facility capacity in the second intermittent heating operation cycle (Hp) and performs the heating for 10 generations or more, the households that start the latest heating at a relatively short heating time, The heating operation is carried out in succession to each of them.

That is, as shown in FIG. 4, the 7th generation, the 10th generation, and the 12th generation perform the latest heating in the first intermittent heating operation cycle (Hp), the 9th generation in the second intermittent heating operation cycle (Hp) Because the heating time of the eleventh generation and the thirteenth generation is the shortest, when the heating of the 9th generation is completed, the heating of the 7th generation is performed. When the heating of the 11th generation is completed, the heating of the 10th generation is performed. When the heating of the household is finished, the heating of the 12th generation is performed.

"Instant heating stage-S20"

The digital direct controller DDC operates the intermittent heating operation by operating the electric combined type valve PICV and the circulation pump P in accordance with the intermittent heating operation cycle Hp at a predetermined time interval (S21) If a household user manually sets at least one of the room temperature controllers (RT1 to RTN) and manually sets the room heating temperature higher than the current room temperature, the arbitrary temperature controller (RT1 to RTN) The heating is performed with the present point of time as the heating start point Hs of an arbitrary generation irrespective of the period Hp and the corresponding control signal is transmitted so that the heating is performed in the digital direct controller DDC (S22) The controller (DDC) operates the electric combined valve (PICV) and the circulation pump (P) so that the heating is performed immediately in a given generation, and at the same time, Thermostat (RT1 ~ RTN) performs immediately the heating by applying a heating time calibration (Hm) (S23).

That is, if the first generation A and the second generation A have requested heating before the first intermittent heating operation cycle, the first intermittent heating operation cycle Hp is performed with the same heating start time Hs .

If the heating operation is performed irrespective of the intermittent heating operation period (Hp) in the third generation A, the room temperature regulator (RT1 to RTN) of the third generation A is heated to the heating start point (Hs) (PICV) and the circulation pump (P) are operated by supplying a control signal to the digital direct controller (DDC) so that the heating water is supplied into the household, The heating is immediately supplied to the heating start point (Hs), and the heating is immediately performed by applying the heating correction time (Hm) in the first generation A and the second generation A.

Then, the actual temperature controller (RT1 ~ RTN) of A, B, and A, N, will use the shared information to determine the next heating cycle Controls heating to occur in time.

More specifically, the intermittent heating operation period Hp is set to 60 minutes, and the heating operation time is set to 1 minute at 0.1 ° C, which is the temperature difference between the indoor setting heating temperature value Ts and the current room temperature value Tc , A case where the difference in temperature difference Δt between the indoor heating temperature value Ts and the present room temperature value Tc is 0.4 ° C and the case where the difference between the average temperature difference Δt and the current room temperature value Tc is 0.2 ° C, If there is a household, the first generation calculates the amount of heat required to overcome the 0.4 ° C difference at 10 o'clock, which is the heating supply time, and determines the operating time.

In the second generation A, the amount of heat required to overcome the difference of 0.2 ° C in the heat supply time is calculated, and only the necessary operation time is heated. At this time, if households A and B are heating loads under the same conditions, the difference in heating supply time will be doubled.

That is, the room temperature regulators RT1 to RTN within the first generation A are opened so that the room heating electromagnets V1 to VN are opened in accordance with the intermittent heating operation period Hp, Assuming that the temperature difference? T of the present room temperature value Tc is set to 0.1 minute and the heating operation time is set to 1 minute, if? T is 0.4 占 폚, the heating start time Hs in the intermittent heating operation period Hp The heating solenoid valves 1 to N (V1 to N) are opened at 10:00 and heating is continued. After 4 minutes by Δt 0.4 ° C, the heating solenoid valves 1 to N (V1 to N) are closed to stop heating.

In addition, the actual temperature controllers (RT1 to RTN) within the second generation A are connected to the heating solenoid valves 1 to N (V1 to NN) at the time of starting the heating (Hs) at the intermittent heating operation period (Hp) N) is opened and heating is continued. After 2 minutes by Δt 0.2 ° C, the heating solenoid valves 1 to N (V1 to N) are closed to stop heating.

On the other hand, if at least one of the actual temperature controllers (RT1 to RTN) in the third generation of A is delivered to the heating valve controller (VC) at 10:20, (A) and (B), the heating control valves (RT1 to RTN) of the third generation (A) of the third generation generate the heating solenoid valves 1 to N (V1 to NN) at 10:20 with the current time not the intermittent heating operation cycle (Hp) N), the corresponding heating solenoid valve is opened, and the heating operation is started for 5 minutes by Δt 0.5 ° C.

Assuming that Δt is 0.3 ° C as a result of an artificial heating operation signal transmitted to the heating valve controller (VC) at 10:40 in at least one of the room temperature controllers (RT1 to RTN) (A) and (B), respectively, the temperature control devices (RT1 to RTN) of the (A) and (N) generations change the current time from the intermittent heating operation period (Hp) to the heating start time N), the corresponding heating solenoid valve is opened, and the heating is operated for 3 minutes by? T 0.3 ° C.

In this case, the households A and B generate heat at the heating start time (Hs) of 10 seconds at the intermittent heating operation cycle (Hp) and then terminate the heating at 4 and 2 minutes, respectively, The heating starts at the heating start point (Hs) at 11 o'clock for another 4 minutes for 2 minutes. However, the third generation A starts heating at the heating start point (Hs) regardless of the intermittent heating operation period (Hp) After heating for 5 minutes at 10:20, heating is continued for 5 minutes at 11 o'clock, which is the heating start point (Hs), in the next intermittent heating operation cycle (Hp) The disaster room starts in a quick 35 minutes, and the household No. A is heated for 3 minutes at 10:40 regardless of the intermittent heating operation cycle (Hp), then 17 minutes (43 minutes) for the next intermittent heating operation cycle The disaster room begins.

In this case, when heating is controlled for each household, normal heating is performed according to Δt in the case of generation 1 and generation 2 of generation A. However, There is a risk of overheating.

Accordingly, in the present invention, when the third generation A starts heating, the heating correction time (Hm) for each household is adjusted in consideration of the heating start time (Hs) in the first generation A and the second generation A, The heating correction time (Hm) for each household is calculated taking into consideration the heating start time (Hs) in household A, household A, household A 2 and household A 3, ) To perform heating immediately.

More specifically, the first generation A and the second generation A generate heat for four minutes and two minutes, respectively, at a heating start time (Hs) of 10 at an intermittent heating operation cycle (Hp) , And the third generation of building A performs heating, the heating correction time (Hm) is calculated and the heating is performed immediately.

In other words, when the intermittent heating operation cycle is Hp, and the heating start time for each household in the previous intermittent heating cycle is Hs and the heating time for each household according to? T is Hb, The heating correction time Hm for each household during the intermittent heating operation cycle is calculated.

When the above equation is applied to each generation, when the intermittent heating operation cycle (Hp) is 60 minutes,

In the case of household A,

Assuming that the heating start time Hs of the previous heating operation cycle Hp is 0 and Δt is 0.4 ° C., since the heating time Hb for each household is 4 minutes, the heating of the next intermittent heating operation cycle Hp Since the correction time Hm is 4 minutes, the heating solenoid valves 1 to N (V1 to N) are opened at 10:20, which is the heating start point of the third generation A, and heating is started 4 minutes later, ~ N (V1 ~ N) are closed and heating is terminated.

In the case of household No. 2 A,

Assuming that the heating start time Hs of the previous heating operation cycle Hp becomes 0 and Δt is 0.2 ° C., since the heating time Hb of each generation is 2 minutes, the heating of the next intermittent heating operation cycle Hp The heating solenoid valves 1 to N (V1 to N) were opened at 10:20, the heating start time point of the third generation of the same household A, and the heating was started 4 minutes later, the heating solenoid valve 1 ~ N (V1 ~ N) are closed and heating is terminated.

On the other hand, an atmospheric heating operation signal is transmitted to the heating valve controller (VC) at 10:40 in at least one of the room temperature controllers (RT1 to RTN) (RT1 ~ RTN), the current time is not the intermittent heating operation period (Hp) but the heating start time (Hs) is 10:40 The corresponding heating solenoid valve among the heating solenoid valves 1 to N (V1 to N) is opened, and the heating is operated for 3 minutes by? T 0.3 ° C.

Then, the room temperature controller (RT1 ~ RTN) within the 1st to 3rd generation of A calculates the heating correction time (Hm) and performs heating immediately.

In the case of household A,

Assuming that the heating start time Hs of the previous heating operation cycle Hp is 20 and Δt is 0.4 ° C, the heating time Hb of each generation is 4 minutes, so that the heating of the next intermittent heating operation cycle Hp Since the heating time (Hm) is 2.6 minutes, the heating solenoid valves 1 to N (V1 to N) are opened at 10:40 of the heating start time of the No. N household, ~ N (V1 ~ N) are closed and heating is terminated.

In the case of household No. 2 A,

Assuming that the heating start time Hs of the previous heating operation cycle Hp is 20 and Δt is 0.2 ° C., since the heating time Hb of each generation is 2 minutes, the heating of the next intermittent heating operation cycle Hp Since the correction time (Hm) is 1.3 minutes, the heating is started while the heating solenoid valves 1 to N (V1 to N) are opened at 10:40, which is the starting point of heating of the No. N household, ~ N (V1 ~ N) are closed and heating is terminated.

In the case of the third generation of building A,

Assuming that the heating start time Hs of the previous heating operation cycle Hp is 20 and Δt is 0.5 ° C., since the heating time Hb for each household is 5 minutes, heating of the next intermittent heating operation cycle Hp Since the correction time (Hm) is 3.3 minutes, the heating is started while the heating solenoid valves 1 to N (V1 to N) are opened at 10:40 of the heating start time of the No. N household, and after 3.3 minutes, ~ N (V1 ~ N) are closed and heating is terminated.

"Intermittent Heating Phase-S30"

In this state, the digital direct controller (DDC) controls the electric combined valve (PICV) and the circulation pump (P) to supply and recover the district heating water to the next intermittent heating operation cycle (Hp) And if another arbitrary generation user sets the room heating temperature higher than the current room temperature by manually operating at least one of the room temperature regulators RT1 to RTN among the room temperature controllers RT1 to RTN, (S20). If there is no manual operation, the intermittent heating step S30 is performed.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It is to be understood, however, that the invention is not to be limited to the specific forms thereof, which are to be considered as being limited to the specific embodiments, but on the contrary, the intention is to cover all modifications, equivalents, and alternatives falling within the spirit and scope of the invention as defined by the appended claims. .

DDC: Digital Direct Controller EX: Heat Exchanger
HD: Hot water dispenser L1: Heat pipe for district heating
L2: User side heat pipe L3: Heating pipe
FM: Heating meter P: Circulation pump
P1 to P4: Pressure sensors 1 to 4 PICV: Electric combined valve
RT1 ~ RTN: Room temperature controller T1 ~ T4: 1st ~ 4th temperature sensor
V: Heating solenoid valve VC: Heating valve controller

Claims (4)

A real heating control system including a room temperature controller (RT), a heating valve controller (VC) and a heating meter (FM) in each household to be applied to a district heating or central heating heating facility, a digital direct controller (DDC) interlocked with each other to control heating according to an arbitrary intermittent heating operation cycle (Hp)
(RT) is operated in an arbitrary generation while performing heating according to an arbitrary intermittent heating operation cycle (Hp), the corresponding heating electric motor valve is instantaneously changed in accordance with the set temperature value and the current room temperature value (DDC) immediately operates a pressure independent control valve (PICV) and a circulation pump in conjunction with the digital direct controller (DDC) of the machine room. At the same time, The heating correction time Hm according to the following equation is applied to the generation to immediately perform the heating and to prevent the case where the loads are all buried in the first intermittent heating operation cycle Hp, (Hs) of the actual temperature controller (RT) of the generation exceeding the facility capacity by sharing with the room temperature regulator (RT) within each household is the shortest A heating valve controller (VC) in each of the households controls the room temperature controller (RT), and communicates with the heating meter (FM) within the household (PICV) and the number of revolutions of the circulation pump by adjusting the flow rate of the circulation pump by measuring the flow rate of the designed flow through the gateway and the wired / wireless communication to the digital direct controller (DDC) A heating control method in which a room thermostat in each household of a collective heat supply facility is interlocked with a digital direct controller in a machine room.

In this case, Hp is the intermittent heating operation cycle, Hs is the heating start time of each generation in the previous intermittent heating cycle, and Hb is the heating time of each household according to? T. The method according to claim 1,
The digital direct controller (DDC)
Calculates a required heat amount to be received from an external server and estimates the heat supply expected time and the intermittent heating operation cycle Hp, The heating time is calculated for each household according to the temperature difference Δt between the indoor set temperature of the room temperature regulator RT and the current room temperature in each of the generations, and then the intermittent heating operation cycle (Hs) of each household is matched in each household room, and then heating is performed for each heating room for each household room. The digital temperature controller of each household and the digital direct controller of the machine room Interlocked heating control method. delete The method according to claim 1,
The room temperature regulator (RT)
The calorific value to be inputted based on the outside temperature, the room temperature and the set temperature is calculated according to the user's set fare for the month, and the calorie value measured by the heating metering (FM) Wherein the temperature controller in each household of the group heat supply facility is interlocked with the digital direct controller of the machine room.

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