KR101766310B1 - Revision control method of heating calorie using flexible cycle - Google Patents

Abstract

The present invention relates to a method for correcting and controlling heating heat quantity by a fluidic repetition period. The method comprises: a heating operation period correcting step; a chamber target heat quantity value correcting step; and a heating operation time correcting step. According to the present invention, various internal and external changes are reflected in real time, and thus an optimal heating environment can be set. Also, overheating can be prevented therethrough. At the same time, unnecessary energy consumption can be minimized.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a control method for heating calorie correction,

The present invention relates to a heating calorie correction control method by a fluid repetition cycle, and more particularly, to a heating calorie correction control method for controlling a heating calorie correction control method, The present invention relates to a heating calorie correction control method using a fluid repetition period, which is configured to achieve optimal heating by reflecting various changes such as a temperature change of a heating water.

Generally, the heating method is classified into an individual heating method and a district heating method according to a production method of a heat source. The individual heating method is to heat by individual boilers installed by households (households) Or a heat source produced in a batch by a heat production facility of a certain scale is supplied to a multi-family housing or a large-scale building in a certain area to be heated.

In the following Patent Document 1, the temperature at which the hot water distributed through the distribution port of the hot water distributor is circulated and recovered is sensed, the flow rate is corrected by the difference, and the recovered temperature is made to agree with each other. A method and a system for providing uniform heating of each room so as to prevent a difference in heating effect from occurring in each room and to keep the heating of each room at a uniform temperature and a hot water distributor.

In the following Patent Document 2, the heating flow rate of each of the rooms is supplied differently in consideration of the length of the heating pipes of the respective rooms, so that the heating is performed uniformly (to reach the set temperature at substantially the same time when the set temperatures are the same) A heating control method of a heating system is disclosed.

However, the above-mentioned conventional technology is merely configured to compensate the flow rate according to the recovery temperature of the heating water, or to supply the heating flow rate differently according to the length of the heating pipe of each room, thus failing to adequately reflect various internal and external conditions .

Particularly, the above-described conventional technology does not include the concept of the heating operation cycle and the heating operation time, which substantially control the heating of each room, and thus it is not practical.

Patent Registration No. 10-0613167 (Method and system for providing uniform heating of each room and hot water distributor) Patent Registration No. 10-0767430 (Heating Control Method of Heating System)

SUMMARY OF THE INVENTION The present invention has been made in order to solve the problems of the prior art described above, and it is an object of the present invention to provide an air conditioner, And an object of the present invention is to provide a heating calorie correction control method by a fluid repetition period configured to calculate an optimum heating operation cycle and a heating operation time after calculating a target calorie value and a flow rate value.

In order to achieve the above object, according to the present invention, the heating operation cycle (Pn) is controlled by the temperature difference (Dtmax) between the set temperature (Ts) and the present temperature maximum value (Tcmax) while operating according to the initial input value of the heating operation cycle Pn) by increasing or decreasing an initial input value of the heating calorie correction control unit.

The present invention is characterized in that the temperature difference Dt between the set temperature (Ts) and the present temperature (Tc) = the calorimetric number (Mn) in accordance with the room temperature change characteristic of each side of each pipe length (Rn) Qn is inversely proportional to the room temperature change rate [Delta] Te calculated for each heating cycle.

Further, the present invention is characterized in that the present invention is characterized in that the flow rate value Ln of the cubic heating pipe length Rn and the opening amount Vn of the electric driver x the temperature difference Wn of the heating water x the heating time Tm = , And then compares the target heating value Qn with the target calorie value Qn to correct the heating operation time Tn for each heating cycle.

The present invention configured as above can provide an effect of setting an optimal heating environment by reflecting various internal and external changes in real time, preventing heating overheating and minimizing unnecessary energy consumption do.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1. Initial input values

The temperature difference Dt between the set temperature Ts and the present temperature Tc and the set temperature Ts and the present temperature Tc and the initial input value Default are inputted in the respective temperature regulators. Since the initial input value (Default) differs from the actual value and is a value for calculating the rate of change of the flow rate value or controlling the amount of heat to be supplied proportionally, an empirical method, a means for deriving a predicted or expected result value As shown in FIG.

2. Calibration of each heating heating cycle (Pn)

The correction value of the heating operation cycle Pn is a value that changes depending on the thermal inertia characteristic of the cubic structure. The correction value of the heating operation cycle Pn is a characteristic that the current temperature Tc is increased or decreased according to the deviation of the current temperature Tc by the thermal inertia after reaching the set temperature Ts Lt; / RTI >

In other words, the heating operation period Pn of the room in which the temperature deviation is severe is set so as to be shorter than the initial input value, and the value is retained if the variation is the same.

Temperature difference (Dtmax) = Set temperature (Ts) - Present temperature maximum value (Tcmax)

At this time, the heating operation cycle is set to be increased or decreased according to the respective temperature difference Dtmax. When the temperature difference Dtmax increases, the temperature difference Dtmax is corrected so as to be shorter than the initial input value of the heating operation cycle. Becomes smaller than the initial input value of the heating operation cycle.

For example, when the initial input value of the heating operation period Pn is input as 60 minutes when the temperature difference Dtmax is 0 ° C, when the temperature difference Dtmax is increased to 2 ° C, the heating operation period is 60 minutes For example, 36 minutes reduced by 4 minutes.

3. Correction of each target calorie value (Qn)

(1) The target calorie value Qn of each square = the pipe length Rn of each square x the calorimetric value Mn according to the room temperature change characteristic x the temperature difference Dt,

Here, the temperature difference Dt is a temperature difference value between the set temperature Ts of the room temperature regulator and the present temperature Tc.

The calorimetric number Mn according to each room temperature change characteristic is configured to have a characteristic of being added or subtracted in accordance with each temperature change state.

In other words, in a well-heated room, the calorimetric number (Mn) according to the room temperature change characteristic of each room becomes smaller than the initial input value. In a room where heating is not good, the calorimetric coefficient (Qc) .

At this time, the calorimetric number (Mn) according to each room temperature change characteristic is stored in the memory, and if the same amount of change is the same, the initial input value is maintained.

For example, if the pipe length Rn of each side is 10, the temperature difference Dt is 0.4 占 폚, and the calorimeter number Mn according to the room temperature change characteristic is 5, the target calorific value Qn of each side is Can be calculated together.

       Qn = 10 x 5 x 2 = 100 (Kcal)

(2) Each target calorie value Qn set in proportion to the temperature difference Dt is corrected so as to be increased or decreased in accordance with the room temperature change state in each heating mode.

In other words, in the present invention, by using the temperature difference between the preheating temperature value Tcb and the post-heating temperature value Tca and the room temperature change rate? Te calculated from the ratio of the heating operation time Tn, The target calorie value Qn of the target value Qn is corrected.

It is necessary to decrease the target calorie value Qn for each of the rooms because the temperature value Tca after the heating operation increases as the calculated room temperature change rate? Te is larger. On the other hand, It is necessary to increase the respective target calorie value Qn since the temperature value Tca after the heating operation does not change as the temperature difference Te decreases.

Therefore, the target calorie value Qn for each of the rooms is adjusted in such a manner that it is inversely proportional to the room temperature change rate? Te of each room.

4. Calculation of flow rate value (Ln)

Each flow rate value Ln is determined by the heating pipe length Rn of each side and the opening amount Vn of the electric actuator.

The flow rate value Ln of each square = the heating pipe length Rn of each square X the opening amount Vn of the electric actuator

And calculates the flow rate values Ln of the respective chambers from the respective flow rates.

5. Correction of the target calorie value (Qn) reflecting the outside temperature

The target calorie value Qn calculated based on the initial input value of the outside air temperature is set so that it can be corrected when the actual outside air temperature To is reflected. When the actual outside air temperature To is lower than the initial input value of the outside air temperature And is corrected so as to increase when the actual outside temperature To is higher than the initial input value of the outside air temperature.

6. Calibration of the heating operation time (Tn)

The target calorie value Qn = the heating operation time Tn x the flow rate value Ln of each square x the temperature difference Wn of the heating water,

The heating operation time Tn = the target calorie value Qn / the flow rate value Ln of each square times the temperature difference Wn of the heating water.

However, the temperature difference Wn of the heating water is the temperature difference between the heating water supply temperature of the main pipe and the heating water recirculation temperature of each side.

Meanwhile, in the present invention, the accumulated heat quantity Cn is calculated at a constant time interval during the heating operation and is compared with the set target heat quantity value Qn to increase or decrease the set heating operation time Tn.

The cumulative amount of heat input Cn = the flow rate value Ln of each square × the temperature difference Wn of the heating water times the heating time Tm,

The heating time Tm means the heating accumulation time from the heating start time to the instant when the accumulated heat amount Cn is calculated during the set heating operation time Tn.

The accumulated heat amount Cn calculated from the above equation means the heating heat amount input into each room during the heating time Tm.

At this time, if there is no difference in the amount of heat between the target calorie value Qn and the accumulated heat amount Cn, or if the negative value is calculated, the heating operation is immediately stopped regardless of the set heating operation time Tn , And the heating operation time (Tn) is corrected by the difference of the heat quantity when the difference in the amount of heat is calculated as the (+) value.

Further, if the target calorie value Qn is corrected to reflect the actual outside temperature, the heating operation time Tn is corrected to increase or decrease according to the corrected target calorie value Qn.

In addition, the heating operation time Tn is changed by the temperature difference Wn of the heating water according to the change of the length of the heating pipe, and the heating operation time is automatically changed due to the change of the flow rate value depending on the opening and closing of each valve.

Although the present invention has been described in connection with certain exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments.

Therefore, it should be understood that the practical scope of the present invention should not be limited by the above-described embodiments, but should be determined by the constitution equivalent to the claims, as well as the claims described below.

Claims (4)

The initial input value of the heating operation period Pn is increased or decreased by the temperature difference Dtmax between the set temperature Ts and the present maximum temperature Tcmax while operating in accordance with the initial input value of the heating operation cycle Pn, A heating operation cycle correction step of operating the heating operation cycle;
The temperature difference Dn between the set temperature Ts and the present temperature Tc = the target heat quantity value Qn for each side A target calorie value correcting step of correcting the target calorie value Qn so as to be inversely proportional to the room temperature change rate? Te calculated during heating;
The temperature difference Wn of the heating water times the heating time Tm = the amount of heat input cumulative value Cn calculated by the cubic flow amount value Ln by the cubic heating pipe length Rn and the opening amount Vn of the electric driver A heating operation time correcting step of correcting each heating operation time Tn by comparing the input heat quantity accumulated value Cn with each target heat quantity value Qn;
Wherein the heating calorie correction control method comprises: delete The method according to claim 1,
If the actual outside temperature To is lower than the initial input value of the outside air temperature, the target calorie value Qn is corrected so that the target calorie value Qn is increased And if the actual outside temperature To is higher than the initial input value of the outside air temperature, the target calorie value Qn is corrected so as to decrease. delete