METHOD FOR CONTROLLING HEATING APPARATUS

Description

TECHNICAL FIELD

The present invention relates to a method of controlling a heating apparatus, and more particularly, to a method of controlling a heating apparatus that is capable of minimizing a difference between a room temperature set by a user and a room temperature measured when the heating apparatus operates.

BACKGROUND ART

In general, a heating apparatus means an apparatus that supplies hot water to a heating device. The heating apparatus burns fuel, such as gas, in the heating apparatus, heats water using heat of combustion generated by the burning, and circulates the heated water through piping that is laid in floors of rooms to heat the rooms or supplies hot water using the heated water.

As a control method that allows a heating apparatus to maintain a room temperature at a temperature set by a user, there are the following methods: a method that measures a room temperature and turns on/off the heating apparatus; a method that measures a temperature of heated water and turns on/off a heating apparatus; and a method that operates a heating apparatus during a period of time set by a user and stops the operation of the heating apparatus during a predetermined period of time.

The control method that measures the room temperature and turns on/off the heating apparatus is a control method that compares a room temperature measured by a temperature sensor attached to a room temperature controller and a room temperature set by a user and then correspondingly turns on/off a heating apparatus. The process of controlling the heating apparatus using the control method is shown in FIG. 1.

FIG. 1 is a graph illustrating a variation process of a room temperature according to a method of controlling a heating apparatus according to the related art.

First, a user sets a desired room temperature using a room temperature controller that is installed indoor. In this case, the set room temperature becomes T_—set, and a heating-off temperature T_—off and a heating-on temperature T_—on are respectively set to have predetermined upper and lower temperature ranges on the basis of the room temperature T_—set set by the user.

In this case, the heating-off temperature T_—off and the heating-on temperature T_—on are values that are input to the room temperature controller in advance. For example, when the user sets the desired room temperature to 25° C., the heating-off temperature T_—off may be set to 26° C. and the heating-on temperature T_—on may be set to 24° C. such that upper and lower temperature ranges are maintained within 1° C. on the basis of the room temperature of 25° C.

If the heating apparatus operates, the room temperature increases. At this time, the room temperature is detected by a temperature sensor that is installed in the room temperature controller. If the room temperature detected by the temperature sensor reaches a temperature of 26° C. that is the heating-off temperature T_—off, it is determined that the temperature reaches the room temperature set by the user, and the operation of the heating apparatus is stopped.

In this case, since the operation of the heating apparatus is stopped, heat transfer to the heating piping that is laid in the floors of rooms is also stopped, but heat accumulated in the floors of the rooms is continuously radiated to the indoor. As a result, the room temperature increases to a temperature (for example, 27° C.) that is higher than the heating-off temperature T_—off of 26° C. and then decreases. As such, when the room temperature increases to a temperature that is higher than the set heating-off temperature T_—off, this is called overshoot.

When the heating apparatus stops its operation to decrease the room temperature and the room temperature reaches the heating-on temperature of 24° C., the heating apparatus operates again.

In this case, since the heating apparatus operates, heat is transferred to heating piping that is laid in the floors of the rooms, but a predetermined amount of time is needed until the temperature at the floors of the rooms increases to the room temperature set by the user. Thus, the room temperature decreases to a temperature (for example, 23° C.) that is lower than the heating-on temperature T_—on and then increases again. As such, when the room temperature decreases to a temperature that is lower than the set heating-on temperature T_—on, this is called undershoot.

When the overshoot and undershoot occur as described above, upper and lower variations of the room temperature T_—set increase in a temperature range of 23° C. to 27° C. on the basis of the room temperature T_—set of 25° C. set by the user, and thus it is not possible to provide a comfortable indoor environment for the user.

DISCLOSURE OF INVENTION

Technical Problem

The present invention has been made to solve the above-described problems, and it is an object of the present invention to provide a method of controlling a heating apparatus that is capable of automatically controlling a heating-off temperature T_—off and a heating-on temperature T_—on according to an operation environment of the heating apparatus such that upper and lower variations of a room temperature set by a user are reduced on the basis of the room temperature, thereby allowing the user to feel comfortable.

Technical Solution

In order to achieve the above-described object, according to an aspect of the present invention, there is provided a method of controlling a heating apparatus. In this case, a temperature when the heating apparatus is operated to increase the room temperature and the operation of the heating apparatus is stopped is set as a temperature that is obtained by subtracting a heating-off temperature at a cycle immediately before a current cycle by a compensation value determined according to overshoot that has occurred at the cycle immediately before the current cycle, and a temperature when the operation of the heating apparatus is stopped to decrease the room temperature and the heating apparatus is operated is set as a temperature that is obtained by adding the heating-on temperature at the cycle immediately before the current cycle and a compensation value determined according to undershoot that has occurred at the cycle immediately before the current cycle, such that a difference between the measured room temperature and the room temperature set by the user is minimized.

Preferably, in the heating-off temperature, a minimum heating-off temperature is set as a temperature that is a predetermined temperature higher than the room temperature set by the user, and in the heating-on temperature, a maximum heating-on temperature is set as a temperature that is a predetermined temperature lower than the room temperature set by the user.

When the room temperature is controlled at the minimum heating-off temperature and the overshoot occurs, a control operation may be performed to reduce the amount of heat produced by the heating apparatus. In this case, it is preferable that a control operation be performed to reduce the amount of heat produced by the heating apparatus in proportion to the amount of overshoot.

ADVANTAGEOUS EFFECTS

As specifically described above, according to the method of controlling a heating apparatus according to the present invention, it is possible to automatically control a heating-off temperature and a heating-on temperature according to an operation environment of the heating apparatus such that upper and lower variations of a room temperature are reduced, thereby providing a comfortable indoor environment for a user who uses the heating apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a graph illustrating a variation process of a room temperature according to a method of controlling a heating apparatus according to the related art.

FIG. 2 is a graph illustrating a variation process of a room temperature when a heating apparatus operates according to a method of controlling a heating apparatus according to an embodiment of the present invention.

FIG. 3 is a flowchart illustrating a method of controlling a heating apparatus according to an embodiment of the present invention.

FIG. 4 is a graph illustrating a control method that reduces the amount of heat according to an embodiment of the present invention.

FIG. 5 is a graph illustrating a variation of a room temperature according to a method of controlling a heating apparatus according to an embodiment of the present invention.

FIG. 6 is a schematic diagram illustrating an example of a heating system to which a method of controlling a heating apparatus according to an embodiment of the present invention is applied.

BEST MODE FOR CARRYING OUT THE INVENTION

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

FIG. 2 is a graph illustrating a variation process of a room temperature when a heating apparatus operates according to a method of controlling a heating apparatus according to an embodiment of the present invention. FIG. 3 is a flowchart illustrating a method of controlling a heating apparatus according to an embodiment of the present invention.

The present invention relates to implementing a method of controlling a heating apparatus that, when the heating apparatus is turned on/off according to a compared result that is obtained by comparing a room temperature measured by a temperature sensor installed in a room temperature controller and a room temperature set by a user, enables heating to be maintained such that there is a minimal temperature difference on the basis of the room temperature set by the user.

First, a user sets a desired room temperature using a room temperature controller installed indoor (S101). The set room temperature is represented as T_—set in FIG. 2, and may become, for example, 25° C.

If the room temperature T_—set is set by the user, first, a first heating-off temperature T_—off1 and a first heating-on temperature T_—on1 are respectively set to have predetermined upper and lower temperature ranges on the basis of the room temperature T_—set (S103). For example, the first heating-off temperature T_—off1 may become 25.5° C. and the first heating-on temperature T_—on1 may become 24.5° C.

If the user sets the room temperature and the heating apparatus operates, the room temperature increases. The heating apparatus continuously operates until the room temperature reaches the first heating-off temperature T_—off1 (S105).

If the heating apparatus operates and the room temperature reaches the first heating-off temperature T_—off1 (S107), the operation of the heating apparatus is stopped (S109).

Here, even though the operation of the heating apparatus is stopped, a large amount of heat that is supplied when the heating apparatus is operated is accumulated in the floors of rooms. As a result, heat is continuously radiated from the floors to the inside of the rooms, which causes overshoot to occur, in which the room temperature increases to a temperature higher than the first heating-off temperature T_—off1.

At this time, the temperature sensor measures a maximum temperature T_—max1 of the room temperature that increases due to overshoot, and a control unit computes a difference between the maximum temperature T_—max1 and the first heating-off temperature T_—off1, that is, the amount of overshoot, and defines a computed value as A₁.

A compensation value is determined according to the overshoot that has occurred at the first cycle, and a heating-off temperature T_—off2 at a next cycle is determined using the determined compensation value.

T_{13 off2}=T_—off1−(A₁/2)  [Equation 1]

A₁=T_—max1−T_—off1  [Equation 2]

That is, the compensation value that is determined according to the overshoot that has occurred at the first cycle is defined as (A₁/2), and a value that is obtained by subtracting the first heating-off temperature T_—off1 by the compensation value is defined as a heating-off temperature at a next cycle. In this case, a compensation value may be defined as having various values, such as (A₁/2) or (A₁/3).

If the operation of the heating apparatus is stopped, the room temperature decreases. If the room temperature reaches the first heating-on temperature T_—on1 (S111), the heating apparatus operates again (S113).

In this case, the room temperature does not immediately increase due to specific heat of indoor air but becomes lower than the first heating-on temperature T_—on1, which causes undershoot. At this time, the temperature sensor measures a minimum temperature T_—min1 of the room temperature that decreases due to the undershoot, and the control unit computes a difference between the minimum temperature T_—min1 and the first heating-on temperature T_—on1, that is, the amount of undershoot, and defines a computed value as B₁.

A compensation value is determined according to undershoot that has occurred at the first cycle, and a heating-on temperature T_—on2 at a next cycle is determined using the determined compensation value.

T_—on2=T_—on1+(B₁/2)  [Equation 3]

B₁=T_—on1−T_—min1  [Equation 4]

That is, the compensation value that is determined according to the undershoot that has occurred at the first cycle is defined as B₁/2, and a value that is obtained by adding the first heating-on temperature T_—on1 and the compensation value is defined as a heating-on temperature at a next cycle. In this case, the compensation value may be defined as having various values, such as B₁/2 or B₁/3.

The heating apparatus operates and the room temperature increases again. In this case, if the temperature sensor detects that the room temperature reaches the heating-off temperature (that is, T_—off2 determined in Equation 1) at the second cycle, the operation of the heating apparatus is stopped (S115 and S117).

As such, the operation of the heating apparatus is stopped at the temperature that is obtained by subtracting the first heating-off temperature by the compensation value A₁/2 determined according to the amount of overshoot A₁ that has occurred at the first cycle. Thus, a maximum temperature T_—max2 of the room temperature becomes lower at the second cycle. Accordingly, it is possible to resolve the problem according to the related art in that a variation in room temperature is large.

At this time, the temperature sensor measures the maximum temperature T_—max2 of the room temperature that increases due to overshoot at the second cycle, and the control unit computes a difference between the maximum temperature T_—max2 and the second heating-off temperature T_—off2, that is, the amount of overshoot, and defines a computed value as A₂.

A compensation value A₂/2 is determined according to the overshoot that has occurred at the second cycle, and a heating-off temperature T_—off3 at a next cycle is determined using the determined compensation value.

T_—off3=T_—off2−(A₂/2)  [Equation 5]

A₂=T_—max2−T_—off2  [Equation 6]

As the operation of the heating apparatus is stopped, the room temperature decreases. In this case, if the room temperature reaches the second heating-on temperature T_—on2, the heating apparatus operates again (S119 and S121).

At this time, the temperature sensor measures a minimum temperature T_—min2 of the room temperature that decreases due to the undershoot at the second cycle, and the control unit computes a difference between the minimum temperature T_—min2 and the second heating-on temperature T_—on2, that is, the amount of undershoot, and defines a computed value as B₂.

A compensation value B₂/2 is determined according to the undershoot that has occurred at the second cycle, and a heating-on temperature T_—on3 at a next cycle is determined using the compensation value.

T_—on3=T_—on2+(B₂/2)  [Equation 7]

B₂=T_—on2−T_—min2  [Equation 8]

If the above-described method is used to determine the heating-off temperature T_—off and the heating-on temperature T_—on and the start/stop operation of the heating apparatus is repeated, it is possible to reduce a difference between the room temperature T_—set set by the user and the room temperature measured by the temperature sensor. As a result, it is possible to provide a comfortable indoor environment for the user.

Further, the amounts of overshoot and undershoot that occur when the heating apparatus operates depend on an installation environment of the heating apparatus. Thus, it is difficult to accurately predict the amounts of overshoot and undershoot at the time of designing the heating apparatus. Accordingly, if using the compensation values that are determined according to the amounts of overshoot and undershoot measured by using the above-described method, it becomes possible to automatically set the heating-off temperature T_—off and the heating-on temperature T_—on, which reduce a variation in the room temperature.

When the control operation is performed according to the above-described method, Equations 1 to 8 that compute the heating-off temperature and the heating-on temperature may be represented by the following general Equations.

T_—off(n)=T_{—off(n−1)}−(A_(n−1)/2)

T_—on(n)=T_—on(n−1)+(B_(n−1)/2)

A_(n−1)=T_{—max(n−1)}−T_{—off(n−1)}

B_(n−1)=T_—on(n−1)−T_{—min(n−1)}

In this case, (n) indicates a value at a current controlled cycle, and (n−1) indicates a value determined at a cycle immediately before the current controlled cycle.

Meanwhile, in order to control the heating-off temperature and the heating-on temperature without error, the heating-off temperature needs to be controlled to be higher than the room temperature T_—set set by the user, and the heating-on temperature needs to be controlled to be lower than the room temperature T_—set set by the user.

Accordingly, the heating-off temperature is preferably controlled to be higher than the minimum heating-off temperature T_—off—min that is higher than the room temperature T_—set set by the user by a predetermined temperature. For example, when the room temperature T_—set set by the user is 25° C., the minimum heating-off temperature T_—off—min may be defined as 25.2° C.

The heating-on temperature is preferably controlled to be lower than the maximum heating-on temperature T_—on—max that is lower than the room temperature T_—set set by the user by a predetermined temperature. For example, when the room temperature T_—set set by the user is 25° C., the maximum heating-on temperature T_—on—max may be defined as 24.8° C.

FIG. 4 is a graph illustrating a control method that reduces the amount of heat according to an embodiment of the present invention.

Even when temperature control is performed such that the room temperature is maintained at the minimum heating-off temperature T_—off—min, if overshoot occurs, it is possible to reduce a temperature variation by reducing the amount of heat produced by the heating apparatus.

That is, when it is determined that the heating-off temperature T_—off is continuously decreased to the minimum heating-off temperature T_—off—min and overshoot occurs even at the minimum heating-off temperature T_—off—min, the control unit controls a gas valve (not shown in the drawings) that controls the amount of gas supplied and reduces the pressure of gas supplied (that is, reduces the amount of heat), thereby preventing overshoot from occurring.

In this case, in regards to a decreasing rate of the amount of heat, the amount of heat may be decreased in proportion to the amount of overshoot, as shown in FIG. 4. That is, when the overshoot does not occur, the amount of heat is controlled to become 100%, and when the overshoot ratio exceeds a predetermined ratio, the amount of heat is controlled to become 50%. Here, the overshoot ratio may be defined as A/(T_—off−T_—set).

FIG. 5 is a graph illustrating a variation of a room temperature according to a method of controlling a heating apparatus according to an embodiment of the present invention.

As shown in FIG. 5, if controlling a heating apparatus using the method of controlling a heating apparatus according to the embodiment of the present invention with the above-described structure, upper and lower variations of the room temperature can be reduced. A graph having small amplitude is formed on the basis of the room temperature T_—set set by the user.

FIG. 6 is a schematic diagram illustrating an example of a heating system to which a method of controlling a heating apparatus according to an embodiment of the present invention is applied.

The heating system includes a heating apparatus 110 that supplies water heated by burning fuel, a heated water distributing unit 120 that distributes the heated water supplied by the heating apparatus 110 into individual rooms, a valve 130 that controls supply and stop of the heated water distributed by the heated water distributing unit 120 to the individual rooms, a valve controller 140 that controls driving of the valve 130, and a room temperature controller 150 that is connected to the valve controller 140 and sets a predetermined room temperature for each of the rooms.

The valve 130 may be an on/off-typed valve or a proportional control valve that controls the amount of heated water supplied.

The heating apparatus 110, the valve controller 140, and the room temperature controller 150 are connected to each other through communication lines, and exchange necessary data with each other.

If a current temperature is lower than the room temperature that is set by the room temperature controller 150, the valve controller 140 transmits a signal to the heating apparatus 110, and drives the valve 130 to increase the temperature of a corresponding room.

In this case, a method of controlling overshoot and undershoot that occur due to an increase and a decrease in the room temperature is the same as the above-described control method.

A method of controlling the temperature of each room in a district heating system and a central heating system that externally supply heated water also controls overshoot and undershoot using the above-described control method, and can help to provide a comfortable indoor environment for the user.

It will be apparent to those skilled in the art that various modifications and changes may be made without departing from the scope and spirit of the present invention. Therefore, it should be understood that the above embodiments are not limitative, but illustrative in all aspects.