KR102228563B1 - Method of operating a havcr system - Google Patents

Abstract

A cooling and heating-air conditioning and ventilating system operating method for operating a cooling and heating-air conditioning and ventilating system including a cooling and heating apparatus and an air conditioning and ventilating apparatus installed in a building, includes the following steps of: measuring the internal temperature of a building at every preset time; deriving a cooling and heating load and a cooling and heating load reduction rate corresponding to a difference between the internal temperature and a reference temperature; measuring the internal air quality of the building at every preset time; deriving an air conditioning and ventilating load and an air conditioning and ventilating load reduction rate corresponding to a difference between the internal air quality and a reference air quality; determining a first unit operation time of the cooling and heating apparatus based on the cooling and heating load and the cooling and heating load reduction rate; determining a second unit operation time of the air conditioning and ventilating apparatus based on the air conditioning and ventilating load and the air conditioning and ventilating load reduction rate; and operating the cooling and heating apparatus and the air conditioning and ventilating apparatus in a preset energy saving time slot alternately for the first unit operation time and for the second unit operation time.

Description

Cooling, heating and air conditioning ventilation system operation method {METHOD OF OPERATING A HAVCR SYSTEM}

The present invention relates to a heating, ventilation, air conditioning, and refrigeration (HVAC&R) system installed in a building. In more detail, the present invention relates to a heating and cooling-air conditioning ventilation system driving method including a cooling and heating device and an air conditioning ventilation device installed in a building.

As various social problems such as disasters, abnormal temperatures, and diseases arising from global warming and climate change emerge, energy saving and efficiency improvement are drawing attention. In particular, since the energy consumption in the building sector accounts for 22% of the total energy consumption in Korea, it is important to reduce the energy consumption in the building sector in energy saving and efficiency improvement. In general, in the energy consumption of the building sector, the energy consumption of the heating and cooling type and the energy consumption of the lighting type dominate, and the energy consumption of the air conditioning ventilation type is increasing rapidly in recent years due to social issues such as fine dust. . However, when it comes to saving energy of the type of lighting, it is only possible to save energy by turning off unnecessarily lit lights or lowering the brightness of the lights, considering that people inside the building must be active. On the other hand, with regard to the energy saving of the air conditioner type and the air conditioner type energy saving, a considerable amount of energy can be saved if the people inside the building suffer only from feeling uncomfortable. Therefore, it is necessary to reduce the energy consumption of each building through energy saving of air conditioning and ventilation types so that blackouts do not occur during energy saving periods when energy consumption increases rapidly (i.e., power peak hours). have.

One object of the present invention is to minimize the inconvenience of people inside the building during the energy saving time period when energy consumption increases rapidly (i.e., the power peak period), while saving the energy of the air conditioner type and the energy saving of the air conditioner type of the building as a whole. It is to provide a method of driving a cooling/heating-air conditioning ventilation system that can reduce energy consumption. However, the object of the present invention is not limited to the above-mentioned object, and may be variously extended without departing from the spirit and scope of the present invention.

In order to achieve one object of the present invention, the cooling and heating-air conditioning ventilation system according to embodiments of the present invention (in this case, the cooling/heating-air conditioning ventilation system includes a cooling/heating device and an air conditioning ventilation device installed in a building). Measuring the internal temperature of the building every set time, deriving a cooling/heating load and a cooling/heating load reduction rate corresponding to a difference between the internal temperature and a reference temperature, measuring the internal air quality of the building every time, the Deriving an air conditioning ventilation load and an air conditioning ventilation load reduction rate corresponding to the difference between the internal air quality and the reference air quality, determining a first unit operation time of the air conditioning system based on the cooling and heating load and the cooling and heating load reduction rate, the Determining a second unit operating time of the air conditioning ventilation device based on the air conditioning ventilation load and the reduction rate of the air conditioning ventilation load, and determining the air conditioning ventilation device and the air conditioning ventilation device in a preset energy saving time period with the first unit operating time It may include the step of alternately operating the second unit operation time.

According to an embodiment, the method of driving the cooling/heating-air conditioning ventilation system includes the first unit operation time and the second unit operation time so that the sum of the first unit operation time and the second unit operation time becomes a preset reference value. It may further include the step of adjusting according to the ratio.

According to an embodiment, when the air conditioner and the air conditioner alternately operate, the first unit operation time and the second unit operation time may be continuous with each other.

According to an embodiment, when the air conditioner and the air conditioner alternately operate, the first unit operation time and the second unit operation time may be discontinuous from each other.

According to an embodiment, the first unit operation time may be longer as the heating/cooling load increases, and the first unit operation time may be shorter as the cooling/heating load decreases.

According to an embodiment, when the cooling and heating load reduction rate has a positive value, the first unit operation time is shortened by a first decrease, and when the cooling and heating load reduction rate has a negative value, the first unit operation time is a first increase. Can be as long as

According to an embodiment, as the absolute value of the cooling/heating load reduction rate increases, the first increase and the first decrease are set larger, and as the absolute value of the cooling and heating load decrease rate decreases, the first increase and the first decrease are It can be set small.

According to an embodiment, as the air conditioning ventilation load increases, the second unit operation time may be longer, and as the air conditioning ventilation load decreases, the second unit operation time may be shortened.

According to an embodiment, when the air conditioning ventilation load reduction rate has a positive value, the second unit operation time is shortened by a second reduction amount, and when the air conditioning ventilation load reduction ratio has a negative value, the second unit operation time is second. It can be as long as 2 increments.

According to an embodiment, as the absolute value of the air conditioning ventilation load reduction rate increases, the second increase and the second decrease are set larger, and as the absolute value of the air conditioning ventilation load reduction ratio decreases, the second increase and the second decrease. The reduction can be set small.

The cooling/heating-air conditioning ventilation system installed in a building according to embodiments of the present invention (in this case, the cooling/heating-air conditioning ventilation system includes a cooling/heating device and an air conditioning ventilation system) driving method measures the internal temperature of the building at every preset time and , It derives the cooling/heating load and the cooling/heating load reduction rate corresponding to the difference between the internal temperature of the building and the reference temperature, measures the internal air quality of the building every preset time, and air conditioning corresponding to the difference between the internal air quality of the building and the reference air quality. It derives the ventilation load and air conditioning ventilation load reduction rate, determines the first unit operating time of the air conditioner based on the cooling/heating load and the cooling and heating load reduction ratio, and the second unit of the air conditioning ventilation system based on the air conditioning ventilation load and the air conditioning ventilation load reduction ratio The operation time is determined, and the air conditioner and the air conditioner are operated alternately at the first unit operation time and the second unit operation time during the energy saving time period (i.e., the power peak time period). The total energy consumption of the building can be effectively reduced by minimizing discomfort to the people inside the building, while saving energy in the air-conditioning type and air conditioning ventilation type. However, the effects of the present invention are not limited to the above-mentioned effects, and may be variously extended without departing from the spirit and scope of the present invention.

1 is a flowchart illustrating a method of driving a cooling/heating-air conditioning ventilation system according to embodiments of the present invention.
FIG. 2 is a diagram illustrating a method of driving the cooling/heating-air conditioning ventilation system of FIG. 1.
FIG. 3 is a diagram illustrating an example in which a cooling/heating apparatus and an air conditioning ventilation apparatus alternately operate according to the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1.
FIG. 4 is a diagram illustrating another example in which a cooling/heating apparatus and an air conditioning ventilation apparatus alternately operate according to the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1.
5 is a flowchart illustrating an example in which a first unit operation time for a cooling/heating apparatus is determined by the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1.
6 is a flowchart illustrating an example in which a second unit operation time for an air conditioning ventilation device is determined by the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1.
7 is a flowchart illustrating an example in which a first unit operation time and a second unit operation time are adjusted by the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1.
FIG. 8 is a diagram for describing an example in which a first unit operation time and a second unit operation time are adjusted by the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1.

With respect to the embodiments of the present invention disclosed in the text, specific structural or functional descriptions have been exemplified for the purpose of describing the embodiments of the present invention only, and the embodiments of the present invention may be implemented in various forms. It should not be construed as being limited to the embodiments described in.

Since the present invention can apply various changes and have various forms, specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form disclosed, it should be understood to include all changes, equivalents, or substitutes included in the spirit and scope of the present invention.

Terms such as first and second may be used to describe various elements, but the elements should not be limited by the terms. The terms may be used for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first element may be referred to as a second element, and similarly, a second element may be referred to as a first element.

When a component is referred to as being "connected" or "connected" to another component, it is understood that it may be directly connected or connected to the other component, but other components may exist in the middle. It should be. On the other hand, when a component is referred to as being "directly connected" or "directly connected" to another component, it should be understood that there is no other component in the middle. Other expressions describing the relationship between components, such as "between" and "directly between" or "adjacent to" and "directly adjacent to" should be interpreted as well.

The terms used in the present application are only used to describe specific embodiments, and are not intended to limit the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In the present application, terms such as "comprise" or "have" are intended to designate the existence of a set feature, number, step, action, component, part, or combination thereof, but one or more other features or numbers. It is to be understood that the possibility of addition or presence of, steps, actions, components, parts, or combinations thereof is not preliminarily excluded.

Unless otherwise defined, all terms used herein including technical or scientific terms have the same meaning as commonly understood by one of ordinary skill in the art to which the present invention belongs. Terms as defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning of the related technology, and should not be interpreted as an ideal or excessively formal meaning unless explicitly defined in the present application. .

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings. The same reference numerals are used for the same elements in the drawings, and duplicate descriptions for the same elements are omitted.

1 is a flowchart illustrating a method of driving a cooling/heating-air conditioning ventilation system according to embodiments of the present invention, FIG. 2 is a view for explaining a driving method of the cooling/heating-air conditioning ventilation system of FIG. 1, and FIG. -It is a diagram showing an example in which a cooling/heating device and an air conditioning ventilation device alternately operate by the air conditioning ventilation system driving method, and FIG. 4 is a diagram showing an example in which the cooling and heating device and the air conditioning ventilation system are alternately operated by the cooling/heating-air conditioning ventilation system driving method of FIG. It is a diagram showing another example in operation.

1 to 4, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 is to drive a cooling/heating-air conditioning ventilation system 100 including a cooling/heating apparatus 110 and an air conditioning ventilation apparatus 120 installed in a building. I can. Specifically, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 measures the internal temperature of the building at every preset time (S110), and derives the cooling/heating load and the cooling/heating load reduction rate corresponding to the difference between the internal temperature of the building and the reference temperature. (S120), measure the internal air quality of the building at every preset time (S130), derive the air conditioning ventilation load and the air conditioning ventilation load reduction rate corresponding to the difference between the internal air quality of the building and the reference air quality (S140), and the cooling and heating load And a first unit operation time (FUT) of the cooling and heating device 110 is determined based on the cooling and heating load reduction rate (S150), and the second unit operation of the air conditioning ventilation device 120 is based on the air conditioning ventilation load and the air conditioning ventilation load reduction rate. The time (SUT) is determined (S160), and the first unit operation time (FUT) and the second unit operation time (SUT) are alternated between the heating and cooling unit 110 and the air conditioning ventilation unit 120 in a preset energy saving time period. It can be operated (S170).

As shown in FIG. 2, the cooling/heating-air conditioning ventilation system 100 driven by the cooling/heating-air conditioning ventilation system driving method of FIG. 1 includes a cooling/heating apparatus 110, an air conditioning ventilation apparatus 120, a temperature sensor 130, An air quality sensor 140 and a main controller 150 may be included. The air conditioner 110 may control the internal temperature of the building. To this end, the cooling and heating device 110 may include a cooling device (eg, an air conditioner, etc.) and a heating device (eg, a boiler, etc.). For example, when the internal temperature of the building is higher than the reference temperature (eg, a user-set temperature), the air conditioner 110 may perform a cooling operation to lower the internal temperature of the building to the reference temperature. On the other hand, when the internal temperature of the building is lower than the reference temperature, the air conditioner 110 may perform a heating operation to increase the internal temperature of the building to the reference temperature. The air conditioning ventilation device 120 may adjust the air quality of the building. For example, when the internal air quality of the building is lower than the standard air quality (for example, when the fine dust concentration is higher than the user-set level), the air conditioning ventilation device 120 is used to increase the internal air quality of the building to the reference air quality (e.g. For example, in order to lower the fine dust concentration to a user-set level), an air conditioning ventilation operation may be performed. However, this is exemplary, and the air quality inside the building is not limited to the fine dust concentration. The temperature sensor 130 may measure the internal temperature of the building every preset time and provide a first sensing signal SEN1 indicating the internal temperature of the building to the main controller 150. The air quality sensor 140 may measure the internal air quality of the building every preset time and provide a second sensing signal SEN2 indicating the internal air quality of the building to the main controller 150. The main controller 150 controls the air conditioner 110 by providing the first control signal CTL1 to the air conditioner 110, and provides the second control signal CTL1 to the air conditioner 120 to provide air conditioning ventilation. The device 120 can be controlled. Specifically, the main controller 150 derives a cooling/heating load corresponding to the difference between the internal temperature of the building and the reference temperature, derives a cooling/heating load reduction rate corresponding to the degree to which the cooling/heating load decreases, and The air conditioning ventilation load corresponding to the difference between the standard air quality is derived, the air conditioning ventilation load reduction rate corresponding to the degree of decrease in the air conditioning ventilation load is derived, and the cooling and heating device 110 is manufactured based on the cooling and heating load and the cooling and heating load reduction ratio. 1 unit operation time (FUT) is determined, the second unit operation time (SUT) of the air conditioning ventilation device 120 is determined based on the air conditioning ventilation load and the air conditioning ventilation load reduction rate, and a preset energy saving time period (for example, , The power peak time period), the heating and cooling apparatus 110 and the air conditioning ventilation apparatus 120 may be operated alternately by a first unit operation time (FUT) and a second unit operation time (SUT).

Specifically, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 measures the internal temperature of the building at every preset time (S110), and derives the cooling/heating load and the cooling/heating load reduction rate corresponding to the difference between the internal temperature of the building and the reference temperature. (S120) You can. As described above, when the temperature sensor 130 measures the internal temperature of the building at every preset time, the main controller 150 derives the cooling/heating load and the cooling/heating load reduction rate corresponding to the difference between the internal temperature of the building and the reference temperature. can do. For example, the cooling and heating load corresponds to the difference between the internal temperature of the building and the reference temperature, so if the difference between the internal temperature of the building and the reference temperature is large, the cooling and heating load is large, and if the difference between the internal temperature of the building and the reference temperature is small, cooling and heating The load can be small. In addition, since the cooling/heating load reduction rate corresponds to the degree to which the cooling/heating load decreases, the fact that the cooling/heating load reduction rate has a positive value means that the difference between the internal temperature of the building and the reference temperature decreases, and the cooling/heating load reduction rate is Having a negative value means that the difference between the internal temperature of the building and the reference temperature increases. Therefore, the difference between the internal temperature of the building and the reference temperature rapidly decreases (e.g., when the internal temperature of the building is lower than the reference temperature, the internal temperature of the building rapidly increases toward the reference temperature, or the internal temperature of the building increases to the reference temperature. When it is higher, when the internal temperature of the building decreases sharply toward the reference temperature), the absolute value of the positive cooling and heating load reduction rate is large, and the difference between the internal temperature of the building and the reference temperature decreases slowly (for example, When the internal temperature of the building is lower than the reference temperature, the internal temperature of the building gradually increases toward the reference temperature, or when the internal temperature of the building is higher than the reference temperature, the internal temperature of the building gradually decreases toward the reference temperature) The absolute value of the positive heating and cooling load reduction rate may be small. On the other hand, the difference between the internal temperature of the building and the reference temperature increases rapidly (for example, even though the internal temperature of the building is lower than the reference temperature, the internal temperature of the building decreases rapidly, or the internal temperature of the building decreases to the reference temperature. If the internal temperature of the building rises sharply despite the higher), the absolute value of the negative heating and cooling load reduction rate is large, and the difference between the internal temperature of the building and the reference temperature increases slowly (for example, the building's internal temperature rises sharply). If the internal temperature of the building is rather gently lowered even though the internal temperature is lower than the reference temperature, or the internal temperature of the building is rather gradually increased even though the internal temperature of the building is higher than the reference temperature), it has a negative value. The absolute value of the cooling and heating load reduction rate may be small.

In addition, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 measures the internal air quality of the building every preset time (S130), and calculates the air conditioning ventilation load and the air conditioning ventilation load reduction rate corresponding to the difference between the internal air quality of the building and the reference air quality. It can be derived (S140). As described above, when the air quality sensor 140 measures the internal air quality of the building at every preset time, the main controller 150 controls the air conditioning ventilation load and the air conditioning ventilation load reduction rate corresponding to the difference between the internal air quality of the building and the reference air quality. Can be derived. For example, since the air conditioning ventilation load corresponds to the difference between the internal air quality of the building and the standard air quality, if the difference between the internal air quality of the building and the reference air quality is large, the air conditioning ventilation load is large, and the difference between the internal air quality of the building and the reference air quality is small. If so, the air conditioning ventilation load may be small. In addition, since the air conditioning ventilation load reduction rate corresponds to the degree to which the air conditioning ventilation load decreases, the fact that the air conditioning ventilation load reduction ratio has a positive value decreases the difference between the internal air quality of the building and the standard air quality (that is, the internal air quality of the building is reduced). Better), and the fact that the air conditioning ventilation load reduction rate has a negative value means that the difference between the internal air quality of the building and the standard air quality increases (that is, the internal air quality of the building deteriorates). Therefore, when the difference between the internal air quality of the building and the reference air quality rapidly decreases (for example, when the internal air quality of the building is lower than the reference air quality, the internal air quality of the building rapidly improves toward the reference air quality), the air conditioning with a positive value. The absolute value of the ventilation load reduction rate is large, and the difference between the internal air quality and the reference air quality of the building decreases slowly (for example, when the internal air quality of the building is lower than the reference air quality, the internal air quality of the building gradually improves toward the reference air quality) If so, the absolute value of the positive air conditioning ventilation load reduction rate may be small. On the other hand, if the difference between the internal air quality of the building and the standard air quality increases rapidly (for example, if the internal air quality of the building is rather rapidly deteriorating even though the internal air quality of the building is lower than the standard air quality), it has a negative value. The absolute value of the air conditioning ventilation load reduction rate is large, and the difference between the internal air quality of the building and the standard air quality increases slowly (for example, when the internal air quality of the building deteriorates gradually even though the internal air quality of the building is lower than the standard air quality. ), the absolute value of the negative heating and cooling load reduction rate may be small.

Thereafter, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 determines the first unit operation time (FUT) of the cooling/heating device 110 based on the cooling/heating load and the cooling/heating load reduction rate (S150), and the air conditioning ventilation load and the air conditioning ventilation load A second unit operation time (SUT) of the air conditioning ventilation apparatus 120 may be determined based on the reduction rate (S160). As described above, the main controller 150 receives the first sensing signal SEN1 indicating the internal temperature of the building from the temperature sensor 130 to derive the cooling/heating load and the cooling/heating load reduction rate, and the building from the air quality sensor 140 After receiving the second sensing signal (SEN2) indicating the internal air quality of the air conditioning ventilation load and the air conditioning ventilation load reduction rate, based on the cooling and heating load and the cooling and heating load reduction rate, the first unit operation time (FUT) of the cooling and heating device 110 ), and a second unit operation time (SUT) of the air conditioning ventilation device 120 based on the air conditioning ventilation load and the reduction ratio of the air conditioning ventilation load. In this case, in the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1, the first unit operation time FUT may be set longer as the cooling and heating load is larger, and the first unit operation time FUT may be set shorter as the cooling and heating load is smaller. That is, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, since the cooling/heating device 110 needs to operate for a long time when the cooling and heating load is large, the first unit operation time (FUT) during which the cooling and heating device 110 operates is set to be long. If the cooling/heating load is small, since the cooling/heating apparatus 110 does not need to operate for a long time, the first unit operation time (FUT) during which the cooling/heating apparatus 110 operates is set to be short. Similarly, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, the second unit operation time (SUT) may be set longer as the air conditioning ventilation load increases, and the second unit operation time (SUT) may be set shorter as the air conditioning ventilation load decreases. . That is, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, since the air conditioning ventilation device 120 needs to operate for a long time when the air conditioning ventilation load is large, the second unit operation time (SUT) during which the air conditioning ventilation device 120 operates is reduced. If the air conditioning ventilation device 120 is set to be long and the air conditioning ventilation load is small, since the air conditioning ventilation device 120 does not need to operate for a long time, the second unit operation time (SUT) during which the air conditioning ventilation device 120 operates is set to be short. In an embodiment, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 is to determine a first unit operation time (FUT) and a second unit operation time (SUT). A mapping table in which) are recorded and a mapping table in which second unit operation times (SUTs) according to air conditioner loads are recorded may be used.

In one embodiment, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 reduces the first unit operation time (FUT) by a first decrease when the cooling/heating load reduction rate has a positive value, and when the cooling/heating load reduction rate has a negative value, The first unit operation time FUT may be increased by a first increment. As described above, the cooling/heating load reduction rate corresponds to the degree to which the cooling/heating load decreases, and that the cooling/heating load reduction rate has a positive value means that the difference between the internal temperature of the building and the reference temperature decreases, and the cooling/heating load reduction rate is Having a negative value means that the difference between the internal temperature of the building and the reference temperature increases. Accordingly, in the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1, when the cooling/heating load reduction rate has a positive value (that is, when the difference between the internal temperature of the building and the reference temperature is decreasing), the first cooling/heating device 110 operates. By reducing the unit operation time (FUT) by the first decrease, an extra time can be devoted to the air conditioning ventilation operation. On the other hand, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, when the cooling/heating load reduction rate has a negative value (that is, when the difference between the internal temperature of the building and the reference temperature is increasing), the cooling/heating device 110 operates. By increasing the 1 unit operation time (FUT) by the first increment, more time may be devoted to the heating and cooling operation. In this case, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, as the absolute value of the cooling/heating load decrease rate increases, the first increase and the first decrease are set larger, and as the absolute value of the cooling and heating load decrease rate decreases, the first increase and the first decrease. Can be set smaller. As described above, a large absolute value of the cooling/heating load reduction ratio means that the difference between the internal temperature of the building and the reference temperature rapidly decreases or increases, and a small absolute value of the cooling/heating load reduction ratio indicates the internal temperature and the reference temperature of the building. It means that the difference between them gradually decreases or increases. Therefore, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, if the absolute value of the cooling/heating load reduction rate having a positive value is large, it is determined that the cooling/heating device 110 operates more than necessary, and the cooling/heating device 110 operates. The first reduction amount for reducing the first unit operation time FUT may be set large. On the other hand, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, if the absolute value of the cooling/heating load reduction rate having a positive value is small, it is determined that the cooling/heating device 110 does not operate more than necessary, and the cooling/heating device 110 The first reduction for reducing the first unit operation time (FUT) in which) is operated may be set to be small. In addition, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that if the absolute value of the cooling/heating load reduction rate having a negative value is large, it is determined that it is urgent for the cooling/heating device 110 to operate a lot, and the cooling/heating device 110 is operated. The first increment for increasing the first unit operation time FUT may be set large. On the other hand, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, when the absolute value of the reduction rate of the cooling/heating load having a negative value is small, it is determined that it is not urgent that the cooling/heating device 110 operates much, and the cooling/heating device 110 The first increment for increasing the first unit operation time (FUT) during which is operated may be set to be small.

In one embodiment, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 decreases the second unit operation time (SUT) by a second reduction when the air conditioning ventilation load reduction rate has a positive value, and the air conditioning ventilation load reduction ratio is negative. If has, the second unit operation time SUT may be increased by a second increment. As described above, the air conditioning ventilation load reduction rate corresponds to the degree to which the air conditioning ventilation load decreases, and that the air conditioning ventilation load reduction ratio has a positive value means that the difference between the internal air quality of the building and the standard air quality decreases. The fact that the ventilation load reduction rate has a negative value means that the difference between the internal air quality of the building and the reference air quality increases. Therefore, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, when the air conditioning ventilation load reduction rate has a positive value (that is, when the difference between the internal air quality of the building and the reference air quality is decreasing), the air conditioning ventilation device 120 operates. By reducing the second unit operation time SUT by a second reduction amount, an extra time may be devoted to the heating and cooling operation. On the other hand, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, when the air conditioning ventilation load reduction rate has a negative value (that is, when the difference between the internal air quality of the building and the reference air quality is increasing), the air conditioning ventilation device 120 operates. By increasing the second unit operation time SUT by a second increment, more time may be devoted to the air conditioning ventilation operation. In this case, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 sets the second increase and the second decrease as the absolute value of the air conditioning ventilation load reduction rate increases, and the second increase and the second decrease as the absolute value of the air conditioning ventilation load decrease rate decreases. 2 The reduction can be set small. As described above, a large absolute value of the air conditioning ventilation load reduction ratio means that the difference between the internal air quality of the building and the standard air quality decreases or increases rapidly, and a small absolute value of the air conditioning ventilation load reduction ratio indicates that the internal air quality of the building and It means that the difference between the standard air quality gradually decreases or increases. Therefore, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that the air conditioning ventilation device 120 operates more than necessary when the absolute value of the positive air conditioning ventilation load reduction rate is large, and the air conditioning ventilation device 120 A second reduction amount for reducing the second unit operation time SUT during which is operated may be set large. On the other hand, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, when the absolute value of the positive air conditioning ventilation load reduction rate is small, it is determined that the air conditioning ventilation device 120 does not operate more than necessary, and the air conditioning ventilation The second reduction amount for reducing the second unit operation time SUT during which the device 120 operates may be set to be small. In addition, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, if the absolute value of the air conditioning ventilation load reduction rate having a negative value is large, it is determined that it is urgent for the air conditioning ventilation device 120 to operate a lot, and the air conditioning ventilation device 120 The second increment for increasing the second unit operation time (SUT) during which is operated may be set to be large. On the other hand, in the cooling/heating-air conditioning ventilation system driving method of FIG. 1, if the absolute value of the negative air conditioning ventilation load reduction rate is small, it is determined that it is not urgent that the air conditioning ventilation system 120 operates much, and the air conditioning ventilation system The second increment for increasing the second unit operation time SUT during which the 120 is operated may be set to be small.

Next, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 is a first unit operation time (FUT) and a second unit operation time (SUT) of the heating and cooling device 110 and the air conditioning ventilation device 120 in a preset energy saving time zone. It can be alternately operated (S170). In general, if all the facilities in the building operate at the same time during the energy saving period (ie, the power peak period) when energy consumption increases rapidly, there is a high possibility that a situation such as a blackout will occur. Accordingly, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 includes the cooling/heating apparatus 110 and the air conditioning ventilation system in the energy saving time period (that is, the power peak time period) when the energy consumption rapidly increases in driving the cooling/heating-air conditioning ventilation system 100. Do not operate (120) at the same time. However, in very hot or cold weather, when only the air conditioner 110 is operated for a long time during the energy saving period (that is, the power peak period) or only the air conditioning ventilator 120 is operated for a long time in a situation where the concentration of fine dust is also bad, the interior of the building People can feel great discomfort. On the other hand, when the air conditioner 110 and the air conditioner 120 alternately operate for a relatively short period of time, the people inside the building say that the air conditioner 110 and the air conditioning ventilator 120 continue to operate. It can be recognized, and accordingly, people inside the building may have regrets at the speed at which the internal temperature is optimized and the speed at which the internal air quality improves, but the recognition that the air conditioner 110 and the air conditioner 120 do not operate. You may not have the discomfort arising from. Accordingly, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 includes a first unit operation time (FUT) and an air conditioning ventilation device ( The second unit operation time (SUT) at which the 120) operates is optimally set, and accordingly, the air conditioner 110 and the air conditioning ventilation unit 120 are set as a first unit operation time (FUT) and a second unit operation time ( SUT) is operated alternately. In one embodiment, as shown in FIG. 3, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 operates the cooling/heating apparatus 110 and the air conditioning ventilation apparatus 120 as a first unit during an energy saving time period when energy consumption increases rapidly. When alternately operating time (FUT) and second unit operation time (SUT), the first unit operation time (FUT) for the heating and cooling device 110 and the second unit operation for the air conditioning ventilator 120 to operate Time (SUT) can be made continuous with each other. In this case, the time point at which the operation of the air conditioner 110 is terminated and the time point at which the operation of the air conditioning ventilator 120 is started coincide, and the time point at which the operation of the air conditioner 120 is terminated and the The timing at which the operation starts may coincide. In another embodiment, as shown in FIG. 4, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 operates the cooling/heating apparatus 110 and the air conditioning ventilation apparatus 120 as a first unit during an energy saving time period when energy consumption increases rapidly. When alternately operating time (FUT) and second unit operation time (SUT), the first unit operation time (FUT) for the heating and cooling device 110 and the second unit operation for the air conditioning ventilator 120 to operate It is possible to make the time (SUT) discontinuous from each other. In this case, there is an idle time (VT) between the time when the operation of the air conditioner 110 ends and the time when the operation of the air conditioning ventilation device 120 starts, and the time when the operation of the air conditioning ventilation device 120 ends. An idle time (VT) may exist between the time point when the operation of the air conditioning and heating device 110 starts.

As described above, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 is a cooling/heating-air conditioning ventilation system 100 installed in a building (in this case, the cooling/heating-air conditioning ventilation system 100 is a cooling/heating device 110, an air conditioning ventilation system 120 ), the temperature sensor 130, the air quality sensor 140, and the main controller 150), the internal temperature of the building is measured every preset time, and the difference between the internal temperature of the building and the reference temperature It derives the corresponding cooling/heating load and cooling/heating load reduction rate, measures the internal air quality of the building every preset time, derives the air conditioning ventilation load and the air conditioning ventilation load reduction rate corresponding to the difference between the internal air quality of the building and the standard air quality, and The first unit operation time (FUT) of the air conditioner 110 is determined based on the load and the cooling/heating load reduction ratio, and the second unit operation time of the air conditioner 120 based on the air conditioner ventilation load and the air conditioner ventilation load reduction rate ( SUT), and by alternately operating the heating and cooling device 110 and the air conditioning ventilation device 120 at a preset energy saving time period, the first unit operation time (FUT) and the second unit operation time (SUT), energy consumption During this rapidly increasing energy saving period (i.e., power peak hours), the overall energy consumption of the building can be effectively reduced through the energy saving of air conditioning and ventilation type while minimizing the discomfort of people inside the building. Meanwhile, according to an embodiment, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 includes a first unit operation time (FUT) for operating the air conditioning device 110 and a second unit operating time (FUT) for operating the air conditioning ventilation device 120 ( The first unit operation time (FUT) for operating the air conditioner 110 and the second unit operation time (SUT) for operating the air conditioning ventilation unit 120 can be adjusted according to a ratio so that the sum of the SUT becomes a preset reference value. have. In this case, one cycle in which the cooling and heating device 110 and the air conditioning ventilating device 120 are operated may be kept constant. However, this will be described in detail later with reference to FIGS. 7 and 8.

5 is a flowchart illustrating an example in which a first unit operation time for a cooling/heating apparatus is determined by the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1.

Referring to FIG. 5, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 derives a cooling/heating load corresponding to a difference between an internal temperature of a building and a reference temperature and a cooling/heating load reduction rate corresponding to the degree of decrease in the cooling/heating load (S210). )can do. Thereafter, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 may determine a first unit operation time (FUT) for operating the cooling/heating apparatus 110 according to the derived cooling/heating load (S220). For example, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 includes a first unit operation time (FUT) corresponding to a cooling/heating load derived using a mapping table in which first unit operation times (FUTs) according to the heating and cooling loads are recorded. ) Can be determined. Next, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 may check whether the derived cooling/heating load reduction rate has a positive value (S230). At this time, if the derived cooling/heating load reduction rate has a positive value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that the difference between the internal temperature of the building and the reference temperature is decreasing, and accordingly, the cooling/heating device 110 The first unit operation time (FUT) to be operated may be decreased by a first decrease (S240). That is, if the derived cooling/heating load reduction rate has a positive value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that the cooling/heating operation is sufficiently performed, and accordingly, dedicates an extra time to the air conditioning ventilation operation. As described above, when the derived cooling/heating load reduction rate has a positive value (i.e., when the difference between the internal temperature of the building and the reference temperature is decreasing), the first decrease is as the absolute value of the derived cooling/heating load reduction rate increases. Can be set large. On the other hand, if the derived cooling/heating load reduction rate does not have a positive value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 may check whether the derived cooling/heating load reduction rate has a negative value (S250). At this time, if the derived cooling/heating load reduction rate has a negative value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that the difference between the internal temperature of the building and the reference temperature is increasing, and accordingly, the cooling/heating device 110 The first unit operation time (FUT) to be operated may be increased by a first increment (S260). That is, if the derived cooling/heating load reduction rate has a negative value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that the cooling/heating operation is not sufficiently performed, and accordingly, more time is devoted to the cooling/heating operation. As described above, when the derived cooling and heating load reduction rate has a negative value (that is, when the difference between the internal temperature of the building and the reference temperature is increasing), the first increase is as the absolute value of the derived cooling and heating load decrease rate increases. Can be set large. On the other hand, if the derived cooling/heating load reduction rate has neither a positive value nor a negative value, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 determines that the difference between the internal temperature of the building and the reference temperature is maintained, and accordingly , The first unit operation time (FUT) in which the cooling and heating apparatus 110 is to be operated may not be adjusted.

6 is a flowchart illustrating an example in which a second unit operation time for an air conditioning ventilation device is determined by the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1.

Referring to FIG. 6, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 provides an air conditioning ventilation load corresponding to a difference between the internal air quality of a building and a standard air quality, and an air conditioning ventilation load reduction ratio corresponding to the degree of decrease in the air conditioning ventilation load. It can be derived (S310). Thereafter, in the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1, a second unit operation time (SUT) in which the air conditioning ventilation device 120 is to be operated may be determined (S320) according to the derived air conditioning ventilation load. For example, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 is a second unit operation time corresponding to an air conditioning ventilation load derived using a mapping table in which second unit operation times (SUTs) according to the air conditioning ventilation loads are recorded. (SUT) can be determined. Next, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 may check whether the derived air conditioning ventilation load reduction rate has a positive value (S330). At this time, if the derived air conditioning ventilation load reduction rate has a positive value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that the difference between the internal air quality of the building and the standard air quality is decreasing (that is, the internal air quality of the building is good. It is determined that it is losing), and accordingly, the second unit operation time SUT in which the air conditioning ventilation apparatus 120 is to operate may be reduced by a second decrease (S340). That is, if the derived air conditioning ventilation load reduction rate has a positive value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that the air conditioning ventilation operation is sufficiently performed, and accordingly, dedicates extra time to the cooling and heating operation. . As described above, when the derived air conditioning ventilation load reduction rate has a positive value (i.e., when the difference between the internal air quality of the building and the reference air quality is decreasing), the second absolute value of the derived air conditioning ventilation load reduction ratio increases. The reduction can be set large. On the other hand, if the derived air conditioning ventilation load reduction rate does not have a positive value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 can confirm whether the derived air conditioning ventilation load reduction ratio has a negative value (S350). At this time, if the derived air conditioning ventilation load reduction rate has a negative value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that the difference between the internal air quality of the building and the reference air quality is increasing (i.e., the internal air quality of the building is It is determined that it is missing), and accordingly, the second unit operation time SUT in which the air conditioning ventilator 120 is to operate may be increased by a second increment (S360). That is, if the derived air conditioning ventilation load reduction rate has a negative value, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 determines that the air conditioning ventilation operation is not sufficiently performed, and accordingly, more time is spent on the air conditioning ventilation operation. It is to do. As described above, when the derived air conditioning ventilation load reduction rate has a negative value (that is, when the difference between the internal air quality of the building and the reference air quality is increasing), the second absolute value of the derived air conditioning ventilation load reduction ratio increases. The increment can be set large. On the other hand, if the derived air conditioning ventilation load reduction rate does not have a positive value and does not have a negative value, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 determines that the difference between the internal air quality of the building and the reference air quality is maintained. Accordingly, the second unit operation time (SUT) in which the air conditioning ventilation apparatus 120 is to operate may not be adjusted.

FIG. 7 is a flowchart illustrating an example in which a first unit operation time and a second unit operation time are adjusted by the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1, and FIG. 8 is a method of driving the cooling/heating-air conditioning ventilation system of FIG. This is a diagram for explaining an example in which a first unit operation time and a second unit operation time are adjusted accordingly.

Referring to FIGS. 7 and 8, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 provides a cooling/heating load corresponding to a difference between the internal temperature of a building and a reference temperature, and a cooling/heating load reduction ratio corresponding to the degree of decrease in the cooling/heating load. Based on the determination of the first unit operation time (FUT) (S410), the air conditioning ventilation load corresponding to the difference between the internal air quality of the building and the reference air quality, and the air conditioning ventilation load reduction rate corresponding to the degree to which the air conditioning ventilation load decreases. A second unit operation time SUT may be determined (S420) based on the second unit operation time SUT. Thereafter, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 may check whether the sum of the first unit operation time FUT and the second unit operation time SUT is equal to a preset reference value REF (S430). . At this time, if the sum of the first unit operation time (FUT) and the second unit operation time (SUT) is equal to a preset reference value (REF), the cooling/heating-air conditioning ventilation system driving method of FIG. The first unit operation time (FUT) and the second unit operation time (SUT) in which the air conditioning ventilation apparatus 120 operates may be non-adjusted (S440). On the other hand, if the sum of the first unit operation time (FUT) and the second unit operation time (SUT) is not equal to the preset reference value (REF), the cooling/heating-air conditioning ventilation system driving method of FIG. The operating first unit operating time (FUT) and the second unit operating time (SUT) of operating the air conditioning ventilation device 120 may be adjusted (S450). In an embodiment, as illustrated in FIG. 8, the sum of the first unit operation time FUT and the second unit operation time SUT may be greater than a preset reference value REF. In this case, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 is in which the cooling and heating apparatus 110 operates so that the sum of the first unit operation time (FUT) and the second unit operation time (SUT) becomes a preset reference value (REF). The first unit operation time (FUT) and the second unit operation time (SUT) in which the air conditioning ventilator 120 is operated may be reduced according to a ratio. That is, the first unit operation time (FUT) in which the air conditioner 110 operates is reduced to the first unit operation time (FUT'), and the second unit operation time (SUT) in which the air conditioner 120 operates is It may be reduced to the second unit operation time SUT'. In another embodiment, the sum of the first unit operation time FUT and the second unit operation time SUT may be less than a preset reference value REF. In this case, the cooling/heating-air conditioning ventilation system driving method of FIG. 1 is in which the cooling and heating apparatus 110 operates so that the sum of the first unit operation time (FUT) and the second unit operation time (SUT) becomes a preset reference value (REF). The first unit operation time (FUT) and the second unit operation time (SUT) in which the air conditioning ventilator 120 operates may be increased according to a ratio. That is, the first unit operation time (FUT) in which the air conditioner 110 operates is increased to the first unit operation time (FUT'), and the second unit operation time (SUT) in which the air conditioning ventilation apparatus 120 operates is It may be increased as the second unit operation time SUT'. As described above, the method of driving the cooling/heating-air conditioning ventilation system of FIG. 1 may maintain a constant period in which the cooling/heating apparatus 110 and the air conditioning ventilation apparatus 120 operate.

The present invention can be widely applied to a cooling/heating-air conditioning ventilation system including a cooling/heating device and an air conditioning ventilation system installed in a building. Meanwhile, in the above, the present invention has been described with reference to embodiments, but those skilled in the art will variously modify and change the present invention within the scope not departing from the spirit and scope of the present invention described in the claims below. You will understand that you can do it.

100: air conditioning-air conditioning ventilation system 110: air conditioning system
120: air conditioning ventilation device 130: temperature sensor
140: air quality sensor 150: main controller
FUT: first unit operation time SUT: second unit operation time
VT: idle time

Claims (10)

In the cooling/heating-air conditioning ventilation system driving method for driving a cooling/heating-air conditioning ventilation system including a cooling/heating device and an air conditioning ventilation system installed in a building,
Measuring the internal temperature of the building every preset time;
Deriving a cooling/heating load and a cooling/heating load reduction ratio corresponding to a difference between the internal temperature and a reference temperature;
Measuring the internal air quality of the building every time;
Deriving an air conditioning ventilation load and a reduction ratio of the air conditioning ventilation load corresponding to the difference between the internal air quality and the reference air quality;
Determining a first unit operation time of the cooling/heating apparatus based on the cooling/heating load and the cooling/heating load reduction rate;
Determining a second unit operation time of the air conditioning ventilation device based on the air conditioning ventilation load and the reduction ratio of the air conditioning ventilation load; And
And operating the air conditioner and the air conditioning ventilator alternately by the first unit operation time and the second unit operation time during a preset energy saving time period. The method of claim 1,
And adjusting the first unit operation time and the second unit operation time according to a ratio so that the sum of the first unit operation time and the second unit operation time becomes a preset reference value. -How to drive the air conditioning ventilation system. The method of claim 1, wherein when the air conditioner and the air conditioner alternately operate, the first unit operation time and the second unit operation time are continuous with each other. The method of claim 1, wherein when the air conditioner and the air conditioner alternately operate, the first unit operation time and the second unit operation time are discontinuous from each other. The method of claim 1, wherein the first unit operation time becomes longer as the heating and cooling load increases, and the first unit operation time becomes shorter as the cooling and heating load decreases. The method of claim 5, wherein when the cooling and heating load reduction rate has a positive value, the first unit operation time is shortened by a first decrease, and when the cooling and heating load reduction rate has a negative value, the first unit operation time is a first increase. Cooling and heating-air conditioning ventilation system driving method, characterized in that longer than that. The method of claim 6, wherein as the absolute value of the cooling/heating load reduction rate increases, the first increase and the first decrease are set larger, and as the absolute value of the cooling and heating load decrease rate decreases, the first increase and the first decrease are Cooling and heating-air conditioning ventilation system driving method, characterized in that set small. The method of claim 1, wherein the second unit operation time becomes longer as the air conditioning ventilation load increases, and the second unit operation time becomes shorter as the air conditioning ventilation load decreases. The method of claim 8, wherein when the air conditioning ventilation load reduction rate has a positive value, the second unit operation time is shortened by a second decrease, and when the air conditioning ventilation load reduction rate has a negative value, the second unit operation time is zero. Cooling and heating-air conditioning ventilation system driving method, characterized in that the lengthened by 2 increments. The method of claim 9, wherein as the absolute value of the air conditioning ventilation load reduction rate increases, the second increase and the second decrease are set larger, and as the absolute value of the air conditioning ventilation load reduction rate decreases, the second increase and the second decrease. Cooling and heating-air conditioning ventilation system driving method, characterized in that the reduction is set small.

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