KR20210080795A - Smart air conditioning system - Google Patents

Abstract

According to an embodiment of the present invention, a smart air conditioning system includes: an air supply fan for supplying air into an indoor area; an air supply duct for transferring the air discharged from the air supply fan to a plurality of zones; a total air supply volume measurement device measuring the total air supply volume of the air supplied by the air supply fan to the air supply duct; a zonal air supply volume control device installed in each of the plurality of zones to control the flowrate of the air supplied to the plurality of zones through the air supply duct; a zonal air supply volume measurement device installed in each of the plurality of zones to measure the flowrate of the air supplied to the plurality of zones in accordance with the rate of opening of the zonal air supply volume control device; and a control device controlling the air supply fan and the air supply volume control device in accordance with air supply volume information provided from the total air supply volume measurement device and the zonal air supply volume measurement device. Therefore, the present invention is capable of automatically and stably controlling the volume of the air supplied to each of the zones.

Description

Smart air conditioning system {SMART AIR CONDITIONING SYSTEM}

The present invention relates to a smart air conditioning system, and more particularly, to a smart air conditioning system that performs air conditioning for a plurality of zones.

In general, air conditioning equipment for performing air conditioning for each room or zone is installed in various business buildings and multi-use facilities. Air conditioning refers to maintaining the indoor air condition in a state suitable for the purpose of use by controlling the temperature, humidity, airflow and cleanliness of the air.

In modern society, it is common for many people to live densely in the limited space of various business buildings, public institution buildings, residential apartments, and condominiums in downtown areas, so the health of occupants in these places is common. In order to maintain and improve work efficiency, it is required to maintain the temperature, humidity, and cleanliness of indoor air in an appropriate state.

The air conditioning method for this is based on installing an air conditioner in the air conditioning room and supplying the air conditioned by the air conditioner to each room or area through a duct. Based on the air distribution method, it can be divided into a central method and an individual method. have. Among them, the central method produces heat medium such as cold water and hot water from heat source facilities such as refrigerators and boilers installed in the central air conditioning room, supplies them to the air conditioner, and supplies the air conditioned from the air conditioner to each room or zone. supply to the zone.

The central air conditioning method can be divided into a constant air volume method and a variable air volume method depending on whether the temperature or air volume of the air supplied to each room or zone is changed to match the load variation in the room. Among them, the constant air volume system (CAV) is a method to cope with changes in the load in the room by changing the blowing temperature while maintaining the air volume constant, and the variable air volume system (VAV) is a method to control the blowing temperature. It is a method of controlling the indoor temperature by maintaining it constant and changing the amount of air blown according to load fluctuations.

In general, the constant airflow method is mainly used where the range of indoor load fluctuation is small, and the variable airflow method that changes the airflow volume is mainly used where the load fluctuation is large.

However, in the case of the conventional variable air flow rate method in which the air supply air volume is adjusted according to changes in room temperature, the air supply air volume actually supplied to each room or zone could not be determined. In addition, the ventilation air volume discharged from each room or zone varies greatly depending on the distance from the air conditioning room where the air conditioner is installed, so it was not possible to accurately determine the ventilation volume for each room or zone.

Also, in the case of the central air conditioning system, air supplied by one air supply fan is distributed to each room or zone through a duct. If there is a sudden change in the air volume supplied to one room or zone, the amount of air supplied to another room or zone will also affect Therefore, the occupants located in other rooms or areas had no choice but to feel uncomfortable by the fluctuating air volume regardless of their intentions.

However, in the prior art, it is impossible to determine the amount of air supplied to each room or zone and the amount of ventilation exhausted from each room or zone, so even if the occupants feel uncomfortable because the amount of air supplied to each room or zone changes rapidly, it is possible to quickly respond There is no problem.

In addition, in the conventional variable air volume method, by measuring the static pressure inside the duct that supplies the air conditioned by the air conditioner to each room or zone, the load fluctuation was checked and the rotation speed of the supply fan was controlled. had to install a static pressure sensor.

However, in the case of measuring the static pressure of the duct with a static pressure sensor, it is only possible to grasp the total air volume supplied by the air supply fan, but it is not possible to determine the air supply air volume supplied to each room or zone, so the change in the air volume supplied to each room or zone There is a problem that cannot be quickly dealt with by checking the

An embodiment of the present invention provides a smart air conditioning system capable of stably and automatically controlling the supply air volume supplied to each zone.

According to an embodiment of the present invention, a smart air conditioning system includes an air supply fan for supplying air to a room, an air supply duct for transferring the air discharged from the air supply fan to a plurality of zones, and the air supply fan includes the air supply duct a total air flow measurement device for measuring the total air supply air volume of air supplied through the air supply air volume control unit for each zone, respectively, installed in each of the plurality of zones to control the flow rate of air supplied to the plurality of zones through the air supply duct an apparatus, an air supply air volume measuring device for each zone installed in each of the plurality of zones to measure the flow rate of air supplied to the plurality of zones according to an opening rate of the air supply air volume control device for each zone, and the total air supply air volume measuring device and a control device for controlling the air supply fan and the air supply air volume control device installed in each of the plurality of zones according to the air volume information provided by the air supply air volume measuring device for each zone installed in each of the plurality of zones.

The air supply air volume control device may be an electric diffuser or a variable air volume unit.

The electric diffuser includes a diffuser casing having an opening, a diffuser cone that adjusts an opening rate of the opening of the diffuser casing according to position movement, and a position of the diffuser cone installed inside the diffuser cone or inside the diffuser casing It may include a driving motor to move the.

The variable air volume unit includes an air volume control chamber having one side connected to the air supply duct, a plurality of air supply ports connected to the other side of the air volume control chamfer, an air volume control damper installed between the one side and the other side of the air volume control chamber, and the and a damper driving unit for driving the air volume control damper.

The control device may control the rotation speed of the air supply fan so that the air volume measured by the total air supply air volume measuring device follows the total air volume measured by the air supply air volume measuring device for each zone installed in each of the plurality of zones.

When the opening rate of the air supply air volume control device for each zone installed in one of the plurality of zones is changed, the control device is configured to maintain the air volume measured by the air supply air volume measurement device for each zone installed in another zone constant in another zone. It is possible to adjust the opening rate of the air supply air volume control device for each zone installed in the .

The apparatus for measuring air volume for each zone may include a fan for detecting air volume.

The air supply air volume measuring device for each zone may further include a generator connected to the air volume detecting fan to convert the rotational motion of the air volume detecting fan into electricity. And the electricity generated by the generator may drive the air supply air volume control device for each zone.

The smart air conditioning system may further include a duct connection part extending in a direction crossing the longitudinal direction of the air supply duct to connect the air supply duct and the air supply air volume control device for each zone installed in each of the plurality of zones, respectively. A rotation center of the air volume sensing fan may coincide with a center of the duct connection part, and a diameter of the air volume sensing fan may be formed to be greater than 50% of a diameter of the duct connection part.

In addition, the smart air conditioning system may further include a room controller installed in each of the plurality of zones. In addition, the room controller may receive the desired temperature of the occupant and adjust the opening rate of the air supply air volume control device for each zone so that each zone maintains the desired temperature.

The smart air conditioning system includes a ventilation fan for discharging indoor air to the outside, a ventilation duct for moving air to be discharged by the ventilation fan in the plurality of zones, and a ventilation fan for ventilating through the ventilation duct. a total ventilation air volume measuring device for measuring the total ventilation air volume of air; a ventilation air volume control device for each zone installed in each of the plurality of zones to control the flow rate of air discharged from the plurality of zones through the ventilation duct; It may further include a ventilation air volume measuring device for each zone that is installed in each of the plurality of zones and measures the flow rate of air discharged from the plurality of zones according to the opening rate of the ventilation air volume control device for each zone.

The control device may control the rotation speed of the ventilation fan so that the air volume measured by the total ventilation air volume measuring device follows the total air volume measured by the ventilation air volume measuring device for each zone installed in each of the plurality of zones.

When the opening rate of the ventilation air volume control device for each zone installed in one of the plurality of zones is changed, the control device is configured to maintain the air volume measured by the ventilation air volume measuring device for each zone installed in another zone constant in another zone. It is possible to adjust the opening rate of the ventilation air volume control device for each zone installed in the .

According to an embodiment of the present invention, the smart air conditioning system can stably and automatically control the supply air volume supplied to each zone.

1 is a block diagram of a smart air conditioning system according to a first embodiment of the present invention.
FIG. 2 is an enlarged view of an air supply air volume control device for each zone and an air supply air volume measurement device for each zone used in the smart air conditioning system of FIG. 1 .
FIG. 3 is a perspective view exemplarily illustrating an air volume sensing fan used as a device for measuring air volume for each zone of FIG. 2 .
4 to 7 are configuration diagrams illustrating an operating state of an air conditioning system according to a comparative example.
8 to 10 are block diagrams showing the operating state of the smart air conditioning system according to the experimental example.
11 is a block diagram of a smart air conditioning system according to a second embodiment of the present invention.
12 is a block diagram of a smart air conditioning system according to a third embodiment of the present invention.
13 and 14 show an air volume control device for each zone used in the smart air conditioning system of FIG. 12 .

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In addition, in various embodiments, components having the same configuration are typically described in the first embodiment using the same reference numerals, and in other embodiments, only configurations different from those of the first embodiment will be described. do.

It is noted that the drawings are schematic and not drawn to scale. Relative dimensions and proportions of parts in the drawings are shown exaggerated or reduced in size for clarity and convenience in the drawings, and any dimensions are illustrative only and not limiting. In addition, the same reference numerals are used to indicate like features to the same structure, element, or part appearing in two or more drawings.

The embodiment of the present invention specifically represents an ideal embodiment of the present invention. As a result, various modifications of the diagram are expected. Therefore, the embodiment is not limited to a specific shape of the illustrated area, and includes, for example, a shape modification by manufacturing.

Hereinafter, a smart air conditioning system 101 according to a first embodiment of the present invention will be described with reference to FIGS. 1 and 2 . The smart air conditioning system 101 according to the first embodiment of the present invention performs air conditioning for a plurality of zones.

As shown in FIG. 1 , the smart air conditioning system 101 according to the first embodiment of the present invention includes an air supply fan 310 , an air supply duct 610 , a total air supply air volume measurement device 320 , and an air supply air volume for each zone. It includes a control device 360 , a zone-specific air supply air volume measurement device 370 , and a control device 700 .

In addition, the smart air conditioning system 101 according to the first embodiment of the present invention includes a duct connection part 650 , a ventilation fan 410 , a ventilation duct 620 , a total ventilation air volume measuring device 420 , and a ventilation hole 490 . , and may further include a ventilation air volume measuring device 470 for each zone.

In addition, the smart air conditioning system 101 may further include a supply air temperature sensor 770 , a control valve 780 , and a room controller 750 .

The air supply fan 310 is installed to supply air into the room. The air discharged from the air supply fan 310 is transferred through an air supply duct 610 to be described later connected to each zone.

In addition, the air supply fan 310 may include an air supply fan body 311 and an air supply fan inverter 315 . The air supply fan inverter 315 may control the rotation speed of the air supply fan main body 311 according to a signal from the control device 700 to be described later.

The air supply duct 610 connects the air supply fan 310 and the air supply air volume control device 360 for each zone respectively installed in a plurality of zones to be described later. That is, the outdoor air discharged by the air supply fan 301 may move along the air supply duct 610 and may be introduced into the room through the air supply air volume control unit 360 for each zone.

The supply air temperature sensor 770 measures the temperature of the air discharged by the air supply fan 310 to the air supply duct 610 .

The total air supply air volume measuring device 320 measures the total air supply air volume of the air supplied by the air supply fan 310 to a plurality of zones through the air supply duct 610 . That is, the total air supply air volume measuring device 320 measures the total air supply air volume of the air discharged from the air supply fan 310 to the air supply duct 610 .

The air supply air volume control device 360 for each zone is installed in each of the plurality of zones and connected to the air supply duct 610 , and controls the flow rate of air supplied to the plurality of zones through the air supply duct 610 for each zone.

In the first embodiment of the present invention, the air supply air volume control device 360 for each zone may be an electric diffuser. Specifically, the electric diffuser used as the air supply air volume control device 360 for each zone is, as shown in FIG. 2, the diffuser casing 365 having an opening, and the opening of the diffuser casing 365 according to the movement of the position. It may include a diffuser cone 361 for adjusting the opening rate, and a driving motor 363 installed inside the diffuser cone 361 or inside the diffuser casing 365 to move the position of the diffuser cone 361. . Here, the opening of the diffuser casing 365 serves as an air supply port.

As shown in FIG. 2, the duct connection part 650 extends in a direction intersecting the longitudinal direction of the air supply duct 610, and the air supply air volume control device 360 for each zone installed in each of the supply duct 610 and the plurality of zones. connect each

The air supply air volume measuring device 370 for each zone is installed in each of the plurality of zones to measure the air supply air volume supplied to each zone. In particular, the air supply air volume measuring device 370 for each zone may measure a change in flow rate of air supplied to a plurality of zones according to a change in the opening rate of the air supply air volume adjusting device 360 for each zone. That is, by feedback-controlling the opening rate of the air supply air volume control device 360 for each zone according to the air volume measured by the air supply air volume measuring device 370 for each zone, it is supplied to each zone through the zone-specific supply air volume control device 360. The supply air volume can be kept constant.

For example, even though the opening rate of the air supply air volume control device 360 for each zone is kept constant, the operating state of the air supply fan 310 or the opening rate of the air supply air volume control device 360 for each zone installed in another zone Depending on the change, the supply air volume supplied to the area may be increased regardless of the intention of the occupants. However, in the first embodiment of the present invention, when the air supply air volume measuring device 370 for each zone detects an increase or decrease in the supply air volume supplied to the zone, the opening rate of the air supply air volume control device 360 for each zone is measured in real time based on this. Since it can be controlled by the occupant, it is possible to minimize the fluctuation of the supply air volume supplied to the corresponding area regardless of the intention of the occupant.

Specifically, the air supply air volume measuring device 370 for each zone may include an air volume sensing fan. 3 is a perspective view exemplarily showing the shape of the air volume sensing fan. That is, the air supply air volume measuring device 370 for each zone may calculate the air volume based on the number of rotations of the air volume sensing fan rotated by the air supply.

In addition, the air supply air volume measuring device 370 for each zone may be installed on the duct connection part 650 or installed on the diffuser casing 365 of the electric diffuser used as the zone supply air volume control device 360 . In this case, the rotational center of the air volume sensing fan coincides with the center of the duct connection part 650 , and the diameter of the air volume detection fan may be formed to be greater than 50% of the diameter of the duct connection part 650 . In this case, as the diameter of the air volume sensing fan is as close as possible to the diameter of the duct connection part 650 in a range in which rotation is possible without interference, the accuracy of air volume measurement may be improved.

On the other hand, since the air supply duct 610 and the connecting duct 650 are not formed only in a straight line and are bent at least once or are connected in a direction crossing each other, the air flow distribution within the supply air duct 610 and the connecting duct 650 is It is not uniform and is biased. Therefore, when measuring the amount of air supplied through the air supply duct 610 and the connecting duct 650 at any one point, the error is bound to increase due to the deflected air flow, and even if a reverse flow occurs in some areas instantaneously, it is not detected. can not do it.

However, according to the first embodiment of the present invention, since the air supply air volume measuring device 370 for each zone measures the air volume through the air volume sensing fan, it is possible to measure the air volume more accurately even if the air flow distribution is not uniform and is deflected. In addition, since the air volume is measured in the rotational speed and the rotational direction of the air volume sensing fan, it is possible to detect even if a headwind is generated.

In addition, since it is possible to obtain the effect that the deflected air flow is evenly spread while passing through the air volume detection fan, the air flowing into each zone through the air supply air volume control device 360 for each zone after going through the air supply air volume measuring device 370 for each zone is reduced. It can also reduce airflow drift.

In addition, the air supply air volume measuring device 370 for each zone may further include a generator connected to the air volume detecting fan to convert the rotational motion of the air volume detecting fan into electricity. And the electric furnace generated by the generator may drive the driving motor 363 of the air supply air volume control device 360 for each zone. In addition, the zone-specific air supply air flow measurement device 370 may further include a battery for storing electricity generated by the generator. In addition, the zone-specific air supply air volume control device 360 may operate with electricity supplied from the outside when the electricity generated by the generator is insufficient.

As shown in FIG. 1 , the room controller 750 may be installed in each of a plurality of zones. The room controller 750 may receive information from the air supply air volume measuring device 370 for each zone and control the operation of the air supply air volume adjusting device 360 for each zone. That is, the room controller 750 may include a control unit for controlling the operation of the air supply air volume control device 360 for each zone.

Also, the room controller 750 may receive the desired air volume of the occupants for each zone. That is, the room controller 750 may further include an input unit for receiving the desired air volume of the occupant.

In addition, the room controller 750 may further include a temperature sensor for measuring the indoor temperature of each zone. However, the first embodiment of the present invention is not limited thereto, and the temperature sensor for measuring the indoor temperature of each zone may be installed in the air supply air volume control device 360 for each zone.

Accordingly, the room controller 750 may adjust the opening rate of the air supply air volume control device 360 for each zone to maintain the desired indoor temperature input by the occupant. That is, the room controller 750 adjusts the opening rate of the air volume control device 360 for each zone according to the difference between the desired indoor temperature input by the occupant and the current indoor temperature.

Specifically, the room controller 750 includes the temperature of the air supplied by the supply fan 310 measured by the supply air temperature sensor 770 and the amount of air flowing into each zone measured by the supply air volume measuring device 370 for each zone, And, based on the current indoor temperature, the opening rate of the air supply air volume control device 360 for each zone is automatically adjusted so that the temperature of each zone becomes the desired indoor temperature input by the occupant.

Meanwhile, the control unit of the room controller 750 may not be included in the room controller 750 but may be included in the control device 700 to be described later.

The control device 700 includes a total supply air volume measurement device 320 , a zone-specific supply air volume measurement device 370 , a supply air temperature sensor 770 , a total ventilation air volume measurement device 420 , and a zone-specific ventilation air volume measurement device 470 . ) and the like, and controls the supply fan 310 , the air supply air volume control unit 360 for each zone, the ventilation fan 410 , and the control valve 780 .

In particular, in the first embodiment of the present invention, the control device 700 controls the air supply fan ( 310) and organically control the supply air volume control device 360 installed in each of the plurality of zones.

Specifically, the control device 700 controls the air supply fan 310 so that the air volume measured by the total air supply air volume measuring device 320 tracks the total air volume measured by the air supply air volume measuring device 370 for each zone installed in each of the plurality of zones. ) to control the number of rotations. The sum of the air volume measured by the total supply air volume measuring device 320 and the air volume measured by the air supply air volume measuring device 370 for each zone does not always match. Since there is a difference in distance between the air supply fan 310 and the plurality of zones, if the air volume supplied to any one of the plurality of zones changes due to a change in the opening rate of the air volume control device 360 for each zone, the total air supply air flow measurement device ( The sum of the air volume measured by 320 and the air volume measured by the supply air volume measuring device 370 for each zone is temporarily changed.

For example, when the air supply air volume control device 360 for each zone installed in any one of the plurality of zones is closed and the measured air volume of the supply air volume measurement device 370 for each zone in the corresponding zone becomes 0, the control device 700 is By reducing the rotational speed of the air supply fan 310, the total air volume supplied by the air supply fan 310 is controlled to follow the sum of the air volumes measured by the air supply air volume measuring device 370 for each zone installed in the remaining areas.

In this way, by controlling the supply fan 310 to discharge air only by the total amount of the air volume measured by the supply air volume measuring device 370 for each zone installed in each of the plurality of zones, the static pressure of the supply duct 610 is excessively increased. Not only can it be prevented, but also it is possible to efficiently operate the air supply fan 310 to reduce energy wastage.

In addition, it is possible to control the air supply fan 310 without a static pressure sensor for measuring the static pressure of the air supply duct 610 as well as a method of controlling the air supply fan 310 using a static pressure sensor. The control method of the air conditioning system 101 according to the embodiment can greatly improve the reaction speed of the air supply fan 310 to cope with environmental changes for each zone.

In addition, when the opening rate of the air supply air volume control device 360 for each zone installed in one of the plurality of zones is changed, the control device 700 determines the air volume measured by the air supply air volume measurement device 370 for each zone installed in another zone. The opening rate of the air supply air volume control device 360 for each zone installed in another zone is adjusted to keep this constant.

When the air supply air volume control device 360 for each zone installed in any one of the plurality of zones is closed, the amount of air reduced by the air supply fan 310 is reduced even if the control device 700 reduces the rotation speed of the air supply fan 310 . It takes time to reach each zone. Accordingly, the volume of air supplied to other zones may be temporarily increased by the static pressure wave generated when the air supply air volume control device 360 for each zone is closed among the plurality of zones, and the air supply for each zone installed in each zone may be temporarily increased. The air volume measuring device 370 detects the change in the air volume caused by the static pressure wave and adjusts the opening rate of the air supply air volume control device 360 for each zone installed in each zone, thereby maintaining a constant supply air volume supplied to each zone. have. In addition, in the first embodiment of the present invention, since the rotation speed of the air supply fan 310 is quickly adjusted, it is possible to minimize the static pressure rise of the air supply duct 610 and quickly eliminate the influence of the static pressure wave.

The ventilation fan 410 discharges the air for each zone to the outside. Specifically, the ventilation fan 410 may include a ventilation fan body 411 and a ventilation fan inverter 415 . The ventilation fan inverter 415 may control the rotation speed of the ventilation fan main body 411 according to a signal from the control device 700 .

The ventilation duct 620 connects a plurality of zones and the ventilation fan 410 to ventilate the air of each zone to the outside. That is, the ventilation duct 620 is installed to move the air to be discharged by the ventilation fan 410 from the plurality of zones.

The ventilation holes 490 are installed for each of the plurality of zones and are connected to the ventilation ducts 620 .

The total ventilation air volume measurement device measures the total ventilation air volume of the air ventilated by the ventilation fan 410 through the ventilation duct 620 .

The ventilation air volume measuring device 470 for each zone is installed in each of the plurality of zones to measure the amount of air discharged from the plurality of zones, respectively.

The control valve 780 may indirectly control the amount of air introduced into or discharged from each zone through the air supply fan 310 and the ventilation fan 410 .

With such a configuration, the smart air conditioning system 101 according to the first embodiment of the present invention can stably and automatically control the amount of air supplied to each zone.

In addition, energy consumed in the operation of the smart air conditioning system 101 can be saved by smartly minimizing unnecessary operation of the air supply fan 310 .

In addition, the smart air conditioning system 101 according to the first embodiment of the present invention also implements a CAV (constant air volume) function capable of supplying a predetermined air volume to each zone at any time even when a change in pressure in the air supply duct 610 occurs. can

That is, the actual detected by the set air volume Qs of the air supply air volume control device 370 for each zone instructed by the control device 700 and the air volume measurement device 380 for each zone, that is, the rotation speed (RPM) of the air volume detection fan. It may be operated to automatically adjust the opening rate of the air supply air volume control device 370 for each zone so that there is no difference between the discharge air volumes Qd of the air supply air volume control device 370 for each zone. That is, the discharge air volume (Qd) may be automatically adjusted so that the set air volume (Qs).

Hereinafter, a comparative example of controlling an air supply fan using the static pressure sensor 76 and an experimental example according to the first embodiment of the present invention will be described with reference to FIGS. 4 to 10 .

4 to 7 sequentially show the operation process of the conventional air conditioning system for controlling the air supply fan using the static pressure sensor 76.

First, as shown in FIG. 4 , when the air supply fan supplies a total air volume of 1000CMH, an air volume of 500CMH is supplied to each of the two zones.

Next, as shown in FIG. 5, when the air supply air volume control device 36 for each zone installed in one of the two zones is closed and the opening rate is 0, the air supply air volume to the corresponding zone also becomes 0 CMH, and a static pressure wave is generated. Accordingly, the amount of air supplied to the other zones is greatly increased. As an example, a supply air volume of 700CMH may be supplied to another zone. In addition, as the supply air volume supplied to the other zones is greatly increased, the indoor temperature of the other zones is lowered, and when the indoor temperature is lowered, the room controller operates to reduce the opening rate of the air supply air volume control device 36 for each zone.

In this way, when the opening rate of the air supply air volume control device 36 for each zone in one of the two zones becomes 0, the air supply air volume control device 36 for each zone in the other zone also lowers the opening ratio, and As shown, the static pressure of the air supply duct 61 is greatly increased.

As shown in Fig. 7, when the static pressure sensor 76 detects an increase in the static pressure of the air supply duct 61, only then does the rotation speed of the air supply fan decrease to reduce the total air supply air volume, and each zone installed in another zone As the opening rate of the supply air volume control device 36 returns to the set opening rate, the air conditioning system finds stability.

Meanwhile, FIGS. 8 to 10 sequentially show the operation process of the smart air conditioning system 101 according to the first embodiment of the present invention.

First, as shown in FIG. 8 , when the air supply fan 310 supplies a total air volume of 1000CMH, an air volume of 500CMH is supplied to each of the two zones.

Next, as shown in FIG. 9, when the air supply air volume control device 360 installed in one of the two zones is closed and the opening rate is 0, the air supply air volume to the corresponding zone also becomes 0 CMH, and a static pressure wave is generated. In this case, the control device 700 immediately controls the air supply fan 310 so that the air volume measured by the total air supply air volume measuring device 320 follows the total air volume measured by the air supply air volume measuring device 370 for each zone installed in each of the plurality of zones. ) to control the number of rotations.

Therefore, when the air supply air volume control device 360 for each zone installed in one of the two zones is closed and the measured air volume of the zone supply air volume measurement device 370 installed in the corresponding zone becomes 0, the control device 700 controls the air supply fan By immediately reducing the rotational speed of 310, the total air volume supplied by the air supply fan 310 is controlled to follow the sum of the air volumes measured by the air supply air volume measuring device 370 for each zone installed in the remaining areas, thereby controlling the air supply duct 610. It prevents the static pressure of the air conditioner from rising excessively and enables the smart air conditioning system 101 to quickly escape from the influence of the static pressure wave.

However, when the air supply air volume control device 360 installed in one of the two zones is closed, the air volume reduced by the air supply fan 310 even if the control device 700 reduces the rotation speed of the air supply fan 310 . Since it takes time to reach this other zone, the amount of air supplied to another zone may be temporarily increased by the static pressure wave. According to the first embodiment of the present invention, the air supply air volume measuring device for each zone installed in another zone By sensing the change in the air volume 370 and adjusting the opening rate of the air supply air volume control device 360 for each zone installed in another zone, the air supply air volume supplied to the other zone may be constantly maintained.

As shown in FIG. 10, in the first embodiment of the present invention, it is possible to quickly control the rotation speed of the air supply fan 310 in response to a change in the amount of air supplied to each zone without using a static pressure sensor, The smart air conditioning system 101 is quickly stabilized while maintaining a constant supply air volume supplied to the other zones even if the air supply air volume supplied to one of the plurality of zones rapidly fluctuates.

In addition, even if the supply air volume supplied to any one of the plurality of zones is rapidly changed, the smart air conditioning system 101 can prevent excessive static pressure rise of the supply duct 610 and the supply fan 310 is unnecessary. It is possible to reduce energy consumption and improve the lifespan of the air supply fan 310 by minimizing the operation.

Hereinafter, a smart air conditioning system 102 according to a second embodiment of the present invention will be described with reference to FIG. 11 .

11 , the smart air conditioning system 102 according to the second embodiment of the present invention is installed in each of a plurality of zones to adjust the flow rate of air discharged from the plurality of zones through the ventilation duct 620 . It further includes a ventilation air volume control device 460 for each zone.

The ventilation air volume measuring device 470 for each zone measures the flow rate of air discharged from a plurality of zones according to the opening rate of the ventilation air volume adjusting device 460 for each zone. And when the opening rate of the ventilation air volume control device 460 for each zone installed in one of the plurality of zones is changed, the control device 700 determines that the air volume measured by the ventilation air volume measuring device 470 for each zone installed in another zone is changed. It is possible to adjust the opening rate of the ventilation air volume control device 460 for each zone installed in another zone to be kept constant.

In addition, the control device 700 controls the air supply fan 420 so that the air volume measured by the total ventilation air volume measuring device 420 follows the total air volume measured by the ventilation air volume measuring device 470 for each zone installed in each of the plurality of zones. can control the rotation speed.

In addition, the smart air conditioning system 102 according to the second embodiment of the present invention controls the air supply air volume for each zone with the air volume information measured by the zone-specific supply air volume measurement device 370 and the zone-specific ventilation air volume measurement device 470 . By controlling the device 360 and the ventilation air volume control device 460 for each zone, each zone may be maintained at the same atmospheric pressure, a positive pressure higher than the atmospheric pressure, or a negative pressure lower than the atmospheric pressure.

That is, the smart air conditioning system 102 according to the second embodiment of the present invention can make each zone a positive pressure room or a negative pressure room according to the use.

With such a configuration, the smart air conditioning system 102 according to the second embodiment of the present invention can stably and automatically control the supply air volume supplied to each zone.

In addition, unnecessary operation of the ventilation fan 410 can also be smartly minimized, thereby saving energy consumed in the operation of the smart air conditioning system 102 .

In addition, the smart air conditioning system 102 according to the second embodiment of the present invention may be usefully used in various places such as a research institute or a hospital.

Hereinafter, a smart air conditioning system 103 according to a third embodiment of the present invention will be described with reference to FIG. 12 .

As shown in FIG. 12 , the smart air conditioning system 103 according to the third embodiment of the present invention may use a variable air volume unit as the air supply air volume control device 380 for each zone.

13 and 14 specifically show the variable air volume unit from different angles. 13 and 14 , the variable air volume unit has an air volume control chamber 381 connected to the air supply duct 620 on one side, and a plurality of air supply ports connected to the other side of the air volume control chamfer 381, and the air volume control chamber It may include a damper driving unit 385 for driving an air volume control damper 387 for adjusting the opening ratio of the opening 389 installed between one side and the other side of the 381, and the air volume control damper 387.

That is, in the first embodiment, the electric diffuser is installed for each air inlet, but according to the third embodiment, the amount of air discharged from the plurality of air inlets installed in each zone can be adjusted through one variable air volume unit.

With such a configuration, the smart air conditioning system 103 according to the third embodiment of the present invention can also stably and automatically control the amount of air supplied to each zone.

In addition, the present invention is not limited to the above-described embodiments, and in another embodiment of the present invention, the first embodiment and the second embodiment may be combined or the second embodiment and the third embodiment may be combined and implemented. .

Although the embodiments of the present invention have been described above with reference to the accompanying drawings, those skilled in the art to which the present invention pertains can understand that the present invention may be embodied in other specific forms without changing the technical spirit or essential features thereof. will be.

Therefore, the embodiments described above are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the following claims, the meaning and scope of the claims, and All changes or modifications derived from the equivalent concept should be construed as being included in the scope of the present invention.

101, 102, 103: smart air conditioning system
310: air supply fan
311: air supply fan body
315: air supply fan inverter
320: total air supply air volume measuring device
360, 380: air supply air volume control device for each zone
361: diffuser cone
363: drive motor
365: diffuser casing
370: air supply air volume measuring device for each zone
410: ventilation fan
411: ventilation fan body
415: ventilation fan inverter
420: total ventilation air volume measuring device
460: ventilation air volume control device for each zone
470: ventilation air volume measuring device for each zone
490: ventilation hole
610: supply air duct
620: ventilation duct
650: duct connection
700: control device
750: room controller
770: supply air temperature sensor
780: control valve

Claims (13)

an air supply fan for supplying air into the room;
an air supply duct for transferring the air discharged from the air supply fan to a plurality of zones;
a total air supply air volume measuring device for measuring a total air supply air volume of the air supplied by the air supply fan through the air supply duct;
an air supply air volume control device for each zone installed in each of the plurality of zones to control the flow rate of air supplied to the plurality of zones through the air supply duct;
an air supply air volume measuring device for each zone installed in each of the plurality of zones to measure the flow rate of air supplied to the plurality of zones according to an opening rate of the air supply air volume control device for each zone; and
A control device for controlling the air supply fan and the air supply air volume control device installed in each of the plurality of zones according to the air volume information provided by the total air supply air volume measuring device and the air supply air volume measuring device for each zone installed in each of the plurality of zones
A smart air conditioning system that includes According to claim 1,
The smart air conditioning system, characterized in that the supply air volume control device is an electric diffuser or a variable air volume unit (Variable Air Volume Unit). 3. The method of claim 2,
The electric diffuser,
a diffuser casing having an opening;
a diffuser cone for adjusting an opening rate of the opening of the diffuser casing according to the movement of the position; and
A driving motor installed inside the diffuser cone or inside the diffuser casing to move the position of the diffuser cone
A smart air conditioning system comprising a. 3. The method of claim 2,
The variable air volume unit,
an air volume control chamber having one side connected to the air supply duct;
a plurality of air supply ports connected to the other side of the air volume control chamfer;
an air volume control damper installed between the one side and the other side of the air volume control chamber; and
Damper driving unit for driving the air volume control damper
A smart air conditioning system comprising a. According to claim 1,
The control device controls the rotation speed of the air supply fan so that the air volume measured by the total air supply air volume measuring device follows the sum of the air volume measured by the air supply air volume measuring device for each zone installed in each of the plurality of zones. smart air conditioning system. 6. The method of claim 5,
When the control device changes the opening rate of the air supply air volume control device for each zone installed in any one zone among the plurality of zones,
The smart air conditioning system, characterized in that the opening rate of the air supply air volume control device for each zone installed in another zone is adjusted so that the air volume measured by the air supply air volume measuring device for each zone installed in another zone is maintained constant. According to claim 1,
The smart air conditioning system, characterized in that the air supply air volume measuring device for each zone includes an air volume detection fan. 8. The method of claim 7,
The air supply air volume measuring device for each zone further comprises a generator connected to the air volume detecting fan to convert the rotational motion of the air volume detecting fan into electricity,
The smart air conditioning system, characterized in that the electricity generated by the generator drives the air supply air volume control device for each zone. 8. The method of claim 7,
Further comprising a duct connecting portion extending in a direction crossing the longitudinal direction of the air supply duct to connect the air supply duct and the air supply air volume control device for each zone installed in each of the plurality of zones, respectively,
The rotation center of the air volume sensing fan coincides with the center of the duct connection part,
The smart air conditioning system, characterized in that the diameter of the air volume sensing fan is greater than 50% of the diameter of the duct connection part. According to claim 1,
Further comprising a room controller installed in each of the plurality of zones,
The room controller receives the desired temperature of the occupant and adjusts the opening rate of the air supply air volume control device for each zone so that each zone maintains the desired temperature. 11. The method according to any one of claims 1 to 10,
a ventilation fan for discharging indoor air to the outside;
a ventilation duct for moving the air to be discharged by the ventilation fan in the plurality of zones;
a total ventilation air volume measuring device for measuring a total ventilation air volume of the air ventilated by the ventilation fan through the ventilation duct;
a ventilation air volume control device for each zone installed in each of the plurality of zones to control the flow rate of air discharged from the plurality of zones through the ventilation duct; and
A ventilation air volume measuring device for each zone that is installed in each of the plurality of zones and measures the flow rate of air discharged from the plurality of zones according to the opening rate of the ventilation air volume control device for each zone
Smart air conditioning system, characterized in that it further comprises. 12. The method of claim 11,
The control device controls the number of rotations of the ventilation fan so that the air volume measured by the total ventilation air volume measuring device follows the total air volume measured by the ventilation air volume measuring device for each zone installed in each of the plurality of zones. smart air conditioning system. 13. The method of claim 12,
When the control device changes the opening rate of the ventilation air volume control device for each zone installed in any one zone among the plurality of zones,
The smart air conditioning system, characterized in that the opening rate of the ventilation air volume control device for each zone installed in another zone is adjusted so that the air volume measured by the ventilation air volume measuring device for each zone installed in another zone is maintained constant.

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