KR102478868B1 - Constant air volume electric damper and centralized high-efficiency constant static pressure ventilation system having same - Google Patents

Abstract

According to the present invention, disclosed is a constant airflow electric damper and a centralized high-efficiency constant static pressure ventilation system having the same. According to an embodiment of the present invention, the constant airflow electric damper comprises: a cylindrical body in which a flow passage is formed; an opening and closing part which is coupled to the body to open and close the flow passage; a sensing part which is coupled to the body to measure the airflow passing through the flow passage; and a control part which adjusts the opening and closing part based on information transmitted from the sensing part to maintain a constant airflow. The sensing part may include: a radial mounting bracket which is coupled to the inner circumference of the body; a generator which is coupled at the center of the mounting bracket to convert rotational energy into electrical energy; a rotating fan which is coupled to the generator to be rotatable; and a computation part which measures the airflow by using the electrical energy produced by the generator. Therefore, the resultant constant airflow electric damper can fundamentally block the noise generated from a power-driven exhaust device and save energy.

Description

Constant air volume electric damper and centralized high-efficiency constant static pressure ventilation system having same

The present invention relates to a constant air volume electric damper and a centralized high-efficiency constant pressure ventilation system having the same, and more particularly, to a constant air volume applied to a ventilation system installed to discharge air inside a building such as an apartment building or a building to the outside. It's about electric dampers.

In general, exhaust ducts installed in buildings such as multi-unit dwellings such as apartments or high-rise buildings with many offices are vertical exhaust pipes (rising ducts) installed in the vertical direction of the structure and a number of branch exhaust pipes (branch pipes) connected to the interior of each floor. this is connected

In a conventional vertical exhaust pipe, an exhaust fan operated by a power source or a non-powered exhaust fan rotating by natural wind is installed to quickly discharge polluted air inside, and the exhaust fan installed at the top of the vertical exhaust pipe circulates indoor air to a branch exhaust pipe. And it is guided to the vertical exhaust pipe and discharged to the outside.

In the conventional ventilation system, a powered exhaust device such as a hood fan in the kitchen or a ventilation fan in the bathroom is formed to forcibly collect indoor air, and the collected indoor air is discharged to the outside via a branch exhaust pipe and a vertical exhaust pipe through the exhaust fan. It is configured to be forced exhaust.

In addition, the ventilation system controls the air volume by adjusting the opening of the damper installed in the branch exhaust pipe in order to supply a constant air volume even when the pressure changes.

Korean Registered Patent No. 10-0846230 (registration date: July 08, 2008)

One problem to be solved by the present invention is to provide a constant air volume electric damper capable of maintaining a constant air volume automatically discharged.

Another problem to be solved by the present invention is to provide a constant air volume motorized damper that can be applied to a centralized high-efficiency constant pressure ventilation system capable of supplying a constant air volume regardless of changes in the environment outside the building.

In order to achieve the above object, a constant air volume electric damper according to an embodiment of the present invention includes a cylindrical body in which a flow path is formed; An opening and closing unit coupled to the body to open and close the flow path; a sensing unit coupled to the body and capable of measuring an air volume passing through the flow path; and a control unit that maintains a constant air volume by adjusting the opening/closing unit based on information transmitted from the sensing unit.

In addition, in order to achieve the above object, the sensing unit of the constant air volume electric damper according to an embodiment of the present invention, a radial holder coupled to the inner circumferential surface of the body; A generator coupled to the center of the cradle to convert rotational energy into electrical energy; Rotating fan coupled to the generator to rotate; And it may include a calculation unit for measuring the air volume by using the electrical energy produced by the generator.

In addition, in order to achieve the above object, the calculation unit of the constant air volume electric damper according to an embodiment of the present invention transmits air volume information changed by the operation of the servo motor to the controller, and the controller operates the servo motor based on the air volume information. Thus, the air volume can be kept constant.

In addition, in order to achieve the above object, the sensing unit of the constant air volume electric damper according to an embodiment of the present invention may further include an energy storage device capable of storing electrical energy produced by the generator.

In addition, in order to achieve the above object, the control unit of the constant air volume electric damper according to the embodiment of the present invention may operate the servo motor using electrical energy stored in the energy storage device.

In addition, in order to achieve the above object, one or more batteries of the constant air volume electric damper according to an embodiment of the present invention may be coupled to the cradle.

In addition, in order to achieve the above object, the opening and closing portion of the constant air volume electric damper according to an embodiment of the present invention, the shaft is rotatably coupled through the body; A disc-shaped blade coupled to the shaft to open and close the flow path; And it may include a servomotor coupled to the first duct to rotate the shaft.

In addition, in order to achieve the above object, a centralized high-efficiency constant pressure ventilation system having a constant air volume electric damper according to an embodiment of the present invention includes one or more standing ducts installed in a multi-story building; A plurality of branch pipes branching from the riser duct to each floor; A plurality of constant air volume electric dampers capable of opening and closing the branch pipes so that the air of each floor can move to the riser duct; a suction unit coupled to an upper portion of the riser duct and discharging air inside the riser duct to the outside; a sensor unit capable of measuring a difference between pressure inside the riser duct and atmospheric pressure; and a controller capable of operating the air intake unit and the constant air volume electric damper based on the information obtained from the sensor unit.

In addition, the controller of the centralized high-efficiency constant pressure ventilation system having the constant air volume motorized damper according to the embodiment of the present invention always maintains the pressure inside the riser duct at a negative pressure based on the atmospheric pressure by operating the suction unit and the constant air volume motorized damper. And the amount of air discharged to the plurality of branch pipes can be maintained the same.

According to the constant air amount electric damper according to an embodiment of the present invention, the opening and closing part can be automatically adjusted in conjunction with the amount of air passing through the passage.

In addition, according to the constant air volume electric damper according to an embodiment of the present invention, it is possible to perform maintenance work conveniently by separating the duct in which the opening/closing unit is installed and the duct in which the sensing unit is installed.

In addition, according to the constant air volume electric damper according to an embodiment of the present invention, the air volume can be measured using a sensor having a simple configuration.

In addition, according to the constant air amount electric damper according to an embodiment of the present invention, the control unit can adjust the opening and closing unit again using a change in air volume according to the adjustment of the opening and closing unit.

In addition, according to the centralized high-efficiency constant pressure ventilation system having a constant air volume motor damper according to an embodiment of the present invention, since the pressure inside the riser duct is always maintained at a negative pressure based on the atmospheric pressure, the air flowing into the riser duct is can be fundamentally prevented from flowing backward.

In addition, according to the centralized high-efficiency constant pressure ventilation system having a constant air volume motor damper according to an embodiment of the present invention, condensation can be prevented through rapid exhaust.

In addition, according to the centralized high-efficiency constant pressure ventilation system having a constant air volume motorized damper according to an embodiment of the present invention, since a powered exhaust device such as a hood fan in the kitchen or a ventilation fan in the bathroom is not required, the powered exhaust device It is possible to fundamentally block the noise generated from and save energy.

1 is a perspective view of a constant air volume electric damper according to an embodiment of the present invention.
2 is an exploded perspective view of the constant air volume electric damper of FIG. 1;
3 to 5 are side cross-sectional views of the constant air amount electric damper of FIG.
Figure 6 schematically shows the configuration of a centralized high-efficiency constant pressure ventilation system having a constant air volume motor damper according to an embodiment of the present invention.
Figure 7 schematically shows the configuration of the suction part of the centralized high-efficiency constant pressure ventilation system having a constant air volume motor damper according to an embodiment of the present invention.
FIG. 8 is a perspective view of an air purifier provided inside part A (auxiliary duct) of FIG. 1 .
9 schematically illustrates a wireless communication configuration of a centralized high-efficiency constant pressure ventilation system having a constant air volume motorized damper according to an embodiment of the present invention.

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

However, in describing the present invention, descriptions of already known functions or configurations will be omitted to clarify the gist of the present invention.

The X, Y, and Z axes shown in the drawing are arbitrarily determined for convenience of description, not for limitation of rights. , and the Z-axis is defined as pointing up and down.

Each direction described below is based on this, except for cases specifically limited otherwise.

Top (top), bottom (bottom), left and right (side or side), front (front, front), back (back, back), etc., which refer to directions in the description and claims of the invention, etc., are not intended to limit the use of rights. For convenience of description, the relative position between the drawings and configurations is set as a standard, and each direction described below is based on this, except when specifically limited otherwise.

1 to 5, the constant air volume electric damper 30 according to an embodiment of the present invention includes a cylindrical body 100 having a flow path formed therein; An opening/closing unit 200 coupled to the body 100 to open and close the passage; a sensing unit 300 coupled to the body 100 and capable of measuring the amount of air passing through the passage; and a control unit 400 that maintains a constant air volume by adjusting the opening/closing unit 200 based on information transmitted from the sensing unit 300 .

The constant air volume motorized damper 30 according to an embodiment of the present invention can automatically adjust the opening/closing unit 200 in conjunction with the air volume passing through the passage.

Referring to Figures 1 to 5, the body 100 is a configuration of a cylindrical shape that connects a line through which a fluid such as wind flows in and out.

The body 100 is a part where the opening/closing unit 200 and the sensing unit 300 are coupled.

The body 100 includes a first duct (not shown) to which the opening/closing unit 200 is coupled; and a second duct (not shown) connected to the first duct and to which the sensing unit 300 is coupled.

The body 100 may be formed by connecting a first duct and a second duct having a circular pipe shape.

If the first duct in which the opening/closing unit 200 is installed and the second duct in which the sensing unit 300 is installed are separated, the maintenance work can be conveniently performed when necessary.

The first duct is a part connected to the wind outflow line, and the passage inside the first duct can be opened or closed by the opening/closing unit 200 .

The second duct is a part connected to the wind flow line, and the sensing unit 300 may be coupled to the inside of the second duct.

The second duct may be formed with a fitting part (not shown) that protrudes or is recessed spaced apart from the inner circumferential surface, and the holder 310 may be fixed to the fitting part.

Referring to Figures 1 to 5, the opening and closing portion 200 is a shaft 210 rotatably coupled through the body 100; A disc-shaped blade 220 coupled to the shaft 210 to open and close the passage; And it may include a servo motor 230 coupled to the body 100 to rotate the shaft 210.

In the opening/closing unit 200, the blade 220 located inside the body 100 rotates the shaft 210 positioned perpendicular to the flow path as a rotating shaft to open and close the flow path to adjust the air volume.

The shaft 210 is a component corresponding to a rotating shaft for rotating the blade 220 and can be rotated by the servomotor 230 .

The shaft 210 may be installed through the body 100 so as to be positioned perpendicularly to the flow path.

The blade 220 is configured to open and close the passage, and may be rotated by the servomotor 230 rotating the shaft 210 .

The servomotor 230 may be coupled to the outside of the body 100 and electrically connected to the control unit 400 .

The rotation shaft of the servo motor 230 may be connected to one end of the shaft 210 protruding out of the body 100 .

1 to 5, the sensing unit 300 includes a radial holder 310 coupled to an inner circumferential surface of the body 100; A generator 320 coupled to the center of the cradle 310 to convert rotational energy into electrical energy; Rotating fan 330 that can rotate by being coupled to the generator 320; And it may include a calculation unit 340 for measuring the air volume by using the electrical energy produced by the generator 320.

The sensing unit 300 has a simple configuration including a cradle 310, a generator 320, a rotating fan 330, and a calculation unit 340, and can measure the amount of wind passing through the passage.

The cradle 310 is configured to support the generator 320 .

The cradle 310 may include a central portion and a plurality of legs extending radially from the central portion.

The cradle 310 may be formed in a streamlined shape to minimize resistance to wind passing through the passage.

Cradle 310 is formed radially so that the generator 320 can be located in the center and can be coupled to the inner circumferential surface of the body (100).

A mounting groove into which the generator 320 is inserted may be formed in the center of the cradle 310 .

The generator 320 is a component that converts the rotational energy of the rotating fan 330 rotated by the wind passing through the passage into electrical energy.

The generator 320 may be coupled to the center of the cradle 310 and positioned at the center of the flow path.

The rotation fan 330 is coupled to the rotation shaft of the generator 320 and may have a plurality of rotation blades.

As the amount of wind passing through the passage increases, the rotating fan 330 rotates at a high speed, and the electrical energy produced by the generator 320 increases.

The calculation unit 340 is a component that can measure the air volume of wind passing through the flow path by using the characteristics of the electrical energy produced by the generator 320 is changed.

Since the electric energy produced by the generator 320 changes when the rotary fan 330 rotates, the calculation unit 340 can measure the amount of wind passing through the flow path according to the degree of rotation of the rotary fan 330 .

The calculation unit 340 may transmit electrical energy information changed by the operation of the servomotor 230 to the control unit 400 again.

The calculation unit 340 may transmit electrical energy information that changes in real time to the control unit 400 .

The sensing unit 300 may further include one or more energy storage devices 350 coupled to the cradle to store electrical energy produced by the generator 320 .

The energy storage device 350 may be a battery or a super capacitor.

One or more energy storage devices 350 may be coupled to the cradle 310 .

The energy storage device 350 may be mounted inside the radial legs of the cradle 310 .

When a plurality of energy storage devices 350 are coupled to the cradle 310 , the plurality of energy storage devices 350 may be radially disposed on the cradle 310 at predetermined intervals.

During normal times and/or emergencies, the energy storage device 350 may provide electrical energy to the control unit 400 .

In normal times, the control unit 400 can save energy by operating the servo motor 230 using electrical energy stored in the energy storage device 350 .

In an emergency such as a power outage, the control unit 400 may operate the opening/closing unit 200 by operating the servo motor 230 using electrical energy stored in the energy storage device 350 .

Referring to FIGS. 1 to 5 , the controller 400 is a component for adjusting the degree of opening and closing of the passage.

The control unit 400 may maintain a constant air volume of wind passing through the passage.

The control unit 400 may be electrically connected to the sensing unit 300 and the opening/closing unit 200 through a wire or wireless connection.

The control unit 400 may adjust the opening/closing degree of the passage based on air volume information transmitted from the sensing unit 300 .

The controller 400 may adjust the opening/closing unit 200 again based on a change in air volume according to the adjustment of the opening/closing unit 200 .

The control unit 400 adjusts the opening/closing unit 200 based on the air volume information transmitted from the sensing unit 300, and the sensing unit 300 transmits the air volume information changed according to the adjustment of the opening/closing unit 200 back to the controller 400. And, the control unit 400 may adjust the opening/closing unit 200 again based on the changed air volume information.

The control unit 400 may adjust the servomotor 230 in real time based on the electric energy information transmitted from the calculation unit 340 in real time to maintain a constant air volume of wind passing through the passage.

The control unit 400 may directly measure the air volume of wind passing through the passage by using the electrical energy produced by the generator 320 without going through the calculation unit 340. In this case, the detection unit 300 is may not include

6 to 9, a centralized high-efficiency constant pressure ventilation system having a constant air volume electric damper 30 according to an embodiment of the present invention includes one or more riser ducts 10 installed in a multi-story building; a plurality of branch pipes 20 branching from the riser duct 10 to each floor; A plurality of constant air amount electric dampers 30 capable of opening and closing the branch pipes 20 so that the air of each floor can move to the riser duct 10; a suction unit 40 coupled to an upper portion of the riser duct 10 and discharging air inside the riser duct 10 to the outside; a sensor unit 50 capable of measuring a difference between atmospheric pressure and internal pressure of the riser duct 10; and a controller 60 capable of operating the suction unit 40 and the constant air volume electric damper 30 based on the information obtained from the sensor unit 50 .

In addition, the controller 60 of the centralized high-efficiency constant pressure ventilation system having the constant air volume motorized damper 30 according to an embodiment of the present invention operates the suction unit 40 and the constant air volume motorized damper 30 to obtain atmospheric pressure. As a standard, the pressure inside the riser duct 10 can always be maintained at negative pressure, and the amount of air discharged to the plurality of branch pipes 20 can be maintained the same.

Referring to FIG. 6 , a centralized high-efficiency static pressure ventilation system according to an embodiment of the present invention includes one or more riser ducts 10 installed in a multi-story building; a plurality of branch pipes 20 branching from the riser duct 10 to each floor; A plurality of electric dampers 30 capable of opening and closing the branch pipes 20 so that the air of each floor can move to the riser duct 10; a suction unit 40 coupled to an upper portion of the riser duct 10 and discharging air inside the riser duct 10 to the outside; a sensor unit 50 capable of measuring a difference between pressure inside the riser duct and atmospheric pressure; and a controller 60 capable of operating the suction unit 40 and the electric damper 30 based on information obtained from the sensor unit 50 .

The controller 60 can operate the suction unit 40 and the electric damper 30 to always maintain the pressure inside the riser duct 10 at a negative pressure based on the atmospheric pressure.

If the pressure inside the riser duct 10 is always maintained at a negative pressure based on the atmospheric pressure, it is possible to prevent air flowing into the riser duct 10 from flowing backward into the room.

Referring to FIG. 6, the riser duct 10 is a vertical exhaust pipe installed in the vertical direction of a multi-story building.

The riser duct 10 may be a combination of a plurality of branch pipes 20 connected to the interior of each floor or to individual households.

The riser duct 10 corresponds to a centralized passageway for discharging air introduced from the inside of each floor or from individual households to the outside of a multi-story building.

The riser duct 10 can maintain a stable state by being coupled to the support 1 installed in the vertical direction of the multi-story building.

The pressure inside the riser duct 10 may always be maintained at a negative pressure based on the external atmospheric pressure.

An intake unit 40 may be coupled to an upper portion of the riser duct 10 .

When the flexible duct 70 is further coupled to the upper portion of the riser duct 10, the suction portion 40 may be coupled to the upper portion of the flexible duct 70.

The flexible duct 70 can flexibly connect between the riser duct 10 and the suction part 40 .

When the auxiliary duct 80 is further coupled to the upper portion of the flexible duct 70, the suction part 40 may be coupled to the upper portion of the auxiliary duct 80.

The auxiliary duct 80 may provide a space in which an air purifier 90 for removing harmful substances and odors can be installed.

When the expansion duct 3 is further coupled to the upper portion of the auxiliary duct 80, the suction part 40 may be coupled to the upper portion of the expansion duct 3.

Referring to FIG. 6 , the branch pipe 20 is a branch exhaust pipe installed in the horizontal direction of a multi-story building.

The branch pipe 20 corresponds to a passage connecting the riser duct 10 and the interior of each floor or individual households.

One end of the branch pipe 20 is coupled to the riser duct 10 and the other end may be coupled to a hood 2 or a duct connected to an exhaust port.

The branch pipe 20 may be coupled to the electric damper 30 at the middle or the other end.

The branch pipe 20 may be opened and closed by the electric damper 30.

Referring to FIG. 6 , the electric damper 30 is configured to open and close the branch pipe 20 so that air introduced from each floor or individual household can move to the riser duct 10 .

The electric damper 30 may be composed of a butterfly damper operated by a servo motor 230.

The electric damper 30 may further include a sensing unit 300 .

The controller 60 may be electrically connected to the control unit 400 of the electric damper 30 through a wire or wireless connection.

The controller 60 may operate the servomotor 230 according to the air volume value measured by the sensing unit 300 to secure a constant air volume of air passing through the branch pipe 20 .

The controller 60 may operate the servo motors 230 of the individual electric dampers 30 so that the constant air volume of individual air passing through the individual branch pipes 20 is all the same.

Referring to FIGS. 6 and 7 , the suction unit 40 is configured to always maintain the pressure inside the riser duct 10 at a negative pressure based on the atmospheric pressure.

The suction unit 40 may include a plate 41 , a casing 42 , a support frame 43 , a driving motor 44 and an impeller 45 .

The suction unit 40 may discharge air inside the riser duct 10 to the outside.

The suction unit 40 may be formed as one module with the sensor unit 50 and the controller 60 .

When the suction unit 40, the sensor unit 50, and the controller 60 are formed as a single module, there is no need to install additional equipment, and thus, construction convenience can be increased.

Referring to FIG. 7 , the plate 41 is disposed on the bottom of the intake unit 40 and may be coupled to the top of the riser duct 10 .

The plate 41 may be connected to the riser duct 10 to form an inlet nozzle through which air may be discharged.

The plate 41 may provide a foundation on which the casing 42 and the support frame 43 are installed.

The plate 41 is coupled to the upper portion of the support 1 to maintain a stable state.

When the flexible duct 70 is further coupled to the upper portion of the riser duct 10, the plate 41 may be coupled to the upper portion of the flexible duct 70.

When the auxiliary duct 80 is further coupled to the upper portion of the flexible duct 70, the plate 41 may be coupled to the upper portion of the auxiliary duct 80.

When the expansion duct 3 is further coupled to the upper portion of the auxiliary duct 80, the plate 41 may be coupled to the upper portion of the expansion duct 3.

Referring to FIG. 7 , the casing 42 is configured to protect the support frame 43, the drive motor 44, and the impeller 45 located therein.

The casing 42 may be coupled to the top or side of the plate 41 .

The casing 42 is open at the top and bottom and may surround the support frame 43, the drive motor 44, and the impeller 45 positioned therein.

Referring to FIG. 7 , the support frame 43 is configured to fix the drive motor 44 .

The support frame 43 may be coupled to an upper portion around the inlet nozzle of the plate 41 .

A bird screen may be coupled to the upper portion of the support frame 43 .

The bird screen can prevent birds from entering the open top of the casing 42 .

Referring to FIG. 7 , the driving motor 44 (EC Motor) is configured to rotate the impeller 45 .

The driving motor 44 is fixed to the support frame 43 to rotate the impeller 45 in a stable state.

The controller 60 may also adjust the rotation of the impeller 45 by adjusting the rotation of the driving motor 44 .

Referring to FIG. 7 , the sensor unit 50 is configured to measure a difference between the pressure inside the riser duct 10 and the atmospheric pressure outside.

The sensor unit 500 may be composed of a differential pressure sensor including a first tube 51 for measuring the pressure inside the riser duct 10 and a second tube 52 for measuring the atmospheric pressure outside the riser duct 10. there is.

The sensor unit 50 may be installed in the suction unit 40 .

The sensor unit 50 may be located inside or outside the casing 42 .

Information obtained from the sensor unit 50 is transmitted to the controller 60 .

The sensor unit 50 may be integrally formed with the controller 60 .

Referring to FIGS. 7 and 9 , the controller 60 operates the suction unit 40 and the electric damper 30 to always maintain the pressure inside the riser duct 10 at a negative pressure based on the atmospheric pressure.

Since the controller 60 always maintains the pressure inside the riser duct 10 at a negative pressure, it is possible to prevent air flowing into the riser duct 10 from flowing backward into the room.

Since the controller 60 always maintains the pressure inside the riser duct 10 at a negative pressure, a powered exhaust device such as a hood fan in the kitchen or a ventilation fan in the bathroom is not required, and the noise generated by the powered exhaust device is fundamentally reduced. This can be prevented, and the energy used in the powered exhaust system can be saved.

The controller 60 may independently operate the suction unit 40 and the electric damper 30 based on information obtained from the sensor unit 50 and/or the detection unit 300 .

The controller 60 controls the opening and closing of the electric damper 30 to keep the pressure of the entire branch pipe 20 constant and the same.

The controller 60 adjusts the opening and closing of the electric damper 30 to ensure the same and constant air flow of the branch pipes 20 in the entire lower and upper floors.

The controller 60 detects the air volume of the branch pipe 20 by interlocking artificial intelligence with the sensor unit 50 and/or the sensor unit 300, and the required air volume (set value) for each household is 200㎥/h ± 5% A range of constant air volumes can be realized.

When the ventilation system is not in use, the controller 60 can maintain the inside of the riser duct 10 at the lowest negative pressure, so that low-noise operation can be realized and power consumption can be kept to a minimum.

The controller 60 may be installed in the suction unit 40 .

The controller 60 may be located inside or outside the casing 42 .

The controller 60 may be integrally formed with the sensor unit 50 and the communication module 61 .

The controller 60 may display information obtained from the sensor unit 50 and/or the detection unit 300 and energy consumption on the screen in real time.

Since the controller 60 has a display and can display the static pressure and energy consumption (voltage, current, power, etc.), the information obtained from the sensor unit 50 and/or the detection unit 300 without separate measuring equipment. and energy consumption can be checked in real time.

The controller 60 may include a communication module 61 capable of wirelessly transmitting operation information of the suction unit 40 to the repeater 1000 in real time.

The controller 60 also includes operation information of the electric damper 30 together with operation information of the suction unit 40, information obtained from the sensor unit 50, information obtained from the sensor unit 300, and information on energy consumption. It can be delivered to the repeater 1000 in real time.

The communication module 61 may use ZigBee technology.

ZigBee is a technology for a low-speed, low-cost, and low-power wireless network mainly used in a home network and a wireless sensor network based on a two-way wireless personal area network (WPAN).

The repeater 1000 may wirelessly transmit driving information transmitted from the communication module 61 to the monitoring unit 1100 in real time.

The repeater 1000 is a component that connects the communication module 61 and the monitoring unit 1100 through wireless communication.

The repeater 1000 may use LoRa (Long Range) technology.

LoRa is a low power wide area (LPWA) technology that helps objects communicate with each other.

The monitoring unit 1100 may monitor and manage driving information in real time through wireless communication.

The monitoring unit 1100 provides operation information of the suction unit 40, operation information of the electric damper 30, information obtained from the sensor unit 50, information obtained from the sensor unit 300, and information about energy consumption. A display capable of displaying may be included.

Since the manager can check the state of the ventilation system in real time through the monitoring unit 1100, it is possible to quickly respond to a breakdown or an emergency.

When the electric damper 30, the sensor unit 50 or the controller 60 fails, the suction unit 40 may be set to be forcibly operated at maximum efficiency.

When the electric damper 30, the sensor unit 50, or the controller 60 has a failure, the monitoring unit 1100 may notify the manager of the failure by sounding a notification sound or displaying a notification screen.

When the electric damper 30, the sensor unit 50, or the controller 60 fails, the suction unit 40 is forcibly operated at maximum efficiency, so the ventilation system continues to operate without stopping, and the manager identifies the failure and requires necessary action can be taken.

The controller 60 can adjust the static pressure or air volume inside the branch pipe 20 according to the degree of opening and closing of the electric damper 30 by artificial intelligence.

The controller 60 can save energy by automatically operating as much as the amount of air consumed in the household based on artificial intelligence.

The controller 60 may learn the change in static pressure or air volume inside each branch pipe 20 .

Specifically, the controller 60 may repeatedly learn the static pressure or air volume change pattern inside each branch pipe 20 according to the surrounding environment such as time, weather, and fine dust concentration.

The controller 60 may perform automatic operation by inferring the static pressure or air volume change inside each branch pipe 20 according to the surrounding environment such as time, weather, fine dust concentration, etc. through repetitive learning.

Here, artificial intelligence (AI) is a field of computer science and information technology that studies ways to enable computers to do thinking, learning, and self-development that can be done with human intelligence. It can mean allowing you to imitate intelligent behavior.

Also, artificial intelligence does not exist by itself, but is directly or indirectly related to other fields of computer science. In particular, in modern times, attempts to introduce artificial intelligence elements in various fields of information technology and use them to solve problems in those fields are being actively made.

Machine learning is a branch of artificial intelligence that can include areas of study that give computers the ability to learn without being explicitly programmed. Specifically, machine learning can be said to be a technology that studies and builds a system that learns based on empirical data, makes predictions, and improves its own performance, as well as algorithms for it. Algorithms in machine learning can take the form of building specific models to derive predictions or decisions based on input data, rather than executing rigidly defined static program instructions.

Both unsupervised learning and supervised learning may be used as the machine learning method of the artificial neural network.

6 to 8, the centralized high-efficiency static pressure ventilation system according to an embodiment of the present invention includes a flexible duct 70 coupled to an upper portion of the riser duct 10; An auxiliary duct 80 coupled between the flexible duct 70 and the suction part 40; and an air purifying unit 90 coupled to the inside of the auxiliary duct 80 to remove harmful substances and odors.

The air purifier 90 is a component for removing harmful substances and odors included in the discharged air.

The air purifier 90 includes a first frame 91 coupled to the inside of the auxiliary duct 80; A second frame 92 coupled over the inside of the auxiliary duct 80; and a plurality of UV lamps 93 coupled to the first frame 91 and the second frame 92 at an oblique distance.

The first frame 91 and the second frame 92 may be vertically spaced apart from each other and arranged in parallel inside the auxiliary duct 80 .

The air purifier 90 may further include an auxiliary frame 94 connecting the first frame 91 and the second frame 92 spaced apart vertically.

Through the auxiliary frame 94, the first frame 91 and the second frame 92 may be configured as one frame.

The ultraviolet lamp 93 (UV Lamp) is a component that uses ultraviolet rays to sterilize microorganisms such as mold, bacteria, and viruses contained in the air.

The UV lamp 93 may be operated by the controller 60.

UV is classified into UV-A (400~315nm), UV-B (315~280nm), UV-C (280~200nm), and Vacuum UV (200~100nm) according to the wavelength.

It is preferable to perform sterilization using the ultraviolet lamp 93 with a UV-C wavelength in the range of 250 to 280 nm that destroys the DNA structure of microorganisms.

The UV lamp 93 also emits ultraviolet rays of 185 nm wavelength that generate ozone, so that strong deodorization can be performed.

The UV lamps 93 disposed in an oblique direction may have a lower portion coupled to the first frame 91 and an upper portion coupled to the second frame 92 .

When a plurality of UV lamps 93 are spaced apart in an oblique direction, air flow can be induced in a spiral shape.

The air purifier 90 may further include a filter 95 coupled to the inside of the auxiliary duct 80 .

The filter 95 is a component for removing chemical components, fine dust, harmful substances, oil vapor, and odor contained in the air.

The filter 95 may be located above or below the UV lamp 93.

The filter 95 may be coupled to one of the auxiliary duct 80, the first frame 91 or the second frame 92.

The filter 95 may include a pre-filter that filters out large particles, a deodorization filter that removes odor, and a HEPA filter that filters out fine particles that the pre-filter fails to filter out.

The filter 95 may further include a photocatalytic filter.

A photocatalyst is a material that causes a catalytic reaction by a strong oxidation-reduction reaction when it receives light, and can perform odor removal, decomposition of organic matter, sterilization, etc. together with the ultraviolet lamp 93.

In the foregoing, although specific embodiments of the present invention have been described and shown, the present invention is not limited to the described embodiments, and it is common knowledge in the art that various modifications and variations can be made without departing from the spirit and scope of the present invention. It is self-evident to those who have

Therefore, such modifications or variations should not be individually understood from the technical spirit or viewpoint of the present invention, and modified embodiments should be said to belong to the scope of the present invention.

1: Support 2: Hood
3: expansion duct 10: riser duct
20: branch pipe 30: electric damper
40: suction part 41: plate
42: casing 43: support frame
44: drive motor 45: impeller
50: sensor unit 51: first tube
52: second tube 60: controller
61: communication module 70: flexible duct
80: auxiliary duct 90: air purifier
91: first frame 92: second frame
93: UV lamp 94: auxiliary frame
95: filter 100: body
200: opening and closing part 210: shaft
220: blade 230: servomotor
300: sensing unit 310: cradle
320: generator 330: rotating fan
340: calculation unit 350: energy storage device
400: control unit 1000: repeater
1100: monitoring unit

Claims (7)

A cylindrical body in which a flow path is formed; an opening/closing unit coupled to the outlet side of the body to open and close the passage; a sensing unit coupled to an inlet side of the body to measure an air volume passing through the passage; And a control unit for maintaining the air volume constant by adjusting the opening and closing unit based on information transmitted from the sensing unit,
The sensing unit, a radial holder coupled to the inner circumferential surface of the body; a generator coupled to the center of the cradle and positioned at the center of the passage to convert rotational energy into electrical energy; Rotating fan coupled to the generator to rotate; And a calculation unit for measuring the air volume by using the characteristics of the electric energy produced by the generator changes,
The opening/closing part may include a shaft that passes through the body and is rotatably coupled; a disk-shaped blade coupled to the shaft to open and close the passage; And a servomotor coupled to the body to rotate the shaft,
The cradle includes a central portion in which a mounting groove to which the generator is coupled is formed; And a plurality of legs extending radially from the center,
The operation unit transmits air volume information changed by the operation of the servomotor to the control unit in real time;
The control unit operates the servomotor in real time based on the air volume information to keep the air volume constant. delete delete According to claim 1,
the sensor,
The constant air volume motor damper further comprises one or more energy storage devices coupled to the cradle and capable of storing electrical energy produced by the generator. According to claim 4,
The control unit can operate the servomotor using the electrical energy stored in the energy storage device, characterized in that the constant air volume electric damper. delete A centralized high-efficiency constant pressure ventilation system having a constant air volume motorized damper of any one of claims 1, 4 or 5,
One or more riser ducts installed in a multi-story building;
a plurality of branch pipes branching from the riser duct to each floor;
a plurality of constant air quantity electric dampers capable of opening and closing the branch pipes so that the air of each floor can move to the riser duct;
a suction unit coupled to an upper portion of the riser duct and discharging air inside the riser duct to the outside;
a sensor unit capable of measuring a difference between pressure inside the riser duct and atmospheric pressure; and
A controller capable of independently operating the suction unit and the constant air volume electric damper based on information obtained from the sensor unit and the detection unit;
The controller operates the suction unit and the constant air volume electric damper to always maintain the pressure inside the riser duct at a negative pressure based on the atmospheric pressure, and maintain the same volume of air discharged to the branch pipes of the entire multi-story building, A centralized high-efficiency constant pressure ventilation system, characterized in that for maintaining the negative pressure inside the riser duct lower than when the ventilation system is not in use.

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