KR102583048B1 - Ventilation system and control method thereof - Google Patents

Abstract

The present invention relates to systems for ventilation of air in any space, and methods for controlling such systems. Specifically, the present invention is a ventilation system that allows air to be sucked in using a duct provided on the lower surface even within an arbitrary space, and at the same time allows air from the outside to be supplied from the upper part of the space, thereby inducing a downward flow of air inside the space. It is about the system and its control method.

Description

Ventilation system and control method thereof {VENTILATION SYSTEM AND CONTROL METHOD THEREOF}

The present invention relates to systems for ventilation of air in any space, and methods for controlling such systems. Specifically, the present invention is a ventilation system that allows air to be sucked in using a duct provided on the lower surface even within an arbitrary space, and at the same time allows air from the outside to be supplied from the upper part of the space, thereby inducing a downward flow of air inside the space. It is about the system and its control method.

A duct is a passage or structure through which a fluid such as air flows, and such ducts are widely used when implementing a ventilation system for ventilation of indoor air.

However, conventional ventilation systems have been exposed to many problems because they are designed to supply new air and exhaust existing air in indoor spaces, especially at the top near the ceiling. Specifically, when air supply and exhaust are performed at the top of an indoor space, the hydrodynamically clean air becomes an environment where it only stays on the ceiling, which further accelerates the spread of viruses and contamination within the indoor space.

In addition, products such as air purifiers are operated to keep the air in indoor spaces clean, but these air purifiers do not emit contaminants and viruses but only circulate them internally, thereby reducing the actual indoor air quality. There are also problems that make it difficult to expect quality improvement.

As such, ventilation systems and air purifiers that have been used to improve air quality in indoor spaces have limitations in that they do not provide high ventilation performance, and even cause side effects by allowing viruses and pollutants to enter indoor spaces. There is a need for an improved ventilation system compared to the past.

The present invention was designed with this technical background in mind. In addition to solving the above technical problems, the present invention was invented to provide additional technical elements that cannot be easily invented by those skilled in the art.

KR 10-2199003 B1 (2020.12.30. registration)

The purpose of the present invention is to provide a ventilation system to improve the air quality in any space, and in particular, to provide an environment in which air in the space flows downward by supplying new air at the top and suctioning air at the bottom. The purpose is to implement.

In addition, the present invention aims to enable a streamlined insertion-type nozzle to be inserted into a branch duct provided at the bottom of the space, so that the air sucked through the suction hole can be moved and discharged to the outside more quickly through the branch duct. .

In addition, the purpose of the present invention is to not only control air suction from installed ducts simultaneously, but also to selectively suction air from only some ducts, thereby enabling more efficient ventilation in a space.

Additionally, the purpose of the present invention is to remove contaminants from the supplied or exhausted air by adding a sterilizing device to at least one of the exhaust or air supply unit.

Additionally, the purpose of the present invention is to maintain a downward flow of air in the space by controlling the amount of air discharged from the space to be maintained at a value greater than the amount supplied.

Additionally, the purpose of the present invention is to enable customized ventilation depending on the situation by counting the number of objects entering and exiting an indoor space or monitoring the positions of objects within the indoor space.

Meanwhile, the technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the description below.

In order to solve the above problem, the ventilation system for ventilating the inside of an arbitrary space according to the present invention allows air to be sucked in by a duct - the duct sucks in air and moves it downward from the arbitrary space. , an exhaust unit that discharges the sucked air to the outside; an air supply unit supplying air downward from the top of the space; and a control unit that controls the exhaust unit and the air supply unit.

In addition, in the ventilation system, the duct is formed with a plurality of suction holes for sucking air, and may further include a filter for filtering the air passing through the suction holes or the air passing through the suction hole. .

Additionally, in the ventilation system, the duct may include: a branch duct installed adjacent to a lower surface within the space; and a granular duct connected to the branch duct and extending from the bottom to the top in the space.

Additionally, the ventilation system may further include a monitoring unit for monitoring the amount of air passing through the duct.

In addition, the ventilation system may further include an insertable nozzle that can be inserted into the suction hole and is formed with an intake port through which air is sucked from outside the duct, and an outlet through which the sucked air is discharged into the inside of the duct.

At this time, the insertion-type nozzle may be streamlined, the front and rear ends of the insertion-type nozzle may have different widths, and the outlet may be formed at the rear end with a relatively smaller width.

Additionally, in the ventilation system, the exhaust unit may be connected to the duct and may further include an exhaust fan that exhausts air inside the duct to the outside or sucks air in the space toward the duct.

At this time, the exhaust unit may further include an exhaust filter for filtering out contaminants from the air before discharging the air to the outside. Additionally, the exhaust unit may remove contaminants in the air before discharging the air to the outside. It may further include an exhaust sterilization device for removal.

Additionally, in the ventilation system, the air supply unit includes an air supply fan for supplying air from the outside into the space; and an air supply filter for filtering contaminants in the air supplied into the space.

At this time, the air supply unit may further include an air supply sterilization device for removing contaminants in the air supplied into the space.

Meanwhile, a ventilation system according to another embodiment of the present invention - the ventilation system includes an exhaust part that sucks air in a certain space from the bottom and discharges it to the outside, and an air supply part that supplies air from the outside downward from the top. Included - The control method includes operating the exhaust unit to suck in air in the arbitrary space and discharge it to the outside; and operating the air supply unit to supply air into the arbitrary space. may include.

In addition, the ventilation system control method may further include monitoring the air discharge amount, which is the amount of air discharged from the space to the outside, and the air supply amount, which is the amount of air supplied into the space.

Additionally, the ventilation system control method may be characterized in that at least one of the exhaust unit or the air supply unit is controlled so that the air discharge amount is maintained at a value greater than the air supply amount.

Additionally, the ventilation system control method includes detecting the number of objects entering and leaving the space; and controlling the ventilation system according to the number of objects present in the space; may further include.

Additionally, the ventilation system control method includes detecting the position of an object existing in the space; and controlling the ventilation system with reference to the location of the object. may further include.

At this time, the ventilation system further includes a branch duct provided adjacent to the lower surface in the space, wherein the air sucked in according to the operation of the exhaust unit moves through the branch duct, and the ventilation system The controlling step may further include adjusting the air intake amount of the branch duct within a preset range based on the position of the object with reference to the position of the object.

According to the present invention, the air flow in a space can be made to move downward, that is, from the top to the bottom, and the effect of minimizing the sideward spread of viruses and contaminants in the space by using this hydrodynamic movement. There is.

In addition, according to the present invention, it is possible to selectively control air intake for ducts installed on the lower surface of the room, thereby increasing ventilation efficiency in the indoor space.

In addition, according to the present invention, contaminants in the air flowing into the interior can be removed, thereby improving the quality of indoor air.

In addition, according to the present invention, it is possible to monitor objects in a space, that is, people, and obtain information such as spaces where people exist, spaces where people do not exist, the number of people, etc. to ensure the most efficient ventilation within the space. There is an effect.

Meanwhile, the effects of the present invention are not limited to those mentioned above, and other technical effects not mentioned will be clearly understood by those skilled in the art from the description below.

Figure 1 briefly shows the overall configuration of the ventilation system according to the present invention.
Figure 2 exemplarily shows how a ventilation system is implemented in an arbitrary space.
Figure 3 shows detailed configurations of the exhaust section, and Figure 4 shows detailed configurations of the air supply section.
Figure 5 shows a suction hole formed in a duct.
Figure 6 shows a suction hole formed diagonally on the side of a duct.
FIG. 7 shows the air flow in a space when air is sucked in by a duct as shown in FIG. 6.
Figure 8 shows a streamlined insertable nozzle that can be inserted into the duct.
Figure 9 shows the flow of air sucked when the insertable nozzle of Figure 8 is inserted.
Figure 10 shows a soundproofing mat and frames further provided on the outside of the branch duct.
Figure 11 lists the method for controlling the ventilation system according to the present invention in order.
Figure 12 shows how the position of a specific object in space is detected and the ventilation system is controlled accordingly.

Details regarding the purpose and technical configuration of the present invention and its operational effects will be more clearly understood by the following detailed description based on the drawings attached to the specification of the present invention. Embodiments according to the present invention will be described in detail with reference to the attached drawings.

The embodiments disclosed herein should not be construed or used as limiting the scope of the present invention. It is obvious to those skilled in the art that the description, including embodiments, of this specification has various applications. Accordingly, any embodiments described in the detailed description of the present invention are illustrative to better explain the present invention and are not intended to limit the scope of the present invention to the embodiments.

The functional blocks shown in the drawings and described below are only examples of possible implementations. Other functional blocks may be used in other implementations without departing from the spirit and scope of the detailed description. Additionally, although one or more functional blocks of the present invention are shown as individual blocks, one or more of the functional blocks of the present invention may be a combination of various hardware and software components that perform the same function.

Additionally, the expression including certain components is an “open” expression and simply refers to the presence of the components and should not be understood as excluding additional components.

Furthermore, when a component is referred to as being “connected” or “connected” to another component, it should be understood that although it may be directly connected or connected to the other component, other components may exist in between. do.

First, let us briefly look at the ventilation system 1 according to the present invention with reference to FIGS. 1 and 2. The ventilation system (1) can basically be installed to ventilate the air in any space. It exhausts the air in the existing room to the outside through a duct provided in the space, and draws air from the outside in in the same way. It is understood as a system for bringing in money. As will be explained in more detail later, the ventilation system (1) according to the present invention prevents bad viruses or pollutants in the air from spreading indoors by creating an environment in which air in the space can flow downward, and also prevents the spread of harmful viruses or contaminants in the room. The purpose is to maximize ventilation efficiency by ensuring suction and air supply in three dimensions. For this purpose, the ventilation system 1 according to the present invention uses a duct, but it is assumed that the duct is installed in the lower part of the space. The bottom of the space can be understood as the three-dimensional space closer to the floor when the three-dimensional space is divided into upper and lower by the same volume, and more preferably at a predetermined distance from the floor ( For example, it can be understood as a three-dimensional space with 0cm to 50cm) as the height and the floor as the base.

Meanwhile, the duct may include a branch duct installed in the lower part of the space, and a standing duct for discharging air moving through the branch duct to the outside. Among these, branch ducts can be installed in various shapes and lengths at the bottom of the space. For example, if the floor surface of the space is polygonal, branch ducts may be installed along each side, or branch ducts may be installed along each side. It can also be installed double, that is, in two layers.

FIG. 2 is intended to show how the ventilation system described above can be implemented in an actual space. When referring to FIG. 2, a branch duct 10A is installed at the bottom of the space, more precisely on the floor, and It can be confirmed that the standing duct 10B is installed from one point of the duct 10A toward the upper part of the space.

Referring again to Figure 1, the ventilation system 1 according to the present invention largely includes an exhaust unit 100, an air supply unit 200, and a control unit 300, and additionally a monitoring unit 400, or a detection unit. It may further include unit 500.

First, the exhaust unit 100 allows air to be sucked in through a duct and discharges the sucked air to the outside of the space. Among the functions of the exhaust unit 100, a noteworthy feature is to suck air through a duct so that the air in the space flows from top to bottom, that is, the air in the space flows downward. As mentioned before, the duct is installed at the bottom of the space, and when the exhaust unit 100 is driven, air is sucked from the bottom, so a natural flow of air occurs from the top to the bottom of the space. The present invention utilizes this fluid flow to It is characterized by preventing irregular indoor spread of contaminants or viruses.

Figure 3 shows the exhaust unit 100 and its detailed configuration. Referring to FIG. 3, the exhaust unit 100 is connected to the duct and may include an exhaust fan 110 that exhausts air inside the duct to the outside or sucks air in the space toward the duct. The exhaust fan 100 is basically configured to move air from one side to the other, and in this process, the pressure of one space is lowered or higher than the pressure of the other space, thereby utilizing the fluid movement property according to the pressure difference. It can be. In addition, the exhaust unit 100 may further include an exhaust filter 130 for filtering contaminants from indoor air remaining in the space before discharging it to the outside. The exhaust filter 130 may include various types of things, for example, a pre-filter to filter out dust and allergens of large size or volume such as hair, coarse dust, and pet hair, volatile organic compounds, and harmful substances. A carbon filter that can remove gas, yellow dust, household dust, floating mold, pollen, cigarette smoke, food odor, mold odor, etc. and has a deodorizing function, or PM2.5 fine dust, harmful substances, and 0.3um fine dust. At least one HEPA filter that can be used may be included. In Figure 3, one exhaust filter 130 is installed in the inlet direction of the exhaust unit 100, that is, at the opening through which air enters. However, unlike the drawing, there are two or more different types of exhaust within the exhaust unit 100. Filters 130 may be further provided.

On the other hand, the exhaust unit 100 may further include an exhaust sterilization device 150 for removing contaminants in the air before discharging the air to the outside. The exhaust sterilization device 150 may preferably use ultraviolet rays in the UV-C wavelength range (100 to 280 nm), and when irradiated for 1 minute, the ultraviolet rays in the UV-C wavelength range kill Escherichia coli, diphtheria, and dysentery bacteria. It is known to be capable of removing 99%, so it is suitable for sterilizing bacterial substances in indoor air. In relation to the location of the exhaust sterilization device 150, it is preferable that the exhaust sterilization device 150 be installed in a location where it can irradiate as much ultraviolet rays as possible to the air to be sterilized. To this end, in FIG. 3 It can be seen that the exhaust sterilization device 150 can be installed at a location facing the inlet of the exhaust unit 100. This positioning allows the exhaust sterilizing device 150 to face the air coming in through the inlet for as long as possible, thereby maximizing the amount of ultraviolet irradiation to the incoming air. In addition, if necessary, the driving intensity of the exhaust fan 110 can be adjusted by the control unit 300, which will be described later. When the driving intensity is weakened, the moving speed of the air flowing in through the inlet is slowed so that the air is exposed to ultraviolet rays. The exposure time can be increased, and thus the sterilization effect of the exhaust sterilization device 150 can be further improved.

Next, the air supply unit 200 is configured to supply air downward from the top of the space. The position of the air supply unit 200 is not particularly limited. However, in order to induce the air in the space to flow downward, the air supply unit 200 may be provided at the top of the space, preferably on the ceiling side of the space. . Referring to FIG. 1, the air supply unit 200 may include an air supply fan 210 for introducing air from the outside into the space. The air supply fan 210 may have a structure similar to the exhaust fan 110 described above, but may not necessarily have a fan structure as long as it can introduce air from the outside to the inside. In addition, the air supply unit 200 may also include an air supply filter 230 and a sterilizing device 250. The air supply filter 230, like the exhaust filter 130, may be one of a pre-filter, a carbon filter, and a HEPA filter. The number may also include one or more, and the sterilizing device 250 may also use ultraviolet rays in the UV-C wavelength range. FIG. 4 shows an actual implementation example of the air supply unit 200. Like the exhaust unit 100 in FIG. 3, the air supply unit 200 has an air supply filter 230 at the inlet where air from the outside enters, In addition, it can be confirmed that the air supply sterilization device 250 can be provided on the side facing the inlet through which air is introduced. In addition, as a matter of special note, the air supply fan 210 is not shown in the air supply unit 200 in FIG. (210) may be omitted.

Next, the ventilation system 1 according to the present invention may further include a control unit 300 for controlling the exhaust unit 100 and the air supply unit 200. The control unit 300 may be implemented in hardware as an arithmetic device including a central processing unit and memory. In this case, the central processing unit may be a controller, a microcontroller, a microprocessor, or a microprocessor. It may also be called a computer (microcomputer), etc. The central processing unit may be implemented by hardware, firmware, software, or a combination thereof. When implemented using hardware, an application specific integrated circuit (ASIC) or a digital signal processor (DSP), When implemented using firmware or software such as a digital signal processing device (DSPD), programmable logic device (PLD), or field programmable gate array (FPGA), a module, procedure, or function that performs the above functions or operations is used. Firmware or software may be configured to include. In addition, memory includes ROM (Read Only Memory), RAM (Random Access Memory), EPROM (Erasable Programmable Read Only Memory), EEPROM (Electrically Erasable Programmable Read-Only Memory), flash memory, SRAM (Static RAM), It can be implemented with HDD (Hard Disk Drive), SSD (Solid State Drive), etc.

The control unit 300 controls the exhaust unit 100 and the air supply unit 200 according to a pre-designed algorithm. If a plurality of exhaust units 100 or air supply units 200 are installed in the space, individual exhaust units 100 and air supply units 200 are installed. It is also possible to control the base or supply section. In addition, in some cases, the duct 10 may be manufactured from a structure that simply acts as a passage for moving air to a structure that can be operated by receiving control commands from the control unit 300. In this case, the control unit 300 ) may also be controllable for the duct 10. For example, a plurality of suction holes 11 capable of sucking air may be formed in the duct 10, and there may be a mechanical drive unit that can adjust the size of each suction hole 11, and the control unit may be (300) may also be capable of controlling the driving unit for adjusting the size of the suction hole (11). In addition, the duct 10 may be further provided with a damper (not shown) to control the amount of air passing therein, and these damper(s) may also be controlled by the control unit 300.

Meanwhile, referring again to FIG. 1, the ventilation system 1 according to the present invention may further include a monitoring unit 400 capable of monitoring the amount of air passing through the duct. The existence of the monitoring unit 400 is ultimately intended to control the amount of air passing through the duct 10 as desired by the user, or to uniformly control the amount of air passing through the duct 10. By measuring the amount in real time, the amount of air at each location of the duct 10 is determined, and based on this information, the angle of the damper is adjusted, the driving strength of the exhaust part 100 is adjusted, the driving strength of the air supply part 200 is adjusted, etc. This can be done.

The monitoring unit 400 may be implemented by a device that can directly or indirectly measure the amount of fluid, such as a flow meter, pressure gauge, etc., and such devices are preferably installed inside the duct 10, further. Specifically, it may be provided within a predetermined distance not far from the suction hole, for example, within 1 cm to 30 cm in a straight line from the center of the suction hole. This is to obtain the flow rate or pressure value when air is sucked from each suction hole as accurately as possible by placing the monitoring unit 400 at a location not far from the suction hole.

Meanwhile, in one embodiment, considering that the entire duct 10 is composed of a plurality of duct assemblies, the monitoring unit 400 may be provided in each duct assembly. That is, each duct assembly may exist in the shape of a pipe, and a passage through which air can pass and a suction hole(s) for sucking air may be formed on each duct assembly. In addition, a flow gauge or pressure gauge may be formed. A monitoring unit 400 such as may be further provided inside.

The values obtained by the monitoring unit 400 can be used to control the ventilation system 1. For example, the P value was detected by the first monitoring unit provided in the first branch duct, and the second The Q value is detected by the second monitoring unit provided in the branch duct, and when the P value and Q value show a large gap beyond the preset range, the exhaust unit 100, the air supply unit 200, and the intake unit At least one component of the mechanical drive unit or damper that adjusts the size of the hole is controlled by the control unit 300 so that the P value and Q value have a difference within a preset range, that is, the suction amount (or The amount of fluid) can be made to have a uniform value with the amount of suction (or amount of fluid) in the second branch duct. Alternatively, in some cases, the user can control the direction in which air flows in the space by controlling the suction amount from the first branch duct to have an overwhelmingly larger value (a value exceeding a preset range) than the suction amount from the second branch duct. can be changed as desired, and through this, it may be possible to further increase the ventilation effect at a specific location in the space.

Referring again to FIG. 1, the ventilation system 1 according to the present invention may further include a detection unit 500. While the monitoring unit 400 is a device for obtaining information about the fluid (air) passing through the duct, the sensing unit 500 is a device for obtaining numerical information or location information of objects entering or exiting the space or existing within the space. It can be understood as a means. As an easy example, the sensing unit 500 can acquire information such as how many people are in the space, how many people entered and left, when the people entered and left, and at what point in the space a specific person is located. This information can be provided to the control unit 300 and used to control the ventilation system 1 in the space. While the number of places for people to stand or sit in a space is relatively limited, there are many cases where positions where people cannot exist are determined by the arrangement of furniture, etc., and when the ventilation system (1) is operated, people are present. If the exhaust unit 100, air supply unit 200, duct 10, etc. are controlled to differentiate between locations and non-positions and vary ventilation performance for each specific location, there is an effect of increasing efficiency. The sensing unit 500 enables control of the ventilation system 1 and is a means of obtaining numerical information of objects (eg, people) in the space and location information of the objects in the space.

The actual implementation of the detection unit 500 is a counter sensor that counts the entry and exit of objects, an image analysis-based position detection device that estimates the location of an object from an image taken inside the space, and other objects in the space. This can be achieved through various means, such as a motion sensor that detects movement.

With reference to FIGS. 1 and 2 , the main components of the ventilation system 1 according to the present invention were discussed. Below, we will look into more specific embodiments of the main components with reference to the drawings.

Figure 5 shows an example of a duct, particularly a branch duct 10A that can be installed in the lower part of the space. (a) shows the first embodiment of the branch duct. The branch duct 10A may preferably be fixed on the floor, as long as there is a passage through which fluid can move therein. It can be said that there is no limit to the shape. Meanwhile, the branch duct 10A shown in (a) is characterized in that a suction hole 11a is formed on the upper surface of the branch duct 10A. At this time, hair, dust, etc. are contained in the suction hole 11a. A pre-filter that can filter out contaminants can be installed. This pre-filter is a type of exhaust filter 130 described in FIG. 1 and can serve to filter out contaminants in the air passing through the suction hole 11a.

On the other hand, the branch duct 10A shown may be part of several branch ducts 10A constituting the entire duct, and the suction hole 11a may not be formed in some other branch ducts 10A. . That is, assuming that the entire duct is installed along the inner perimeter of the lower space of any space, for example, the floor and side walls forming the space, the entire duct may be composed of a plurality of branch duct (10A) assemblies. In addition, each branch duct 10A may or may not have a suction hole formed as needed. In particular, if there are areas that do not require ventilation compared to other areas due to the structure of the space, the cost of building the ventilation system (1) can be reduced by mainly arranging branch ducts (10A) without suction holes. It may be possible. In addition, each branch duct (10A) assembly has a unique identification number and the identification number can be used when control is performed by the control unit 300. For example, when you want to know what the air pressure is in a specific branch duct or which branch duct the air quality around is the worst, or when adjusting the size of the suction hole of a specific branch duct or the amount of air passing inside it. The above identification number can be used when you want to make adjustments.

On the other hand, only one suction hole 11a formed on the branch duct 10A is shown in the drawing, but a plurality of suction holes may be formed, and the shape and size of the suction hole may also be determined in various ways. On the other hand, the branch duct 10A may be separately provided with a suction hole adjuster (not shown) that allows adjustment of the size of the suction hole. The suction hole adjuster controllable by the control unit 300 may be, for example, a device structure that blocks or opens the suction hole by placing a cover surface that can cover the suction hole, or may reduce or increase the size of the suction hole itself. It may be a device structure that can be used. Additionally, a damper (not shown) may be further provided inside the branch duct 10A. The damper is used to control the amount of air passing inside the branch duct 10A, and may include an air control plate that can control the flow on the air passage as a basic configuration. The damper can also be controlled by the control unit 300. For example, if the amount of air passing through a specific branch duct (10A) increases and the amount of air passing through other nearby branch ducts (10A) decreases, the control unit 300 may By closing the damper in the specific branch duct (10A), the air passage amount or air pressure in the entire duct can be maintained uniformly.

Figure 5(b) shows the second embodiment of the branch duct, in which a plurality of suction holes 11b are formed on the side of the branch duct 10A, more precisely in the direction facing the inside of the space. It shows the appearance. The branch duct shown in (b) is characterized in that the suction hole is formed on the side rather than the top. This arrangement of the suction hole (11b) will still suck air from the lower part of the space, creating a downward flow of air in the space. In that it is the same as the branch duct according to the first embodiment, but since the branch duct according to the second embodiment has suction holes 11b formed on the side, there is a possibility that the function of the branch duct may be impaired by foreign substances such as hair or dust. There is less, and accordingly, there are some efficient advantages compared to the branch duct of the first embodiment in terms of maintenance.

Meanwhile, Figure 6 shows a branch duct (10A) and a suction hole (11C) according to the third embodiment. The branch duct 10A according to the third embodiment has a suction hole 11C formed on the side, and as shown in (a) and (b), the suction hole 11C is formed at an angle to the branch duct 10A. It is characterized by Specifically, the central axis of the suction hole 11C may form an acute angle of less than 90 degrees with the central axis of the branch duct 10A when viewed in plan view.

The branch duct 10A according to the third embodiment is for inducing a specific airflow to the lower part of the space when air is sucked in through the suction holes 11C from the lower part of the space, for example, as shown in FIG. 7 As shown in the plan view, a plurality of branch ducts 10A according to the third embodiment are provided around the square bottom surface, and when air is sucked in by each suction hole 11C, it flows in a specific direction at the bottom of the space. This allows the air flow to induce a rotating vortex. The formation of such vortices can help to more efficiently create the clean room environment that the present invention seeks to achieve. For example, the air supply unit 200 provided on the ceiling of the space allows the rotation of the vortices. When new air is supplied from the outside in accordance with the direction, a downward flow of air from the ceiling to the floor can be created in the space, so that the contaminated air in the space flows into the suction holes (11C) without further diffusion. can be discharged by

For reference, it is understood that the top view and the direction of rotation of the vortex shown in FIG. 7 are only one example, and that the shape and direction of rotation of the vortex may vary depending on how the plurality of suction holes 11C are controlled. . However, with reference to FIGS. 6 and 7, the ventilation system 1 according to the present invention can induce a specific air flow to the lower part of the space using the suction holes 11C formed obliquely on the side of the branch duct 10A. It can be seen that there is a certain air flow from the upper part of the space to the lower part of the space by supplying air by adjusting the direction of the air supply unit 200 at the top of the space.

Figure 8 shows a nozzle of a shape that can be inserted into the branch duct 10A, that is, an insertable nozzle 13. In the previous drawings, it was explained that suction holes can be formed on the branch duct 10A. If necessary, insertion-type nozzles 13 as shown in FIG. 8 are inserted into the suction holes to suction air. and can help with fluid movement within the duct. For reference, Figure 8 (a) shows the insertable nozzle 13 being inserted into the branch duct 10A, and Figures (b) to (d) show a side view, perspective view, and top view of the insertable nozzle 13, respectively.

Figure 8 (a) shows the insertion type nozzle 13 being inserted into the suction hole 11 on the branch duct 10A and the insertion direction, where the suction hole 11 is located at the top of the branch duct 10A. If formed, it can be inserted as shown in the drawing. Meanwhile, the insertable nozzle 13 may have an upper surface wider than the suction hole 11, that is, a catching portion 13A, so that it can be caught when inserted into the suction hole 11. The catching portion 13A is shown in FIG. 8 as being only for fastening the insertion type nozzle 13 to the suction hole 11, but is used for fixing the insertion type nozzle 13 on the suction hole 11. Understand that various means may exist.

On the other hand, when referring to (a) to (d) of FIG. 8, the insertable nozzle 13 may preferably have a streamlined shape and may include an inlet 13B and an outlet 13C for sucking/exhaling air. You can. Specifically, when the direction of air flow within the branch duct upon insertion is defined as the front direction, the insertable nozzle 13 may have a streamlined shape with a wider width in the rear direction than in the front direction, and the inlet 13B may be formed on the upper surface of the insertable nozzle 13, and the discharge port 13C may be formed on the front side. The intake port 13B is configured to replace the suction hole 11, and the discharge port 13C is configured to discharge the air sucked through the intake port 13B. Figure 9 shows the air sucked by the insertion nozzle 13 joining a larger air flow passing through the branch duct 10A through the outlet 13C.

As can be seen in FIG. 8(d), the streamlined shape having a wider width in the rear direction than in the front direction minimizes resistance to the air passing through the insertion type nozzle 13 when inserted into the branch duct 10A. It has the effect of allowing it to pass while receiving it, and at this time, it has the effect of slightly attracting the air discharged through the outlet (13C), that is, according to Bernoulli's law, which states that fluid passing at high speed is in a relatively low pressure state. This effect can be expected to increase the efficiency of air intake within the space and the efficiency of the intake air discharge.

On the other hand, when the insertion-type nozzle 13 is viewed from the side, the surface extending from the rear to the bottom of the insertion-type nozzle 13 may have an “L” shaped curve, and this curve shape is also inserted through the insertion-type nozzle 13. It is designed to facilitate the flow of inhaled air and at the same time minimize resistance when moving air through the inside of the duct.

Figure 10 shows a soundproofing mat 60 formed on the outside of the branch duct 10A as part of an effort to reduce the noise of the ventilation system 1, and frames 65 further provided here. It was done . Since the ventilation system 1 is essentially a system whose basic mechanism is to move air through passages, a certain amount of noise is inevitably generated during the movement of fluid. The ventilation system 1 according to the present invention proposes several methodologies to reduce this noise as much as possible, one of which is to surround the outer surface of the duct with a soundproofing mat 60, as shown in Figure 10(a). It was done. In other words, the noise generated during ventilation can be reduced by installing the soundproofing mat 60 on the side of the passage through which air passes.

On the other hand, Figure 10(b). As shown in (c), noise and vibration generated during exhaust can be more effectively reduced by providing not only the soundproofing mat 60 but also the frames 65. In particular, significant vibration may occur when the exhaust fan 110 is operated, and the vibration of the exhaust fan 110 may eventually cause vibration in the branch duct 10A and cause greater noise. 10(b) and 10(c), the frame 65 can be used to reduce vibration in the branch duct 10A and also reduce noise. In addition, preferably, the frames 65 can be placed together with the soundproofing mat 60 on the outside of the branch duct 10A to support the branch duct 10A and the soundproofing mat 60 at the same time. In the drawing, The effect of reducing vibration can be achieved by providing frames 65 to correspond to each vertex of the rectangular planar branch duct 10A as shown.

On the other hand, it can be seen in FIG. 3 described above that the soundproofing mat 60 is formed to surround the exhaust unit 100. Referring to FIG. 3, the outer surface of the exhaust unit 100 may be formed to surround the inner wall 50 and the outer wall 70, and a soundproofing mat 60 may exist between them, resulting in two walls. , and the noise of the exhaust unit 100 was greatly reduced by the soundproofing mat.

As such, the ventilation system 1 according to the present invention can reduce noise generated during ventilation by actively utilizing structures such as soundproofing mats and inner and outer walls when installing components in a space.

With reference to FIGS. 1 to 10 , each detailed configuration of the ventilation system 1 was examined. Below, with reference to the drawings, we will look at what steps the ventilation system 1 is controlled at.

Figure 11 shows the method of controlling the ventilation system 1 according to the present invention in sequence. Referring to this, the method of controlling the ventilation system 1 begins with the control unit 300 first operating the exhaust unit 100 to start discharging air. (S101) Specifically, the operation of the exhaust unit 100 is initiated by an input from the user managing the ventilation system 1, or when the control unit 300 detects a signal from the plurality of monitoring units 400 or detection units 500. A judgment may be made based on the acquired information (the judgment at this time may be a judgment made by an artificial intelligence algorithm) or based on whether predetermined conditions are satisfied.

On the other hand, the method of controlling the ventilation system 1 may include a step (S103) of operating the air supply unit 200 to start supplying air into the space. The steps S101 and S103 do not necessarily have to be performed in the above order, and the air supply unit 200 may be operated first according to user operation or according to a predetermined algorithm, and then the exhaust unit 100 may be operated subsequently. It may be possible. However, preferably, the exhaust unit 100 is first operated for a certain period of time to exhaust some of the contaminated air in the space, and at the same time, the pressure in the space is lowered to a certain extent, and then the air supply unit 200 is operated to cause a downward flow of air in the space. It may be more advantageous to form a .

After the exhaust unit 100 and the air supply unit 200 are operated, a step (S105) of monitoring the amount of air passing through the branch duct 10A or the upright duct 10B may be performed. Step S105 may also be understood as a step in which the control unit 300 receives measured values from a plurality of monitoring units 400 provided in the branch duct 10A or the standing duct 10B. In this step, representative values are monitored for the amount of air discharged to the outside through the exhaust unit 100 (air discharge amount) and the amount of air supplied into the space through the air supply unit 200 (air supply amount). It may be provided to the control unit 300. This monitoring of air discharge and air supply can be used as a reference to later enable the control unit 300 to control the ventilation system 1 while maintaining a higher value of air discharge than air supply in the space.

In the monitoring stage, not only can measurement values from each duct be received, but overall monitoring can be carried out to determine whether the amount of air passing through each duct is uniform and whether the amount of air being sucked in from each duct is uniform. This is done by checking whether the received values are outside the preset range according to a preset algorithm and whether the measured value in a specific duct exceeds the preset range compared to the average value of the received values. It can be done. In addition, in this monitoring step, not only is it checked whether the air volume is uniform, but the ventilation system (1) is properly controlled according to the environment inside the space (number of people in the space, location where people are, degree of air pollution, etc.). The process of checking whether or not it is working may also be included. For example, while 5 people are detected in the space, whether the exhaust section 100 and the air supply section 200 in the ventilation system 1 are operating at an intensity appropriate for the number of people, or whether the exhaust section 100 and the air supply section 200 are operating at an intensity appropriate for the number of people, are detected in a random area in the space. While it is detected that there are many people in the area, it can be confirmed whether suction is being performed properly in the duct mapped to the area.

Meanwhile, in addition to this, in the monitoring step, sensors capable of measuring indoor fine dust, temperature, humidity, VOCs, CO2 concentration, etc. can provide various information to the control unit 300, and the control unit 300 provides this information. With reference to this, it is possible to control the overall operation of the ventilation system (1).

As a step parallel to step S105, the control unit 300 may further include a step (S107) of receiving information from the detection unit 500 that detects an object existing inside the space. As already mentioned in the description of FIG. 1, the sensing unit 500 is a means of obtaining numerical information or location information of objects entering or exiting a space or existing within the space, and in particular, determines how many people are in the space and whether a specific person is present. Information such as where it is located in space can be obtained and provided to the control unit 300. Briefly looking at how the information acquired by the detection unit 500 is used to control the entire ventilation system 1, for example, when it is detected that no one is entering the space, the control unit 300 controls the ventilation system 1. (1) can be stopped or maintained in a state where minimum ventilation is possible. In addition, when it is detected that there are three people in the space, the control unit 300 operates the ventilation system (1) efficiently by operating it only at an intensity that maps to the number of people (3). can do. Also, in the same way, when it is detected that there are more than six people in the space, ventilation in the space can be promoted by operating the ventilation system 1 at an intensity appropriate for the number of people.

For reference, steps S105 and S107 are not necessarily necessary for controlling the ventilation system 1, and even if only one of the two steps is performed, sufficient information can be provided to the control unit 300. There will be no problem in operating the ventilation system (1) with any one of the three stages.

After step S105 or step S107, a step (S109) in which the control unit 300 controls the entire ventilation system 1 by referring to the information received in the previous steps may be performed. Step S109 can be understood as a step of controlling some components by giving different control commands if the ventilation system 1 was already in operation before this step, and the ventilation system 1 was not in operation before this step. This can be understood as a stage where new control is achieved.

On the other hand, in this step, the ventilation system 1 is controlled so that the amount of air discharged from the space is greater than the amount of air supplied into the space in order to create a downward air flow within the space. can do. In other words, the air intake in the lower part of the space can be made to have a larger value than the air supply amount, even if only slightly, so that the air in the space can flow downward.

For reference, Figure 12 shows that after receiving the location information of an object (person), the control unit 300 defines a predetermined area as a detection area, and adjusts the suction rate of the branch duct (10A) around the detection area to detect the location of the object (person) in the space. This shows control that improves ventilation efficiency.

Referring to FIG. 12, it can be detected by the detection unit 500 that two people are present in the space, and the location information of the two people in the space (location at this time) can be detected by the detection unit 500. The information may be based on the person's position in the image captured by the sensing unit 500, or the inside of the space may be defined as an arbitrary coordinate system and the information may be based on the person's position based on that coordinate system) If is shared with the control unit 300, the control unit 300 can define a predetermined detection area, that is, an area where a person is estimated to exist. This detection area is defined to send a control command to a specific area in space. When a specific detection area is defined, the control unit 300 controls the components around the detection area (exhaust unit, air supply unit, branch duct). , standing ducts, etc.), three-dimensional ventilation may be possible by selectively sending control commands. In Figure 12, it can be seen that suction is occurring more strongly in the duct around the detection area (length of the arrow indicating suction), and in other areas, suction is occurring weakly. Meanwhile, a control command can be sent not only to the exhaust unit 100 or the suction hole of the branch duct, but also to the air supply unit 200. For example, the air supply unit 200 is supplied only in the direction of the detection area. By doing so, a downward flow of air can be formed in the sensing area.

We looked at the ventilation system and its control methods. The present invention is not limited to the specific embodiments and application examples described above, and various modifications can be made by those skilled in the art without departing from the gist of the invention as claimed in the claims. Of course, these modified implementations should not be understood separately from the technical idea or outlook of the present invention.

1 ventilation system
10 duct 10A branch duct 10B standing duct
11 Suction hole 12 Filter
13 Insertable nozzle 13A catching part 13B suction part 13C discharge part
50 inner wall 60 soundproofing mat 70 outer wall
100 Exhaust unit 110 Exhaust fan 130 Exhaust filter 150 Exhaust sterilizer
200 Air supply unit 210 Air supply fan 230 Supply air filter 250 Supply air sterilization device
300 control unit
400 monitoring department
500 detection unit

Claims (2)

In a ventilation system that ventilates the interior of an arbitrary space,
An exhaust unit that allows air to be sucked in through a plurality of ducts and discharges the sucked air to the outside;
an air supply unit supplying air downward from the top of the space;
A plurality of monitoring units provided in at least some of the plurality of ducts to monitor the amount of air passing through the ducts; and
a control unit that controls the exhaust unit, air supply unit, and monitoring unit;
Including,
The ducts include a branch duct installed adjacent to a lower surface in the arbitrary space, and a vertical duct connected to the branch duct and extending from the lower part to the upper part of the space,
In addition, at least some of the plurality of ducts further include a plurality of dampers controlled by the control unit to control the amount of air passing inside the duct,
The control unit determines the angles of the dampers based on the amount of air passing through the ducts measured by the monitoring units so that the amount of air monitored within the plurality of branch ducts provided with the monitoring units has a difference within a preset range, Characterized in controlling at least one of the driving strength of the exhaust part, the driving strength of the air supply part, and the size of the suction hole formed in the ducts,
ventilation system.
Ventilation system - The ventilation system includes an exhaust part that sucks air from the bottom and discharges it to the outside by a plurality of ducts in an arbitrary space, an air supply part that supplies air from the outside downward from the top, and air that passes through the ducts. Monitoring the amount of air, including a plurality of monitoring units provided in at least some of the plurality of ducts, and a control unit for controlling the exhaust unit, air supply unit, and monitoring units - a method of controlling Because,
operating the exhaust unit to suck in air in the arbitrary space and discharge it to the outside; and
supplying air into the arbitrary space by operating the air supply unit;
Including,
The ducts include a branch duct installed adjacent to a lower surface in the arbitrary space, and a vertical duct connected to the branch duct and extending from the lower part to the upper part of the space,
In addition, at least some of the plurality of ducts further include a plurality of dampers controlled by the control unit to control the amount of air passing inside the duct,
The control unit determines the angles of the dampers based on the amount of air passing through the ducts measured by the monitoring units so that the amount of air monitored within the plurality of branch ducts provided with the monitoring units has a difference within a preset range, Characterized in controlling at least one of the driving strength of the exhaust part, the driving strength of the air supply part, and the size of the suction hole formed in the ducts,
How to control ventilation systems.