KR20120062485A - Ventilation control system for decentralized ventilation of separated space and ventilation method using this - Google Patents

Abstract

PURPOSE: A ventilation control system for independently ventilating separated spaces and a ventilation method using the same are provided to respectively ventilate each space according to the state of each space. CONSTITUTION: A ventilation control system for independently ventilating separated spaces comprises an air discharge unit(300) and an air supply unit(200). A guide unit is placed in the outlet port of the air discharge unit. The guide unit selectively sucks air from a plurality of inlet ports or a part of the inlet ports. A control unit, which respectively controls the amount of outdoor air, is placed in the air supply unit. A main controller is connected to the air discharge unit and the air supply unit. The air discharge unit and the air supply unit selectively confirm the air state of predetermined spaces among inner spaces by controlling the guide unit. The air discharge unit and the air supply unit control the amount of air supplied to the inner spaces.

Description

Ventilation control system for individual ventilation in independent space and ventilation method using this

The present invention relates to a ventilation system, and more particularly to a ventilation control system and a ventilation method using the same for the individual ventilation of the independent space to be discharged to the outside through the air conditioner according to the condition of the indoor air.

Ventilation facilities are installed in large buildings such as apartments, buildings, and libraries. In particular, according to the recently announced building equipment standard, the installation of such ventilation equipment is mandatory when new apartments with more than 100 households are constructed.

In general, the ventilation system has a structure such as a duct whose ends are connected to the inside and outside of the building, respectively. The duct is divided into an air supply duct for introducing outside air and an exhaust duct for discharging the air inside, respectively, to flow air inside and outside the building.

1 is a perspective view of a configuration of a ventilation system according to the prior art. According to this, the ducts 13, 14 and 15 are installed in the installation space corresponding to the slab and the ceiling of the building. As shown, a plurality of ducts 13, 14, and 15 are installed along a predetermined path.

The ducts 13, 14, and 15 are composed of first and second ducts 13 and 14, and the first and second ducts 13 and 14 are in addition to the air supply duct 13 and the exhaust duct 14. ). The air supply duct 13 serves to supply the outside air to the room, and the exhaust duct 14 serves to discharge the air of the room to the outside.

In this case, a plurality of ducts (13, 14, 15) may be installed for the ventilation of each room of a separate space, for example, a multi-unit house. That is, as shown in FIG. 1, the second duct 15 may be installed separately from the first ducts 13 and 14. Of course, in addition to the first and second ducts 13, 14 and 15, a larger number of ducts may be installed to correspond to the number of partitioned spaces.

In addition, the ventilation facility may be used for cooling or heating indoors by acting as a passage for supplying cooled or heated air.

In some cases, a plurality of ducts 13, 14, and 15 may be connected by a duct connector (not shown) to connect the plurality of ducts 13, 14, and 15. The duct connector can be made to properly distribute the air flowing through the duct (13, 14, 15) into each space, or to control the amount or discharge direction of the air discharged according to the structure.

To this end, the duct connector is formed with a plurality of connection holes for connecting the air duct is connected, the connection hole is connected to the air duct is discharged.

By such a duct connector it is possible to more efficient air distribution, it can be adjusted according to the user's intention.

However, the prior art as described above has the following problems.

The air in each space may be discharged or supplied by the ducts 13, 14, and 15, and these ducts 13, 14, and 15 may be connected and efficiently distributed by the duct connectors.

However, when connected by the duct 13, 14, 15 and the duct connector it is difficult to control each space separately, there is a problem that it is difficult for the user or operator to arbitrarily adjust.

Of course, a separate control system may be installed to solve this problem. However, the construction cost is greatly increased and the system is complicated.

In addition, the degree of ventilation and the time required for each space, for example, the space of each room and the kitchen may be different according to the CO ₂ concentration and the degree of fine dust in each space, such as the duct (13, 14, 15) and In the case of the duct connector, it is difficult to control the state of each room.

In order to solve this problem, even if each of the sensors to check the state of each room, even if the sensor must be installed in each space, there is a problem that also increases the installation cost.

An object of the present invention is to solve the problems of the prior art as described above, and to implement an air discharge system capable of individual ventilation according to the state of each space of the building.

Another object of the present invention is to enable the ventilation operation by checking the state of each room with a minimum sensor module without installing a separate sensor in each space.

Another object of the present invention is to allow the air to be discharged together by using the output of the other duct in the process of discharging the air through the duct independently installed for a special space such as a toilet.

According to a feature of the present invention for achieving the above object, the present invention provides a ventilation control system for the ventilation of each of the plurality of internal spaces, a plurality of intake ports through which the air in each of the internal spaces through the exhaust duct; , An air discharge device having a discharge port through which suctioned air is discharged to the outside, and an air supply having a plurality of supply ports through which the inlet and the air introduced from the outside air are discharged into each interior space through a supply duct It is configured to include a device, the outlet of the air discharge device is provided with a sensor module to detect the state of the internal air discharged, the air discharge device to selectively suck the air from all or some of the plurality of intake ports A guide unit is provided to enable the air supply device. A control unit is provided to adjust the amount of water separately, and the air discharge device and the air supply device are connected to the main control device to control the guide unit to select the state of the air in a specific interior space of the plurality of interior spaces Check, and adjust the supply amount supplied to each internal space by adjusting the control unit according to the state.

The control unit includes a plurality of guide pans each extending toward the inlet and the supply port and rotatable in a direction independent of each other, and in each internal space through adjustment of the rotation angle of the pair of guide fans. It is possible to independently adjust the flow rate and the direction of the flow, or it is rotatably installed in each of the supply port is composed of a flow rate control unit for adjusting the opening degree of the supply port through the rotation is supplied to each interior space Independent adjustment of is possible.

The guide unit may include a plurality of pairs of guide fans each extending toward the inlet and outlet of the air discharge device and rotatable in directions independent of each other, thereby adjusting the rotation angle of the pair of guide fans. It is configured to enable independent adjustment of the amount of air and the direction of air sucked from each interior space through, or rotatably installed in each of the inlet is composed of a flow rate control unit for adjusting the opening degree of the inlet through rotation Independent control of the amount of air sucked from each interior space is possible.

The sensor module is configured of at least one of a carbon dioxide sensor, a human body sensor, a odor sensor, a smoke sensor or a fine dust sensor to detect abnormal air.

When abnormal air above the reference value is detected by the sensor module, the main control device selects the internal space where abnormal air above the reference value is generated by adjusting the guide unit to sequentially open the respective suction ports.

The control unit controls the supply amount of external air supplied through the supply port by operating a guide fan according to the state of each internal space detected by the sensor module.

The control unit adjusts the opening degree of each supply port in accordance with the abnormal degree of the abnormal air of the inner space.

The air discharge device is provided on the discharge path of the discharge port of the air discharge device is connected to the discharge guide for guiding the air discharge through the discharge port, the independent duct connected to a separate independent space that is distinct from the plurality of internal spaces It is provided to surround the discharge guide is provided with a guide case for forming a moving space between the outer surface of the discharge guide, the air of the separate space introduced into the moving space through the independent duct is discharged through the discharge guide Induced by the flow of air in the inner space is discharged together.

According to another feature of the invention, the present invention is a ventilation control system for the ventilation of each of the plurality of internal spaces, the preliminary check step of checking the abnormal air of the internal space by the sensor module installed in the outlet of the air discharge device; When the abnormal air is detected, the guide unit of the air discharge device operates to selectively open the suction port connected to the respective internal spaces, and then checks each chamber for checking the abnormal air in each internal space with the sensor module. When abnormal air is detected in the space, the guide unit of the air discharge device opens only the suction port of the specific internal space to discharge the internal air to the outside, and at the same time, the control unit of the air supply device operates to supply the specific internal space. And a ventilation step of opening the sphere to supply outside air.

In the ventilation step, the main control device controls the adjustment unit of the air supply device according to the degree of abnormal air to adjust the opening degree and the opening time of the supply port.

Following the ventilation step, a check step of rechecking the state of the air sucked from the internal space where the abnormal air is sucked by using the sensor module after a predetermined time, and if the abnormal air is not detected in the checking step, A restoration step of restoring the air supply device and the air exhaust device to its original state is further included.

Following the restoration step, after a predetermined time elapses, the process returns to the preliminary check step and repeats each step.

According to the ventilation control system and the ventilation method using the same for the individual ventilation of the independent space according to the present invention can be expected the following effects.

In the present invention, by checking the internal air condition of a plurality of independent spaces to individually ventilate, it is possible to prevent unnecessary ventilation and to perform only the ventilation of the necessary space independently, as a result, the power reduction effect compared to the entire ventilation system There is a relatively improved effect.

And since the individual ventilation of the independent space is automatically made by the control of the air discharge device and the air supply device, there is an advantage that the user's operation is not necessary, and thus the operation of the ventilation system is easy.

In addition, in the present invention, instead of installing a separate sensor in each independent space, by installing one sensor module in the air discharge device and controlling the opening of the inlet connected to each internal space to detect the internal space from which the abnormal air is discharged As a result, installation cost can be reduced.

In the present invention, since the ventilation is made by adjusting the air discharge device and the air supply device step by step according to the abnormal degree of the abnormal air in each interior space, it is expected that the waste of energy and the maintenance cost of the ventilation system are also reduced. Can be.

1 is a perspective view showing the configuration of a ventilation system according to the prior art.
Figure 2 is a block diagram showing the configuration of a preferred embodiment of the ventilation control system for individual ventilation of the independent space according to the present invention.
Figure 3 is a plan view showing the configuration of an air supply device constituting an embodiment of the present invention.
Figure 4 is a plan view showing the control unit and other internal configuration of the air supply device constituting an embodiment of the present invention.
Figure 5 is a front view showing the configuration of an air supply device constituting an embodiment of the present invention.
6 is an exemplary view showing various examples of supplying air to each internal space using the air supply device constituting the embodiment of the present invention.
Figure 7 is a perspective view showing another embodiment of the control unit of the air supply device constituting an embodiment of the present invention.
Figure 8 is a cross-sectional view showing the configuration of the discharge guide and guide case constituting an embodiment of the present invention.
9 is a flow chart showing the configuration of a ventilation method using a ventilation control system for individual ventilation of the independent space according to the present invention.
10 is a flow chart illustrating a process of detecting carbon dioxide by the present invention.
11 is a flow chart showing a procedure for ventilating the internal space using the embodiment of the present invention.

Hereinafter, a configuration of a ventilation control system for individual ventilation of an independent space according to the present invention as described above will be described in detail with reference to the accompanying drawings.

Figure 2 shows the configuration of a preferred embodiment of the ventilation control system for the individual ventilation of the independent space according to the present invention.

As shown, the ventilation system is provided with an air supply / discharge unit 110. The air supply / exhaust unit 110 may be an air purifier or may be a simple building exterior without undergoing separate purification.

The air supplied from the air supply / discharge unit 110 passes through the heat exchange device 20. The heat exchanger 20 serves to enable heat exchange between the air supplied into the building and the air discharged.

That is, in the case of heating the interior of the building, when the air whose temperature rises through the building and the relatively cold air supplied from the air supply / exhaust unit 110 undergo heat exchange, the air supply / exhaust unit 110 The air supplied from) can be heated primarily to increase the thermal efficiency. Of course, the same applies to cooling the inside of a building.

Although not shown in the heat exchanger 20, a blower fan is provided to discharge air to the air supply / discharge unit 110 or to build air supplied from the air supply / discharge unit 110. It can also discharge in the inner direction.

Induction discharge device 100 is installed in the heat exchange device (20). Looking at the induction discharge device 100 in more detail, the induction discharge device 100 is configured to include a discharge guide 1200 and the guide case 1300 as shown in FIG. The discharge guide 1200 and the guide case 1300 are assembled to the heat exchanger 20, through which the air through the heat exchanger 20 is discharged to the outside, and the discharge guide 1200. And through the space between the guide case 1300, the air moved through the independent duct (D3, see FIG. 2) is discharged.

In addition, the air (air in rooms 4 and 5 (R4 and R5)) moved through the space between the discharge guide 1200 and the guide case 1300 is a flow of air discharged through the discharge guide 1200. Drawn by and discharged together.

Referring to the structure of the discharge guide 1200, the discharge guide 1200 is composed of a fixed portion 1210, the inclined portion 1220, and the discharge portion 1230. The fixing part 1210 is a part fixed to the heat exchanger 20, and is formed in a substantially cylindrical shape as shown.

The inclined portion 1220 extends inclined from the fixing portion 1210 to be narrower, and is formed in a kind of truncated conical shape with the cross section decreasing toward one end thereof. The inclined portion 1220 allows the cross-sectional area of the discharge guide 1200 to be smaller so that the flow rate of the discharged air is faster. This is because when the fluid flows at the same height, the velocity of the fluid increases as it flows through the narrow passage and decreases as it flows through the wide passage.

A discharge part 1230 is connected to the inclined part 1220. The discharge part 1230 is a portion extending from the inclined part 1220 to substantially discharge air, and is formed in a substantially cylindrical shape similar to the fixing part 1210.

Due to this structure, the air discharged through the heat exchanger 20 is discharged through the discharge unit 1230 in a state where the flow velocity is increased while passing through the inclined unit 1220.

In this case, the distal end of the discharge portion 1230 of the discharge guide 1200 is protruded more than one end of the connection portion 1320 of the guide case 1300 to be described later, that is by the guide portion 1330 of the guide case 1300 It is preferably formed in the enclosed position.

Next, with reference to the guide case 1300, the guide case 1300 is to be assembled to the heat exchange device 20 while surrounding the discharge guide 1200, with the outer surface of the discharge guide 1200 It forms a moving space in which air moves between.

At the same time, the guide duct 1300 is connected to the independent duct D3. As a result, the guide case 1300 guides the air moved through the independent duct D3 to be discharged through the moving space. Play a role.

Looking in more detail with respect to the structure of the guide case 1300, as shown in Figure 10, the guide case 1300 is to audit the fixed portion 1210 of the discharge guide 1200 and the independent duct ( The base portion 1310 to which D3) is connected forms its skeleton.

The base portion 1310 is formed in a substantially cylindrical shape similar to the fixing portion 1210, and the independent duct D3 is connected to the side surface thereof.

The connection part 1320 is connected to the base part 1310, and the connection part 1320 is formed in a truncated cone shape such that the cross sectional area becomes smaller toward one end thereof, like the inclined part 1220 of the discharge guide 1200.

An induction part 1330 is formed at one end of the connection part 1320. The induction part 1330 protrudes relatively more than the discharge part 1230 of the discharge guide 1200 to form an induction space therebetween. The guide space corresponds to a space that guides the moving space to be discharged together by being attracted to the flow of air discharged through the discharge unit 1230. For reference, reference numerals 1231 and 1331 mean openings of the discharge guide 200 and the guide case 300, respectively.

Next, with reference to Figures 2 and 8 will be described the operating principle of the air is discharged by the air discharge device.

First, the air heat exchanged by the heat exchanger 20 (air delivered through the discharge duct D2 from rooms 1 to 3 (R1 to R3)) is moved by an internal fan to open the discharge hole 25. It is discharged to the outside at a rapid rate, the air discharge is moved through the discharge guide 1200 because the discharge guide 1200 is installed in the discharge hole (25).

In addition, the air moved through the discharge guide 1200 is faster through the inclined portion 1220, the flow rate is faster, and is discharged through the discharge unit 1230 in this state.

Meanwhile, air existing in the moving space formed by the discharge guide 1200 and the guide case 1300 surrounding the air (air delivered through the independent duct D3 from the rooms 4 and 5 (R4 and R5)) is Since it does not receive the force discharged by the heat exchange device 20, it is present in a state that can not be discharged by itself.

However, the air present in the moving space is drawn by the air discharged through the discharge unit 1230 and discharged together. This phenomenon is due to Bernoulli's theorem.

The heat exchange device 20 is connected to the duct connector. The duct connector serves as a kind of hub for connecting a plurality of ducts, an air supply device 200 for supplying air to each room, and an air discharge device 300 for discharging air from each room to the outside. It consists of

A plurality of ducts (hereinafter referred to as 'feed ducts D1') are connected to the air supply device 200 to supply air to each room (independent interior space). In Figure 2, a separate reference numeral is given to each room for convenience.

At this time, air is supplied from the air supply apparatus 200 to all of the rooms 1 to 5 (R1 to R5), which are each distributed with air through a separate supply duct (D1).

On the other hand, the air supplied to the rooms 1 to 5 (R1 ~ R5) should be discharged again for ventilation, in this case it can be discharged through the air discharge device (300). That is, the discharge duct D2 is connected to the rooms 1 to 5 (R1 to R5), respectively, to discharge the internal air.

At this time, the room 1 to room 3 (R1 ~ R3) (defined as the inner space) is connected to the air discharge device 300 through a duct (hereinafter referred to as 'discharge duct (D2)') to the air inside Room 4 and Room 5 (R4, R5) (defined as separate spaces) are referred to as separate and separate ducts (hereafter referred to as 'independent ducts' (D3)).

This is separated from general residential rooms (for example, rooms 1 to 3 (R1 to R3)) when rooms 4 and 5 (R4 and R5) are spaces that may contain bad smell or soot, such as toilets and kitchens. This is to prevent odor or soot mixed through heat exchange process.

Unlike the discharge duct D2, the independent duct D3 is not connected to the air discharge device 300 and is discharged to the outside through a separate air discharge device 300 to be described below.

The independent duct D3 may be provided with a separate blower device 150. The blower 150 is operated when the air can not be discharged by the air discharge device 300 to induce the internal air of the room 4 (R4) or room 5 (R5), separate operation switch (S) is provided so that a user can operate arbitrarily.

In this case, although FIG. 2 shows that rooms 4 and 5 (R4, R5) are both connected to the blower 150, a separate blower 150 is connected to each of rooms 4 and 5 (R4, R5). Can be operated individually.

The independent duct D3 connected from the blower 150 is connected to the air discharge device 300 again. The air discharge device 300 is for discharging air introduced through the independent duct D3, and is connected to the independent duct D3 and simultaneously connected to the heat exchanger 20. This is to allow air discharge from the independent duct D3 by using a flow of air discharged from the heat exchanger 20.

Meanwhile, a sensor module 500 is installed between the air supply device 200 and the heat exchanger 20. The sensor module 500 detects whether there is an abnormality in the air of the internal space discharged from the air discharge device 300, a discrete ring carbon sensor, a human body sensor, a odor sensor, a smoke sensor, fine dust At least one of the sensing sensor or the temperature sensor.

That is, the sensor module 500 is for detecting the state of the air in the internal space, in this embodiment between the air discharge device 300 and the heat exchanger 20, more precisely the air discharge device 300 It is installed at the position adjacent to the.

Next, the configuration of the air supply device 200 and the air discharge device 300 will be described. At this time, since the configuration of the air supply device 200 and the air discharge device 300 is the same, it will be described below with reference to the air supply device 200.

3 to 5, the skeleton of the air supply device 200 is formed by the housing 220. A plurality of ducts (D) are connected to the housing 220. The ducts (D) are a kind of pipe for guiding the flow of air, and both ends thereof are opened.

That is, one end of the duct D is connected to the housing 220, more precisely, the inlet I and the supply port 230 to be described later, and the other end extends in various directions to serve to flow air into various spaces. do. The duct D corresponds to the supply duct D1 based on FIG. 2.

At this time, by connecting a plurality of ducts (D) to the one air supply device 200 to control the air volume and the wind direction, the air supply device 200 serves as a kind of air distribution / regulator.

And, as shown in Figure 3, the connecting portion 260 may be provided between the duct (D) and the supply port 230 of the housing 220. The connection part 260 is formed to be open to both sides, and is coupled to the supply port 230 and at the same time coupled to the duct (D) serves to connect between the two.

The housing 220 may be made of various materials such as polyvinyl chloride (PVC) or fiberglass reinforced plastics (FPC).

As shown in FIG. 5, the housing 220 of the air supply device 200 has a flow space S formed therein, and a plurality of inlets I and supply holes 230 are formed around the sides thereof. More specifically, the housing 220 is composed of a main body 227 and a cover 221 assembled to the upper surface of the main body 227, the flow by the main body 227 and the cover 221 The space S is formed therein.

The inlet (I) is provided on one side of the air supply device 200 is a portion in which air is introduced from the outside, is connected to the duct (D) extending to the outside air is introduced. The inlet I may be heated air or cooled air, or ventilated air may be introduced, depending on the purpose of use, such as cooling and heating of the air supply device 200.

In addition, the supply port 230 is a portion through which the air flowing through the inlet port I and passing through the flow space S of the housing 220 is discharged, and the duct D is connected to the duct D. It serves to discharge air to other spaces spaced through.

At this time, the supply port 230 is provided with a plurality along the outer surface of the housing 220 of the air supply device 200, at least part or all of the supply port 230 is provided along a substantially arc-shaped path It is preferable to be. This is for the supply port 230 to correspond to the rotation path of the guide fan 235, 237 of the control unit (C) to be described below so that the flow of air can be accurately controlled.

In the present embodiment, a total of four supply ports 230 positioned at the top are provided side by side along a path of an arc, and two supply ports 230 are provided at both sides, but this may be changed for convenience. In addition, in the present embodiment, the inlet I and the supply port 230 are provided with one and six, respectively, but are not necessarily limited thereto, the number of the inlet (I) and the supply port 230 is to be changed according to the use and installation location of the air supply device 200 Can be.

As shown in Figure 3, the upper surface of the cover 221 is formed a ruler 222, the ruler 222 serves to guide the operation of the control lever 225 to be described below. That is, the ruler 222 allows the operator to operate the control lever 225 accurately to a desired degree while visually checking it. To this end, the ruler 222 may display a unit for the air volume or the wind direction. The ruler 222 may be embossed on an upper surface of the cover 221, or a separate object may be attached.

The cover 221 is provided with an adjustment lever 225. The control lever 225 is for manipulating the control unit (C) to be described below, is provided to protrude out of the upper surface of the cover 221. The control lever 225 may be rotated by the operator to direct the guide fan 235, 237 of the control unit (C), in this embodiment, the control lever 225 is driven by a drive motor (not shown) It will rotate automatically.

At this time, the control lever 225 is provided with a display unit 226, the display unit 226 corresponds to a kind of arrow corresponding to the ruler 222. That is, when the control lever 225 is rotated, the display unit 226 rotates together, and the sharp tip thereof points to a predetermined position of the ruler 222. Accordingly, the user can accurately adjust the control unit (C) or check the position of the display unit 226 to recognize the state of the control unit (C).

As shown in Figure 5, the flow unit (S) of the housing 220 is provided with a control unit (C). The control unit (C) is for controlling the air introduced into the flow space (S) through the inlet (I), and more precisely serves to adjust the wind direction and air volume.

The control unit (C) includes at least one guide fan (235, 237). The guide fans 235 and 237 serve to distribute the air introduced into the flow space S to the supply port 230, and more precisely to set the amount of air discharged and the supply port 230 to be discharged. Play a role.

The control unit (C) may be provided with a plurality of guide fans (235, 237), in this embodiment a total of three guide fans (235, 237) are provided. Of course, two or less or four or more may be provided depending on the installation space and use environment of the air supply device 200.

The guide pans 235 and 237 are composed of an inlet guide fan 235 and a distribution guide fan 237, which extend toward the inlet I and the supply port 230, respectively, and are provided to be rotatable independently of each other. It controls the incoming air and the discharged air in various ways. Hereinafter, these will be described sequentially.

The inflow guide fan 235, as shown in Figure 4, one end is rotatably fixed to the base body of the housing 220 around the rotation axis 233, the other end to extend toward the inlet (I) It is provided. The inflow guide fan 235 installed to be rotatable as described above controls the inflow direction and the flow amount of the inflowing air.

In addition, the inlet guide fan 235 also serves to divide the inlet path of the air introduced through the inlet (I). That is, the three inflow guide fans 235 divide the air inflow path into four. Accordingly, a portion of the air inflow path is selectively shielded or the width is adjusted according to the rotation of the inflow guide fan 235, thereby changing the air volume.

At this time, the inlet guide fan 235 is provided so that one end thereof extends to the inlet edge of the inlet opening of the inlet port I, which is simultaneously introduced into the inlet guide fan 235. This can be controlled by.

In addition, an interval between two inflow guide fans 235 adjacent to each other is preferably shorter or equal to the length of the inflow guide fan 235. This is to allow the air inlet of the inlet I to be completely shielded when the inlet guide fan 235 is completely rotated. Through this, some air inflow path in the flow space (S) can be selectively shielded (see Fig. 6 (a), (f)).

In addition, the inlet guide fan 235 is provided to have a rotation path that may interfere with each other adjacent inlet guide fan 235. This is in order to allow the inlet guide fan 235 and the adjacent inlet guide fan 235 to interfere with each other, so that a part of the air inlet paths can be completely blocked (see FIG. 6 (a)).

Next, referring to the distribution guide fan 237, the distribution guide fan 237 is provided to extend toward the supply port 230 in a position adjacent to the inlet guide fan 235, the inflow guide It is rotated independently of the fan 235. Accordingly, the various directions of the wind direction and the amount of wind can be controlled by the free rotation of the inlet guide fan 235 and the distribution guide fan 237.

As shown in Figure 4, the distribution guide fan 237 is provided to be rotated about the rotation axis 236, the supply port 230 or the discharge port through which the air introduced through the inlet (I) through the rotation is discharged Serves to control.

A fixed flange B is provided between the inflow guide fan 235 and the distribution guide fan 237. The fixed flange (B) guides the flow of air while connecting the inflow guide fan 235 and the distribution guide fan 237 and is fixed to the main body 227. Of course, the fixed flange (B) may be omitted depending on the change in the overall size of the air supply device 200 and the number of the supply port 230.

FIG. 6 shows various paths formed by using the control unit C of the air supply device 200. By using the control unit (C) in this way, it is possible to selectively supply the external air to be supplied to the desired specific internal space.

Similarly, the air discharge device 300 can also control the air discharged from the internal space. More precisely, by using the guide unit (not shown, the same as the control unit (C)) of the air discharge device 300, it is possible to selectively discharge the indoor air delivered from each of the internal space (R1 ~ R3). .

For reference, the air discharge device 300 is provided with an inlet port (not shown) connected to each of the internal spaces R1 to R3 and the discharge duct D2, and passes through the flow space of the air discharge device 300. A discharge port (not shown) to be connected is provided.

As the guide unit of the air discharge device 300 is driven in various ways, the indoor air of each internal space (R1 ~ R3) can be selectively sucked. This selectively sucks the indoor air of each of the internal spaces (R1 ~ R3), by sensing the air with the sensor module 500 to be able to sense the state of each of the internal space (R1 ~ R3) individually For sake. Accordingly, one sensor module 500 can also detect the state of each of the internal space (R1 ~ R3) individually.

On the other hand, Figure 7 shows another example of the control unit constituting the embodiment of the present invention.

That is, in the above embodiment, the control unit (C) is installed inside the air supply device 200, but in the embodiment to be described below, the control unit (C) of the above embodiment is omitted and has the following configuration. .

As shown in Figure 7, the adjustment unit (C ') is composed of a connecting portion 260 and the adjustment plate 280 and the drive motor (M) provided in the air supply device 200.

The control unit (C ') is for controlling the amount of air discharged from the supply port 230, it is possible to control the amount of air flowing into the duct (D) to control the amount of air flowing into each room as a result .

Looking at the structure of the control unit (C '), the inside of the connection portion 260 is provided with a control plate 280 rotatably provided. As shown in FIG. 7B, the control plate 280 is formed in a plate shape having a rotation center, and the control plate 280 is rotatably fixed to both sides of the connection part 260, respectively.

At this time, the control plate 280 is connected to the drive motor (M), the drive motor (M) is to provide a rotational force so that the control plate 280 is rotated, it is controlled by the main control device.

On the other hand, the adjustment plate 280 may be set to rotate by a predetermined angle step by step. That is, the control plate 280 is rotated at a predetermined angle while the opening and closing amount of the connecting portion 260 is adjusted according to the angle. This adjustment is made by the control of the main control device according to the air supply amount required in each compartment.

In the present embodiment, the control plate 280 is divided into 90 ° (orthogonal), 60 °, 30 °, 0 ° (horizontal) stages based on the direction in which the connecting portion 260 is opened, and thus shielding (0%) ), 1/3 open (33% discharge), 2/3 open (67% discharge), and full open (100% discharge). Of course, the opening and closing angle may be modified according to the building structure.

Of course, the shape of the control plate 280 and the connecting portion 260 is not necessarily limited to this, as shown in Figure 12, may be composed of a disk-shaped control plate 280 and the circular tubular connecting portion 260. In this case, the shielding or discharging method by the rotation of the control plate 280 is made the same.

At this time, this control unit (C ') is determined according to the amount of air required in each compartment as described above, which is the main control device according to the state of each of the inner space (R1 ~ R3) by the sensor module It is calculated and adjusted by. That is, when indoor air in a specific internal space is contaminated, the outside of the control plate 280 is rotated according to the degree of contamination to supply fresh air outside.

Of course, the control unit (C ') can be equally applied to the air discharge device (300). That is, the guide unit inside the air discharge device 300 is omitted, and the guide unit having the same configuration as the control unit C 'is provided with the suction port (each internal space R1 to R3) of the air discharge device 300. Guide unit having the same configuration as the control unit (C ') may be installed in the portion connected by the duct (D2).

Hereinafter, the ventilation method using the ventilation control system for the individual ventilation of the independent space according to the present invention having the configuration as described above will be described in detail.

9 is a flow chart showing the configuration of a ventilation method using a ventilation control system for individual ventilation of the independent space according to the present invention, Figure 11 is a flow chart showing a procedure for ventilating the internal space using the embodiment of the present invention have.

As shown in the drawing, first, when the ventilation system is operated, the sensor module 500 operates to check the state of each internal space R1 to R3. The sensor module 500 includes a fine dust sensor, a carbon dioxide sensor, and the like, and the sensor module 500 sequentially or simultaneously checks the concentration or carbon dioxide concentration of the fine dust (preliminary check step, S100).

At this time, the sensor module 500 is installed around the outlet of the air discharge device 300, more precisely between the air discharge device 300 and the heat exchanger (20). Accordingly, the sensor module 500 detects a state of the air discharged through the air discharge device 300, and can distinguish which air is contaminated from which internal space is discharged from a plurality of internal spaces R1 to R3. none.

Therefore, once the air contaminated by the sensor module 500 is sensed, each of the inner spaces R1 to R3 may be independently checked by operating the guide unit of the air discharge device 300.

That is, by opening only the suction port connected to any one of the internal spaces R1 to R3 and shielding the remaining suction port, it is possible to check the internal air state of one internal space, for example, the first chamber R1. (Each check step, S110)

Then, by checking the state of each of the remaining internal space (R2, R3) with a certain time difference, it is possible to sort out the space where the previously detected polluted air is generated.

At this time, the adjustment of the guide unit of the air discharge device 300 is made by the main control device. For reference, the structure of the guide unit may be both the embodiment shown in Figure 4 (control unit (C)) or the embodiment shown in Figure 7 (control unit (C ')).

When the specific interior space (hereinafter, assumed to be the first room R1) where contaminated air exists is detected, ventilation of the first room R1 is started. (Ventilation step S120).

More precisely, the air supply device 200 completely opens the supply port connected to the first chamber R1 so that the outside air is sufficiently supplied. At the same time, the intake port connected to the first chamber R1 is also completely opened in the air discharge device 300 so that the contaminated internal air can be smoothly discharged.

After a predetermined time has elapsed, the sensor module 500 senses the same degree of contamination to re-measure the pollution level (step S130), and when it is determined that the ventilation is performed (below the input reference value), the air supply device 200. ) And the air discharge device 300 is restored to its original state to stop the ventilation. (Restore step, S140)

As described above, since the state of each of the internal spaces R1 to R3 can be selectively checked by one sensor module 500, the sensor module 500 is individually stored in all the internal spaces R1 to R3. No need to install

In the above description, if there is contaminated air, the supply port (air supply device) and the inlet port (air exhaust device) are completely opened and ventilated, but the present invention is not limited thereto. You can also ventilate with.

That is, the degree of ventilation can be precisely controlled through the operation of the control unit (example shown in FIG. 4 or the example shown in FIG. 7) and the stepwise operation and opening time of the guide unit (the same structure as the control unit).

Of course, even if the polluted air is not detected, it may always be maintained at a certain degree, for example, 30% open according to the user's choice.

And, by repeating this process through the control of the main control device, it is possible to smoothly ventilate the polluted air in each of the interior space (R1 ~ R3).

 The scope of the present invention is not limited to the embodiments described above, but is defined by the claims, and various changes and modifications can be made by those skilled in the art within the scope of the claims. It is self evident.

In the above embodiment, only one sensor module 500 is installed, but the sensor module 500 may be installed in each of the internal spaces R1 to R3, respectively.

20: heat exchanger 100: induction discharge device
110: air supply / discharge unit 150: blower
200: air supply device 220: housing
221: cover 227: main body
230: air outlet 233: rotating shaft
235: inflow guide fan 236: rotating shaft
237 exhaust guide fan C, C ': control unit
I: air inlet 300: air exhaust device
500: sensor module

Claims (12)

In the ventilation control system for the individual ventilation of the independent space for the ventilation of each of a plurality of independent interior space,
An air discharge device having a plurality of inlets for introducing air from each of the internal spaces through the discharge ducts, and an outlet for discharging the sucked air to the outside;
It is configured to include an air supply device having a plurality of supply ports for the inlet and the inlet air from which the outside air is introduced into each of the interior space through the supply duct,
A sensor module is provided at a discharge port of the air discharge device to sense a state of the discharged internal air, and the air discharge device is provided with a guide unit to selectively suck air from all or some of the plurality of suction ports. The air supply device is provided with a control unit for individually adjusting the supply amount of the external air supplied to the plurality of internal spaces,
A main control device is connected to the air discharge device and the air supply device to adjust the guide unit to selectively check a state of air in a specific internal space among the plurality of internal spaces, and adjust the control unit according to the state. Ventilation control system for individual ventilation of the independent space, characterized in that by adjusting the amount of supply supplied to each internal space by adjusting.
The method of claim 1, wherein the control unit,
A plurality of guide pans each extending toward the inlet and the supply port and rotatable in directions independent of each other are included, and the air volume and the wind direction supplied to each internal space through adjustment of the rotation angle of the pair of guide fans. Can be adjusted independently, or
It is configured to adjust the opening degree of the supply port through the rotation of the control plate is rotatably installed in each of the supply port is the individual ventilation of the independent space, characterized in that the independent control of the amount of air supplied to each interior space Ventilation control system.
The method of claim 1, wherein the guide unit,
A plurality of guide fans each extending from the inner space of the air discharge device toward the inlet and the outlet and rotatable in directions independent of each other are included, and each inner space is controlled by adjusting the rotation angle of the pair of guide fans Is configured to allow independent adjustment of the amount of wind and direction of air sucked in from, or
It is configured to adjust the opening degree of the suction port through the rotation of the adjustment plate is rotatably installed in each of the inlet port for independent ventilation of the independent space, characterized in that the independent control of the amount of air sucked from each interior space Ventilation control system.
The sensor module of claim 3, wherein the sensor module comprises at least one of a carbon dioxide sensor, a human body sensor, an odor sensor, a smoke sensor, a temperature sensor, and a fine dust sensor to detect abnormal air. Ventilation control system for individual ventilation in independent space.
According to any one of claims 1 to 4, When the abnormal air more than the reference value is detected by the sensor module, the main control device by adjusting the guide unit to open the respective inlet in order to the respective inner space Ventilation control system for individual ventilation in an independent space, characterized in that the internal space where abnormal air above the standard value is generated.
The method according to claim 5, wherein the control unit of the independent space, characterized in that the guide fan is operated in accordance with the state of each internal space detected by the sensor module to control the amount of external air supplied through the supply port Ventilation control system for individual ventilation.
According to claim 6, wherein the control unit is controlled by the main control device for controlling the individual ventilation in the independent space, characterized in that the step of adjusting the opening degree of the respective supply port in accordance with the abnormality of the abnormal air of the internal space Ventilation control system.
According to claim 7, wherein the air exhaust device
A discharge guide installed on the discharge path of the discharge port of the air discharge device and guiding the air discharge through the discharge port;
Independent ducts connected to separate independent spaces distinguished from the plurality of internal spaces are connected to each other, and are provided to surround the discharge guide, and a guide case is provided to form a moving space between the outer surface of the discharge guide.
The air of the separate space introduced into the moving space through the independent duct is guided by the flow of air in the inner space discharged through the discharge guide and is discharged together.
In the ventilation control method for the individual ventilation of the independent space for the ventilation of each of a plurality of independent interior space,
A preliminary checking step of checking whether there is an abnormality in the exhaust air of the internal space by a sensor module installed at the outlet of the air exhaust device;
When the abnormal air is detected, the guide unit of the air discharge device is operated to open a plurality of inlets connected to the respective inner spaces sequentially, each chamber checking step of individually checking the abnormal air in each inner space with the sensor module,
When abnormal air is detected in a specific internal space, the guide unit of the air discharge device opens only the suction port of the specific internal space to discharge internal air to the outside, and at the same time, the control unit of the air supply device operates to operate the specific internal space. Ventilation control method for individual ventilation of an independent space comprising a ventilation step of supplying the outside air by opening the supply port of.
10. The method of claim 9, wherein in the ventilation step, the main control device controls the control unit of the air supply device in accordance with the degree of abnormal air to adjust the opening degree and opening time of the supply port of the independent space Ventilation control method for individual ventilation.
The method according to claim 9 or 10, further comprising a check step of rechecking the state of the air sucked from the internal space in which the abnormal air is sucked by using the sensor module after a predetermined time after the ventilation step;
And if the abnormal air is not detected in the checking step, a restoring step of restoring the air supplying device and the air exhausting device to its original state.
12. The ventilation control method according to claim 11, wherein after the restoration step, a predetermined time passes and the process returns to the preliminary check step and repeats the steps.

Images