KR20080011507A - Control method of outdoor air suction equipment - Google Patents

Abstract

A control method of an outside-air intake apparatus is provided to improve efficiency of ventilating for an inner space by controlling flow direction of air according to physical property of internal or external air. A control method of an outside-air intake apparatus comprises the steps of: sensing physical property of internal air by mounting an indoor sensor(S2) at one side of a case which includes an inner space; sensing the physical property of the external air by installing an outdoor sensor(S1) at the other side of the case; comparing the physical property of air sensed from the outdoor sensor and the indoor sensor; generating driving force by the result from the comparing step; and rotating a vane for selectively covering the inner space of the case by a link powered by the driving force generated from the driving step. The physical property of air sensed by the internal or external sensors is carbon dioxide or enthalpy.

Description

Control method of outdoor air intake device {Control method of outdoor air suction equipment}

1 is a perspective view showing the appearance of a general air conditioner according to the prior art.

Figure 2 is an exploded perspective view showing the internal configuration of a general air conditioner according to the prior art.

Figure 3 is a perspective view showing the external appearance of the external air induction apparatus employing a preferred embodiment of the present invention.

Figure 4 is a schematic exploded perspective view showing the internal configuration of the external air induction apparatus employing a preferred embodiment according to the present invention.

Figure 5 is a schematic diagram showing a state in which the central portion of the inner space of the external air filling apparatus employing a preferred embodiment of the present invention is shielded.

Figure 6 is a schematic view showing a state in which the central portion of the inner space of the external air filling apparatus is adopted preferred embodiment according to the present invention.

7 is a block diagram showing a system configuration for controlling an external air filling apparatus employing a preferred embodiment of the present invention.

Figure 8 is a flow chart showing the control flow of the outdoor air inlet apparatus using the indoor and outdoor enthalpy difference employed one preferred embodiment according to the present invention.

9 is a flow chart showing the control flow of the outdoor air inlet apparatus using the concentration difference of indoor and outdoor carbon dioxide employing a preferred embodiment according to the present invention.

Explanation of symbols on the main parts of the drawings

100.Case 120.Front Intake

122. Suction duct fastening part 124. Side discharge port

124 '. Discharge guide 126. Side suction port

126 '. Suction guide 140.Center vane section

142.Center Post 144. Center Bain

160. Center link part cover 200. Side ejection part

210. Discharge guide 220. Auxiliary control unit

230. Discharge link part cover 240. Discharge vane part

242. Discharge post 244. Discharge vane

300. Side suction part 310. Suction guide

320. Suction filter 322. Filter frame

324. Filters 330. Filter guides

340. Suction link cover 350. Suction vane

352. Suction posts 354. Suction vanes

410. Link drive plate 420. Central link part

430. Discharge link part 440. Suction link part

S ₁ . Outdoor sensor S ₂ . Indoor sensor

The present invention relates to an external air inlet apparatus of an air conditioner, and more particularly, to a control method of an external air inlet apparatus that senses physical properties of outdoor air and indoor air to control air flow of the external air inlet apparatus according to physical properties. will be.

An air conditioner is a device that harmonizes the air of a space for air conditioning to an optimum state according to the purpose, and there is an increasing demand in order to create a more comfortable and comfortable living environment. It is a device installed in a space or wall to cool or heat a room, and constitutes a series of cycles of compression, condensation, expansion, and evaporation.

An air conditioner is equipped with a condenser and a compressor, and is mainly an outdoor unit (also called an outdoor side or a heat dissipating side) installed outdoors, and an indoor unit (also called an indoor side or an endothermic side) equipped with an evaporator and mainly installed indoors. Separated by. The air conditioner is divided into a separate air conditioner in which the outdoor unit and the indoor unit are installed separately, and an integrated air conditioner in which the outdoor unit and the indoor unit are installed integrally.

The indoor unit of the separate air conditioner is provided with an indoor unit each having a primary side flow path formed in each indoor space, and an outdoor unit having a secondary side flow path may be installed in connection with each indoor unit, and each indoor unit may be installed in one outdoor unit. It may be connected and installed.

In addition, the integrated air conditioner is a duct type air conditioner that is formed integrally with the indoor unit and the outdoor unit is connected to each indoor space and the duct to harmonize the indoor air, and the window type air that is installed in a window in one indoor space to harmonize the indoor air It can be divided into a harmonic and the like.

In addition to air conditioning and heating, the air conditioner has a variety of functions such as an air purifying function of re-purifying clean air by suctioning and purifying indoor contaminated air, and a dehumidification function of re-injecting humid air into wet and dry air. Additional features are being added.

Hereinafter, a duct type air conditioner of the integrated air conditioner will be described with reference to the drawings.

Figure 1 is a perspective view showing the appearance of a conventional air conditioner according to the prior art, Figure 2 is an exploded perspective view showing the internal configuration of the air conditioner according to the prior art.

Looking at the air conditioner with reference to these drawings, the air conditioner is the appearance is formed by the main body 10 of a substantially rectangular box shape. The main body 10 includes a right side panel 20 forming a right side appearance, a front panel 30 forming a front side appearance, a left side panel 40 forming a left side appearance, and an upper side panel 50 forming a top appearance. Then, it is composed of a lower panel (60) to form the outer surface.

A plurality of components are mounted inside the main body 10, and the front panel 30 is equipped with a suction duct (not shown) for guiding air in a space for air conditioning into the main body 10. do. Between the right panel 20 and the left panel 40 of the main body 10, the barrier 70 is provided across the left and right.

The barrier 70 is formed into a rectangular plate shape having a predetermined thickness, and the inside of the main body 10 is formed by the barrier 70 in the front of the barrier 70 and the primary side flow path 80 is formed forward. In the rear, a secondary side flow path 90 is formed.

An indoor fan 81 is mounted in the primary side flow path 80. The indoor fan 81 is rotated to generate a suction force in the internal space of the main body 10, by the suction force the air of the space for air conditioning into the interior of the main body 10. It is sucked into the primary side flow path formed inside the main body 10, that is, in front of the barrier 70.

The outside of the indoor fan 81 is provided with a fan housing 82. The lower surface of the fan housing 82 is mounted while contacting the upper surface of the lower panel 60, and the left end is mounted to contact the inner surface of the left panel 40.

The front panel 30 is formed with a perforated front rectangular opening 32 which is a passage through which air for air conditioning is sucked into the body 10 in a longitudinal direction. In the left side of the front suction port 32, the front discharge port 36 is formed in a rectangular shape in which the air harmonized inside the main body 10 is discharged.

An intake duct guide 34 to which an intake duct (not shown) is fastened protrudes toward the front of the front inlet 32 so that air of a space for air conditioning is sucked into the body 10. Is formed. The discharge duct guide 38 is fastened to the edge of the front discharge port 36 to which the discharge duct (not shown) is fastened to guide the air conditioned inside the main body 10 to be discharged into the space for air conditioning. Is formed.

The rear side of the front suction port 32 is equipped with an indoor heat exchanger 83 through which the air sucked into the inside of the primary side flow path 80 through the front suction port 32 is heat-exchanged. The indoor heat exchanger 83 is mounted in a substantially " / " shape when viewed from above between the front suction port 32 and the front discharge port 36 from the rear surface of the front panel 30 to the right end of the barrier 70. .

A refrigerant that is a working fluid flows inside the indoor heat exchanger 83, and a train fan 84 is provided below the indoor heat exchanger 83. The drain pan 84 is formed in the shape of a rectangular parallelepiped having an upper surface, and is provided at a position corresponding to the lower end of the indoor heat exchanger 83.

The drain pan 84 collects condensed water falling downward along the surface of the indoor heat exchanger 83. A drain hole 85 is formed on the side surface of the drain pan 84, and the drain hole 85 is formed to be in communication with the outside while contacting the right panel 20. The drain hole 85 serves as a passage for discharging condensed water collected in the drain pan 84 to the outside of the main body 10.

At the center of the secondary side flow path 90 formed behind the barrier 70, a compressor 91 for compressing a refrigerant, which is a working fluid, in a state of high temperature and high pressure is mounted. As the compressor 91, a relatively large scroll compressor 91 is used.

The outdoor side heat exchanger 92 is mounted on the secondary side flow path 90. The outdoor heat exchanger 92 is mounted to allow the refrigerant, which is a working fluid flowing therein, to exchange with the air flowing into the secondary side flow path, and is shaped into a substantially "∩" shape when viewed from above, and thus the secondary side flow path ( 90) along the inner side.

An outdoor fan 51 is mounted to the upper panel 50 forming the outer surface of the main body 10. The outdoor fan 51 is mounted on the upper side of the secondary side passage 90 and rotates to discharge the internal air of the secondary side passage 90 to the outside. In other words, in the latter half of the top panel 50, the top discharge port 52 is formed in the top panel 50 provided above the outdoor fan 51.

The top discharge port 52 is formed in a circular shape having a larger diameter than the outdoor fan 51, and guides the air flowing upward by the rotational movement of the outdoor fan 51 on the inner circumferential surface of the top discharge port 52. Orifice 53 is provided, the discharge grill 54 is mounted on the upper surface of the top discharge port (52).

However, the following problems occur in the duct type air conditioner according to the prior art configured as described above.

The air conditioner according to the prior art is installed in an underground space outside or inside a building to harmonize air in the indoor space guided by the suction duct (not shown), and then to the indoor space through the discharge duct (not shown). By discharging, the indoor space is cooled or heated.

In this prior art, the indoor space may be cooled or heated to properly maintain the temperature of the indoor space, but contaminants of the indoor space are not removed, resulting in a problem that the indoor space is not clean.

In addition, a problem arises in that a window or door is ventilated for ventilation in order to clean the indoor space, and when the window or door is ventilated, the load of cooling or heating is increased, thereby providing air conditioning. The problem arises that the cost of using the machine increases.

In addition, as the load of cooling or heating increases, a problem arises that the lifespan of the air conditioner is shortened.

Therefore, there is a problem that the use of energy increases according to the use of the air conditioner to increase the load, the service cost increases.

The control method of the external air filling apparatus according to the present invention for solving the above problems is to provide a control method of the external air filling apparatus to control the air in the internal space of the external air filling apparatus to flow efficiently.

The control method of the outdoor air induction apparatus according to the present invention for achieving the object as described above, the indoor air for detecting the physical properties of the indoor air by the indoor sensor mounted on one side of the case forming the appearance while forming an internal space A detection step, an outdoor air detection step of detecting physical properties of outdoor air by an outdoor sensor mounted on the other side of the case, a comparison step of comparing the physical properties of air detected from the outdoor sensor and the indoor sensor; Rotating rotation of the vane for selectively shielding the inner space of the case by a drive driven by the driving force generated by the driving step generated by the result of the comparison step and a link driven by the driving force generated through the drive step Characterized in that comprises a step.

The physical properties of the air sensed by the indoor sensor and the outdoor sensor are characterized in that carbon dioxide (CO ₂ ) or enthalpy.

When the enthalpy detected by the indoor sensor is higher than the enthalpy detected by the outdoor sensor, the external air is controlled to be sucked into the inner space of the case.

When the concentration of carbon dioxide detected by the indoor sensor is higher than the concentration of carbon dioxide detected by the outdoor sensor, the outside air is controlled to be sucked into the inner space of the case.

When the enthalpy detected by the indoor sensor is the same as the enthalpy detected by the outdoor sensor, the external air is controlled to be sucked into the case.

When the concentration of carbon dioxide detected by the indoor sensor is the same as the concentration of carbon dioxide detected by the outdoor sensor, the outside air is controlled to be sucked into the inside of the case.

The central link unit, the discharge link unit and the suction link unit is controlled to be operated by the user's operation.

According to the control method of the external air induction apparatus controlled in this way, it is possible to efficiently flow the external air, there is an advantage that the ease of use is maximized.

Recently, as buildings have become larger and living standards have increased, there has been a growing tendency to pursue a pleasant indoor environment.In order to reduce energy consumption, the airtightness of the enclosed indoor space is increased in the indoor space as the airtightness is increased. It has a direct impact on human health.

Therefore, when the air in the sealed indoor space is contaminated, ventilation with the outside air is required.

Hereinafter, a control method of an external air filling apparatus will be described with reference to the drawings.

Figure 3 is a perspective view showing the external appearance of the external air induction apparatus employing a preferred embodiment according to the present invention, referring to the external appearance of the external air induction apparatus with reference to Figure 3, the external air induction apparatus is a case forming an inner space The appearance is formed by 100.

The case 100 may be formed in a rectangular parallelepiped panel having a predetermined thickness and formed into a rectangular parallelepiped shape, or each panel is integrally formed to form a rectangular parallelepiped case 100.

The front center part and the rear center part of the case 100 formed in a rectangular parallelepiped shape are formed to be opened except for an edge. As such, the opened front surface of the case 100 becomes a front suction opening 120 which serves as a passage through which air in the indoor space for air conditioning enters the internal space of the case 100. The suction duct fastening part 122 to which the suction duct (not shown) for guiding air in the indoor space is protruded forward is formed at the edge of the front suction hole 120.

The right side surface of the case 100 is provided with a side discharge portion (200). The side discharge portion 200 is formed into a shape of an approximately rectangular parallelepiped having a predetermined width, and the left side and the right side are molded into a shape that is opened to have a predetermined area. The vertical length of the side discharge portion 200 is formed in a length corresponding to the vertical length of the right side of the case 100.

The side discharge part 200 formed in a shape in which the left side and the right side are opened to have a predetermined area has air conditioning sucked into the inner space of the case 100 through the front suction opening 120 of the case 100. It serves as a passage for discharging the air of the indoor space for the outer space.

A plurality of discharge guides 210 are mounted on the right side of the side discharge part 200 in the front and rear in the inner space of the side discharge part 200. The discharge guide 210 is molded into a rectangular plate shape having a predetermined thickness, and the left and right lengths are narrow and long in front and rear. The discharge guide 210 is mounted so that the front surface is in contact with the inner front surface of the side discharge portion 200, the rear surface is in contact with the inner rear surface.

The right side surface of the discharge guide 210 is mounted to be located on the same plane as the right side surface of the side discharge portion 200, and a plurality of the discharge guide 210 is mounted from the upper end portion to the bottom portion of the inner space of the right side discharge portion 200. The discharge guide 210 is mounted at an inclined angle with a predetermined angle such that the right side is positioned below the left side.

Therefore, the air discharged to the outer space through the side discharge portion 200 is discharged downward somewhat, the external dust and foreign matter is introduced into the inner space of the side discharge portion 200 by the discharge guide 210 Is prevented.

The discharge fan duct fastening part (not shown) is mounted on the right side edge of the side discharge part 200 so as to mount a discharge fan duct (not shown) having a separate discharge fan (not shown) for generating a discharge output by rotating. Is formed to protrude to the right side. The discharge fan duct fastening part (not shown) may be equipped with a side discharge duct (not shown) for guiding the discharged air to be discharged into a desired space instead of the discharge fan duct (not shown).

A side suction part 300 is provided spaced apart from the rear surface of the side discharge part 200 by a predetermined interval. The side suction part 300 is formed in a shape of a rectangular parallelepiped having a predetermined left and right width, and the left and right surfaces are formed in an opening shape to have a predetermined area. The vertical length of the side suction part 300 is formed in a length corresponding to the vertical length of the right side of the case 100.

The side suction part 300 formed in a shape in which the left side and the right side are opened to have a predetermined area plays a role of a passage through which external air flows into the inner space of the case 100.

A plurality of suction guides 310 are mounted in a space inside the right side of the side suction part 300. The suction guide 310 is molded into a rectangular plate shape having a predetermined thickness and having a narrow width in the left and right direction and a long length in the front and rear direction. The suction guide 310 is mounted such that the front surface is in contact with the inner front surface of the side suction port 300, and the rear surface is in contact with the inner rear surface of the side suction hole 300.

The suction guide 310 is mounted to have a downward slope at a predetermined angle toward the right side so that the left side is positioned above the right side. Therefore, dust and foreign matter in the external space are prevented from entering the internal space of the suction discharge part 300 by the suction guide 310 mounted at a predetermined angle.

Figure 4 is a schematic exploded perspective view showing the internal structure of the external air induction apparatus employing a preferred embodiment according to the present invention, referring to the internal configuration of the external air induction apparatus with reference to Figure 4, the case 100 In the central portion of the inner space of the case 100 is provided with a central vane 140 for selectively partitioning the inner space of the first half and the second half.

The central vane 140 is a central post 142 which is rotatably mounted on the inner upper surface and the inner lower surface of the central portion of the inner space of the case 100 and the central post 142 by the rotation of the central post 142. Rotating to the center of rotation is configured to include a central vane 144 to selectively partition the internal space of the case 100 into the first half and the second half.

The center post 142 is formed in a round bar shape having a predetermined diameter, the upper end is rotatably mounted on the inner upper surface of the case 100, the lower end is mounted to be rotatable on the bottom of the case 100. The center vane 144 is formed into a rectangular plate shape having a predetermined thickness, and is formed symmetrically with respect to the center post 142. That is, the central post 142 is positioned at the center of the central vane 144, and the central vane 144 is mounted around the central post 142.

The center vane 144 is formed on the right side of the center vane 144 and the center post 142 formed on the left side of the center post 142 by the rotation center of the center post 142 by the rotation of the center post 142. The center vane 144 to be molded is molded to rotate at the same time. In addition, it is formed so as to overlap a predetermined portion with the central vane 144 mounted on the adjacent central post 142 is formed so as to prevent the leakage of air when the internal space of the case 100 partitioned into the first half and the second half.

That is, the central vane unit 140 mounted to the center of the case 100 is composed of a plurality of central posts 142 and the central vanes 144, the left end of the central vane 144 is located on the leftmost Is mounted to contact the inner left side of the case 100, the right end is mounted to contact the left end of the central vane 144 is formed adjacent to a predetermined portion to prevent the leakage of air.

The left end of the center vane 144 is bent and molded to round forward with a predetermined curvature. When the left end of the center vane 144 is viewed from above, it is shaped into a substantially "∪" shape. The left side of the central vane 144 is formed in contact with the left inner surface of the case 100 to prevent the leakage of air.

The central vane 144, which is bent and shaped to be rounded forward with a predetermined curvature, extends to the right side in a rectangular plate shape having a predetermined thickness. The right end of the center vane 144 to be shaped into a square plate shape is bent and rounded to have a predetermined curvature in a direction opposite to the left end, that is, to the rear.

The central link part cover 160 is installed at the center of the upper surface of the case 100 to protect the central link part 420 that generates rotational power for rotating the central vane part 140. The central link part cover 160 is formed in a rectangular parallelepiped shape having an approximately lower surface thereof, and a predetermined space is formed therein.

The central link part cover 160 is formed in a shape in which a horizontal length thereof corresponds to a horizontal length of the case 100 and is formed to have a predetermined longitudinal length. In the inner space of the central link portion cover 160, a drive motor (not shown) that generates rotational power by an external power source applied thereto, and a link driving rotated by the rotational power of the drive motor (not shown). The driving force is generated by the rotation of the plate 410 and the link driving plate 410, and the center link unit 420 is installed to rotate the center post 142 of the center vane unit 140.

The drive motor (not shown) is equipped with a step motor capable of controlling the rotation angle of the motor shaft (not shown) to be rotated by the rotational power, and thus the rotation angle control of the drive motor is possible. It is fastened to enable the control of the rotation angle of the link drive plate 410 coupled to the rotation shaft.

The discharge link part cover 230 is provided on an upper surface of the side discharge part 200. The discharge link part cover 230 is formed in a shape of a rectangular parallelepiped having a lower surface having a predetermined horizontal length and a longitudinal length corresponding to the longitudinal length of the side discharge part 200.

The suction link part cover 340 is provided on an upper surface of the side suction part 300. The suction link part cover 340 has a predetermined horizontal length and has a front and rear direction length corresponding to the front and rear direction length of the side suction part 300, and the front and rear directions corresponding to the front and rear direction length of the side suction part 300. The lower surface is molded into the shape of an open rectangular parallelepiped so as to have a direction length.

5 is a schematic view showing a state in which a central portion of the inner space of the external air filling apparatus employing a preferred embodiment according to the present invention is shielded, and FIG. 6 shows an interior of the external air filling apparatus employing a preferred embodiment of the present invention. A schematic diagram is shown showing the open state of the central space.

Referring to FIGS. 5 and 6, the center vane unit 140, the discharge vane unit 240, and the suction vane unit 350 will be described in more detail. The center vane 144 is mounted, and the center post 142 is provided at the center of the center vane 144. Therefore, the center vane 144 is rotatable with the center post 142 as the rotation center.

The link driving plate 410 is provided above the center vane unit 140. The link driving plate 410 is formed into a triangular plate shape having a predetermined thickness, and the center post 142 is fastened to a vertex of the link driving plate 410 at a third position from the left side of the center vane 140. do.

The center driving link 421 is installed below the vertex of the link driving plate 410 to generate driving power by the rotation of the link driving plate 410. The central drive link 421 is formed in the shape of a long rectangular plate in the horizontal direction, both sides are formed to protrude round outward.

The central post 142 penetrates the center portion of the central driving link 421 in the vertical direction and is mounted at a vertex portion of the link driving plate 410. That is, the center portion of the center drive link 421 is located below the vertex portion of the link driving plate 410, and the center drive link 421 and the link driving plate 410 is the upper end of the central post 142 It penetrates from below and is fastened with nuts.

As such, the link driving plate 410 has a predetermined angle to rotate the center post 142 fastened through the link driving plate 410 and the central driving link 421 to rotate the driving motor (not shown). It is rotated by power.

The central drive link 421 is mounted to have a substantially "＼" shape so that the upper end is located to the left side than the lower end when viewed from the top, the central first link 422 for transmitting the driving force of the central drive link 421 The left end of) is fastened. The central first link 422 is formed in a shape of a square plate having a narrow width and long in the horizontal direction, and both sides are protruded outwardly to the outside.

The central first link 422 having the left end coupled to the center driving link 421 has the center post having the right end positioned at the rightmost side of the center vane 140 (see FIG. 5). 142) to the right. The right end of the central first link 422 located on the right side of the central post 142 is engaged with the right end of the central first auxiliary link 423 which rotates the central post 142 with the received driving force.

The left end of the central first auxiliary link 423, the right end of which is fastened to the right end of the central first link 422, is fastened to the center post 142. Accordingly, the center drive link 421 is rotated by the rotation of the link driving plate 410, and the center first link 422 is driven by the rotation of the center drive link 421. The central first auxiliary link 423 is rotated by the driving of the 422 to rotate the central post 142.

The other end of the central drive link 421 is fastened to the central second link 424 and the central third link 426. The central second link 424 is fastened toward the front toward the left side, and the central third link 426 is fastened to the left side to be horizontal with the central vane 140.

Therefore, the left end of the central second link 424 and the left end of the central third link 426 are positioned in opposite directions with respect to the center vane 140. That is, the left end of the central second link 424 is positioned forward with respect to the center vane unit 140, and the left end of the central third link 426 is rearward with respect to the center vane unit 140. Will be located.

As such, each central post 142 fastened to the central second link 424 and the central third link 426 by the central second link 424 and the central third link 426 positioned in opposite directions. ) Rotate in opposite directions.

The right end of the central second link 424 is fastened to the rear end of the central drive link 421 and is mounted to have a forward inclination toward the left side, and the left end of the central second link 424 is The left side of the center vane 140 is located in the left front of the center post 142 is located second.

The front end portion of the central second auxiliary link 425 which rotates the central post 142 by the driving force of the central second link 424 is fastened to the left end of the central second link 424. The rear end of the second auxiliary link 425 is fastened to the center post 142.

The right end of the center third link 426 is fastened to the rear end of the center drive link 421, and is formed long in the left direction so that the left end is located at the left end of the center vane portion 140 It is located at the left rear of the post 142. The rear end of the central third auxiliary link 427, which rotates the central post 142 by the driving force of the central third link 426, is fastened to the left end of the central third link 426, and the central third auxiliary link The front end of 427 is engaged with the central post 142 and is mounted in a substantially "＼" shape when viewed from above.

On the other hand, when looking at the discharge vane portion 240 provided in the interior of the side discharge portion 200, a plurality of discharge vanes (244) in the inner space of the side discharge portion 200 is shown in FIG. Is mounted. The discharge vane 244 is rotated in a direction opposite to the center vane 144. That is, when the center vane 144 opens the inner space of the case 100, the discharge vane 244 shields the inner space of the side discharge part 200, and the center vane 144 is the case 100. When the inner space of the shield is shielded, the discharge vane 244 opens the inner space of the side discharge portion (200).

The left end of the discharge driving link 431 which rotates the discharge vane 244 is fastened to the upper surface of the right end rear of the vertex of the link driving plate 410. The discharge driving link 431 has a predetermined thickness and is molded into a shape of a long rectangular plate in a horizontal direction, and both sides are protruded to be rounded outward.

The right end of the discharge drive link 431 is located above the discharge vane portion 240, and the discharge drive auxiliary to transfer the driving force of the discharge drive link 431 to the right end of the discharge drive link 431. The rear end of the link 432 is fastened. The front end of the discharge driving auxiliary link 432 is fastened to the upper end of the discharge post 242 which is the rotation center of the discharge vane 244 which is located at the rear of the discharge vane part 240.

A central portion of the discharge first link 433 that transmits the driving force of the discharge drive auxiliary link 432 is fastened to the lower side of the front end of the discharge drive auxiliary link 432. The discharge first link 433 is formed into a rectangular plate shape having a predetermined thickness, and the left and right side surfaces protrude round to the outside.

A discharge vane 244 positioned at the rear of the discharge vane part 240 is positioned below the discharge first link 433, and a discharge post 242 serving as a rotation center of the discharge vane 244 is provided. ) Is fastened while penetrating the central portion of the discharge first link 433 from below to the front end of the discharge driving auxiliary link 432.

The front end of the discharge first link 433 is coupled to the rear end of the discharge second link 434 and the discharge third link 436. The discharge second link 434 has a rear end coupled to the front end of the discharge first link 433, and the front end is discharged from the discharge vane 244 mounted to the center of the discharge vane 240. More forward.

The discharge second auxiliary link which rotates the discharge post 242 by receiving the driving force of the discharge first link 433 to the front end of the discharge second link 434 positioned on the front right side of the discharge post 242. A front end of the discharge 435 is fastened, and a rear end of the second discharge link 435 is fastened to an upper end of the discharge post 242.

The rear end of the discharge third link 436 is engaged with the front end of the discharge first link 433, and the front end of the discharge third link 436 is positioned in front of the discharge vane 240. The discharge post 242 is located on the front left side. A discharge third auxiliary link for transmitting the driving force of the discharge third link 436 to the front end of the discharge third link 436 positioned on the front left side of the discharge post 242 to rotate the discharge post 242. A front end of the discharge 347 is fastened, and a rear end of the discharge third auxiliary link 347 is fastened to an upper end of the discharge post 242.

Meanwhile, a left end of the suction driving link 441 for fastening the suction vane 350 mounted in the inner space of the side suction part 300 is fastened to the left rear lower surface of the vertex of the link driving plate 410. do. The suction drive link 441 is formed in a shape of a long rectangular plate in a horizontal direction while having a predetermined thickness, and the left and right sides protrude round to the outside.

The left end of the suction drive auxiliary link 442 that transfers the driving force of the suction drive link 441 is fastened to the right end of the suction drive link 441, and the lower end of the right end of the suction drive link 442 is The upper end of the suction post 352, which is the rotation center of the suction vane 354, which is positioned at the most front of the suction vane 350 formed in the inner space of the side suction unit 300, is fastened.

The central portion of the suction first link 443 which transfers the driving force of the suction driving auxiliary link 442 is positioned below the right end of the suction driving auxiliary link 442, and the upper end of the suction post 352 is the suction agent 1. The center portion of the link 443 penetrates from below, and the right end of the suction drive auxiliary link 442 penetrates from below.

The rear end of the first suction link 443 is positioned to the right rear of the discharge post 352, and the front end of the second suction link 444 and the third suction link 446 is located at the rear end of the first suction link 443. The part is fastened. The suction agent 2 link 444 has a rear end portion at a rear left side of the suction post 352 which is a rotation center of the suction vane 354 mounted to the inner space center of the side suction part 300. The rear end of the three links 446 is located at the right rear side of the suction post 352 mounted at the rear of the inner space of the side suction unit 300.

A rear end portion of the second suction link 445 that transmits the driving force of the second suction link 444 is fastened to a rear end of the suction second link 444 positioned to the left rear of the suction post 352. The front end of the second auxiliary link 445 is fastened to the upper end of the suction post 352.

A rear end portion of the third suction link 447 which transfers the driving force of the third suction link 446 is fastened to a rear end of the suction third link 446 positioned at the right rear side of the suction post 352. The front end of the third auxiliary link 447 is fastened to the upper end of the suction post 352.

Covers 160, 230, and 340 are provided on upper portions of the central link part 420, the discharge link part 440, and the suction link part 450, respectively. The central link part cover 160, the discharge link part cover 230, and the suction link part cover 340 protect the respective link parts and prevent foreign substances and dust from entering the respective link parts.

On the other hand, between the side discharge unit 200 and the side suction unit 300 is equipped with an outdoor sensor (S ₁ ) for detecting the concentration of enthalpy or carbon dioxide of the outdoor air, the front of the case 100 Indoor sensor (S ₂ ) for detecting the concentration of enthalpy or carbon dioxide is mounted.

In addition, the auxiliary control unit 220 is provided with an auxiliary microcomputer on the bottom of the inner space of the side discharge unit 200. The auxiliary control unit 220 transmits the concentration of enthalpy or carbon dioxide, which is a physical property of air detected by the outdoor sensor S ₁ and the indoor sensor S ₂ , to the main control unit.

That is, the auxiliary control unit 220 detects the temperature and humidity detected by the outdoor sensor (S ₁ ) and the indoor sensor (S ₂ ) to derive the enthalpy values of outdoor air and indoor air by the calculated value. The derived enthalpy value is transmitted to the main controller. In addition, the main control unit controls the air flow path of the case 100 by driving the link driving plate by the concentration of indoor and outdoor carbon dioxide and the enthalpy value.

The auxiliary control unit 220 is located on the bottom of the inner space of the side discharge unit 200 is located in the outdoor, easy to cool, the side discharge unit 200 is opened to discharge the air in the indoor space This is to facilitate the cooling by the discharged air.

FIG. 7 is a block diagram showing a system configuration for controlling an external air filling apparatus employing a preferred embodiment of the present invention. Referring to FIG. 7, the outdoor sensor S ₁ for detecting the enthalpy or carbon dioxide concentration of the outdoor air and the indoor sensor S ₂ for detecting the enthalpy or carbon dioxide concentration of the indoor air and the enthalpy value of the outdoor space and the indoor space are shown. The concentration of carbon dioxide is transmitted to the auxiliary control unit 220.

The auxiliary controller 220 transmits the carbon dioxide concentration or enthalpy value transmitted from the outdoor sensor S ₁ and the indoor sensor S ₂ to the main controller, and the main controller compares the received value with the link driver plate. The rotation range of 410 is controlled.

When the rotation range of the link driving plate 410 is controlled, the rotation of the central link unit 420, the discharge link unit 430, and the suction link unit 440 rotated by the rotation of the link driving plate 410. The angle is controlled to control the amount of air flow in the inner space of the case 100.

Hereinafter will be described the operation of the external air inlet device configured as described above.

8 is a flow chart showing the control flow of the outdoor air inlet apparatus using the indoor and outdoor enthalpy difference employing a preferred embodiment according to the present invention, Figure 9 is the difference in concentration of indoor and outdoor carbon dioxide employing a preferred embodiment according to the present invention A flow chart showing the control flow of the external air filling apparatus using the drawing is shown.

First, referring to FIG. 8, a control flow of an external air filling apparatus using a difference in enthalpy will be described.

The control flow of the outside air inlet device is to detect the physical properties of the indoor air in the indoor air detection step of detecting the physical properties of the indoor air by the indoor sensor (S ₂ ) mounted on one side of the case 100, The outdoor sensor S ₁ mounted on the other side of the case 100 detects the physical property of the outdoor air through the outdoor air detection step of detecting the physical property of the outdoor air.

The physical properties of the indoor air and the outdoor air detected through the indoor air detection step and the outdoor air detection step are compared with the physical properties of the indoor air and the outdoor air through a comparison step, and the driving force is determined by the result derived through the comparison step. The driving step is to generate a.

The vanes 144, 244, and 354 selectively shield the inner space of the case 100 by the rotation of the link driven by the driving force generated through the driving step.

Looking in more detail, when the external power is applied to the case 100, the indoor sensor (S ₂ ) detects the temperature and humidity of the air in the indoor space that is a space for air conditioning to the auxiliary control unit 220 Will be sent. The auxiliary control unit 220 receiving the temperature and humidity of the indoor air calculates an enthalpy value of the indoor air.

In addition, the outdoor sensor S ₁ senses the temperature and humidity of the outside air and transmits it to the auxiliary control unit 220. The auxiliary control unit 220 receiving the temperature and humidity of the outside air calculates an enthalpy value of the outside air.

The enthalpy value calculated by the auxiliary controller 220 is transmitted to the main controller, and the main controller compares the received enthalpy value of the outdoor space with the enthalpy value of the indoor space. That is, the rotation direction of the link driving plate 410 is controlled by comparing the enthalpy value of the indoor space with the enthalpy value of the outdoor space, and the rotation range of the link driving plate 410 is controlled.

When the enthalpy value of the indoor space is less than or equal to the enthalpy value of the outdoor space in the main controller, the link driving plate 410 is rotated to operate the central link unit 420.

When the center link unit 420 is operated, the center vane unit 140 is rotated, and the inner space of the case 100 is partitioned into the first half and the second half by the rotation of the center vane 140. . When the inner space of the case 100 is partitioned into the first half and the second half, the central flow path of the case 100 is shielded.

When the central channel of the case 100 is shielded, air of the indoor space sucked through the front suction opening 120 by the suction duct (not shown) may not be discharged to the rear of the case 100.

In addition, the discharge link unit 430 is operated by the rotation of the link driving plate 410. The discharge vane 240 rotates by the operation of the discharge link unit 430. When the discharge vane 240 rotates as described above, the inner space of the side discharge part 200 is opened.

When the inner space of the side discharge portion 200 is opened, the air in the indoor space sucked through the front suction opening 120 of the case 100 does not flow to the rear of the case 100 without the side discharge portion 200 ) Is discharged to the outdoor space or the external space.

In addition, the suction link unit 440 is operated by the rotation of the link driving plate 410. The suction vane unit 350 rotates by the operation of the suction link unit 440. As such, when the suction vane 350 rotates, the inner space of the side suction part 300 is opened.

When the inner space of the side suction part 300 is opened, air, that is, outdoor air, in the outer space is sucked into the inner space of the case 100 through the side suction part 300. The outdoor air sucked into the inner space of the case 100 through the side suction part 300 flows to the rear of the case 100 and is discharged to the outside of the case 100.

On the other hand, hereinafter, the outdoor sensor (S ₁ ) and the indoor sensor (S ₂ ) to look at the operation of the case 100, for example, to operate to detect the carbon dioxide concentration of the outdoor air and indoor air.

When external power is applied to the case 100 and the power is turned on, the indoor sensor S ₂ detects the concentration of carbon dioxide contained in the air of the indoor space, and the outdoor sensor S _1. ) Detects the concentration of carbon dioxide contained in the air in the outdoor space.

The concentration of carbon dioxide detected by the outdoor sensor S ₁ and the indoor sensor S ₂ is transmitted to the auxiliary controller 220, and the auxiliary controller 220 is an outdoor sensor S ₁ and an indoor sensor S _2. Compared to the concentration of carbon dioxide detected by). When the concentration of carbon dioxide is compared by the auxiliary controller 220, the compared result is transmitted to the main controller, and the main controller rotates the link driving plate 410 according to the compared result.

The main controller controls the rotation range of the link driving plate 410 according to the result of the concentration of carbon dioxide compared in the auxiliary controller 220. That is, when the result of comparing the concentration of carbon dioxide is transmitted from the auxiliary controller 220 to the main controller, the main controller controls the rotation range of the link driving plate 410 according to the comparison result to flow the internal space of the case 100. To control the amount of air flow.

When the comparison value compared in the auxiliary controller 220 is equal to or higher than the carbon dioxide concentration in the indoor space, the main controller rotates the link driving plate 410. The center link unit 420 is operated by the rotation of the link driving plate 410, and the center vane unit 140 is rotated by the operation of the center link unit 420.

When the central vane 140 is rotated, the inner space of the case 100 is divided into a first half and a second half. When the inner space of the case 100 is divided into the first half and the second half, the air of the indoor space guided by the suction duct (not shown) and sucked through the front suction hole 120 does not flow to the rear of the case 100. I can't.

In addition, the discharge link unit 430 is operated by the rotation of the link driving plate 410. The discharge vane 240 rotates by the operation of the discharge link unit 430. When the discharge vane unit 240 rotates, air in the indoor space sucked through the front suction hole 120 is discharged to the outdoor space through the side discharge unit 200.

In addition, the suction link unit 440 is operated by the rotation of the link driving plate 410. The suction vane 350 rotates by the operation of the suction link unit 440. When the suction vane 350 rotates, the inner space of the side suction part 300 is opened. When the internal space of the side suction unit 300 is opened, the air of the outdoor space flows into the internal space of the case 100 through the side suction unit 300, and the outdoor space flows into the internal space of the case 100. Air is flowed to the rear of the case (100).

Meanwhile, the rotation range of the link driving plate 410 is determined by the main controller according to the difference between the enthalpy of the indoor space and the outdoor space or the concentration of carbon dioxide detected by the outdoor sensor S ₁ and the indoor sensor S ₂ . By controlling the rotation range of the center vane 140, the discharge vane 240 and the suction vane 350 to control the direction of the air flowing in the case 100 and the amount of air It becomes possible.

The scope of the present invention is not limited to the above embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

For example, in the present invention, the side discharging part 200 and the side suction part 30 are provided on one side of the case 100, but it is also possible to be provided on both sides.

In the control method of the outdoor air induction apparatus according to the present invention configured as described above to compare the physical properties of the indoor air and outdoor air to selectively control the air flow direction of the inner space of the case.

By selectively controlling the air flow direction using physical properties of the indoor air and the outdoor air, efficient ventilation of the indoor space is possible.

As efficient ventilation of the indoor space is possible, there is an effect that the health of the user living in the closed indoor space is not deteriorated.

In addition, it is possible to effectively ventilate the indoor space, thereby improving the convenience of use.

In addition, as it becomes possible to control the amount of air flowing in the inner space of the case, there is an effect that can selectively control the amount of air flow, and the amount of air flow can be selectively controlled to the outside air There is also an effect of smoothing the internal air flow of the introduction device.

In addition, the user can directly operate the center link unit, the discharge link unit, and the suction link unit, so that it is possible to control the air flow direction according to the user's state, thereby maximizing the convenience of use.

Claims (7)

An indoor air detection step of detecting physical properties of the indoor air by an indoor sensor mounted on one side of a case forming an exterior while forming an internal space; An outdoor air detection step of detecting physical properties of the outdoor air by an outdoor sensor mounted on the other side of the case; A comparison step of comparing physical properties of air detected from the outdoor sensor and the indoor sensor; A driving step of generating a driving force by the result derived through the comparing step; And a rotating step of rotating the vane to selectively shield the inner space of the case by a link driven by a driving force generated through the driving step. The method of claim 1, wherein the physical properties of the air sensed by the indoor sensor and the outdoor sensor are carbon dioxide (CO ₂ ) or enthalpy. According to claim 1 or claim 2, If the enthalpy detected by the indoor sensor is higher than the enthalpy detected by the outdoor sensor Control of the external air inlet device, characterized in that for controlling the outside air to be sucked into the inner space of the case. Way. According to claim 1 or 2, wherein if the concentration of carbon dioxide detected by the indoor sensor is higher than the concentration of carbon dioxide detected by the outdoor sensor, the outside air is controlled to be sucked into the inner space of the case Control method of introduction device. The method of claim 3, wherein when the enthalpy detected by the indoor sensor is the same as the enthalpy detected by the outdoor sensor, the outside air is controlled to be sucked into the inside of the case. The outdoor air induction apparatus of claim 4, wherein when the concentration of carbon dioxide detected by the indoor sensor is the same as the concentration of carbon dioxide detected by the outdoor sensor, external air is sucked into the case. Control method. The method of claim 1, wherein the driving step is controlled to be operated by a user's operation.

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