KR101662672B1 - Air conditioning system with the wind power generator of self adaptative type having the self generatoing - Google Patents

Abstract

The present invention relates to an air conditioning system with an autonomous adaptive wind power generation means having an autonomous power generation function which is installed on a duct of an air conditioning system and uses a fluid moved according to an operation of the air conditioning system to produce electric energy to be used as a power source of a sensing unit which senses an operational state of the air conditioning system. The air conditioning system with an autonomous adaptive wind power generation means having an autonomous power generation function comprises: a duct in which a fluid is moved in an air conditioning system; a wind power generation means to use the fluid moved in the duct to produce electric energy; and a sensing unit to receive power by the electric energy produced by the wind power generation means to sense an operational state of the air conditioning system.

Description

TECHNICAL FIELD [0001] The present invention relates to an air conditioning system equipped with an autonomous adaptive wind turbine generator having a self-generating function,

The present invention relates to an air conditioning system equipped with an autonomous adaptive wind power generator having a self-generating function, and more particularly, to an air conditioning system using a fluid that is installed in a duct of an air- To an air conditioning system equipped with an autonomous adaptive wind power generation means having a self generating function which can be utilized as a power source of a sensing unit for sensing the operation state of the air conditioning system.

Generally, in recent buildings, the number of windows that can be opened and closed is reduced in order to increase the cooling and heating efficiency. Accordingly, a separate air conditioning system can be installed for air conditioning of the room. In addition, an air conditioning system for quickly discharging polluted air can be installed in an underground building where external air is difficult to enter.

The air conditioning system can keep the indoor air pleasant by discharging the air in the contaminated room through the duct to the outside or supplying fresh air outdoors to the room.

In order to control the operation of the air conditioning system, a duct is provided with a sensing unit for sensing the operation state of the air conditioning system such as the flow rate of the fluid, the temperature of the fluid, and the humidity of the fluid.

However, the conventional air conditioning system requires separate control logic for operating the sensing unit depending on whether the air conditioning system is operating or not. Further, since the sensing unit must receive power from the main power source, the electric wire for applying power may be long, and electric power leakage may occur at a long electric wire. Further, when power is supplied to the sensing unit through the battery, there is a limitation in the power source of the battery, so that it is difficult to maintain the sensing operation of the sensing unit, frequent replacement of the battery, and maintenance becomes difficult.

Korean Patent Laid-Open Publication No. 2009-0120195 (entitled "Air-conditioning system equipped with wind power generation means, disclosed on November 24, 2009)

An object of the present invention is to solve the conventional problems, and it is an object of the present invention to provide a sensing unit which is installed in a duct of an air conditioning system and generates electric energy by using a fluid that moves according to the operation of the air conditioning system, And an autonomous adaptive wind power generator having a self-generating function that can be utilized as a power source of the autonomous wind turbine.

According to a preferred embodiment of the present invention, an air conditioning system including an autonomous adaptive wind power generator having a self-generating function according to the present invention includes a duct in which a fluid is moved in an air conditioning system; A wind turbine generator for generating electric energy by using a fluid to be moved in the duct; And a sensing unit that is powered by electric energy generated by the wind power generation unit and senses an operation state of the air conditioning system.

At this time, the wind turbine generator includes a plurality of blades mounted in the duct and rotated by the movement of the fluid; A connection axis in which a plurality of the blades are arranged in a rotating direction and a rotating force is generated by the blades; A drive shaft connected to the connection shaft and transmitting a rotational force of the connection shaft; A generator shaft connected to the drive shaft and transmitting a rotational force of the drive shaft; A power generation unit connected to the power generation shaft in a state of being enclosed or embedded in the duct and converting the rotational force of the power generation shaft into electric energy; A storage battery for storing electric energy converted by the power generation unit to apply power to the sensing unit; And a direction switching unit provided in the duct for pivoting the drive shaft with respect to the power generation shaft according to a flow rate of the duct.

The wind power generation means and the sensing unit are integrally provided.

Here, the connection axis is substantially parallel to the moving direction of the fluid or perpendicular to the moving direction of the fluid.

Here, the wind turbine generator further includes an angle-of-attack adjusting unit that connects the blade and the connecting shaft to each other and adjusts the angle of attack of the blade.

The wind turbine generator further includes an angle of attack control unit for controlling the operation of the angle-of-attack angle adjusting unit according to the opening and closing degree of the adjusting damper unit installed in the duct to adjust the flow rate of the fluid.

An air conditioning system equipped with an autonomous adaptive wind power generator having a self-generating function according to the present invention is a duct in which a fluid moves in an air conditioning system. A wind turbine generator for generating electric energy by using a fluid to be moved in the duct; And a sensing unit for sensing an operation state of the air conditioning system, the power being applied by electric energy generated by the wind power generation means, wherein the wind power generation means is built in the duct, A plurality of blades rotated; A connection axis in which a plurality of the blades are arranged in a rotating direction and a rotating force is generated by the blades; A drive shaft connected to the connection shaft and transmitting a rotational force of the connection shaft; A generator shaft connected to the drive shaft and transmitting a rotational force of the drive shaft; A power generation unit connected to the power generation shaft in a state of being enclosed or embedded in the duct and converting the rotational force of the power generation shaft into electric energy; A storage battery for storing electric energy converted by the power generation unit to apply power to the sensing unit; An angle of attack control unit for interconnecting the blade and the connection shaft and adjusting an angle of attack of the blade; And an angle of attack control unit for controlling the operation of the angle-of-attack angle adjusting unit according to the opening and closing degree of the adjusting damper unit installed in the duct to adjust the flow rate of the fluid.

Here, the wind power generation means includes a thermoelectric element connected to the accumulator in a state where it is installed in a hot water pipe disposed at one side of the duct, and converting the heat of the hot water pipe into electric energy; And a vibration element connected to the accumulator in a state where it is installed on the drive shaft or the generator shaft, the vibration element converting the vibration generated in the drive shaft or the generator shaft into electric energy; As shown in FIG.

According to the air conditioning system provided with the autonomous adaptive wind power generation means having the self-generating function according to the present invention, electric energy is generated by using the fluid that is installed in the duct of the air conditioning system and is moved according to the operation of the air conditioning system, It can be utilized as a power source of a sensing unit for sensing the operation state of the system.

Further, according to the present invention, the flow rate can be adjusted by the position of the blades embedded in the duct or the angle of attack of the blades, and the damper for controlling the flow rate can be reduced.

Further, according to the present invention, it is possible to change the arrangement position of the blades toward the side having a larger flow rate or the flow rate smaller depending on the change of the flow rate at the branch portion of the duct, and the power generation efficiency can be controlled or the power generation efficiency can be kept constant.

In addition, the present invention smoothes the pivoting motion of the drive shaft relative to the generator shaft, and the rotational force of the drive shaft can be transmitted stably to the generator shaft.

In addition, the present invention simplifies installation of an air conditioning system in a duct through integration of components, improves compatibility with a conventional sensing unit, and improves duct construction efficiency.

Further, the present invention stabilizes the transmission of rotational force between the connection shaft and the drive shaft, and can stably cope with the shape of the blade.

Further, by adjusting the angle of attack of the blades, the present invention can improve the power generation efficiency by the fluid moving in the duct.

Further, by adjusting the angle of attack of the blades, the flow rate can be adjusted in the duct, and the installation of the adjustment damper unit installed in the duct can be reduced, thereby improving the construction efficiency.

In addition, the present invention can adjust the angle of attack through connection with the control damper unit, adjust the power generation efficiency in response to the flow rate in the duct, or maintain the power generation efficiency constant.

In addition, the present invention utilizes the vibration of the hot water piping installed in the periphery of the duct or the vibration generated in the air conditioning system, thereby regenerating energy dissipated into the outside air, and can be utilized as an auxiliary power source for the sensing module.

In addition, according to the present invention, the sensing unit can be operated without any separate control logic depending on whether the air conditioning system is operating or not. In addition, it is possible to shorten the length of the electric wire for supplying the power of the sensing unit, and to prevent power leakage according to the length of the electric wire. In addition, stable power can be supplied to the sensing unit, and the operation of the sensing unit can be maintained.

Further, the present invention can easily determine whether or not the sensing unit malfunctions, and can simplify the maintenance of the sensing unit and the air conditioning system.

FIG. 1 is a layout diagram schematically showing an air conditioning system equipped with an autonomous adaptive wind power generator having a self-generating function according to a first embodiment of the present invention.
FIG. 2 is a configuration diagram showing a coupling state of a direction switching unit in an air conditioning system equipped with an autonomous adaptive wind power generating unit having a self-generating function according to the first embodiment of the present invention.
3 is a configuration diagram illustrating an operation state of a direction switching unit in an air conditioning system provided with an autonomous adaptive wind power generator having a self-generating function according to the first embodiment of the present invention.
FIG. 4 is an exploded view showing a coupling state of a modification of the direction switching unit in an air conditioning system provided with an autonomous adaptive wind power generator having a self-generating function according to the first embodiment of the present invention.
FIG. 5 is a layout diagram schematically showing an air conditioning system equipped with an autonomous adaptive wind power generator having a self-generating function according to a second embodiment of the present invention.
FIG. 6 is a layout diagram schematically showing an air conditioning system equipped with an autonomous adaptive wind power generator having a self-generating function according to a third embodiment of the present invention.

Hereinafter, an embodiment of an air conditioning system including an autonomous adaptive wind power generator having a self-generating function according to the present invention will be described with reference to the accompanying drawings. Further, in describing the present invention, a detailed description of well-known functions or constructions may be omitted for clarity of the present invention.

FIG. 1 is a layout diagram schematically showing an air conditioning system equipped with an autonomous adaptive wind power generating means having a self generating function according to a first embodiment of the present invention. FIG. 3 is a schematic view showing a configuration of an autonomous adaptive wind power generation system having an autonomous adaptation type wind power generation system according to a first embodiment of the present invention. FIG. 4 is a diagram showing the operation state of the direction switching unit in the air conditioning system provided with the self-adaptive wind power generating means having the self-generating function according to the first embodiment of the present invention. Fig. 6 is a main part exploded view showing a coupling state for a modification example of the switching unit. Fig.

1 to 4, an air conditioning system including an autonomous adaptive wind power generator having a self-generating function according to a first embodiment of the present invention includes a duct 100, a wind power generator, a sensing unit 10 ).

The air conditioning system including the autonomous adaptive wind power generator having the self-generating function according to the first embodiment of the present invention is installed in the duct 100 of the air conditioning system and is moved in the duct 100 according to the operation of the air conditioning system The fluid can be used to produce electrical energy. The electric energy thus generated can be utilized as a power source of the sensing unit 10 for sensing the operation state of the air conditioning system.

The duct (100) moves the fluid in the air conditioning system.

An air conditioning system having an autonomous adaptive wind power generator having a self-generating function according to the first embodiment of the present invention is applied to a duct 100 having a plurality of inlets 110 and a plurality of outlets 120 Explain.

The air conditioning system including the autonomous adaptive wind power generator having the self-generating function according to the first embodiment of the present invention can be applied to the duct 100 having the plurality of outlets 120 and the single inlet 110 have.

The wind turbine generator generates electric energy by using the fluid moving in the duct 100. The wind power generation means includes a blade 1, a connection shaft 2, a drive shaft 3, a power generation shaft 4, a power generation unit 5, a storage battery 6, and a direction switching unit 20 .

The blade (1) is embedded in a duct (100) through which fluid is moved in the air conditioning system. The blade (1) is rotated about the connecting shaft (2) by the movement of the fluid.

The blade 1 may be composed of a horizontal blade. Here, the horizontal blade means that the connecting shaft 2 is disposed substantially parallel to the moving direction of the fluid.

The connecting shaft (2) has a plurality of blades (1) arranged in the rotating direction. The connecting shaft 2 is rotated by the blade 1.

Here, the blade 1 may be composed of a horizontal blade in which the connecting shaft 2 is disposed substantially parallel to the moving direction of the fluid. Also, as in the third embodiment, the blade 1 may be composed of a vertical blade in which the connecting shaft 2 is disposed substantially perpendicular to the moving direction of the fluid.

The drive shaft (3) is connected to the connection shaft (2). The driving shaft (3) transmits the rotational force of the connecting shaft (2). The driving shaft 3 can be connected to the connecting shaft 2 via the shaft coupling member 8. In the first embodiment of the present invention, the drive shaft 3 is vertically connected to the connection shaft 2 via the shaft coupling member 8. The shaft coupling member 8 is constituted by mechanical coupling such as coupling of gears, coupling of belt and pulley, coupling of chain and sprocket.

The power generating shaft 4 is connected to the drive shaft 3. The power generation shaft 4 transmits the rotational force of the drive shaft 3. The power generation shaft 4 can be connected to the drive shaft 3 via the direction switching unit 20. [

The power generation unit 5 is connected to the power generation shaft 4 in a state where it is enclosed or embedded in the duct 100. The power generation unit 5 converts the rotational force of the power generation shaft 4 into electric energy.

The battery (6) stores the converted electric energy in the power generation unit (5). The battery (6) applies power to the sensing unit (10).

The direction switching unit 20 is provided in the duct 100. The direction switching unit 20 pivots the drive shaft 3 with respect to the power generation shaft 4 according to the flow rate of the duct 100.

For example, the redirecting unit 20 may be composed of a bevel gear assembly and a redirecting unit 23. Then, the direction switching unit 20 includes a first bevel gear portion 21, a second bevel gear portion 22, a clutch portion 24, and a direction switching portion 23.

The first bevel gear portion 21 is coupled to the drive shaft 3. The first bevel gear portion 21 is provided with a first tight contact portion 211 on a surface thereof perpendicular to the drive shaft 3. The second bevel gear portion 22 is coupled to the power generating shaft 4. The second bevel gear portion 22 is provided with a second tight contact portion 221 on a surface perpendicular to the power generating shaft 4. The clutch portion 24 relatively moves the first bevel gear portion 21 with respect to the second bevel gear portion 22 so that the first contact portion 211 and the second contact portion 221 are closely contacted with or spaced from each other.

The direction switching unit 23 rotates the first bevel gear unit 21 with respect to the second bevel gear unit 22 so that the first contact unit 211 and the second contact unit 221 face each other. The direction switching unit 23 includes a switching guide 231 provided in the duct 100 and a first bevel gear unit 21 A switching slider 232 slidably coupled to the switching guide 231 in a state where the driving shaft 3 is coupled to the switching slider 232 and a switching driver 233 for moving the switching slider 232. Here, the switching driver 233 can move the switching slider 232 by the external power source or the power source of the storage battery 6.

As another example, the redirecting unit 20 may comprise a universal joint and a redirecting unit 23. Then, the direction switching unit 20 may include a first yoke portion 31, a second yoke portion 32, a cross bearing portion 33, and a direction switching portion 23.

The first yoke 31 is coupled to the drive shaft 3 and the second yoke 32 is coupled to the generator shaft 4. The criss-cross bearing portion 33 is rotatably coupled to the first yoke portion 31 and the second yoke portion 32 so that the drive shaft 3 is pivotally coupled to the power generation shaft 4.

The direction switching unit 23 rotates the drive shaft 3 with respect to the power generation shaft 4. The direction switching unit 23 is provided with a switching guide 231 provided on the duct 100 in a arc shape to form a moving path of the driving shaft 3, And a switching driver 233 for moving the switching slider 232. The switching slider 232 may be a combination of the switching slider 232 and the switching slider 232, Here, the switching driver 233 can move the switching slider 232 by the external power source or the power source of the storage battery 6.

Another example of the direction switching unit 20 may further include a yoke connecting portion 35. [ The yoke connecting portion 35 includes at least one yoke portion 34, and a cross bearing portion 33 is added. The yoke portion 34 includes a connecting shaft 341, a third yoke portion 342 coupled to one side of the connecting shaft 341 and a fourth yoke portion 343 coupled to the other side of the connecting shaft 341 do. At this time, the connecting shaft 341 may be configured as a stretch joint member.

The cross bearing portion 33 connects the first yoke portion 31 and the third yoke portion 342 as well as the second yoke portion 32 and the fourth yoke portion 343. When the yoke portion 34 is composed of a plurality of yoke portions 34, the cross bearing portion 33 can connect the adjacent two yoke portions 34.

The sensing unit 10 senses the operation state of the air conditioning system by applying electric power by the electric energy produced by the wind power generation means. In other words, the sensing unit 10 senses the operating state of the air conditioning system by a power source applied from the battery 6. [

The sensing unit 10 may include a state sensing unit 11, a sensor support unit 12, and a wireless communication unit 13.

The state sensing unit 11 is a sensor for sensing the operation state of the air conditioning system. The state sensing unit 11 is built in the duct 100 and can sense the operation state of the air conditioning system such as the flow rate of the fluid, the temperature of the fluid, and the humidity of the fluid. The state sensing unit 11 may be exposed to the outside of the duct 100 to sense the operation state of the air conditioning system such as the temperature, humidity, and the like around the duct 100.

The sensor support 12 fixes the state sensing unit 11 to the duct 100. The sensor supporting part 12 protects the state sensing part 11 and can fix the position of the state sensing part 11. [

The wireless communication unit 13 wirelessly transmits a signal sensed by the state sensing unit 11.

Then, the sensing unit 10 senses the operation state of the air conditioning system with the power supplied through the storage battery 6, and can transmit the sensing signal in a wireless manner.

At this time, the wind power generation means and the sensing unit 10 may be integrally provided. In other words, the power generation unit 5, the storage battery 6, and the sensing unit 10 may be integrally provided. The power generation unit 5, the storage battery 6, and the sensing unit 10 may be integrally provided on the outside of the duct 100. Here, the power generation unit 5 may be embedded in the duct 100. [ Further, the power generation unit 5 and the battery 6 can be embedded in the duct 100. [ In addition, the sensing unit 10 may be embedded in the duct 100.

Although not shown, the power generation unit 5 and the battery 6 are integrally provided, and the sensing unit 10 can be separated from the battery 6 and connected by electric wires.

In addition, the power generation unit 5, the storage battery 6, and the sensing unit 10 may be integrally provided in the duct 100 through various forms.

The direction switching unit 20 pivots the drive shaft 3 according to the flow rate of the fluid flowing from the inlet 110 to the outlet 120 of the duct 100 to change the longitudinal direction of the connection shaft 2 have.

Hereinafter, an air conditioning system equipped with an autonomous adaptive wind power generator having a self generating function according to a second embodiment of the present invention will be described. In the air conditioning system equipped with the autonomous adaptive wind power generating means having the self generating function according to the second embodiment of the present invention, the air conditioning system having the autonomous adaptive wind power generating means having the self generating function according to the first embodiment of the present invention The same reference numerals are assigned to the same components as those of the system, and a description thereof may be omitted.

FIG. 5 is a layout diagram schematically showing an air conditioning system equipped with an autonomous adaptive wind power generator having a self-generating function according to a second embodiment of the present invention.

5, an air conditioning system including an autonomous adaptive wind power generator having a self-generating function according to a second embodiment of the present invention includes a duct 100, a wind power generator, and a sensing unit 10 do.

An air conditioning system including an autonomous adaptive wind power generator having a self-generating function according to a second embodiment of the present invention includes a duct 100 having one inlet 110 and one outlet 120, Is applied. Here, the horizontal blade means that the connecting shaft 2 is disposed substantially parallel to the moving direction of the fluid. The power generation unit 5 is incorporated in the duct 100 and the storage battery 6 and the sensing unit 10 are integrally formed on the outside of the duct 100. The wind power generation means and the sensing unit 10 are integrally formed, As shown in FIG.

However, the wind turbine generator generates electric energy by using the fluid moving in the duct 100. The wind power generating means is constituted by the blade 1, the connecting shaft 2, the drive shaft 3, the power generating shaft 4, the power generating unit 5, the battery 6, And a control unit (7).

The angle of attack adjusting unit 7 interconnects the blade 1 and the connecting shaft 2. The angle of attack adjusting unit 7 adjusts the angle of attack of the blade 1. The angle of attack control unit 7 can control the flow rate of the fluid. At this time, the angle of attack control unit 7 can adjust the angle of attack of the blade 1 according to the opening / closing degree of the control damper unit 40 installed in the duct 100.

At this time, the adjustment damper unit 40 is installed in the duct 100, and the flow rate of the fluid can be adjusted by adjusting the opening / closing degree.

The wind power generation means may further include an angle of attack control unit (50).

The angle of attack control unit 50 controls the operation of the angle of attack control unit 7 according to the degree of opening and closing of the control damper unit 40. The angle of attack control unit 50 can connect the control damper unit 40 and the angle-of-attack control unit 7 through mechanical coupling such as engagement of gears, engagement of the belt and pulleys, engagement of chain and sprocket, and the like.

The wind power generation means may further include a thermoelectric element (60).

The thermoelectric element 60 is connected to the battery 6 in a state where the thermoelectric element 60 is installed in a hot water pipe 200 disposed on one side of the duct 100. The thermoelectric element 60 converts heat generated in the hot water pipe 200 into electric energy. Then, the electric energy converted by the heat is stored in the storage battery 6, and can be used as an auxiliary power source for the sensing unit 10.

The wind power generation means may further include a vibration element (70).

The vibration element 70 is connected to the storage battery 6 in a state where it is installed on the drive shaft 3 or the power generation shaft 4. The vibration element 70 converts the vibration generated in the drive shaft 3 or the power generation shaft 4 into electric energy in accordance with the movement of the fluid. Then, the electric energy converted by the vibration is stored in the storage battery 6, and can be utilized as an auxiliary power source for the sensing unit 10. [

In the air conditioning system provided with the autonomous adaptive wind power generator having the self-generating function according to the modification of the second embodiment of the present invention, the wind power generator includes the duct 100, the blade 1, (2), the drive shaft (3), the power generating shaft (4), the power generating unit (5), the battery (6), the angle of attack control unit (7) ).

Hereinafter, an air conditioning system equipped with an autonomous adaptive wind power generator having a self-generating function according to a third embodiment of the present invention will be described. In an air conditioning system provided with an autonomous adaptive wind power generating means having a self generating function according to a third embodiment of the present invention, an autonomous adaptive wind power generating system having a self generating function according to the first or second embodiment of the present invention The same reference numerals are assigned to the same components as those of the air conditioning system provided with the means, and the description thereof can be omitted.

FIG. 6 is a layout diagram schematically showing an air conditioning system equipped with an autonomous adaptive wind power generator having a self-generating function according to a third embodiment of the present invention.

Referring to FIG. 6, an air conditioning system including an autonomous adaptive wind power generator having a self-generating function according to a third embodiment of the present invention includes a duct 100, a wind power generator, and a sensing unit 10 do.

The air conditioning system including the autonomous adaptive wind power generator having the self-generating function according to the third embodiment of the present invention is applied to a vertical blade in a duct having one inlet 110 and one outlet 120 . As the vertical blade is applied, the connection shaft 2 and the drive shaft 3 are made substantially concentric. Here, the vertical blade means that the connecting shaft 2 is disposed substantially perpendicular to the moving direction of the fluid. Further, the wind power generating means and the sensing unit 10 may be integrally formed on the outside of the duct 100.

In the air conditioning system including the autonomous adaptive wind power generation unit having the self-generating function according to the third embodiment of the present invention, the wind power generation unit further includes the intake angle control unit 7, As shown in FIG.

In the air conditioning system provided with the autonomous adaptive wind power generating means having the self generating function according to the third embodiment of the present invention, the wind power generating means may further include at least one of the thermoelectric element 60 and the vibrating element 70 .

According to the air conditioning system provided with the autonomous adaptive wind power generating means having the self-generating function described above, the electric energy is generated by using the fluid which is installed in the duct 100 of the air conditioning system and is moved according to the operation of the air conditioning system, It can be utilized as a power source of the sensing unit 10 for sensing the operation state of the air conditioning system.

In addition, the flow rate can be adjusted by the position of the blades 1 installed in the duct 100 or the angle of the blades 1, and the damper for controlling the flow rate can be reduced.

In addition, the arrangement position of the blades 1 can be changed to a side having a larger flow rate or a smaller flow rate depending on a change in the flow rate at a portion where the duct 100 is branched, and the power generation efficiency can be controlled or the power generation efficiency can be kept constant .

Also, the pivotal movement of the drive shaft 3 can be smoothly performed on the basis of the generator shaft 4, and the rotational force of the drive shaft 3 can be transmitted to the generator shaft 4 in a stable manner.

Also, by integrating the components, it is possible to simplify the installation of the air conditioning system in the duct 100, to improve the compatibility with the conventional sensing unit 10, and to increase the duct construction efficiency.

In addition, the transmission of the rotational force between the connecting shaft 2 and the drive shaft 3 can be stabilized, and the shape of the blade 1 can be stably coped with.

Further, by adjusting the angle of attack of the blade 1, it is possible to improve the power generation efficiency by the fluid moving in the duct 100.

Further, by adjusting the angle of attack of the blade 1, the flow rate can be adjusted in the duct 100, and the installation of the adjustment damper unit 40 installed in the duct 100 can be reduced, thereby improving the construction efficiency.

In addition, the angle of attack can be adjusted through cooperation with the control damper unit 40, and the power generation efficiency can be controlled in accordance with the flow rate in the duct 100 or the power generation efficiency can be maintained constant.

Further, by utilizing the vibration of the hot water piping 200 installed in the periphery of the duct 100 or the vibration generated in the air conditioning system, it is possible to regenerate the energy dissipated into the outside air, and as the auxiliary power source of the sensing unit 10 Can be utilized.

Also, depending on whether the air conditioning system is operating, the sensing unit 10 can be operated without any separate control logic. Further, the length of the electric wire for supplying power to the sensing unit 10 can be shortened, and power leakage due to the length of the electric wire can be prevented. Further, stable power can be supplied to the sensing unit 10, and the operation of the sensing unit 10 can be maintained.

It is also possible to easily determine whether the sensing unit 10 is malfunctioning, and to simplify the maintenance of the sensing unit 10 and the air conditioning system.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Modify or modify the Software.

1: blade 2: connecting shaft 3: drive shaft
4: generator shaft 5: power generator unit 6: storage battery
7: angle of attack control unit 8: shaft coupling member 10: sensing unit
11: state detecting unit 12: sensor supporting unit 13: wireless communication unit
20: direction switching unit 21: first bevel gear unit 211: first tightening unit
22: second bevel gear portion 221: second tightly coupled portion 23: direction changing portion
231: switching guide 232: switching slider 233: switching driver
24: clutch portion 31: first yoke portion 32: second yoke portion
33: Cross bearing part 34: Yoke part 341: Connection shaft
342: third yoke portion 343: fourth yoke portion 40: regulating damper unit
50: angle of attack control unit 60: thermoelectric element 70:
100: duct 110: inlet 120: outlet
200: Hot water piping

Claims (7)

A duct in which fluid is moved in an air conditioning system;
A wind turbine generator for generating electric energy by using a fluid to be moved in the duct; And
And a sensing unit for sensing an operating state of the air conditioning system, the power being applied by electric energy generated by the wind power generating means,
The wind turbine generator
A plurality of blades embedded in the duct and rotated by movement of the fluid;
A connection axis in which a plurality of the blades are arranged in a rotating direction and a rotating force is generated by the blades;
A drive shaft connected to the connection shaft and transmitting a rotational force of the connection shaft;
A generator shaft connected to the drive shaft and transmitting a rotational force of the drive shaft;
A power generation unit connected to the power generation shaft in a state of being enclosed or embedded in the duct and converting the rotational force of the power generation shaft into electric energy;
A storage battery for storing electric energy converted by the power generation unit to apply power to the sensing unit; And
And a direction switching unit provided in the duct for pivotally moving the drive shaft with respect to the power generation shaft in accordance with a flow rate of the duct. 2. The air conditioning system according to claim 1, wherein the self- . The method according to claim 1,
Wherein the wind power generating means and the sensing unit are integrally provided. 2. The air conditioning system according to claim 1, wherein the self-adjusting wind power generating means has a self-generating function. The method according to claim 1,
Wherein the connection shaft is substantially parallel to the direction of movement of the fluid or perpendicular to the direction of movement of the fluid. The method according to claim 1,
The wind turbine generator
And an angle of attack control unit for interconnecting the blade and the connection shaft and adjusting an angle of attack of the blade. 5. The method of claim 4,
The wind turbine generator
And an angle of attack control unit for controlling the operation of the angle-of-attack angle control unit according to the degree of opening and closing of the adjustment damper unit installed in the duct to adjust the flow rate of the fluid. Air conditioning system equipped with means. delete 6. The method according to any one of claims 1 to 5,
The wind turbine generator
A thermoelectric element connected to the accumulator in a state where it is installed in a hot water pipe disposed at one side of the duct and converting the heat of the hot water pipe into electric energy; And
A vibration element connected to the drive shaft or the power generation shaft and connected to the battery, for converting vibration generated in the drive shaft or the power generation shaft into electric energy; Wherein the self-adaptive wind power generator has a self-generating function.

Images