KR101526136B1 - Energy regeneration type reversible fan ventilator and ventilation system and comprising the same - Google Patents

Abstract

An energy recovery type reversible fan ventilator is disclosed. Wherein the energy recovery type reversible fan ventilator comprises: a ventilating unit (10) located indoors when installed; And a heat recovery duct unit (30) connected to the ventilation unit (10) and extending to the outside through a building wall, wherein the ventilation unit (10) has a ventilation grille (112) A reversible EC fan 120 installed in the housing 110 and capable of blowing in both forward and reverse directions by normal and bidirectional rotation driving, a reversible EC fan 120 installed in the housing 110, And an air shutter 130 installed between the reversible EC fan 120 and the ventilating grill 112 to selectively block the inflow and outflow of air. The heat recovery duct unit 30 includes an inner duct 31a, A length variable air duct 31 including an outer duct 31b slidably fitted on an outer circumferential surface of the duct 31a and whose length is adjusted according to the thickness of the building wall; Serra with air holes in the lattice structure A viscous heat insulating material (not shown) which is formed so as to surround the outer circumferential surface of the ceramic heat accumulator 32 and exists in a compressed state between the length variable duct 31 and the ceramic heat accumulator 32 33).

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an energy recovery type reversible fan ventilator and a ventilation system including the same.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an energy recovery type reversible fan ventilator, and more particularly, to an energy recovery type reversible fan ventilator which can be installed in an individual room and used for individual room ventilation while recovering energy, It is possible to ventilate indoors including a plurality of individual rooms in cooperation with the fan ventilation device and to prevent condensation that may be caused due to a temperature difference despite being installed so as to pass through the outer wall to connect indoor and outdoor with a large temperature difference The present invention relates to an energy recovery type reversible fan ventilator which can easily be deformed easily to various wall thicknesses and can minimize the loss of room heat energy by using a ceramic heater installed in a warm state.

Every building has at least two air pollutants. One of the pollutants is the building material used to build the building, and the other pollutant originates from the activity of the person or person. A wide variety of suspended particulates and microorganisms come from people or animals, or from well-managed ventilation or ducts into the room. In particular, microorganisms as pollutants cause unpleasant odors and, moreover, cause bacterial infections in humans. There are many types of pollutants in the rooms, such as dust, toxic gases, tobacco smoke, artificial carpets and polyurethane insulation, formaldehyde from furniture and furniture, hazardous chemicals from household appliances, high concentrations of carbon dioxide, radon and so on. Problems caused by partially contaminated indoor air can be solved through natural ventilation to open the windows, but ventilation by opening the windows can cause uncomfortable high airflow, which can make a person feel uncomfortable. In addition, opening the windows to natural ventilation results in a lot of heat loss. For example, during the winter season, indoor air warmed by using a heating facility is cold due to the outside air, resulting in a large heat loss. In addition, when the window is opened and ventilated, problems due to external noise may occur.

On the other hand, various types of ventilators have been proposed in the past. The conventional ventilating apparatus has an intake fan for sucking outside air and an exhaust fan for exhausting indoor air. However, the conventional ventilation device has a drawback in that it is large and complicated and difficult to install because it comprises an exhaust structure including an exhaust fan and an intake structure including an intake fan. In addition, the conventional ventilator still has a problem of energy loss due to the inflow of outside air, and there is still a problem of condensation due to the temperature difference between the inside air and the outside air.

Korean Patent Registration No. 10-0552439 (February 8, 2006)

One of the problems to be solved by the present invention is to provide a refrigerator which can be installed in an individual room and can be used for ventilating an individual room by a reversible EC fan capable of rotating forward and backward while recovering energy, The condensation phenomenon caused by the temperature difference can be suppressed and it can be easily deformed even with various outer wall thicknesses and can be easily installed and the loss of the indoor heat energy can be prevented by using the ceramic heat- And to provide an energy recovery type reversible fan ventilator which can be minimized.

Another problem to be solved by the present invention is to provide a plurality of energy recovery type reversible fan ventilators which can be used for individual room ventilation by a reversible EC fan installed in an individual room, Wherein the plurality of energy recovery type reversible fan ventilators are connected to the plurality of energy recovery type reversible fan ventilators through a network so as to ventilate the indoor space including a plurality of individual rooms comprehensively.

An energy recovery type reversible fan ventilator according to one aspect of the present invention includes: a ventilating unit (10) located indoors when installed; And a heat recovery duct unit (30) connected to the ventilation unit (10) and extending to the outside through a building wall, wherein the ventilation unit (10) has a ventilation grill (112) A reversible EC fan 120 installed in the housing 110 and capable of bi-directional bi-directional blowing by normal and bidirectional rotational driving, a reversible EC fan 120 installed in the housing 110, And an air shutter 130 installed between the EC fan 120 and the ventilation grill 112 to selectively block air inflow and outflow. The heat recovery duct unit 30 includes an inner duct 31a, (31) having an outer duct (31b) slidably fitted on an outer circumferential surface of the lengthwise air duct (31a), the length of which is adjustable according to the thickness of the building wall, Ceramic shaft with air holes in the structure And a heat insulating material 33 of a viscoelastic material that is formed to surround the outer circumferential surface of the ceramic heater 32 and exists in a compressed state between the length variable duct 31 and the ceramic heater 32, ).

The heat recovery duct unit 30 includes a sliding enhancement layer 34 formed on the outer circumferential surface of the heat insulating material 33 and closely adhered to the inner circumferential surface of the variable air duct 31, 10, and a turbulence suppressing member 37 for suppressing turbulence of the air flow.

According to one embodiment, the ventilation unit 10 integrally includes a plurality of support ribs 115 extending from an inner circumferential surface of the inner blowing pipe 114 to a central motor mounting portion, and the reversible EC fan 120 An EC motor 120a mounted on the motor mounting portion and an axial fan blades 120b rotated in normal and reverse directions by the EC motor 120 to blow air in both forward and reverse directions through the internal blowing pipe 114, A PCB is disposed outside the blowing pipe 114 in the housing 110 and an electric wire extending from the PCB is inserted into the motor mounting portion 114a through a wiring passage formed in the support rib 115, And a mounting plate 106 having a hole surrounding the extension of the blowing pipe 114 is coupled to the rear of the ventilation unit 10. The ventilation unit 10 is mounted on the mounting plate 106, Is mounted on the building wall .

According to one embodiment, the heat recovery duct unit 30 further includes a pair of filters disposed at both ends of the ceramic heat accumulator 32, and each of the pair of filters 35 is disposed on both opposite sides And a pair of cut-out grooves 352 and 352. The ceramic heat-collectors 32 are provided at both ends thereof with a "C " ) Is sandwiched between the "C" -shaped strings 36, thereby releasably holding the pair of filters 35 at both ends of the ceramic heat accumulator 32.

According to another aspect of the present invention, there is provided an energy recovery type reversible fan ventilator (1) comprising a plurality of energy recovery type reversible fan ventilators (1) installed through a wall of a building having a plurality of individual rooms, And an integrated control unit (2) for individually and integrally controlling them. In the ventilation system, the plurality of energy recovery type reversible fan ventilators (1) are integrated into one remote control ventilation network so that they can be integrally controlled by the integrated control unit (2), and the integrated control unit The mode conversion unit 203 includes a natural air supply mode 203a and an air supply mode 203b. The air supply mode 203b is a mode in which the natural air supply mode 203a, the air supply mode 203b, ), The heat recovery ventilation mode (203c), and the ventilation mode (203d), wherein the natural air supply mode (203a) is a mode in which the energy recovery type reversible fan The air supply mode 203b is a mode in which air is supplied by opening the air shutter while the reversible EC fan of the ventilating apparatuses 1 is stopped and the air supply mode 203b is a mode in which the air shutters 130 of the energy- The reversible EC fan 120 is opened And the heat recovery ventilation mode (203c) is a mode in which the fresh air from outside is forcedly supplied to the inside through the energy recovery type reversible fan ventilators (1), the energy recovery type reversible fan ventilator 1 is a mode in which the reversible EC fan is controlled so as to perform forced air supply and forced air discharge in a predetermined cycle, and the ventilation mode 203d is a mode in which all the energy recovery type reversible fan fans 1 in the network are forced air discharge or forced air In the ventilation mode (203d), the energy recovery type reversible fan ventilator (1) in the half of the network is in the forced air supply mode and the other half of the energy recovery type reversible fan The ventilator 1 becomes the forced air discharge mode.

According to an aspect of the present invention, a reversible EC fan installed in an individual room and recovering energy can be used for individual room ventilation by a reversible EC fan capable of rotating forward and backward, and is installed to pass through an outer wall Despite the fact that the condensation phenomenon caused by the temperature difference can be suppressed, it can be easily deformed to various wall thicknesses and can be easily installed, and the loss of the indoor heat energy can be minimized by using the ceramic heat- An energy recovery type reversible fan ventilation device is realized.

According to another aspect of the present invention, a plurality of energy recovery type reversible fan ventilators, which are installed in individual rooms and can be used for individual room ventilation by a reversible EC fan capable of rotating forward and backward while recovering energy, And the plurality of energy recovery type reversible fan ventilators are connected to each other through a network to realize a ventilation system capable of ventilating indoors including a plurality of individual rooms comprehensively.

1 is a side view showing an energy recovery type reversible fan ventilator according to an embodiment of the present invention.
FIG. 2 is a cross-sectional view of the energy recovery type reversible fan ventilator shown in FIG. 1. FIG.
3 is an enlarged view of circle "A" in Fig.
4 is a cross-sectional view taken along line II in Fig.
5 is a view for explaining a filter holding structure of the energy recovery type reversible fan ventilating apparatus shown in Figs. 1 to 4. Fig.
6 is a view for explaining a ventilation system including a plurality of energy recovery type reversible fan fans according to an embodiment of the present invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings and the description thereof are intended to aid those of ordinary skill in the art in understanding the present invention. Accordingly, the drawings and description are not to be construed as limiting the scope of the invention.

FIG. 1 is a side view showing an energy recovery type reversible fan ventilator according to an embodiment of the present invention, FIG. 2 is a sectional view showing the energy recovery type reversible fan ventilator shown in FIG. 1, FIG. 4 is a cross-sectional view taken along II of FIG. 2, and FIG. 5 is a view illustrating a filter holding structure of the energy recovery type reversible fan ventilator shown in FIGS. 1 to 4 And FIG. 6 is a view for explaining a ventilation system including a plurality of energy recovery type reversible fan fans according to an embodiment of the present invention.

1 to 5, the energy recovery type reversible fan ventilator 1 according to an embodiment of the present invention can be installed in an individual room and can be used for individual room ventilation while recovering energy alone , A ventilating unit (10) located indoors at the time of installation, and a ventilating unit (10) located inside the ventilating unit And a heat recovery duct unit 30 extending to the outside of the room through the wall W.

The ventilation unit 10 includes a box-type housing 110 having a ventilation grill 112 formed at a front side thereof and an internal ventilation pipe 114 at a rear side of the ventilation grill 112, And an air shutter 130 installed between the reversible EC fan 120 and the ventilating grill 112 to selectively block the inflow / outflow of the air, . The ventilation unit 10 may further include a front panel 105 connected to the ventilation grill 112 by a plurality of connection parts spaced apart from the front of the ventilation grill 112. The front plate 105 can spread the ventilating air introduced from the ventilating grill 112 and spread the ventilating air to the room.

The inner blowing pipe 114 integrally includes a plurality of support ribs 115 extending from the inner circumferential surface to the central motor mounting portion. The reversible EC fan 120 includes an EC motor 120a mounted on the motor mounting section and an axial fan blade 122 that is rotated in normal and reverse directions by the EC motor 120 to blow air in both the forward and reverse directions through the internal blowing tube 114. [ (120b).

A control unit including a PCB is installed outside the blowing pipe 114 in the housing 110. The electric wiring extending from the control unit is inserted into the motor mounting portion 114a through a wiring passage formed in the support rib 115, And is connected to the EC motor 120.

A mounting plate 106 having a hole surrounding the extension of the blowing pipe 114 is coupled to the rear of the ventilation unit 10. The ventilation unit 10 is mounted on the wall As shown in FIG. The mounting plate 106 may be provided with a power line holding holder.

The normal rotation and rotation speeds of the reversible EC fan 120 and the opening and closing operations of the air shutter 130 are controlled by a control unit which controls an operation switch provided outside the housing of the ventilation unit 10, And controls the reversible EC fan 120 or the air shutter 130 according to various input signals input through input means such as a remote controller.

The heat recovery duct unit 30 is installed in a duct hole formed in the building wall W and includes a length variable air duct 31 which can be installed with a length adjusted according to the thickness of the wall W, A cylindrical ceramic accumulator 32 installed in the variable air duct 31 and having a lattice air hole, a heat insulating material 33 of a viscoelastic material formed to surround the outer circumferential surface of the cylindrical ceramic accumulator 32, And a slip enhancement layer (34) formed on the outer circumferential surface of the heat insulating material (33) and brought into close contact with the inner circumferential surface of the variable - length air duct (31).

The ceramic accumulator 32 has a lattice-shaped air hole formed by a plurality of grid holes 321 to permit air flow from the room to the outside or outdoors to the room. The ceramic heat accumulator 32 serves as an enthalpy heat exchanger that heats and accumulates warm heat in the room air at the time of evacuation and heats the air supplied from the outside by the heat accumulated in the supply or ventilation. The lattice structure constituting the air passage of the ceramic heat accumulator 32 increases the contact area with air and contributes to enhance the heat conduction characteristics and the heat storage performance of the ceramic heat accumulator 32.

Since the heat in the indoor air discharged by only the ceramic accumulator 32 is recovered and the temperature of the air supplied to the room from the outside is increased, the energy caused by the heat of the room air in the ventilating process The loss can be minimized.

The heat insulating material 33 is made of an annular heat insulating material having a viscoelastic property such as a sponge and is installed so as to surround the outer peripheral surface of the ceramic heater 32 with almost the same thickness. The ceramic heat accumulator 32 has a large temperature difference between a portion near the center of the ceramic heat accumulator 32 and an outer peripheral surface adjacent to the inner surface of the duct hole of the building wall. Which greatly contributes to suppressing the dew condensation phenomenon. Particularly in winter, the temperature of the outer peripheral surface of the ceramic heat accumulator 32 is low, so that a large amount of heat loss is generated in the vicinity of the outer peripheral surface. The temperature of the heat insulating material 33, It prevents the descent and contributes more to reducing heat loss. The thermally insulating material 33 is made of a viscoelastic material that can be compressed between the ceramic heat accumulator 32 and the heat insulating material 33 when the thermally insulating material 33 is inserted into the length variable air duct 31, And completely blocks the gap between the ceramic heater 32 and the variable air duct 31. The slip enhancement layer 34 is formed of a lower piece serving to fix the heat insulating material 33 to the ceramic heat accumulator 32 while being formed of an insulating resin tape such as Teflon tape, The slidability with respect to the inner circumferential surface of the variable air duct 31 is increased so that the ceramic heat accumulator 32 enclosed with the heat insulating material 33 can be inserted more smoothly into the variable air duct 31.

The length-variable air duct 31 includes an inner duct 31a and an outer duct 31b slidably fitted on an outer circumferential surface of the inner duct 31a. The length of the length-variable duct 31 is adjusted by the relative sliding movement of the inner duct 31a and the outer duct 31b. It is preferable that the portion of the length variable air duct 31 in which the ceramic heat accumulator 32 surrounded by the heat insulating material 33 is inserted and held is an internal duct 31a having a small diameter. The inner duct 31a is connected to the ventilation unit 31a and the outer duct 31b extends to the outside of the building wall W with the exhaust grille 39 detachably attached to the end thereof. It is also conceivable to provide an outside ventilation hood outside the building wall W to cover the exhaust grill 37 of the length-variable duct 31.

The heat recovery duct unit 30 further includes a pair of filters 35 and 35 disposed at both ends of the ceramic heat accumulator 32. The pair of filters 35 collects and removes contaminants in the air flowing into the room, and has a total filter grade of G3. Preferably, the filter 35 is antimicrobial, easily detachable, and easily cleanable with a vacuum cleaner or water.

The pair of filters 35 has a pair of cutout grooves 352 and 352 on opposite sides thereof. C type ropes 36 fixedly fitted in the lattice holes are provided at both ends of the ceramic heat accumulator 32. The pair of the cutting grooves 352 are inserted into the C type rope 36, And the pair of filters 35 are detachably held at both ends of the ceramic heat accumulator 32. The heat recovery duct unit 30 is arranged so as to be close to the side connected to the ventilation unit 10 while suppressing the turbulence of the air flow so that the turbulence suppressing member 37 Respectively.

The above-described energy recovery type reversible fan ventilator 1 can be installed in an individual room and can be used solely for individual room ventilation while recovering energy. In addition, the energy recovery type reversible fan ventilator 1 can be combined with another energy-recoverable reversible fan ventilator connected to the network to constitute one integrated ventilation system, Can be generically evoked.

The ventilation system to which the above-described energy recovery type reversible fan ventilator 1 is applied will be described with reference to FIG.

Referring to FIG. 6, the ventilation system includes a plurality of energy recovery type reversible fan ventilators 1 installed through a wall of a building, and a plurality of energy recovery type reversible fan ventilators 1 individually and integrally And an integrated control unit (2) for controlling the control unit. The plurality of energy recovery type reversible fan ventilators 1 are integrated into one remote control ventilation network and can be integrally controlled by the integrated control unit 2. [ The integrated control unit 2 includes an air volume adjusting unit 201 and a humidity adjusting unit 202. The air flow rate regulator 201 and / or the humidity controller 202 adjusts the rotation speed of the reversible EC fan 202 according to a user's input using a speed control switch or a remote controller provided in the energy recovery type reversible fan ventilator 1 To adjust the air volume or humidity. The integrated control unit 2 includes a mode conversion unit 203 which controls the collecting type reversible fan ventilator 1 provided in the system integrally or individually according to the selected mode. The modes that can be converted by the mode conversion unit 203 include a natural air supply mode 203a, an air supply mode 203b, a heat recovery ventilation mode 203c, and a ventilation mode 203d. The mode converter 203 opens only the air shutter 130 (see FIG. 2) with the reversible EC fan 120 (see FIG. 2) stopped when the natural air supply mode 203a is selected. In addition, when the air supply mode 203b is selected, the mode conversion unit 203 switches the air shutters 130 of all the energy recovery type reversible fan ventilators 1 to open the air shutters 130 of all the energy- The reversible EC fan 120 of the apparatus 1 is driven in the normal direction so that fresh air outside is forcedly supplied to the inside through all the energy recovery type reversible fan ventilators 1. When the heat recovery ventilation mode 203c is selected, all of the energy recovery type reversible fan fans 1 are switched to the forced air supply (forced air supply) and the forced air discharge (forced air discharge) at regular intervals And controls the reversible EC fan 120. [ When the ventilation mode 203d is selected, the mode conversion unit 203 controls all the energy recovery type reversible fan fans 1 in the network to be continuously operated in forced air discharge mode or forced air supply mode. Particularly, in the ventilation mode 203d, the energy recovery type reversible fan ventilator 1 in the half of the network is in the forced air supply mode and the other half of the energy recovery type reversible fan ventilator 1 is in the forced air discharge mode So as to control the energy recovery type reversible fan ventilators (1).

10: ventilation unit 30: heat recovery duct unit
110: housing 120: reversible EC fan
130: Air shutter 31: Length variable air duct
31a: inner duct 31b: outer duct
32: ceramic shaft opening 33: thermal insulation

Claims (5)

A ventilation unit (10) located indoors when installed; And
And a heat recovery duct unit (30) connected to the ventilation unit (10) and extending out to the outside through a building wall,
The ventilation unit 10 includes a box-type housing 110 having a ventilation grill 112 formed at the front and having an internal ventilation pipe 114 at a rear side of the ventilation grill 112, An air shutter 130 installed between the reversible EC fan 120 and the ventilating grill 112 to selectively block the inflow and outflow of air, a reversible EC fan 120 capable of blowing air in two directions by bidirectional rotation, Lt; / RTI >
The heat recovery duct unit 30 includes an inner duct 31a and an outer duct 31b slidably fitted on an outer circumferential surface of the inner duct 31a, The air conditioner according to any one of claims 1 to 3, further comprising: a duct (31); a ceramic heater (32) installed in the length-variable air duct (31) A heat insulating material 33 of a viscoelastic material in a compressed state between the duct 31 and the ceramic heat accumulator 32 and an inner peripheral surface of the length variable air duct 31 formed on the outer peripheral surface of the heat insulating material 33, And a turbulence suppressing member (37) disposed so as to be close to the side connected to the ventilation unit (10) and suppressing turbulent air flow, characterized in that the sliding member Reversible fan Ventilation system. delete The reversible EC fan (120) according to claim 1, wherein the ventilation unit (10) integrally includes a plurality of support ribs (115) extending from an inner circumferential surface of the inner blowing pipe (114) An EC motor 120a mounted on the motor mounting portion and an axial fan blades 120b rotated in normal and reverse directions by the EC motor 120 to blow air in both forward and reverse directions through the internal blowing pipe 114, An electrical wiring extending from the PCB is inserted into the motor mounting portion 114a through a wiring passage formed in the support rib 115 and connected to the EC motor 120 And a mounting plate 106 having a hole surrounding an extension of the blowing pipe 114 is coupled to the rear of the ventilation unit 10 so that the ventilation unit 10 Mounted on a building wall Reversible fan energy recovery type ventilating device according to claim. The heat recovery duct unit (30) according to claim 1, wherein the heat recovery duct unit (30) further includes a pair of filters disposed at both ends of the ceramic heat accumulator (32), wherein each of the pair of filters And a pair of cutting grooves 352 and 352. The ceramic heat sink 32 has a pair of cutting grooves 352 formed at both ends of the ceramic heat sink 32, Wherein the pair of filters (35) are held removably at both ends of the ceramic heater (32) by inserting the pair of filters (35) into the "C" type string (36). A plurality of energy recovery type reversible fan ventilators (1) installed through walls of a building having a plurality of individual rooms,
And an integrated control unit (2) for individually and integrally controlling the plurality of energy recovery type reversible fan fans (1)
The plurality of energy recovery type reversible fan ventilators 1 are integrated into one remote control ventilation network so that they can be integrally controlled by the integrated control unit 2. The integrated control unit 2 includes an air volume adjusting unit And a mode conversion unit 203. The mode conversion unit 203 includes a natural air supply mode 203a, an air supply mode 203b, a heat recovery ventilation unit 203b, And the mode of the energy recovery type reversible fan ventilators 1 is switched in the ventilation mode 203c and the ventilation mode 203d while the natural air supply mode 203a is switched between the modes of the energy recovery type reversible fan ventilators 1 And the air shutter is opened and the air is supplied while the reversible EC fan is stopped. The air supply mode 203b is a mode in which the air shutter 130 of the energy recovery type reversible fan ventilators 1 is opened Driving the reversible EC fan in the forward direction, And the heat recovery ventilation mode (203c) is a mode in which the energy recovery type reversible fan ventilators (1) are energized at regular intervals And the ventilation mode 203d is a mode for controlling all the energy recovery type reversible fan fans 1 in the network to continuously operate in the forced air discharge mode or the forced air supply mode In the ventilation mode 203d, the energy recovery type reversible fan ventilator 1 in the network half is in the forced air supply mode and the other half of the energy recovery type reversible fan ventilator 1 is in the ventilating mode 203d And a forced air discharge mode.

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