JP2004156885A - Air-conditioning indoor unit and ceiling embedded air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an air-conditioning indoor unit and a ceiling embedded air conditioner capable of reducing the noise of a turbo fan. <P>SOLUTION: The air-conditioning indoor unit 11 comprises a driving part 18 fixed to a top plate 24 of a casing 17, a fan 19 driven by the driving part 18 to boost and blow air sucked from a suction port 20, and an indoor heat exchanger 22 for heating or cooling the air blown off from the fan 19, inside the casing 17 with the suction port 20 for allowing the air to flow in. The air-conditioning indoor unit 11 is characterized by providing passage enlarging members 33, 35 for gradually enlarging the flow of air blown off from the fan 19, toward the indoor heat exchanger 22. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an air conditioning indoor unit in which a main body casing is embedded in a ceiling surface, and a ceiling embedded air conditioner including the air conditioning indoor unit.
[0002]
[Prior art]
FIG. 18 is a cross-sectional view of the indoor unit 110 for air conditioning of the ceiling-embedded air conditioner 100 buried in the ceiling surface.
In FIG. 18, the air conditioning indoor unit 110 includes a casing 111, a motor 112 fixed to the casing 111, a turbo fan 113 driven by the motor 112, a suction port 114 for sucking room air, and a The bell mouth 115 which guides to the turbo fan 113, the indoor heat exchanger 116 which heats or cools air, and the outlet 117 which is the outlet of the air which heat-exchanged are comprised as main elements.
[0003]
The motor 112 is fixed substantially at the center of the top plate 118 of the casing 111 with the main shaft 119 directed substantially vertically downward. A turbo fan 113 is connected to the main shaft 119. The turbo fan 113 includes a main plate 120 facing the top plate 118, a shroud 121 facing the main plate 120 below the main plate 120, and a portion between the main plate 120 and the shroud 121. And the blades 122 are arranged at intervals. The main plate 120 is provided with four cooling holes 123 in an annular shape at equal intervals around the main shaft 119. The shroud 121 is arranged so as to cover the upper end of the bell mouth 115 with a gap having a width L1.
[0004]
In the above configuration, the indoor air flows into the air conditioning indoor unit 110 from the suction port 114, passes through the bell mouth 115, and is guided to the turbo fan 113 driven by the motor 112. The air guided to the turbo fan 113 is pressurized and sent out to the indoor heat exchanger 116. In the indoor heat exchanger 116, the air is adjusted to a desired temperature by being heated or cooled, and is returned from the outlet 117 into the room.
[0005]
Further, as shown in FIG. 19, a part of the air pressurized by the turbo fan 113 passes between the main plate 120 and the top plate 118 and flows around the motor 112 to cool the motor 112, After passing through the cooling hole 123, the air is returned to the upstream side of the blade 122 of the turbo fan 113 having a low pressure (upper return path r1).
[0006]
Apart from that, a part of the air pressurized by the turbofan 113 also passes below the shroud 121, passes through the gap between the shroud 121 and the bell mouth 115, and is upstream of the blade 122 of the turbofan 113 having a low pressure. (The lower reflux path r2).
This is a reflux that occurs because an interval (clearance) is provided to avoid interference between the rotating shroud 121 and the non-rotating bellmouth 115.
[0007]
Further, since the indoor heat exchanger 116 is disposed so as to form a substantially quadrangular shape having a flat portion and a corner portion, the indoor heat exchanger 116 is deflected radially outward from the turbo fan 113 in the rotation direction of the turbo fan 113. The air sent out collides obliquely with the plane portion of the indoor heat exchanger 116. Part of the air flows laterally along the flat part, and the rest passes through the flat part while exchanging heat with the refrigerant inside the flat part. The air flowing along the plane collides with the corner of the indoor heat exchanger 116 substantially perpendicularly.
The degree of pressure increase in the collision area changes depending on the collision angle between the air and the indoor heat exchanger 116, so that the pressure distribution inside the indoor heat exchanger 116 becomes uneven.
[0008]
Since the pressure distribution inside the indoor heat exchanger 116 becomes non-uniform, the pressure gradient between the inside of the indoor heat exchanger 116 and the upstream of the blade 122 of the turbo fan 113 also becomes non-uniform, and the upper return path r1 and the lower return path The flow rate and the flow velocity of the air flowing through r2 also become non-uniform in the circumferential direction (for example, see Patent Document 1).
[0009]
[Patent Document 1]
JP-A-11-325497 (Pages 5-7, FIG. 1)
[0010]
[Problems to be solved by the invention]
By the way, in the air conditioning indoor unit 110, the pressure of the air is increased in the turbo fan 113, the energy thereof is increased, and the air is sent out to the indoor heat exchanger 116. As shown in FIG. 19, the energy-enhanced air is rapidly sent out to a wide space, so that the air separates from the wall surface, generates vortices at the boundary surface with the surrounding air, and causes mixing. Due to the generation of the vortex, a part of the energy of the air whose energy has been increased is consumed (pressure loss). Therefore, as shown in FIG. 18, the flow rate of the air that passes through the indoor heat exchanger 116 and blows out from the outlet 117 decreases, and the flow rate of the air flowing into and out of the air conditioning indoor unit 110 is reduced by the energy lost due to the pressure loss. Just drop.
[0011]
In order to compensate for the decrease in the flow rate of air blown out from the outlet 117, a method of increasing the number of revolutions of the turbo fan 113 and increasing the energy given to the air in the turbo fan 113 is adopted. If it is raised, there is a problem that the noise generated from the turbo fan 113 also increases.
[0012]
Further, the plane shape of the suction port 114 is substantially rectangular, and the shape of the portion of the turbo fan 113 into which the air flows is different from the substantially circular shape having a smaller area than the plane shape of the suction port 114. The air flowing over the mouse 115 is as shown in FIG. That is, a large amount of air flows into the turbo fan 113 from the four corners of the suction port 114 having a larger area than the four sides of the suction port 114 as compared with the flow rate from the four sides of the suction port 114. Therefore, the flow velocity of the air flowing from the four corners of the suction port 114 is higher than the flow velocity from the four sides of the suction port 114.
[0013]
The flow velocity of the air flowing from the four corners of the suction port 114 is different from the flow velocity of the air flowing from the four sides of the suction port 114, and the blade 122 of the turbo fan 113 rotates there. Each time you pass through the area, a sound is generated. Therefore, there is a problem that the turbo fan 113 generates noise whose main component is a component that is an integral multiple of 4 of the rotation frequency.
[0014]
Further, since the pressure distribution inside the indoor heat exchanger 116 becomes uneven, the flow rate and the flow velocity of the air flowing through the upper return path r1 and the lower return path r2 also become uneven in the circumferential direction.
Since the blades 122 of the turbo fan 113 rotate at a place where the flow velocity distribution is not uniform, a sound is generated every time the blades 122 pass through a place where the flow velocity is not uniform. For this reason, the turbo fan 113 has a problem in that it generates noise whose main component is a component that is an integral multiple of the rotation frequency.
[0015]
The present invention has been made in view of such circumstances, and an object thereof is to provide an air-conditioning indoor unit and a ceiling-mounted air conditioner that can reduce noise of a turbofan.
[0016]
[Means for Solving the Problems]
In order to solve the above-mentioned problems, the indoor unit for air conditioning and the ceiling-mounted air conditioner of the present invention employ the following means.
The invention according to claim 1 has a drive unit fixed to a top plate of the casing in a casing having a suction port through which air flows, and pressurized air driven by the drive unit and sucked from the suction port. An air-conditioning indoor unit provided with a fan that sends out air and an indoor heat exchanger that heats or cools the air sent out by the fan, the flow of air blown out from the fan is directed toward the indoor heat exchanger. And a flow path enlarging member for gently expanding.
[0017]
According to the air-conditioning indoor unit according to the present invention, the flow of air blown out from the fan adheres to the flow path enlarging member that gradually spreads toward the indoor heat exchanger, so that a pressure loss occurs. Decreases. The sum of the energy that the air has as the flow velocity and the energy that the air has as the pressure is the total energy held by the air, and since the pressure loss has been reduced, the total energy held by the air has increased as compared with the conventional case. Therefore, the static pressure recovered by the decrease in the flow velocity of the air due to the expansion of the flow path increases by an amount corresponding to the reduced pressure loss. As a result, the pressure difference with the room air increases, and the flow rate of the air flowing into and out of the air conditioning indoor unit increases.
[0018]
That is, in order to keep the flow rate of the air flowing into and out of the air-conditioning indoor unit the same as when the flow path expanding member is not provided, the flow velocity and the pressure (energy applied to the air) given to the air by the fan should be It will be reduced by the pressure loss. In order to reduce the energy given to the air, the number of revolutions of the fan must be reduced. When the number of revolutions of the fan decreases, the noise generated from the fan can be reduced.
[0019]
The invention according to claim 2 is the air conditioning indoor unit according to claim 1, wherein the fan is provided with a main plate provided to face the top plate, and a shroud provided at a position facing the main plate. A blade disposed between the main plate and the shroud, wherein the flow channel enlarging member is provided in a substantially annular shape above the main plate, and at least outward of the fan outer edge toward a radially outer side. A first inclined surface for guiding the flow along the lower surface of the main plate toward the top plate of the casing.
[0020]
According to the indoor unit for air conditioning according to the present invention, the flow path enlarging member is provided in a substantially annular shape above the main plate, and at least outside the outer edge of the fan, flows along the lower surface of the main plate. In order to provide a first inclined surface that guides toward the top plate of the casing, the flow of air blown out from the fan adheres to the first inclined surface of the flow path expanding member, flows, and generates a pressure loss. Decreases.
Therefore, in order to keep the flow rate of the air flowing out of the air conditioning indoor unit into the room at the same level as when the flow path expanding member is not provided, the rotation speed of the fan is reduced, and the rotation speed of the fan is reduced. The sound generated from the fan can be reduced.
[0021]
The invention according to claim 3 is the air conditioning indoor unit according to claim 1, further comprising a bell mouth that guides air from the suction port to the fan below the fan, wherein the fan faces the top plate. A main plate provided as described above, a shroud provided at a position facing the main plate, and a blade arranged between the main plate and the shroud, wherein the flow channel expanding member is substantially below the shroud. At least outside the outer edge of the fan, a second inclined surface that guides a flow along an upper surface of the shroud toward the bell mouth at least outward of the outer edge of the fan. I do.
[0022]
According to the indoor unit for air conditioning according to the present invention, the flow path expanding member is provided in a substantially annular shape below the shroud, and at least outside the fan outer edge, flows along the upper surface of the shroud. With the second inclined surface that guides toward the bell mouth, the flow of air blown out from the fan adheres to the second inclined surface of the flow path expanding member and flows, and the generated pressure loss is reduced. .
Therefore, in order to keep the flow rate of the air flowing out of the air conditioning indoor unit into the room at the same level as when the flow path expanding member is not provided, the rotation speed of the fan is reduced, and the rotation speed of the fan is reduced. The sound generated from the fan can be reduced.
[0023]
According to a fourth aspect of the present invention, in a casing having a suction port through which air flows in, a driving unit fixed to a top plate of the casing, and the driving unit is driven by the driving unit to increase the pressure of the air sucked from the suction port. A main plate provided so as to face the top plate, and a main plate provided so as to face the main plate. In the air-conditioning indoor unit including the shroud provided at the position where the air flows and the blade disposed between the main plate and the shroud, the air flows into the blade below the fan in the rotation direction of the blade. It is characterized by comprising a flow velocity equalizing means for uniformizing the flow velocity distribution of the air.
[0024]
According to the indoor unit for air conditioning according to the present invention, since the flow rate uniformizing means for equalizing the flow velocity distribution of the air flowing into the blade in the circumferential direction of the blade is provided, the air flowing into the blade is The flow velocity distribution can be made uniform. Therefore, it is possible to reduce a sound mainly composed of a component that is an integral multiple of the rotation frequency of the fan.
[0025]
The invention according to claim 5 is the air conditioning indoor unit according to claim 4, further comprising a bell mouth that guides air from the suction port to the fan below the fan, and wherein the flow velocity equalizing means is provided on the blade. A first cylindrical wall for temporarily blocking the inflowing air is provided on a lower surface of the bell mouth.
[0026]
According to the indoor unit for air conditioning according to the present invention, since the flow velocity equalizing means includes, on the lower surface of the bell mouth, the first cylindrical wall for temporarily blocking the air flowing into the blades, the air flowing into the blades Can be made uniform.
That is, the air flowing into the blade is temporarily blocked by the first cylindrical wall. The dammed air spreads around the first cylindrical wall and, after being homogenized, climbs over the first cylindrical wall. The air, which has been made uniform over the first cylindrical wall, flows into the upstream side of the blade. Therefore, it is possible to make the flow velocity of the air flowing into the blade uniform, and to reduce sound mainly composed of a component that is an integral multiple of the rotation frequency of the fan.
[0027]
The invention according to claim 6 is the air conditioning indoor unit according to claim 4, wherein the flow velocity equalizing means includes a second cylindrical wall for temporarily blocking air flowing into the blade at the suction port. And
[0028]
According to the indoor unit for air conditioning according to the present invention, since the flow velocity equalizing means includes, at the suction port, the second cylindrical wall for temporarily blocking the air flowing into the blade, the flow velocity of the air flowing into the blade is Can be made uniform.
That is, the air flowing into the blade is temporarily blocked by the second cylindrical wall. The dammed air spreads around the second cylindrical wall and, after being homogenized, climbs over the second cylindrical wall. The air, which has been made uniform over the second cylindrical wall, flows into the upstream side of the blade. Therefore, it is possible to make the flow velocity of the air flowing into the blade uniform, and to reduce sound mainly composed of a component that is an integral multiple of the rotation frequency of the fan.
[0029]
According to a seventh aspect of the present invention, in a casing having a suction port through which air flows, a driving unit fixed to a top plate of the casing, and the driving unit is driven by the driving unit to increase the pressure of the air sucked from the suction port. And an indoor heat exchanger that heats or cools the air sent out by the fan, and a part of the air sent out by the fan passes through the casing and passes through the casing. In the air-conditioning indoor unit including a collision portion that is returned to the upstream side and the indoor heat exchanger collides substantially perpendicularly with the air sent from the fan, at least a part of the flow of the colliding air is subjected to the collision. And a rectifying means for guiding in a direction other than the section.
[0030]
According to the indoor unit for air conditioning according to the present invention, since there is provided a rectifying unit for preventing at least a part of the flow of the colliding air from colliding with the collision unit, the range of the region where the pressure increases can be narrowed. And the degree of the pressure rise can be reduced. Therefore, the unevenness of the pressure difference with the upstream side of the fan is reduced, and the flow velocity of the air recirculating to the upstream side of the fan can be made uniform, and a component of an integral multiple of the rotation frequency of the fan can be obtained. Can be reduced.
[0031]
The invention according to claim 8 is the air conditioning indoor unit according to claim 7, wherein the rectification unit includes a plate member on an upstream side of the collision portion, and the plate member moves in a downstream direction of an air flow. It is characterized by being arranged to be inclined in the direction of rotation of the fan.
[0032]
According to the indoor unit for air conditioning according to the present invention, the rectifying unit includes the plate member on the upstream side of the collision portion, and the plate member is inclined in the rotation direction of the fan toward the downstream direction of the flow of the air. With this arrangement, it is possible to avoid collision between the air ejected from the fan and the collision portion.
The air blown from the fan collides with the indoor heat exchanger, and a part of the colliding air flows along the indoor heat exchanger. The air flowing along the indoor heat exchanger collides with the plate, and a part of the air is changed in the inclination direction of the plate, so that collision with the collision portion is avoided. As a result, the flow rate of the air colliding with the collision portion decreases, the range of the region where the pressure increases can be narrowed, and the degree of the pressure increase can be reduced. Therefore, the unevenness of the pressure difference with the upstream side of the fan is reduced, and the flow velocity of the air recirculating to the upstream side of the fan can be made uniform, and a component of an integral multiple of the rotation frequency of the fan can be obtained. Can be reduced.
[0033]
According to a ninth aspect of the present invention, in the air conditioning indoor unit according to the seventh aspect, the rectifying unit includes a heat exchanger upstream of the collision portion, and the heat exchanger is provided in a downstream direction of the air flow. The fan is arranged so as to be inclined in the rotation direction of the fan.
[0034]
According to the indoor unit for air conditioning according to the present invention, the rectifying unit includes a heat exchanger upstream of the collision unit, and the heat exchanger rotates the fan in a downstream direction of the air flow. Since it is arranged to be inclined in the direction, it is possible to avoid collision between the air ejected from the fan and the collision portion.
The air blown from the fan collides with the indoor heat exchanger, and a part of the colliding air flows along the indoor heat exchanger. Air flowing along the indoor heat exchanger collides with the heat exchanger, and a part of the air is changed in the inclination direction of the heat exchanger, so that collision with the collision portion is avoided. As a result, the flow rate of the air colliding with the collision portion decreases, the range of the region where the pressure increases can be narrowed, and the degree of the pressure increase can be reduced. Therefore, the unevenness of the pressure difference with the upstream side of the fan is reduced, and the flow velocity of the air recirculating to the upstream side of the fan can be made uniform, and a component of an integral multiple of the rotation frequency of the fan can be obtained. Can be reduced.
[0035]
According to a tenth aspect of the present invention, in the air conditioning indoor unit according to the seventh aspect, the rectifying unit includes a guide plate having a curved surface upstream of the collision portion, and the guide plate collides with the collision portion. The flow of the flowing air is guided in the rotation direction of the fan.
[0036]
According to the indoor unit for air conditioning according to the present invention, the rectifying means includes a guide plate having a curved surface on the upstream side of the collision portion, and the guide plate guides the flow of air in the rotation direction of the fan. Therefore, it is possible to avoid collision between the air ejected from the fan and the collision portion.
The air blown from the fan collides with the indoor heat exchanger, and a part of the colliding air flows along the indoor heat exchanger. Part of the air flowing along the indoor heat exchanger is guided by the curved surface of the guide plate and is changed in the rotation direction of the fan, so that collision with the collision portion is avoided. As a result, the flow rate of the air colliding with the collision portion decreases, the range of the region where the pressure increases can be narrowed, and the degree of the pressure increase can be reduced. Therefore, the unevenness of the pressure difference with the upstream side of the fan is reduced, and the flow velocity of the air recirculating to the upstream side of the fan can be made uniform, and a component of an integral multiple of the rotation frequency of the fan can be obtained. Can be reduced.
[0037]
The invention according to claim 11 is such that, in a casing having a suction port through which air flows, a driving unit fixed to a top plate of the casing, and the driving unit is driven to increase the pressure of the air sucked from the suction port. 5. An air-conditioning indoor unit comprising a fan to send out air and an indoor heat exchanger that heats or cools the air sent out by the fan, the flow channel expanding member according to claim 1, and the air conditioning unit according to claim 4. At least two or more of the flow velocity equalizing means and the rectifying means according to claim 7 are provided in combination.
[0038]
According to the air-conditioning indoor unit according to the present invention, according to the air-conditioning indoor unit according to the present invention, the rotation speed of the fan can be reduced, and the flow-path enlarging member and the fan flow into the fan. 9. The flow velocity equalizing means according to claim 4, wherein the flow velocity distribution of the flowing air can be made uniform, and the flow rectifying means according to claim 7, wherein the flow of air returning to the upstream side of the fan can be made uniform. By providing a combination of the above, it is possible to reduce the number of revolutions of the fan, reduce the noise generated from the fan, or have an uneven flow velocity distribution in the circumferential direction of the fan, upstream of the fan. The flow of the air returning to the side can be made uniform, or its influence can be reduced.
[0039]
According to a twelfth aspect of the present invention, in a casing having a suction port through which air flows, a driving unit fixed to a top plate of the casing, and the driving unit is driven by the driving unit to pressurize the air sucked from the suction port. 4. An air-conditioning indoor unit comprising a fan for sending out air and an indoor heat exchanger for heating or cooling the air sent out by the fan, the flow channel expanding member according to claim 2 and claim 3, and claim 5. And at least two of the flow rectifying means according to claims 8 to 10 are provided in combination.
[0040]
According to the indoor unit for air conditioning according to the present invention, the rotational speed of the fan can be reduced, and the flow velocity distribution of the air flowing into the fan and the flow path expanding member according to claims 2 and 3 can be made uniform. 11. A combination of at least two of the flow rectifying means according to items 5 and 6, and the rectifying means according to claims 8 to 10, which can equalize the flow of air returning to the upstream side of the fan. By reducing the number of revolutions of the fan, it is possible to reduce the noise generated from the fan, or to have a non-uniform flow velocity distribution in the circumferential direction of the fan. The flow can be made uniform or its influence can be reduced.
[0041]
According to a thirteenth aspect of the present invention, there is provided the air conditioning indoor unit according to any one of the first to twelfth aspects, the compressor for compressing a refrigerant, and the outdoor heat exchanger for performing heat exchange between the refrigerant and outdoor air. And a refrigerant pipe for connecting the air-conditioning indoor unit and the air-conditioning indoor unit to each other and connecting the refrigerant between the air-conditioning indoor unit and the air-conditioning indoor unit. Features.
[0042]
According to the ceiling-embedded air conditioner according to the present invention, the number of revolutions of the fan can be reduced to reduce noise generated from the fan, or the uneven flow velocity in the circumferential direction of the fan. The flow of air having a distribution and returning to the upstream side of the fan can be made uniform, or its influence can be reduced.
[0043]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. 1 to 5 are views showing a first embodiment of the present invention.
In FIG. 1, the ceiling-embedded air conditioner 10 includes an air conditioning indoor unit 11, an air conditioning outdoor unit 12, and a refrigerant pipe 13 as main elements.
The outdoor unit 12 for air conditioning includes a compressor 14 for compressing the refrigerant, an outdoor heat exchanger 15 for performing heat exchange between the refrigerant and the outdoor air, and an outdoor fan 16 for blowing the outdoor air to the outdoor heat exchanger 15. It has.
The refrigerant pipe 13 is arranged so that the refrigerant can be circulated between the indoor unit for air conditioning 11 and the outdoor unit 12 for air conditioning.
[0044]
As shown in FIGS. 1 and 2, the indoor unit 11 for air conditioning includes a casing 17, a motor (drive unit) 18 disposed in the casing 17, and a turbo fan (fan) 19 rotated by the motor 18. A suction port 20 into which indoor air flows, a bell mouth 21 for guiding air from the suction port 20 to the turbo fan 19, an indoor heat exchanger 22 for heating or cooling air, and an air outlet 23 for discharging air into the room. And as the main elements.
The casing 17 includes a structural part 17A made of an iron plate, and a heat insulating part 17B made of a foam material or the like provided outside the structural part 17A. In addition, a top plate 24 that is substantially flat is formed on the upper part of the casing 17.
[0045]
A motor 18 is fixed substantially at the center of the top plate 24 so that its main shaft 25 is directed substantially vertically downward, and a turbo fan 19 is fixed to an end of the main shaft 25.
In the turbofan 19, a main plate 26 fixed to the main shaft 25, a shroud 27 facing the main plate 26, and vanes 29 are arranged between the main plate 26 and the shroud 27 in an annular shape at equal intervals.
[0046]
As shown in FIG. 3, the center of the main plate 26 has a central portion 26 </ b> A recessed downward in a mortar shape, and extends radially outward from an outer peripheral portion of the central portion 26 </ b> A, and slightly descends inward. The extending portion 26B inclined as described above is formed. In the central portion 26A, cooling holes 28 are arranged in an annular shape at equal intervals around the main shaft 25.
[0047]
As shown in FIG. 3, the shroud 27 has a curved portion 27A that covers the bell mouth 21 with a gap L1 from the upper end of the bell mouth 21, and extends radially outward from the upper end of the outer peripheral portion of the curved portion 27A. , And a flat portion 27B that is inclined so as to descend inward.
The blade 29 is connected to the main plate 26 at an extending portion 26B, and is connected to the shroud 27 at a flat portion 27B.
[0048]
As shown in FIGS. 2 and 3, the bell mouth 21 is disposed below the turbo fan 19, and the room air suction port 20 is disposed below the bell mouth 21. On the upper surface of the bell mouth 21, there is provided an electric box 31 for housing an electronic device 30 for controlling the motor 18, the outlet 23, etc., and the electric box 31 is formed in an annular shape and arranged on the upper surface of the bell mouth 21. Have been.
[0049]
Around the turbo fan 19, an indoor heat exchanger 22 is provided in a substantially square shape. As shown in FIG. 4, the indoor heat exchanger 22 has a substantially flat plate portion 22A, a first corner portion (collision portion) 22B having a small radius of curvature connecting the adjacent flat plate portions 22A, and a large radius of curvature. A storage section (collision section) 32 configured with the second corner portion 22 </ b> C and storing equipment such as piping is arranged so as to cut out one corner of the indoor heat exchanger 22.
[0050]
As shown in FIGS. 2 and 3, the top plate 24 is provided with an upper diffuser (flow path enlarging member) 33 having a shape protruding downward around the main shaft 25 in an annular shape. The upper diffuser 33 has an apex T1 that forms an aperture with an interval L2 with the upper surface of the extending portion 26B of the main plate 26, and is inclined upward at least outside the outer edge of the turbofan 19 toward the outside in the radial direction. A first inclined surface 34 is formed.
[0051]
Similarly, the electrical component box 31 is provided with a lower diffuser (flow path enlarging member) 35 having a shape protruding upward about the main shaft 25 in an annular shape. The lower diffuser 35 forms a throttle having an interval L3 with the outer edge of the flat portion 27B of the shroud 27, and at least outside the outer edge of the turbofan 19, a second inclined surface 36 inclined downward radially outward. Is formed.
Further, it is preferable that the top T2 of the lower diffuser 35 has a height up to the imaginary line plane P extending radially outward along the plane portion 27B of the shroud 27 at a maximum. This is to prevent the air blown out from the turbo fan 19 from becoming a resistance.
[0052]
In the ceiling-embedded air conditioner 10 having the above-described configuration, as shown in FIG. 1, the refrigerant is compressed by the compressor 14 in the outdoor unit 12 for air conditioning, and is converted into outdoor air in the outdoor heat exchanger 15. Is discharged, liquefied, and flows into the air conditioning indoor unit 11 through the refrigerant pipe 13. The refrigerant flowing into the air conditioning indoor unit 11 is decompressed by an expansion valve (not shown), flows into the indoor heat exchanger 22, absorbs the heat of the indoor air, and evaporates. The evaporated refrigerant returns to the compressor 14 through the refrigerant pipe 13 and is compressed.
[0053]
Alternatively, the refrigerant is compressed by the compressor 14 in the outdoor unit 12 for air conditioning, flows through the refrigerant pipe 13, flows into the indoor heat exchanger 22 of the indoor unit 11 for air conditioning, and releases heat to indoor air, Liquefy. The liquefied refrigerant is decompressed by an expansion valve (not shown), flows into the outdoor heat exchanger 15 of the outdoor unit 12 for air conditioning through the refrigerant pipe 13, absorbs the heat of the outdoor air, and evaporates. The evaporated refrigerant returns to the compressor 14 again and is compressed.
[0054]
In the air conditioning indoor unit 11, as shown in FIGS. 2 and 3, the air in the room flows into the air conditioning indoor unit 11 from the suction port 20 by the function of the turbo fan 19 that is rotated by the motor 18. The air that has flowed in from the suction port 20 is guided into the turbofan 19 by the bell mouth 21, and is pressurized by the blade 29 between the main plate 26 and the shroud 27. That is, the blade 29 gives energy to the air passing therethrough.
[0055]
The air whose energy has been increased by the pressure increase by the turbo fan 19 adheres to the first inclined surface 34 of the upper diffuser 33 and the second inclined surface 36 of the lower diffuser 35 and flows. The air attached to the first inclined surface 34 and the second inclined surface 36 flows at a reduced flow rate because the flow path is widened, and part of the energy corresponding to the reduced flow rate is converted into pressure, and Increase.
The air that has passed through the upper diffuser 33 and the lower diffuser 35 flows into the room from the outlet at a flow rate determined by the pressure difference between the pressure after the passage and the indoor pressure, and the flow path resistance of the indoor heat exchanger and the like. .
[0056]
Further, as shown in FIG. 4, the air sent from the turbofan 19 is sent in a direction deflected from the radial direction to the rotation direction of the turbofan 19. Then, it collides with the flat plate portion 22A of the indoor heat exchanger 22, and a part flows in the horizontal direction along the flat plate portion 22A, and the rest passes through the flat plate portion 22A while performing heat exchange with the refrigerant inside the flat plate portion 22A. I do. The air flowing along the flat plate portion 22A collides substantially perpendicularly with the first corner portion 22B and the storage portion 32, and forms a pressure increasing portion H as shown in the pressure distribution diagram of FIG.
[0057]
Thereafter, the air passes through the indoor heat exchanger 22 and exchanges heat with the refrigerant therein, and the air adjusted to an arbitrary temperature flows out of the air outlet 23 into the room.
[0058]
As shown in the pressure distribution diagram of FIG. 5, a part of the air having non-uniform pressure flows back to the blade 29 upstream of the low-pressure turbo fan 19 as shown in FIG. Since the pressure distribution inside the indoor heat exchanger 22 is uneven, the pressure difference with the upstream side of the blade 29 also becomes uneven, and the flow rate and the flow velocity become uneven.
[0059]
After passing between the main plate 26 and the top plate 24 of the turbofan 19, the motor 18 is cooled, and flows through a path (hereinafter, referred to as a first return path R1) that returns from the cooling holes 28 to the upstream side of the blades 29. The flow rate of the air is restricted by the restriction of the interval L2 formed by the upper diffuser 33 and the main plate 26.
Similarly, a path that passes between the shroud 27 of the turbofan 19 and the electrical box 31, passes between the shroud 27 and the bellmouth 21, and returns to the upstream side of the blade 29 (hereinafter, a second return path R2) The flow rate of the air flowing through the lower diffuser 35 and the shroud 27 is restricted by the restriction of the interval L3 formed by the shroud 27.
[0060]
According to the above configuration, since the air blown out from the turbo fan 19 adheres to the first inclined surface 34 and the second inclined surface 36 and flows, the air is given by the blade 29 by generating a vortex or the like. The passed energy passes through the upper diffuser 33 and the lower diffuser 35 without loss (pressure loss). Therefore, in order to make the pressure on the upstream side of the indoor heat exchanger 22 equal to that of the conventional air conditioning indoor unit 110, the amount of energy given by the blades 29 is reduced by the pressure loss. That is, the rotation speed of the turbo fan 19 can be lower than that of the conventional air conditioning indoor unit 110, and as a result, the noise generated from the turbo fan 19 can be reduced.
[0061]
The air flowing through the first recirculation path R1 flows into the upstream side of the blade 29 with its flow rate restricted by the restriction between the main plate 26 and the upper diffuser 33. Therefore, the flow rate of the air flowing into the upstream side of the blade 29 is reduced, and the influence of the uneven flow velocity of the air flowing into the upstream side of the blade 29 can be reduced. Can be reduced. As a result, noise of the turbo fan 19 can be reduced.
[0062]
The air flowing through the second recirculation path R2 flows into the upstream side of the blade 29 with its flow rate restricted by the restriction between the shroud 27 and the lower diffuser 35. Therefore, the flow rate of the air flowing into the upstream side of the blade 29 is reduced, and the influence of the uneven flow velocity of the air flowing into the upstream side of the blade 29 can be reduced. Can be reduced. As a result, the noise of the turbo fan 19 can be reduced.
[0063]
In the air conditioning indoor unit 11, it is considered that each of the upper diffuser 33 and the lower diffuser 35 exhibits a noise reduction effect of about 1 dBA as compared with the conventional air conditioning indoor unit 110.
[0064]
6 and 7 are views showing a second embodiment of the present invention. The entire configuration is the same as that shown in FIGS. 1 to 5, the same components are denoted by the same reference numerals, and description thereof will be omitted.
In FIGS. 6 and 7, the air conditioning indoor unit 41 has a first cylindrical wall (flow velocity equalizing means) 42 centered on the main shaft 25 on the lower surface of the bell mouth 21. At the lower end of the first cylindrical wall 42, a protruding portion 43 protruding downward is provided around a line connecting the corner of the substantially square suction port 20 and the main shaft 25.
[0065]
In the air-conditioning indoor unit 41 having the above configuration, as shown in FIGS. 6 and 7, a large amount of air flows in from the four corners of the suction port 20 and flows in from the four sides of the suction port 20. A part (air flowing near the wall surface of the bell mouth 21) is dammed by the first cylindrical wall 42 provided on the lower surface of the bell mouth 21. The air blocked by the first cylindrical wall 42 flows along the first cylindrical wall 42 to the four sides of the inlet 20 having a relatively small inflow rate. After that, it flows over the first cylindrical wall 42 and flows into the turbofan 19.
When a part of the air flowing in from the four corners of the suction port 20 crosses the first cylindrical wall 42, the part of the air passes over the protruding portion 43 which is higher than the other portions, and at the same time, bypasses the right and left of the protruding portion 43. Get over the lower part.
Here, in the present embodiment, as shown in FIG. 7, the protruding portion 43 adopts a shape in which the protruding amount changes continuously. The configuration may be such that the amount of protrusion changes stepwise, but it is more preferable to make the change continuous, in order to reduce disturbance due to the shape of the protrusion 43 and reduce noise.
[0066]
According to the above configuration, a part of a large amount of air flowing from the four corners of the suction port 20 can be blocked by the first cylindrical wall 42 and can be wrapped around the four sides of the suction port 20. Therefore, the flow rate of the air flowing into the turbo fan 19 in the circumferential direction can be made uniform, and the flow velocity can be made uniform. As a result, it is possible to reduce a sound mainly composed of a component that is an integral multiple of the rotation frequency of the turbo fan 19, and reduce noise of the turbo fan 19.
[0067]
Further, when a part of the air flowing from the four corners of the suction port 20 crosses the first cylindrical wall 42, a part of the air further detours to the left and right of the protruding part 43 and crosses the low height part. Therefore, the influence of the air flowing from the four corners of the suction port 20 having a relatively large flow rate can be reduced, and the influence of the flow velocity can be reduced. As a result, it is possible to reduce a sound mainly composed of a component that is an integral multiple of the rotation frequency of the turbo fan 19, and reduce noise of the turbo fan 19.
[0068]
When a noise evaluation test was performed using the air conditioning indoor unit 41, a noise reduction effect of about 0.7 dBA was confirmed as compared with the conventional air conditioning indoor unit 110.
[0069]
8 and 9 are views showing a third embodiment of the present invention. The entire configuration is the same as that shown in FIGS. 1 to 5, the same components are denoted by the same reference numerals, and description thereof will be omitted.
8 and 9, the suction port 20 of the air conditioning indoor unit 51 includes a frame 20A forming an outer frame of the suction port 20, a grid portion 20B surrounded by the frame 20A and serving as a path through which air flows, and a grid. A filter unit 20C is provided on the upper surface of the unit 20B and removes dust and the like mixed in the inflowing air.
A second cylindrical wall (flow velocity equalizing means) 52 centering on the main shaft 25 is provided in the filter section 20C so that an upper end thereof protrudes into a space above the filter section 20C. At the upper end, a protruding portion 53 further protruding upward is provided centering on a line connecting the corner of the substantially square suction port 20 and the main shaft 25.
[0070]
In the air conditioning indoor unit 51 having the above configuration, as shown in FIG. 9, a part of a large amount of air (inflow from the four corners of the suction port 20) flows from the four corners of the suction port 20. Air flowing near the filter section 20C) is blocked by the second cylindrical wall 52 provided in the filter section 20C. The air blocked by the second cylindrical wall 52 circulates along the second cylindrical wall 52 to the four sides of the inlet 20 having a relatively small inflow rate. After that, it flows over the second cylindrical wall 52 and flows into the turbofan 19.
Further, when the air flowing in from the four corners of the suction port 20 crosses the second cylindrical wall 52, the air partially crosses the projection 53 higher than the other portions, and at the same time, detours to the left and right of the projection 53. Get over the lower part.
Here, in the present embodiment, as shown in FIG. 9, the protruding portion 53 adopts a shape in which the protruding amount changes continuously. The configuration may be such that the amount of protrusion changes stepwise, but it is more preferable to make the change continuous so as to reduce disturbance due to the shape of the protrusion 53 and reduce noise.
[0071]
According to the above configuration, a part of the large amount of air flowing from the four corners of the suction port 20 can be blocked by the second cylindrical wall 52 and can be wrapped around the four sides of the suction port 20. Therefore, the flow rate of the air flowing into the turbo fan 19 in the circumferential direction can be made uniform, and the flow velocity can be made uniform. As a result, it is possible to reduce a sound mainly composed of a component that is an integral multiple of the rotation frequency of the turbo fan 19, and reduce noise of the turbo fan 19.
[0072]
Further, when a part of the air flowing from the four corners of the suction port 20 crosses the second cylindrical wall 52, a part of the air further detours to the left and right of the protruding portion 53 and crosses the low height part. Therefore, the influence of the air flowing from the four corners of the suction port 20 having a relatively large flow rate can be reduced, and the influence of the flow velocity can be reduced. As a result, it is possible to reduce a sound mainly composed of a component that is an integral multiple of the rotation frequency of the turbo fan 19, and reduce noise of the turbo fan 19.
[0073]
In the above-described air conditioning indoor unit 51, the factor of noise reduction is the same as that of the air conditioning indoor unit 41, and therefore, similar to the air conditioning indoor unit 41, compared with the conventional air conditioning indoor unit 110, It is considered that a noise reduction effect of about 0.7 dBA is exhibited.
[0074]
FIGS. 10 to 12 are views showing a fourth embodiment of the present invention. The entire configuration is the same as that shown in FIGS. 1 to 5, the same components are denoted by the same reference numerals, and description thereof will be omitted.
In FIGS. 10 and 11, the flat plate portion 22A of the indoor heat exchanger 22 of the indoor unit 61 for air conditioning is located on the upstream side of the flow of the air blown out from the turbo fan 19 rather than the first corner portion 22B and the storage portion 32. A guide fence (rectifying means, plate material) 62 made of resin is provided. The guide fence 62 is provided so as to extend from the top plate 24 on the upper side and to the electrical box 31 on the lower side.
As shown in FIG. 12, the guide fence 62 includes a deflector plate 63 for changing the flow of air flowing along the flat plate portion 22A, and a deflector plate 63 with an interval L4 between the deflector plate 63 and the indoor heat exchanger 22. And a gripping portion 65 at the tip of the supporting portion 64 for gripping the indoor heat exchanger 22 with two claws.
[0075]
As shown in FIG. 11, the guide fence 62 is such that the drift plate 63 is inclined at approximately 45 ° in the rotation direction of the turbo fan 19 with respect to the vertical plane of the flat plate portion 22A, and the guide plate fence 62 and the turbo fan 19 The interval is set to be equal to or longer than the shortest interval between the flat plate portion 22A and the turbo fan 19.
[0076]
In the air-conditioning indoor unit 61 having the above configuration, as shown in FIG. 11, the air deflected from the turbo fan 19 radially outward in the rotation direction of the turbo fan 19 is sent out by the indoor heat. It collides obliquely with the flat part of the exchanger 22. Part of the air flows laterally along the plane portion 22A, and the rest passes through the plane portion 22A while exchanging heat with the refrigerant inside the plane portion 22A.
[0077]
As shown in FIGS. 11 and 12, a part of the air flowing along the plane portion 22A collides with the drift plate 63 at an angle close to 45 °. Since the colliding air collides with the drift plate 63 at an angle, the pressure does not increase so much and flows along the drift plate 63, so that the flow direction can be changed in the circumferential direction of the turbofan 19. The rest passes through the gap of the interval L4 between the plane portion 22A and the drift plate 63, collides with the first corner portion 22B at a substantially right angle, and passes through while exchanging heat. Alternatively, it collides with the storage part 32 at a substantially right angle, and further flows along the storage part 32.
The flow rate of the flow of the air colliding with the first corner portion 22B and the storage portion 32 is reduced by the guide fence 62, and the range of the formed pressure increasing portion is narrowed, and the pressure increasing amount is also reduced. The difference from the pressure on the inner peripheral surface of the heat exchanger 22 is reduced.
[0078]
As shown in FIG. 10, the air that has passed through the indoor heat exchanger 22 and has exchanged heat flows out from the outlet 23 into the room, and a portion of the air that has not passed through the indoor heat exchanger 22 is Due to the pressure difference between the pressure on the inner circumference of the heat exchanger 22 and the pressure on the upstream side of the blades 29, the heat is returned to the upstream of the blades 29 again through the first and second return channels R1 and R2.
[0079]
According to the above configuration, the guide fence 62 reduces unevenness of the pressure distribution in the inner periphery of the indoor heat exchanger 22. Therefore, the unevenness of the pressure difference between the pressure on the inner circumference of the indoor heat exchanger 22 and the pressure on the upstream side of the blade 29 is also reduced, and the heat is returned through the first return flow path R1 and the second return flow path R2. Non-uniformity in air flow rate and flow velocity is also reduced. As a result, it is possible to reduce a sound mainly composed of a component that is an integral multiple of the rotation frequency of the turbo fan 19, and reduce noise of the turbo fan 19.
[0080]
When a noise evaluation test was performed using the air conditioning indoor unit 61, a noise reduction effect of about 0.3 dBA was confirmed as compared with the conventional air conditioning indoor unit 110.
[0081]
In the above embodiment, the guide fence 62 is described as being made of resin. However, the present invention is not limited to the guide fence 62 made of resin. And a guide fence 71 made of sheet metal.
[0082]
The guide fence (rectifying means, plate material) 71 includes a drift plate 72 for changing the flow of air blown from the turbo fan 19, and a support portion for supporting the drift plate 72 with an interval L4 between the drift plate 72 and the indoor heat exchanger 22. 73, a holding portion 74 extending downward from the support portion 73 to clamp the indoor heat exchanger 22, a fixing portion 75 for screwing to the top plate 24, and a screw hole 76 are provided.
[0083]
In the above-described embodiment, the guide fence 62 has been described in conformity with the form in which the guide fences 62 are arranged one by one on the upstream side of the first corner 22B and the storage part 32. The present invention is not limited to the format in which the images are arranged one by one, and can be applied to a format in which a plurality of images are arranged such as two or three.
[0084]
Further, in the above-described embodiment, a description has been given of a case where the drift plate 63 of the guide fence 62 is arranged so as to be approximately 45 ° on the flat plate portion 22A. The present invention is not limited to the arrangement arranged so as to be as described above, and can be adapted to other arrangements arranged at various angles.
[0085]
Further, in the above-described embodiment, the description has been made in accordance with the configuration in which the drift plate 63 of the guide fence 62 is a flat plate, but the present invention is limited to the configuration in which the drift plate 63 is a flat plate. Instead, the drift plate 63 can be adapted to various forms such as a form in which the drift plate 63 is a curved plate having a curved surface curved toward the turbo fan 19 side.
[0086]
FIGS. 14 and 15 are views showing a fifth embodiment of the present invention. The entire configuration is the same as that shown in FIGS. 1 to 5, the same components are denoted by the same reference numerals, and description thereof will be omitted.
14 and 15, on the inner peripheral side of the indoor heat exchanger 22 of the indoor unit 81 for air conditioning, on the upstream side of the first corner portion 22B and the storage section 32, a small heat exchanger (rectifying means, heat The small heat exchanger 82 is provided so as to extend from the top plate 24 on the upper side and to the electrical box 31 on the lower side.
The small heat exchanger 82 is inclined by approximately 45 ° in the rotation direction of the turbo fan 19 with respect to the vertical plane of the flat plate portion 22A, and the distance between the small heat exchanger 82 and the turbo fan 19 is equal to the flat plate portion 22A and the turbo fan. 19 is arranged so as to be equal to or longer than the shortest interval with the number 19.
[0087]
In the air-conditioning indoor unit 81 having the above configuration, as shown in FIG. 15, a part of the air flowing along the plane portion 22A collides with the small heat exchanger 82 at an angle close to 45 °. Since a part of the colliding air collides with the small heat exchanger 82 at an angle, the pressure does not increase so much and flows along the small heat exchanger 82, and flows in the circumferential direction of the turbofan 19. You can change the direction. The rest passes through while exchanging heat with the small heat exchanger 82, collides with the first corner 22B at a substantially right angle, and passes through while exchanging heat. Alternatively, it collides with the storage part 32 at a substantially right angle, and further flows along the storage part 32.
The flow rate of the flow of the air colliding with the first corner portion 22B and the storage portion 32 is reduced by the small heat exchanger 82, and the range of the formed pressure increasing portion is reduced, and the amount of pressure increase is also reduced. Therefore, the difference from the pressure on the inner peripheral surface of the indoor heat exchanger 22 is reduced.
[0088]
According to the above configuration, the small heat exchanger 82 reduces unevenness of the pressure distribution on the inner periphery of the indoor heat exchanger 22. Therefore, the unevenness of the pressure difference between the pressure on the inner circumference of the indoor heat exchanger 22 and the pressure on the upstream side of the blade 29 is also reduced, and the heat is returned through the first return flow path R1 and the second return flow path R2. Non-uniformity in air flow rate and flow velocity is also reduced. As a result, it is possible to reduce a sound mainly composed of a component that is an integral multiple of the rotation frequency of the turbo fan 19, and reduce noise of the turbo fan 19.
[0089]
The addition of the small heat exchanger 82 increases the heat exchange area of the air conditioning indoor unit 81 as a whole, thereby increasing the amount of heat that can be exchanged with air, that is, improving the heat exchange capacity. Therefore, cooler or warmer air can be supplied to the room, and the flow rate of air flowing into and out of the air conditioning indoor unit 81 can be reduced accordingly. As a result, the rotation speed of the turbo fan 19 can be reduced, and the noise of the turbo fan 19 can be reduced.
[0090]
In the air conditioning indoor unit 81, the factor of noise reduction is the same as that of the air conditioning indoor unit 61. It is considered that a noise reduction effect of 0.3 dBA is exhibited.
[0091]
In the above-described embodiment, the small heat exchanger 82 has been described as being adapted to the form in which the small heat exchanger 82 is disposed at approximately 45 ° on the flat plate portion 22A. The present invention is not limited to the arrangement arranged as described above, and can be applied to other arrangements arranged at various angles.
[0092]
FIGS. 16 and 17 are views showing a sixth embodiment of the present invention. The entire configuration is the same as that shown in FIGS. 1 to 5, the same components are denoted by the same reference numerals, and description thereof will be omitted.
16 and 17, between the first corner portion 22B of the air conditioning indoor unit 91 and the turbofan 19, and between the storage portion 32 and the flat portion 22A and the turbofan 19, A rectifying vane (rectifying means, guide plate material) 92 is provided. The straightening vane 92 has a leading edge on the upstream side of the flow of the air blown from the turbofan 19 and a trailing edge on the downstream side. It is arranged so that it becomes.
[0093]
In the air-conditioning indoor unit 91 having the above configuration, as shown in FIG. 17, part of the air flowing along the plane portion 22 </ b> A flows around the rectifying wings 92. Of the flow around the rectifier blade 92, the flow of the rectifier blade 92 on the turbofan 19 side collides with the rectifier blade 92 at an angle and flows along the rectifier blade 92. The flow of the straightening vanes 92 on the side of the indoor heat exchanger 22 is pulled by a low-pressure portion formed on the back surface of the straightening vanes 92 and flows along the straightening vanes 92.
[0094]
The air flowing along the remaining plane portion 22A collides with the first corner portion 22B at a substantially right angle, and passes through while exchanging heat. Alternatively, it collides with the storage part 32 at a substantially right angle, and further flows along the storage part 32.
The flow rate of the flow of the air that collides with the first corner portion 22B and the storage portion 32 is reduced by the rectifying blades 92, and the range of the formed pressure increasing portion is narrowed, and the pressure increasing amount is also reduced. The difference from the pressure on the inner peripheral surface of the heat exchanger 22 is reduced.
[0095]
According to the above-described configuration, the pressure distribution in the inner periphery of the indoor heat exchanger 22 is reduced by the rectifying blades 92. Therefore, the unevenness of the pressure difference between the pressure on the inner circumference of the indoor heat exchanger 22 and the pressure on the upstream side of the blade 29 is also reduced, and the heat is returned through the first return flow path R1 and the second return flow path R2. Non-uniformity in air flow rate and flow velocity is also reduced. As a result, it is possible to reduce a sound mainly composed of a component that is an integral multiple of the rotation frequency of the turbo fan 19, and reduce noise of the turbo fan 19.
[0096]
In the above-described air conditioning indoor unit 91, the factor of noise reduction is the same as that of the air conditioning indoor unit 61, and therefore, similar to the air conditioning indoor unit 61, compared to the conventional air conditioning indoor unit 110, It is considered that a noise reduction effect of 0.3 dBA is exhibited.
[0097]
In the above-described embodiment, the rectifying wings 92 have been described as being applied to the first corner portion 22B and the storage portion 32 one by one. The present invention is not limited to such a format, and can be applied to a format in which a plurality of sheets are arranged, such as two or three sheets.
[0098]
Further, in the above-described embodiment, the description has been given by adapting to the type using the wing-shaped rectifying wings 92. However, the present invention is not limited to the type using the wing-shaped rectifying wings 92, and may be a type using a curved curved plate. It can be adapted to various formats.
[0099]
In the first to sixth embodiments, the upper and lower diffusers 33 and 35, the first cylindrical wall 42, and the like have been individually described. The present invention is not limited to this, and can be applied by combining at least two such as combining at least the upper and lower diffusers 33 and 35 and the first cylindrical wall 42.
[0100]
【The invention's effect】
As described above, according to the first aspect of the invention, even if the rotation speed of the fan is reduced, the conventional air flow rate can be secured, and the rotation speed of the fan can be reduced. Therefore, the noise generated from the fan can be reduced, and the noise of the fan can be reduced.
[0101]
According to the invention according to claim 2, the air blown out from the fan adheres to and flows on the first inclined surface of the flow path enlarging member provided in a substantially annular shape above the main plate. The pressure loss is reduced, and the rotation speed of the fan can be reduced. Therefore, the noise generated from the fan can be reduced, and the noise of the fan can be reduced.
[0102]
According to the invention according to claim 3, the air blown out from the fan adheres to and flows on the second inclined surface of the flow path expanding member provided substantially annularly below the shroud. The pressure loss is reduced, and the rotation speed of the fan can be reduced. Therefore, the noise generated from the fan can be reduced, and the noise of the fan can be reduced.
[0103]
According to the invention according to claim 4, since the flow velocity of the air flowing into the fan can be made uniform, it is possible to reduce the sound mainly composed of an integral multiple of the rotation frequency of the fan. Therefore, there is an effect that noise of the fan can be reduced.
[0104]
According to the invention according to claim 5, since the first cylindrical wall is provided on the lower surface of the bell mouth, the flow velocity of the air flowing into the blade can be made uniform, and the flow velocity of the air flowing into the blade can be reduced. It can be uniform. Therefore, it is possible to reduce a sound mainly composed of an integral multiple of the rotation frequency of the fan, thereby reducing the noise of the fan.
[0105]
According to the invention according to claim 6, since the suction port is provided with the second cylindrical wall, the flow velocity of the air flowing into the blade can be made uniform, and the flow velocity of the air flowing into the blade can be made uniform. can do. Therefore, it is possible to reduce a sound mainly composed of an integral multiple of the rotation frequency of the fan, thereby reducing the noise of the fan.
[0106]
According to the invention according to claim 7, it is possible to narrow the range of the region where the pressure rises inside the indoor heat exchanger and reduce the degree of the pressure rise, so that the upstream of the fan is provided. The flow velocity of the air returning to the side can be made uniform. Therefore, it is possible to reduce a sound mainly composed of an integral multiple of the rotation frequency of the fan, thereby reducing the noise of the fan.
[0107]
According to the invention according to claim 8, the plate member is disposed upstream of the collision portion, and is disposed so as to be inclined in a rotation direction of the fan toward a downstream direction of the air flow. The collision between the air ejected from the fan and the collision portion can be avoided. Therefore, the range of the region where the pressure increases inside the indoor heat exchanger can be narrowed, and the degree of the pressure increase can be reduced, so that the flow velocity of the air circulating upstream to the fan is reduced. It can be uniform. As a result, it is possible to reduce a sound mainly composed of an integral multiple of the rotation frequency of the fan, thereby reducing the noise of the fan.
[0108]
According to the ninth aspect of the present invention, the heat exchanger is disposed upstream of the collision portion, and is disposed so as to be inclined in the rotation direction of the fan toward a downstream direction of the air flow. Thus, it is possible to avoid collision between the air ejected from the fan and the collision portion. Therefore, the range of the region where the pressure increases inside the indoor heat exchanger can be narrowed, and the degree of the pressure increase can be reduced, so that the flow velocity of the air circulating upstream to the fan is reduced. It can be uniform. As a result, it is possible to reduce a sound mainly composed of an integral multiple of the rotation frequency of the fan, thereby reducing the noise of the fan.
[0109]
According to the invention according to claim 10, since the guide plate member is arranged upstream of the collision portion and is arranged to guide the flow of air in the rotation direction of the fan, air ejected from the fan is provided. Collision with the collision portion can be avoided. Therefore, the range of the region where the pressure increases inside the indoor heat exchanger can be narrowed, and the degree of the pressure increase can be reduced, so that the flow velocity of the air circulating upstream to the fan is reduced. It can be uniform. As a result, it is possible to reduce a sound mainly composed of an integral multiple of the rotation frequency of the fan, thereby reducing the noise of the fan.
[0110]
According to the eleventh aspect, at least two or more of the flow path enlarging member according to the first aspect, the flow velocity uniformizing means according to the fourth aspect, and the rectifying means according to the seventh aspect are provided. Since the fan is provided in combination, the noise of the fan can be further reduced.
[0111]
According to the twelfth aspect of the present invention, the flow path enlarging member according to the second and third aspects, the flow velocity uniformizing means according to the fifth and sixth aspects, and the rectifying means according to the eighth to tenth aspects. Since at least two are provided in combination, there is an effect that the noise of the fan can be further reduced.
[0112]
According to the invention according to claim 13, the fan which can reduce the number of revolutions of the fan to reduce noise generated from the fan or has a non-uniform flow velocity in the circumferential direction of the fan The flow of the air returning to the upstream side can be made uniform, and its influence can be reduced. Therefore, it is possible to reduce a sound mainly composed of an integral multiple of the rotation frequency of the fan, reduce the noise of the fan, and reduce the noise of the entire ceiling-mounted air conditioner. Therefore, a comfortable indoor space can be provided to the user.
[Brief description of the drawings]
FIG. 1 is a perspective sectional view showing a first embodiment of an embedded ceiling air conditioner according to the present invention.
FIG. 2 is a sectional view showing a first embodiment of an indoor unit for air conditioning according to the present invention.
FIG. 3 is a sectional view of a main part showing a first embodiment of an indoor unit for air conditioning according to the present invention.
FIG. 4 is a vector diagram showing an air flow in the first embodiment of the air conditioning indoor unit according to the present invention.
FIG. 5 is a pressure distribution diagram showing air pressure in the first embodiment of the air conditioning indoor unit according to the present invention.
FIG. 6 is a sectional view showing a second embodiment of the indoor unit for air conditioning according to the present invention.
FIG. 7 is a perspective view of an essential part showing a second embodiment of the indoor unit for air conditioning according to the present invention.
FIG. 8 is a sectional view showing a third embodiment of the air conditioning indoor unit according to the present invention.
FIG. 9 is a main part view showing a third embodiment of the indoor unit for air conditioning according to the present invention.
FIG. 10 is a sectional view showing a fourth embodiment of an indoor unit for air conditioning according to the present invention.
FIG. 11 is a bottom view of an essential part showing a fourth embodiment of an indoor unit for air conditioning according to the present invention.
FIG. 12 is a perspective view of a main part showing a fourth embodiment of the indoor unit for air conditioning according to the present invention.
FIG. 13 is a perspective view of a main part showing another embodiment of the fourth embodiment of the indoor unit for air conditioning according to the present invention.
FIG. 14 is a sectional view showing a fifth embodiment of the air conditioning indoor unit according to the present invention.
FIG. 15 is a bottom view of an essential part showing a fifth embodiment of the indoor unit for air conditioning according to the present invention.
FIG. 16 is a sectional view showing a sixth embodiment of the air conditioning indoor unit according to the present invention.
FIG. 17 is a main part bottom view showing a sixth embodiment of the indoor unit for air conditioning according to the present invention.
FIG. 18 is a sectional view showing an example of a conventional air conditioning indoor unit.
FIG. 19 is a sectional view of a main part showing an example of a conventional air conditioning indoor unit.
FIG. 20 is a perspective view of a main part showing an example of a conventional air conditioning indoor unit.
[Explanation of symbols]
10 Ceiling embedded air conditioner
11, 41, 51, 61, 81, 91 Indoor unit for air conditioning
17 Casing
18 Motor (drive unit)
19 Turbo fan (fan)
20 Suction port
21 Bellmouth
22 Indoor heat exchanger
24 Top plate
26 Main plate
27 Shroud
29 feather
22B First corner (collision part)
32 storage part (collision part)
33 Upper diffuser (channel expansion member)
34 First slope
35 Lower diffuser (flow channel expansion member)
36 Second slope
42 First cylindrical wall (flow velocity equalizing means)
52 Second cylindrical wall (flow velocity equalizing means)
62, 71 Guide fence (rectification means, plate material)
82 Small heat exchanger (rectifier, heat exchanger)
92 Rectifier blade (rectifier means, guide plate material)

Claims (13)

A driving unit fixed to a top plate of the casing, a fan driven by the driving unit and pressurized and sends out the air sucked from the suction port into a casing having a suction port through which the air flows, In an air conditioning indoor unit provided with an indoor heat exchanger that heats or cools the sent air, a flow path expansion that gently expands the flow of air blown from the fan toward the indoor heat exchanger. An air conditioning indoor unit comprising a member. The indoor unit for air conditioning according to claim 1,
The fan includes a main plate provided to face the top plate, a shroud provided at a position facing the main plate, and a blade disposed between the main plate and the shroud.
The flow path expanding member,
It is provided in a substantially annular shape above the main plate,
At least outside the outer edge of the fan, a first inclined surface that guides a flow along a lower surface of the main plate toward a radially outward direction toward the top plate of the casing, for air conditioning, Indoor unit. The indoor unit for air conditioning according to claim 1,
A bell mouth is provided below the fan to guide air from the suction port to the fan,
The fan includes a main plate provided to face the top plate, a shroud provided at a position facing the main plate, and a blade disposed between the main plate and the shroud.
The flow path expanding member,
It is provided substantially annularly below the shroud,
An indoor unit for air conditioning, comprising: a second inclined surface that guides a flow along an upper surface of the shroud toward the bell mouth at least radially outward from an outer edge of the fan. In a casing having a suction port through which air flows, a driving unit fixed to a top plate of the casing, a fan driven by the driving unit, and pressurizing and sending out the air sucked from the suction port, and a fan An indoor heat exchanger for heating or cooling the sent air is provided,
An air-conditioning indoor unit including: a main plate provided so that the fan faces the top plate; a shroud provided at a position facing the main plate; and blades arranged between the main plate and the shroud. At
An air-conditioning indoor unit, further comprising a flow velocity equalizing means below the fan for uniformizing a flow velocity distribution of air flowing into the blade in a rotation direction of the blade. The indoor unit for air conditioning according to claim 4,
A bell mouth is provided below the fan to guide air from the suction port to the fan,
The air-conditioning indoor unit, wherein the flow velocity equalizing means includes a first cylindrical wall for temporarily blocking air flowing into the blade on a lower surface of the bell mouth. The indoor unit for air conditioning according to claim 4,
The air-conditioning indoor unit, wherein the flow velocity equalizing means includes, at the suction port, a second cylindrical wall for temporarily blocking air flowing into the blade. A drive unit fixed to a top plate of the casing, a fan driven by the drive unit, and pressurized and sends out the air sucked from the suction port into a casing having a suction port through which air flows, and a fan An indoor heat exchanger for heating or cooling the sent air is provided,
Part of the air sent out by the fan passes through the casing and returns to the upstream side of the fan,
In the air conditioning indoor unit, the indoor heat exchanger includes a collision portion that collides substantially perpendicularly with the air sent from the fan,
An air-conditioning indoor unit, comprising: a rectification unit that guides at least a part of the flow of the colliding air in a direction other than the collision portion. The indoor unit for air conditioning according to claim 7,
The rectifying means includes a plate upstream of the collision portion,
The air-conditioning indoor unit, wherein the plate member is disposed so as to be inclined in a rotation direction of the fan toward a downstream direction of an air flow. The indoor unit for air conditioning according to claim 7,
The rectification unit includes a heat exchanger upstream of the collision unit,
The air conditioning indoor unit, wherein the heat exchanger is disposed so as to be inclined in a rotation direction of the fan toward a downstream direction of an air flow. The indoor unit for air conditioning according to claim 7,
The rectifying means includes a guide plate having a curved surface on an upstream side of the collision portion,
The indoor unit for air conditioning, wherein the guide plate guides a flow of air colliding with the collision portion in a rotation direction of the fan. A driving unit fixed to a top plate of the casing, a fan driven by the driving unit and pressurizing and sending out the air sucked from the suction port into a casing having a suction port through which air flows, and a fan In the air-conditioning indoor unit provided with an indoor heat exchanger for heating or cooling the sent air,
An air conditioner comprising a combination of at least two of the flow path expanding member according to claim 1, the flow velocity uniformizing means according to claim 4, and the rectifying means according to claim 7. Indoor unit. A driving unit fixed to a top plate of the casing, a fan driven by the driving unit and pressurizing and sending out the air sucked from the suction port into a casing having a suction port through which air flows, and a fan In the air-conditioning indoor unit provided with an indoor heat exchanger for heating or cooling the sent air,
A combination of at least two of the flow path expanding member according to claims 2 and 3, the flow velocity equalizing means according to claims 5 and 6, and the rectifying means according to claims 8 to 10. An indoor unit for air conditioning characterized by the following. An air conditioning indoor unit according to any one of claims 1 to 12,
A compressor that compresses the refrigerant, and an air conditioning outdoor unit having an outdoor heat exchanger that performs heat exchange between the refrigerant and outdoor air,
An embedded ceiling type, comprising a refrigerant pipe for connecting the air-conditioning indoor unit and the air-conditioning outdoor unit, and for circulating a refrigerant between the air-conditioning indoor unit and the air-conditioning indoor unit. Air conditioner.

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