This application is a U.S. national stage application of PCT/JP2014/078891 filed on Oct. 30, 2014, the disclosure of which is incorporated herein by reference.
The present invention relates to an air-conditioning device.
The air-conditioning device disclosed in PTL 1 has a heat exchanger and a blower fan provided inside a main body. The heat exchanger has a rearward inclined section disposed in the rear part of the main body, and a downward inclined section that is inclined downwards so to fold back from the upper end of the rearward inclined section. The main body of the air-conditioning device is formed in a thin shape having a depth dimension that is greater than the height dimension.
Furthermore, in the air-conditioning device disclosed in PTL 2, an upper surface section of a main body is a flat surface that is substantially parallel with a ceiling surface, a bottom surface section of the main body rises up from a rear surface side towards a front surface side, and a main body is formed in a thin shape having a depth dimension that is greater than the height dimension.
[PTL 1] Japanese Patent Application Laid-Open No. 2001-201077
[PTL 2] Japanese Patent Application Laid-Open No. H5-99454
If the main body of the air-conditioning device is formed in a thin shape of which the depth dimension is greater than the height dimension, as described above, then a merit is obtained in that no sense of incongruity is produced in the indoor interior and the installation surface area on a wall surface can be suppressed.
On the other hand, by adopting a thin shape in the height direction, there are the following problems.
Firstly, in the air-conditioning device of PTL 1 described above, the heat exchanger and fan are in close proximity on the fan inlet side, the fan inlet region is small, and the air is not readily taken in in a uniform manner. Therefore, if the fan output flow is instable, and the air flow resistance has increased due to the adherence of dust, etc. to the filter, or if the air flow resistance on the fan inlet side has increased due to the generation of condensed water in the heat exchanger during cooling, then there is a problem in that back flow of air occurs from the main body outlet port towards the fan, and there is a risk of condensation occurring on the fan and being scattered into the room, especially during cooling.
Furthermore, in the air-conditioning device according to PTL 2 described above, since the distance between the main body outlet port and the outer periphery of the fan is small on the fan outlet side, then as described above, there is a problem in that the fan blow output flow becomes instable and back flow occurs when the flow resistance has increased, and there is a risk of condensation occurring on the fan and being scattered into the room, especially during cooling.
The present invention was devised in view of the foregoing, an object thereof being to provide an air-conditioning device wherein back flow at the outlet port is not liable to occur in relation to the inlet resistance.
In order to achieve the object described above, the air-conditioning device according to the present invention is provided with: a main body having an inlet port and an outlet port; a cross-flow fan provided inside the main body; and a heat exchanger provided in the main body, wherein the main body includes a front surface, a rear surface, an upper surface and a lower surface, the inlet port is formed in the upper surface, a ratio H/Df between the main body height dimension H and the fan outer diameter Df is 2.2 to 2.7, and the angle of inclination β between a rear part of an front upward inclination section of the heat exchanger and a vertical direction is 30° to 45°.
According to the present invention, it is possible to provide an air-conditioning device wherein back flow is not liable to occur at the outlet port in relation to the inlet resistance.
Below, embodiments of an air-conditioning device (indoor unit) according to the present invention are described with reference to the drawings. Sections which are the same or corresponding below are labelled with the same reference numerals. Furthermore, an existing unit can be used for the outdoor unit.
As illustrated in
Furthermore, the air-conditioning device according to the present invention is an air-conditioning device which is not a so-called ceiling embedded-type device, but rather the rear surface of the main body abuts against or is in close proximity to a wall surface demarcating the space that is to be air-conditioned (a wall apart from the ceiling or floor), and the front surface of the main body faces the side of the space to be air-conditioned. In other words, in the air-conditioning device according to the present invention, the inlet port and the outlet port are not provided on the same surface, as in a ceiling embedded-type device, and are disposed alongside a wall surface that demarcates the space to be air-conditioned, away from the central portion of the space to be air-conditioned.
The main body 1 is, in general terms, a cuboid-shaped casing. More specifically, the main body 1 includes a rear surface 1c that opposes a wall 11a of the room 11, a front surface 1a which is on the opposite side to the rear surface 1c, an upper surface 1b, a lower surface 1d, and a left and right-hand pair of side surfaces 1e.
A grille-shaped inlet port 2b for taking indoor air into the air-conditioning device 100 is formed in the upper surface 1b of the main body 1. In the air-conditioning device 100, the inlet port is only provided on the upper surface 1b of the main body 1. An outlet port 3 for supplying conditioned air to the room is formed in a front part of the lower surface 1d of the main body 1. A front surface grille 6 is attached to the front surface 1a of the main body 1.
A cross-flow fan 8 having an impeller 8a, and a guide wall 10, is disposed inside the main body 1. The cross-flow fan 8 is disposed between the inlet-side flow channel (fan inlet-side region) E1 and the outlet-side flow channel (fan outlet-side region) E2, and air is taken in from the inlet port 2b and air is blown out to the outlet port 3. The guide wall 10 extends downwards from the rear of the cross-flow fan 8, and guides the air radiating from the cross-flow fan 8 to the outlet port 3.
The impeller 8a of the cross-flow fan 8 is configured by coupling together a plurality of impeller unit bodies 8d, which are described hereinafter. The impeller unit bodies 8d include a plurality blades 8c and a ring 8b which is fixed to the end portions of the blades 8c. More specifically, the impeller 8a is formed by coupling and integrating, by welding, a plurality of impeller unit bodies 8d, each of which is composed by a plurality of blades 8c extending in a substantially perpendicular direction from an outer peripheral side surface of a circular disk-shaped ring 8b, the blades 8c being disposed continuously at prescribed intervals apart in the circumferential direction of the ring 8b.
Moreover, a filter (air flow resistance body) 5 which removes dust, etc. from the air taken into via the inlet port 2b, a heat exchanger (air flow resistance body) 7 which generates conditioned air by transmitting the heating energy or cooling energy of a refrigerant to the air, and a stabilizer 9 which demarcates an inlet-side flow channel E1 and an outlet-side flow channel E2, are disposed inside the main body 1.
The guide wall 10 configures an outlet-side flow channel E2, in conjunction with a diffuser 3a which is formed on the lower surface of the stabilizer 9. In other words, the front surface 1a side of the main body 1 in the outlet-side flow channel is demarcated by the diffuser 3a, the rear surface 1c side of the main body 1 in the outlet-side flow channel is demarcated by the guide wall 10, and the outlet-side flow channel is configured by the diffuser 3a and the guide wall 10 which are mutually opposing. The guide wall 10 forms a vortex surface from the cross-flow fan 8 to the outlet port 3.
The filter 5 is formed in a mesh-shape, for instance, and removes dust, etc. in the air that is taken in via the inlet port 2b. The filter 5 is provided on the upstream side of the heat exchanger 7, and to the downstream side of the inlet port 2b, in the flow channel from the inlet port 2b to the outlet port 3. Furthermore, the filter 5 extends from the top to the front of the heat exchanger 7.
The heat exchanger 7 (indoor heat exchanger) functions as an evaporator and cools the air during a cooling operation, and functions as a condenser (heat radiator) and heats the air during a heating operation. This heat exchanger 7 is provided to the downstream side of the filter 5 and to the upstream side of the cross-flow fan 8 in the flow channel from the inlet port 2b to the outlet port 3 (the central portion of the interior of the main body 1).
The heat exchanger 7 has a shape that surrounds the front part and upper part of the cross-flow fan 8. The heat exchanger 7 includes a heat exchanger front part 7a. The heat exchanger front part 7a extends over the front and upper part of the cross-flow fan 8. Furthermore, the heat exchanger front part 7a includes a front upward inclination section 7a′, the lower part of which is inclined to be positioned further forward (so as to approach the front surface 1a).
A sealing member 7c which functions as a partition wall is provided at the rear of the cross-flow fan 8 and at the rear of the guide wall 10. The sealing member 7c extends from the upper end of the heat exchanger front part 7a towards the rear surface side of the guide wall 10. For example, the sealing member 7c is configured by a box-shaped member that constitutes the outer profile shape of the heat exchanger.
The heat exchanger 7 is connected to an outdoor unit, which may adopt a well-known mode including a compressor, an outer heat exchanger, and a restrictor device, etc., thereby forming a cooling cycle. Furthermore, a cross-fin type fin-and-tube heat exchanger, which is constituted by a heat conduction pipe and a plurality of fins, for example, is used in the heat exchanger 7.
A vertical air flow direction vane 4a and a lateral air flow direction vane 4b are provided in the outlet-side flow channel. The lateral air flow direction vane 4b is provided rotatably between the vertical air flow direction vane 4a and the cross-flow fan 8. The vertical air flow direction vane 4a adjusts the vertical direction of the air flow blown out from the cross-flow fan 8, and the lateral air flow direction vane 4b adjusts the lateral direction of the air flow blown out from the cross-flow fan 8. The vertical air flow direction vane 4a and the lateral air flow direction vane 4b are driven to rotation in mutually independent fashion.
The vertical air flow direction vane 4a has a projecting shape in which the upper surface and the lower surface of the vertical air flow direction vane 4a both project downwards when viewed in the attitude thereof during a horizontal blowing operation.
The stabilizer 9 demarcates the inlet-side flow channel E1 and the outlet-side flow channel E2, in the manner described above, and is provided on the lower side of the heat exchanger 7 as illustrated in
The stabilizer 9 includes a tongue section 9a, a drain pan 9b which temporarily accumulates water droplets that drip down from the heat exchanger 7, and a diffuser 3a. The tongue section 9a is positioned at the front end portion of the stabilizer 9 and faces the cross-flow fan 8. The diffuser 3a is formed on the lower surface of the stabilizer 9, as described above, and functions as an upper wall surface (front surface-side wall surface) of the outlet-side flow channel of the outlet port 3.
As illustrated in
Furthermore, the upstream section 3a1 of the diffuser 3a has a linear portion when viewed from the side. When the direction of extension of the linear portion of the upstream section 3a1 of the diffuser 3a, as viewed from the lateral side as illustrated in
Furthermore, the downstream section 3a2 of the diffuser 3a has a linear portion when viewed from the side. When the direction of extension of the linear portion of the downstream section 3a2 of the diffuser 3a is the downstream section virtual straight line S2, then the downstream section virtual straight line S2 is situated below the upstream section virtual straight line S1. The diffuser 3a is curved or bent in the portion 3a3 which is positioned between the upstream section 3a1 and the downstream section 3a2 of the diffuser 3a.
In the first embodiment, the depth dimension D of the main body is greater than the main body height dimension H. The depth dimension D of the main body is the maximum value of the interval between the front surface 1a and the rear surface 1c of the main body 1, and the main body height dimension H is the maximum value of the interval between the upper surface 1b and the lower surface 1d of the main body 1. Furthermore, the ratio H/Df between the main body height dimension H and the fan outer diameter Df=2.2 to 2.7. Moreover, the angle of inclination β between the rear part of the front upward inclination section 7a′ of the heat exchanger front part 7a of the heat exchanger 7, and the vertical direction, is 30° to 45°. This angle of inclination β is an angle which broadens in the forward and downward directions, with respect to the point of intersection of a line indicating the vertical direction and the rear part of the front upward inclination section 7a′ (in the example in
By adopting a configuration of this kind, actions of the following kind are obtained. Firstly, if the outer diameter of the fan is too large, then the fan and the heat exchanger are too close to each other on the fan inlet side, the air flow after passing through the heat exchanger cannot readily reach the upstream end of the guide wall, and furthermore, due to the short distance between the outlet port and the fan on the fan outlet side, a low-speed region occurs on the side of the guide wall and there is a risk of back flow from the outlet port. Furthermore, since the air flows in with an uneven distribution, then the loss increases and the power consumption of the motor increases. On the other hand, if the outer diameter of the fan is too small, then it is necessary to raise the rotational speed in order to obtain the required air flow volume, and therefore the output consumption of the motor increases and energy efficiency is poor.
On the other hand, in the first embodiment, since the depth dimension of the main body is greater than the height dimension of the main body, then the main body is thin in the height direction, the distance between the upper surface 1b of the main body 1 and the ceiling surface (not illustrated) and the distance between the lower surface 1d of the main body 1 and the curtain rail (not illustrated) is increased, and it is possible to suppress increase in the resistance to the air flow when installed. Furthermore, even if the heat exchanger, which has received a hydrophilic treatment, loses hydrophilic properties due to the effects of water-repellent materials in the room, the condensed water generated by the heat exchanger does not drip down onto the fan. Moreover, high-density installation of the heat exchanger is possible, the heat exchange volume can be increased, and high performance can be achieved.
Furthermore,
Furthermore,
From the foregoing, provided that at least H/Df=2.2 to 2.7 and β=30° to 45°, back flow at the outlet port is not liable to occur in relation to the inlet resistance, and an air-conditioning device having high quality and good energy efficiency can be obtained.
Furthermore, in the first embodiment, the upper end (rear end) 7d of the heat exchanger front part 7a is situated at a position further toward the front side than the rotation centre O of the fan, in other words, at a position closer to the front surface 1a of the main body 1 than the rotation centre O of the fan in a front/rear direction. Moreover, when the height difference from the upper end 7d of the heat exchanger front part 7a to the outer circumference end of the fan (the uppermost part of the rotational trajectory of the outer circumference end of the fan) is the minimum height H1, and the front/rear distance (horizontal distance) from the upper end 7d of the heat exchanger front part 7a to the guide wall start end (uppermost part) 10b is the front/rear distance Dg, then the ratio H1/Dg between the minimum height H1 and the front/rear distance Dg is 1.1 to 1.4.
By adopting a configuration of this kind, actions of the following kind are obtained. Firstly, if the upper end of the heat exchanger front part is positioned further toward the front side than the rotation centre of the fan, then there is a problem in that the air flow cannot readily reach the guide wall. Furthermore, if the minimum height H1 is too large in relation to Dg, then in a configuration where there is no heat exchanger on the rear side of the cross-flow fan (as illustrated in
On the other hand, in the first embodiment, the upper end 7d of the heat exchanger front part 7a and the start end 10b of the guide wall are provided so as to satisfy the conditions described above, and therefore a stable flow of air is also obtained in the guide wall side region of the fan inlet-side region, the abovementioned problems do not occur and an air-conditioning device of high quality can be achieved.
Furthermore, in the first embodiment, the ratio H1/Df between the minimum height H1 and the fan outer diameter Df is 0.5 to 0.7.
By adopting a configuration of this kind, actions of the following kind are obtained. Firstly, if the minimum height is too small with respect to the outer diameter of the fan, the flow from the upper end of the heat exchanger front part cannot readily reach the guide wall, and in particular in a configuration where there is no heat exchanger on the rear side of the cross-flow fan, the flow becomes instable in the guide wall-side region of the fan inlet-side region, and the air ceases to flow to the guide wall surface of the fan inlet-side region. Therefore, if the air flow resistance is increased due to the accumulation of dust in the filter, or if the air flow resistance is increased due to the adherence of condensed water in the heat exchanger during heating, there is a risk of back flow occurring in the outer part of the main body. Therefore, the quality of the air-conditioning device declines.
On the other hand, in the first embodiment, since the ratio H1/Df between the minimum height H1 and the fan outer diameter Df is 0.5 to 0.7, then the behaviour of the air flow is not liable to become worse even if an air flow resistance is applied, and the quality of the air-conditioning device can be guaranteed.
Furthermore, in the first embodiment, when the position where the distance between the cross-flow fan 8 and the tongue section 9a of the stabilizer 9 is smallest, viewed from the lateral side, is the minimum gap position 9c of the tongue section 9a, the virtual straight line linking the minimum gap position 9c and the rotation centre O of the fan is a straight line X1, the virtual straight line linking the rotation centre O of the fan and the guide wall start end 10b is a straight line X2, and the angle occurring in the fan inlet-side region E1, of the angle formed between the straight line X1 and the straight line X2, is the fan inlet angle γ, then this fan inlet angle γ is 150° to 180°. Moreover, the outlet port 3 is open in the front part of the lower surface 1d of the main body 1, and the diffuser 3a has a portion which, in lateral side view, separates from the upstream section virtual straight line S1, which is the direction of extension of the upstream section 3a1 of the diffuser 3a, towards the downstream side of the diffuser 3a.
By adopting a configuration of this kind, following actions can be obtained. Noise from the fan which is reflected at the guide wall is reflected towards the lower part of the main body by the wall surface of the diffuser to the downstream side of the fan, thereby suppressing the radiation of noise to the front surface side of the air-conditioning device and achieving silent operation. Furthermore, since the wall surface flow accelerates in the downstream portion of the diffuser, then it is possible to inhibit back flow from the inlet port to the fan that occurs due to increase in the air flow resistance caused by accumulation of dust in the filter provided on the inlet side, and therefore hot air of high humidity does not flow back inside the air-conditioning device during cooling, not resulting in causing condensation, and therefore quality is improved. Moreover, if the fan inlet angle γ is too large, then the inlet range becomes too large, the flow is biased towards the side of the circulating vortex, which is a characteristic feature of cross-flow fans and which forms on the tongue section side of the interior of the impeller, and the flow cannot readily reach the guide wall and becomes instable, whereas in the first embodiment, as illustrated in
Furthermore, in the first embodiment, the angle α between the upstream section virtual straight line S1 and the downstream section virtual straight line S2 is desirably 5° to 40°.
Furthermore, one characteristic feature of the first embodiment is that it is possible to combine specifications wherein the heat exchanger front part 7a and the sealing member 7c are arranged about the periphery of the cross-flow fan 8, and specifications wherein the heat exchanger front part 7a and the heat exchanger rear part 7b are arranged about the periphery of the cross-flow fan 8.
The heat exchanger rear part 7b functions as one portion of the heat exchanger 7, similarly to the heat exchanger front part 7a. In other words, in specifications where the heat exchanger front part 7a and the heat exchanger rear part 7b are disposed about the periphery of the cross-flow fan 8, the heat exchanger 7 is configured by the heat exchanger front part 7a and the heat exchanger rear part 7b, and the heat exchanger 7 has a shape which surrounds the front part, upper part and rear part of the cross-flow fan 8.
The heat exchanger rear part 7b extends over the upper part and rear part of the cross-flow fan 8. Furthermore, the heat exchanger rear part 7b includes a rear upward inclination section 7b′, the lower part of which is inclined to be positioned further rearward (so as to approach the rear surface 1c).
Moreover, similarly to the case of the front upward inclination section 7a′ described above, the rear upward inclination section 7b′ has an angle of inclination β. In other words, the angle of inclination β between the vertical direction and the front part of the rear upward inclination section 7b′ of the heat exchanger rear part 7b is the same as the angle of inclination β between the vertical direction and the rear part of the front upward inclination section 7a′ of the heat exchanger front part 7a. To give a specific example, the angle of inclination β between the vertical direction and the front part of the rear upward inclination section 7b′ of the heat exchanger rear part 7b and the angle of inclination β between the vertical direction and the rear part of the front upward inclination section 7a′ of the heat exchanger front part 7a are both 30° to 45°.
By adopting a configuration of this kind, it is possible to meet the required heat exchanger capability in the main body, by modifying the capacity of the heat exchanger, while using the same air flow channels, and therefore it is possible to avoid excessive installation of heat exchangers, thus preventing waste of materials, saving resources and reducing the weight of the main body.
The contents of the present invention have been described above with reference to preferred embodiments, but it would be obvious to a person skilled in the art that various modifications can be made on the basis of the basic technical concepts and teachings of the present invention.
Filing Document | Filing Date | Country | Kind |
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PCT/JP2014/078891 | 10/30/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/067408 | 5/6/2016 | WO | A |
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