BIDIRECTIONAL-BLOW-OUT, CEILING-EMBEDDED AIR CONDITIONER

Description

TECHNICAL FIELD

[0001] The present invention relates to a two-way ceiling-mounted air conditioner, specifically to a configuration of a heat exchanger.

BACKGROUND ART

[0002] Known conventional types of ceiling-mounted air conditioners include four-way and two-way (double flow type) air conditioners. Four-way air conditioners are provided with a decorative panel installed on a ceiling surface and outlets formed in the decorative panel along its four sides. Two-way air conditioners are provided with outlets in a decorative panel along its two opposite sides. For a two-way ceiling-mounted air conditioner to achieve harmony with the design of a room, the decorative panel has a rectangular shape in a planar view and the indoor outlets are placed along the long sides of the rectangular shape in many cases.

[0003] A conventional example of such a two-way ceiling-mounted air conditioner is disclosed in Patent Document 1. This conventional example will now be described with reference to Fig. 9. As illustrated in Fig. 9, the air conditioner includes a rectangular-parallelepiped-shaped product main body 101 having a rectangular shape in a planar view, and a heat exchanger 102 and a turbo fan 103 accommodated in the product main body 101. The heat exchanger 102 is typically made up of two branch heat exchangers 104. The two branch heat exchangers 104 are each located inside a side wall extending in a longitudinal direction of the product main body 101. The turbo fan 103 is located between the two branch heat exchangers 104. The turbo fan 103 is arranged substantially on a center line 105 extending in the longitudinal direction of the product main body 101. The two branch heat exchangers 104 are bent at an obtuse angle at the middle of the product main body 101 in the longitudinal direction in a planar view. The two obtuse-angle bends face each other across the center line 105. By bending the heat exchanger 102 in this manner, the total longitudinal lengths of the branch heat exchangers 104 are increased, leading to an increase in heat exchange area of the heat exchanger 102.

PRIOR ART DOCUMENTS

Patent Document

[0004] Patent Document 1: Japanese Laid-Open Patent Publication No. 2003-287239

[0005] Further related prior art may be found in WO 2010/146852 A1 describing a ceiling-mounted air conditioning unit. Therein, in an indoor heat-exchanger built into an indoor unit serving as a ceiling-mounted air conditioning unit, plural heat transfer tubes are arranged in multiple stages in a vertical direction and in three rows in a flow direction of air blown out from an indoor fan. During cooling, plural liquid refrigerant tubes on a refrigerant inlet side are connected to heat transfer tubes in a first row, second row-side gas refrigerant tubes that are some of plural gas refrigerant tubes on a refrigerant outlet side are connected to heat transfer tubes in a second row, and third row-side gas refrigerant tubes that are the rest of the plural gas refrigerant tubes are connected to heat transfer tubes in a third row.

SUMMARY OF THE INVENTION

Problems that the Invention is to Solve

[0006] There is still room for improvement, however, in the viewpoint of increasing the heat exchange area of the heat exchanger 102. In other words, by changing the shapes of the two branch heat exchangers 104 in the conventional air conditioner described above, the total longitudinal length of the branch heat exchangers 104 can be further increased. To increase the heat exchange area by increasing the total longitudinal length of the branch heat exchangers 104, it is important to design the shape and the structure of the branch heat exchangers such that productivity is not lowered.

[0007] Accordingly, it is an objective of the present invention to provide a two-way ceiling mounted air conditioner including a heat exchanger having an increased heat exchange area, while maintaining the productivity.

Means for Solving the Problems

[0008] To achieve the foregoing objective and in accordance with one aspect of the present invention, a two-way ceiling-mounted air conditioner having a rectangular shape in a planar view is provided. The air conditioner includes a decorative panel and a rectangular-parallelepiped-shaped product main body. The decorative panel has indoor outlets configured to blow out temperature-controlled air into an interior of a room and an indoor inlet configured to draw in indoor air. The rectangular-parallelepiped-shaped product main body accommodates a mechanical fan and heat exchangers. The indoor outlets in the decorative panel are two in number and are formed along opposite long sides of the decorative panel. The mechanical fan is a centrifugal fan located in the product main body such that the mechanical fan has a rotation axis oriented in a vertical direction. The heat exchangers include two branch heat exchangers each located between one of the two indoor outlets and the mechanical fan such that the mechanical fan is located between the branch heat exchangers in a planar view. Each of the two branch heat exchangers is divided into a first end portion, an intermediate portion, and a second end portion in a longitudinal direction. At the first end portion, a refrigerant passage of the branch heat exchangers is connected to an external refrigerant pipe. At the second end portion, the refrigerant passage is turned. The intermediate portion is arranged in parallel with the indoor outlets. The first end portions and the second end portions are bent toward the mechanical fan, and the first end portions and the second end portions are bent at different angles in relation to the intermediate portion.

[0009] In the configuration described above, the end portions of each of the branch heat exchangers are bent toward the mechanical fan. Thus, the total longitudinal length of the branch heat exchangers are increased in comparison with the conventional two-way ceiling-mounted air conditioner described above, leading to an increase in heat exchange area of the branch heat exchangers. Additionally, the bend angles of the end portions from the intermediate portion of each of the branch heat exchangers can be set to any angles in consideration of the dimensions of the product main body, the relationship between the length for a bender used for bending each of the branch heat exchangers to grip on and the bending lengths of the end portions of each of the branch heat exchangers, convenience of a pipe connection operation on the branch heat exchangers, and the like. Manufacturing disadvantages to the branch heat exchangers are averted in this manner.

[0010] In the above described ceiling-mounted air conditioner, in relation to a longitudinal extension line of the intermediate portion of the corresponding branch heat exchanger, each first end portion is preferably bent at a bend angle not more than forty-five degrees.

[0011] With the configuration described above, a brazing operation to connect flow dividing pipes onto the branch heat exchangers is facilitated. This is because the brazing operation is performed as described below. A brazing jig is used to temporarily assemble the two branch heat exchangers. Subsequently, brazing is performed on the pipes at one of the branch heat exchangers, and then brazing is performed on the pipes at the other branch heat exchanger. For brazing, it is necessary to position the branch heat exchangers as temporarily assembled so that the pipes to be brazed are oriented in the vertical direction. For example, to connect the flow dividing pipes at the first end portions of the two branch heat exchangers, it is necessary to reposition the branch heat exchangers, as temporarily assembled, together with the brazing jig so that the ends of the heat exchange tubes protruding at the first end portions are oriented in the vertical direction for each of the two branch heat exchangers. The first end portions each have a bend angle not more than forty-five degrees. The bend angle is defined in relation to an extension line of the intermediate portion of each of the branch heat exchangers in the longitudinal direction. This allows for a small angle change needed to reposition the brazing jig and thus facilitates the positioning operation. Additionally, the frequency at which one of the branch heat exchangers that has been connected to the pipes blocks the brazing operation on the other branch heat exchanger is reduced.

[0012] In the above described ceiling-mounted air conditioner, in relation to the longitudinal extension line of the intermediate portion of the corresponding branch heat exchanger, the second end portion is preferably bent at a bend angle larger than the bend angle of the first end portion in relation to the longitudinal extension line of the intermediate portion.

[0013] Through the configuration described above, the total longitudinal length of the branch heat exchangers can be increased. Because of this, the heat exchange areas of the branch heat exchangers can be increased, leading to an increase in heat exchange area of the heat exchanger.

[0014] In the above described ceiling-mounted air conditioner, the first end portion of each of the branch heat exchangers is preferably connected to flow dividing pipes from a flow divider. In a planar view, the flow dividing pipes are preferably arranged in a substantially triangular region formed by an outermost straight line and two leader lines. The outermost straight line is formed by connecting outermost positions, in the longitudinal direction of the product main body, of the first end portions of the two branch heat exchangers. The two leader lines are each drawn from an edge of an air passing portion at the first end portion of the corresponding branch heat exchanger toward the opposite branch heat exchanger at a right angle to an air passing plane. Connection pipes to allow communication of the refrigerant passage are attached at more than one location on the first end portion of each of the branch heat exchangers in order to set the refrigerant passage in each of the branch heat exchangers to a predetermined length and in a predetermined arrangement. Thus, the outermost straight line for the heat exchanger is defined as a line connecting the outermost positions of these connection pipes in the two opposite branch heat exchangers.

[0015] In the configuration described above, the flow dividing pipes from the flow divider are arranged in a triangular region formed by the outermost straight line and two extension lines, each of which is an extension of the end surface of the first end portion of each of the branch heat exchangers toward the opposite branch heat exchanger, in a planar view. Thus, the flow dividing pipes in a bundle do not block air flows passing through the branch heat exchangers. The flow dividing pipes from the flow divider are arranged so that, in a planar view, the pipes do not protrude outside the outermost straight line, which connects the outermost positions, in the longitudinal direction of the product main body, of the first end portions of the branch heat exchangers 41. Thus, the air conditioner can be made compact.

[0016] In the above described ceiling-mounted air conditioner, the heat exchanger is preferably configured to allow a plurality of refrigerant outlet pipes from the two branch heat exchangers to be connected to one header.

[0017] In the configuration described above, only a single header is needed instead of two headers, which would be normally needed for the two branch heat exchangers. Thus, the space needed for the header is minimized, thereby making the air conditioner compact.

[0018] In the above described ceiling-mounted air conditioner, the mechanical fan is preferably located closer to the second end portion in the longitudinal direction of the product main body.

[0019] Through the configuration described above, the space between the mechanical fan and the first end portions is made larger than the space between the mechanical fan and the second end portions. The larger space can be utilized effectively as a space for purposes such as connection and wiring between an electric component box and electric components. Electric components, such as a drain pump, are often connected to parts near the first end portions in particular. Thus, the larger space between the mechanical fan and the first end portions is advantageous for the connection of such electric components.

[0020] In the above described ceiling-mounted air conditioner, the mechanical fan is preferably one of two mechanical fans, which are spaced in the longitudinal direction of the product main body, and a midpoint between the two mechanical fans is closer to the second end portion.

[0021] In the configuration described above, the two mechanical fans are positioned closer to the second end portions in the product main body. Thus, the space between one of the two mechanical fans and the first end portions is made larger than the space between the other mechanical fan and the second end portions. The larger space can be utilized effectively as a space for purposes such as connection and wiring between an electric component box and electric components. This is particularly convenient for the connection of electric components, such as a drain pump, which is often arranged near the first end portions.

EFFECTS OF THE INVENTION

[0022] The present invention allows the total longitudinal length of the branch heat exchangers to be increased in comparison with the conventional two-way ceiling-mounted air conditioner, leading to an increase in heat exchange area of the branch heat exchangers. Additionally, the end portions of each of the branch heat exchangers are bent to have different bend angles. Thus, the bend angles of the end portions from the intermediate portion can be set to any angles in consideration of the dimensions of the product main body, the relationship between the length for a bender for each of the branch heat exchangers to grip on and the bending lengths of the end portions of each of the branch heat exchangers, convenience of a pipe connection operation on the branch heat exchangers, and the like. Manufacturing disadvantages to the branch heat exchangers are averted in this manner.

BRIEF DESCRIPTION OF THE DRAWINGS

[0023] 

Fig. 1 is an external perspective view of a two-way ceiling-mounted air conditioner according to a first embodiment of the present invention;

Fig. 2 is a cross-sectional plan view of the arrangement of devices in a product main body for the ceiling-mounted air conditioner illustrated in Fig. 1;

Fig. 3 is a cross-sectional side view of the arrangement of the devices in the ceiling-mounted air conditioner illustrated in Fig. 1;

Fig. 4 is an enlarged view of a heat exchanger at its end portion at which pipe connection is made in the ceiling-mounted air conditioner illustrated in Fig. 1;

Fig. 5 is a diagram viewed along arrow V in Fig. 4;

Fig. 6 is a perspective view of the heat exchanger as attached to a brazing jig;

Fig. 7 is an explanatory diagram showing conditions for brazing at first end portions at which external refrigerant pipes are to be connected on the heat exchanger in Fig. 6;

Fig. 8 is a cross-sectional plan view of the arrangement of devices in a product main body for a two-way ceiling-mounted air conditioner according to a second embodiment of the invention; and

Fig. 9 is a cross-sectional plan view of the arrangement of the devices in a product main body for a conventional two-way ceiling-mounted air conditioner.

MODES FOR CARRYING OUT THE INVENTION

First Embodiment

[0024] A first embodiment of the present invention will now be described with reference to Figs. 1 to 7.

[0025] A two-way ceiling-mounted air conditioner according to the first embodiment constitutes an indoor unit for a split-type air conditioner.

[0026] As illustrated in Figs. 1 and 3, the two-way ceiling-mounted air conditioner has a rectangular shape in a planar view and includes a decorative panel 10 and a product main body 20 coupled to an upper surface of the decorative panel 10. The decorative panel 10 is attached to the bottom of the product main body 20 and engaged with a ceiling material 1 (see Fig. 3). The product main body 20 is attached to a building structural member (not shown) located in a space above the ceiling such that the product main body 20 is suspended from the building structural member. Although the product main body 20 and the decorative panel 10 both have rectangular shapes in a planar view, the product main body 20 has a somewhat smaller shape than the decorative panel 10 as in the conventional air conditioner.

[0027] As illustrated in Figs. 1 and 3, the decorative panel 10 has indoor outlets 11 along its two opposite long sides for blowing out temperature-controlled air into the interior of a room. The decorative panel 10 has elongated indoor inlets 12 inside the indoor outlets 11 for drawing in the indoor air.

[0028] As illustrated in Fig. 2, the product main body 20 includes a rectangular-parallel-piped box-shaped main body casing 21, and a mechanical fan 30 and a heat exchanger 40 accommodated in the main body casing 21.

[0029] The mechanical fan 30 is a centrifugal fan, or more specifically a turbo fan, which is located in the product main body 20 such that the mechanical fan 30 has a rotation axis oriented in the vertical direction. As illustrated in Fig. 2, the mechanical fan 30 is arranged such that, in a planar view, its rotation axis is on a center line CL extending in a longitudinal direction of the product main body 20. The mechanical fan 30 is configured to be rotated clockwise, as marked by an arrow in Fig. 2, by a drive motor 32 attached to a top panel of the main body casing 21. As illustrated in Fig. 3, the mechanical fan 30 has a lower surface defined by a shroud 33. The mechanical fan 30 is configured to draw in the air through an opening at the inner circumference side of the shroud 33 and blow out the air with increased pressure from the outer circumference of an impeller 31. The mechanical fan 30 includes a bell mouth 34 in communication with the opening at the inner circumference side of the shroud 33. The bell mouth 34 is configured to communicate through an air filter 22 located thereunder in the product main body 20 with an inner space 13 between the decorative panel 10 and the air filter 22 and with the indoor inlets 12.

[0030] The heat exchanger 40 includes two branch heat exchangers 41 each arranged between one of the two indoor outlets 11 and the mechanical fan 30 in a planar view. The branch heat exchangers 41 are located at the blow-out side of the mechanical fan 30.

[0031] The branch heat exchangers 41 are plate fin coils each including substantially U-shaped heat exchange tubes 42 (see Fig. 4) constituting a refrigerant passage and plate fins 43 attached to the heat exchange tubes 42. As is understandable from Figs. 4 and 5, the branch heat exchangers 41, each of which has two rows and sixteen stages, each have a seven-path refrigerant passage.

[0032] As illustrated in the cross-sectional plan view in Fig. 2, the branch heat exchangers 41 each have an intermediate portion 41a arranged in parallel with the indoor outlets 11 and end portions bent toward the mechanical fan 30, or in other words, toward the center line CL. In the description below, the end portion of each of the branch heat exchangers 41 to which external refrigerant pipes are connected is referred to as a first end portion 41b, and the end portion that is opposite to the first end portion 41b and at which the refrigerant passage in the branch heat exchanger 41 is turned is referred to as a second end portion 41c. As described above, the branch heat exchangers 41 are each divided into the first end portion 41b, which is bent toward the mechanical fan 30, the intermediate portion 41a, and the second end portion 41c, which is bent toward the mechanical fan 30.

[0033] The first end portion 41b has a bend angle α in relation to an extension line of the intermediate portion 41a in the longitudinal direction, and the second end portion 41c has a bend angle β in relation to an extension line of the intermediate portion 41a in the longitudinal direction. The bend angles α and β are preferably ninety degrees from the viewpoint of increasing the total longitudinal length of the branch heat exchangers 41. The bend angles α and β are, however, set smaller than ninety degrees and differently from each other in order to satisfy required manufacturing conditions.

[0034] The bend angle α of the first end portion 41b of each of the branch heat exchangers 41 is set to approximately forty-five degrees to facilitate a brazing operation on the pipes to the heat exchange tubes 42. Since the intermediate portion 41a is arranged substantially parallel with the center line CL, the bend angle α is the same as an angle from the center line CL to an extension line of the first end portion 41b.

[0035] The bend angle β of the second end portion 41c of each of the branch heat exchangers 41 is set such that the second end portion 41c, which is bent, has a length greater than a required length for a bender used for bending the second end portion 41c to grip on and that the second end portion 41c forms a maximum angle from the longitudinal extension line of the intermediate portion 41a. In this embodiment, the bend angle β of the second end portion 41c is approximately sixty degrees. The bend angle α of the first end portion 41b, which is bent, is forty-five degrees as described above, and thus the first end portion 41b sufficiently provides the required length for the bender to grip on. Since the intermediate portion 41a is arranged substantially parallel with the center line CL, the bend angle β of the second end portion 41c is the same as an angle from the center line CL to an extension line of the second end portion 41c.

[0036] The product main body 20 includes a drain pan 50 below the heat exchanger 40.

[0037] A groove portion 51 is formed in a portion of the drain pan 50 immediately below the branch heat exchangers 41 to receive drain water from the branch heat exchangers 41. The drain pan 50 also serves as a partition member to separate the blow-out side of the mechanical fan 30 from the draw-in side thereof. The portion of the drain pan 50 that serves as the partition member is referred to as a partition portion 52 herein. As illustrated in Fig. 3, the partition portion 52 has a round hole 53 formed therein at a position at which the bell mouth 34 is attached, such that the air filter 22 is in communication with the bell mouth 34. As illustrated in Figs. 2 and 3, the partition portion 52 has elongated square holes 54 formed therein below the space between each of the branch heat exchangers 41 and a side wall so as to be in communication with the indoor outlets 11 in the decorative panel 10.

[0038] A configuration in the proximity of the first end portions 41b of the branch heat exchangers 41 will now be described.

[0039] As illustrated in Fig. 2, in the proximity of the first end portions 41b of the branch heat exchangers 41, devices are located, such as one that forms a refrigerant circuit external to the heat exchanger 40, one that is related to the connection of refrigerant pipes to an outdoor unit (not shown), and one that discharges the drain water. Specifically, a flow divider 61 to divide the flow of liquid refrigerant delivered from the outdoor unit, a plurality of flow dividing pipes 62 to deliver the refrigerant divided by the flow divider 61 to the branch heat exchangers 41, a plurality of refrigerant outlet pipes 63 to allow the gas refrigerant to flow out from the branch heat exchangers 41, and a header 64 to collect the refrigerant outlet pipes 63 are located in the proximity of the first end portions 41b of the heat exchanger 40. Additionally, a liquid refrigerant pipe joint 65 and a gas refrigerant pipe joint 66 for connecting connection pipes (not shown) to the outdoor unit are attached to a side panel of the main body casing 21. Furthermore, a level sensor 67 to detect the level of the drain water collected in a collecting portion of the drain pan 50, a drain pump 68 to pump out the drain water, a discharge pipe 68a to discharge the drain water pumped by the drain pump 68, and a pipe joint 69 to connect the discharge pipe 68a to an external drain pipe are located therein.

[0040] Since the branch heat exchangers 41 each have a seven-path refrigerant passage, seven flow dividing pipes 62 from the flow divider 61 are connected to each of the branch heat exchangers 41. In a planar view, the flow dividing pipes 62 are arranged in a substantially triangular region formed by two leader lines 46 and 47 drawn from the branch heat exchangers 41 and an outermost straight line 45 formed by connecting the outermost positions, in the longitudinal direction of the product main body 20, of the first end portions 41b of the branch heat exchangers 41.

[0041] Connection pipes to allow communication of the refrigerant passage are attached to more than one location on the first end portion 41b of each of the branch heat exchangers 41 in order to set the refrigerant passage in each of the branch heat exchangers 41 to a predetermined length and in a predetermined arrangement. Thus, the outermost straight line 45 for the heat exchanger 40 is defined as a line connecting the outermost positions of these connection pipes on the two opposite branch heat exchangers 41. More specifically, substantially U-shaped bent pipes 48 to connect the heat exchange tubes 42 constituting the refrigerant passage are attached to more than one location on the first end portion 41b of each of the branch heat exchangers 41 in order to set the refrigerant passage to the predetermined length and in the predetermined arrangement. The outermost straight line 45 for the heat exchanger 40 represents a line connecting points at the outermost positions of the bent pipes 48.

[0042] The two leader lines 46 and 47 are each drawn from an edge of an air passing portion at the first end portion 41b of each of the branch heat exchangers 41 toward the opposite branch heat exchanger 41 at a right angle to an air passing plane. In this embodiment, the edge of the air passing portion at the first end portion 41b corresponds to a tube plate 41d located at the first end portion 41b of each of the branch heat exchangers 41. More specifically, the leader lines 46 and 47 each represent a line extending from the surface of each of the tube plates 41d.

[0043] Each of the branch heat exchangers 41, which has a seven-path refrigerant passage, is configured to allow seven refrigerant outlet pipes 63 to extend therefrom. As illustrated in Fig. 5, the refrigerant outlet pipes 63 extending from the first end portion 41b of each of the branch heat exchangers 41 are connected at ends thereof to the one header 64. In the present invention, the flow dividing pipes 62 and the refrigerant outlet pipes 63 are the pipes that are external to the branch heat exchangers 41 and connected to the refrigerant passage in each of the branch heat exchangers 41.

[0044] The mechanical fan 30 is located at a position in the product main body 20 closer to the second end portions 41c and away from the first end portions 41b of the branch heat exchangers 41. Because of this, the space between the mechanical fan 30 and the first end portions 41b of the branch heat exchangers 41 is larger than the space between the mechanical fan 30 and the second end portions 41c of the branch heat exchangers 41. An electric component box 71 is arranged in this larger space below the partition portion 52. The utilization of this space allows electric components, such as the drain pump 68 and the level sensor 67 described above, located in the proximity of the first end portions 41b of the branch heat exchangers 41 to be connected to electric components located in an electric component box 71.

[0045] Operation of the two-way ceiling-mounted air conditioner with the configuration described above will be described below.

[0046] Air conditioning operation of the ceiling-mounted air conditioner according to the embodiment will now be described.

[0047] The air conditioning operation of the ceiling-mounted air conditioner is performed by operating a compressor mounted in the non-depicted outdoor unit and the mechanical fan 30 housed in the product main body 20. In the air conditioning operation, the indoor air flows as marked with hollow arrows in Fig. 3. Specifically, the indoor air is drawn in from the indoor inlets 12 through the inner space 13 above the decorative panel 10 and through the air filter 22 to be drawn in by the mechanical fan 30. The air is then blown out from the outer circumference of the mechanical fan 30 to be divided into the two opposite branch heat exchangers 41. The temperature of the air is controlled by passing through the branch heat exchangers 41. The temperature-controlled air is blown out through the elongated square holes 54 formed in the side portions of the drain pan 50 and then from the indoor outlets 11 into the interior of the room.

[0048] For a cooling operation performed as the air conditioning operation, the liquid refrigerant delivered from the outdoor unit (not shown) through the liquid refrigerant pipe joint 65 flows as marked by solid arrows in Fig. 4 to be divided by the flow divider 61 evenly to the flow dividing pipes 62. The liquid refrigerant divided by the flow divider 61 flows through the flow dividing pipes 62 into the refrigerant passages of the branch heat exchangers 41. While passing through the refrigerant passages, the liquid refrigerant is vaporized through heat exchange with the indoor air to turn to a gas refrigerant. The gas refrigerant passes through the refrigerant outlet pipes 63 to be collected in the header 64 and then is returned through the gas refrigerant pipe joint 66 to the outdoor unit. For a heating operation performed by the air conditioner configured as a heat pump system, the refrigerant is allowed to flow in the reverse direction, a detailed description of which will be omitted here.

[0049] The heat exchanger offers improved performance in such air conditioning operations over the conventional example described above. This is due to the intermediate portions 41a of the branch heat exchangers 41 arranged in parallel with the indoor outlets 11 and the first end portions 41b and the second end portions 41c of the branch heat exchangers 41 bent toward the mechanical fan 30. They allow the total longitudinal length of the branch heat exchangers 41 mountable in the product main body 20 to be increased longer than those in the conventional example, thereby increasing the heat exchange area of the heat exchanger 40.

[0050] A pipe connection operation performed on the heat exchanger 40 with the configuration described above will now be described. The pipe connection operation on the heat exchanger 40 mainly involves the brazing operation of the flow dividing pipes 62 and the refrigerant outlet pipes 63 onto the heat exchange tubes 42 at the first end portions 41b of the branch heat exchangers 41.

[0051] As illustrated in Fig. 6, a brazing jig 80 is used to temporarily assemble the two branch heat exchangers 41 into positions identical with those as assembled in the product main body 20.

[0052] The brazing jig 80 includes an outer member 81 to support the heat exchanger 40 at four locations from outside and an inner member 82 to press the intermediate portion 41a of each of the branch heat exchangers 41 against the outer member 81. As illustrated in Fig. 6, the outer member 81 includes a plane supporting wall 81a to support the bottom of the heat exchanger 40, side supporting walls 81b to support the intermediate portions 41a of the two branch heat exchangers 41 at two opposite locations, and a curved end portion supporting wall 81c to support the second end portions 41c of the two branch heat exchangers 41 simultaneously. The side supporting walls 81b and the end portion supporting wall 81c are coupled to the plane supporting wall 81a. The inner member 82 includes pressing walls 82a to press the intermediate portions 41a against the side supporting walls 81b of the outer member 81 from inside and urging members 82b to urge the pressing walls 82a outward.

[0053] The two branch heat exchangers 41 are temporarily assembled using the brazing jig 80 in a manner described below. The second end portions 41c of the branch heat exchangers 41 are coupled with each other. The coupled branch heat exchangers 41 are then fitted in the outer member 81 of the brazing jig 80 as illustrated in Fig. 6 so that the branch heat exchangers 41 form a shape identical with that as housed in the product main body 20. The urging members 82b of the inner member 82 are then operated to allow the pressing walls 82a to press the intermediate portions 41a of the branch heat exchangers 41 against the side supporting walls 81b of the outer member 81. As a result, the intermediate portions 41a of the branch heat exchangers 41 are each held between one of the side supporting walls 81b of the outer member 81 and one of the pressing walls 82a of the inner member 82. The heat exchanger 40 is temporarily assembled using the brazing jig 80 in this manner.

[0054] The end portions of the heat exchanger 40 as temporarily assembled are then brazed. To facilitate the brazing in a reliable manner, the brazing is performed on one of the branch heat exchangers 41 and then on the other branch heat exchanger 41.

[0055] For example, as illustrated in a section of the diagram to the left in Fig. 7, at the left one of the branch heat exchangers 41, the tube plate 41d of its first end portion 41b is retained horizontally so that the axes of the heat exchange tubes 42 to be brazed are oriented in the vertical direction. This facilitates reliable brazing of the flow dividing pipes 62 and the refrigerant outlet pipes 63 onto the heat exchange tubes 42 of the first end portion 41b of the left one of the branch heat exchangers 41. When the brazing on the left one of the branch heat exchangers 41 is finished, the heat exchanger 40 as temporarily assembled is rotated together with the brazing jig 80 as illustrated in a section of the diagram to the right in Fig. 7, so that the brazing is performed on the right one of the branch heat exchangers 41 in a similar manner to the left one of the branch heat exchangers 41.

[0056] It is convenient to perform brazing in the brazing jig 80 also on other pipes and devices that are around the first end portions 41b of the branch heat exchangers 41 and are to be brazed before the assembly into the product main body 20. For example, to braze the refrigerant outlet pipes 63 of the branch heat exchangers 41 onto the header 64, the heat exchanger 40 as temporarily assembled is rotated together with the brazing jig 80 so that the axes of the refrigerant outlet pipes 63 at brazing locations are oriented in the vertical direction, in a manner similar to that described above. This facilitates reliable brazing of the refrigerant outlet pipes 63 onto the header 64.

[0057] The ceiling-mounted air conditioner according to the embodiment with the configuration described above is capable of achieving advantages as described below.

(1) The total longitudinal length of the branch heat exchangers 41 can be increased in comparison with the conventional two-way ceiling-mounted air conditioner described above, leading to an increase in heat exchange area of the branch heat exchangers 41.

(2) The bend angle α of the first end portion 41b and the bend angle β of the second end portion 41c of each of the branch heat exchangers 41 are different from each other. Thus, the bend angles α and β of the end portions can be set to any angles in consideration of the dimensions of the product main body 20, the relationship between the length for a bender for each of the branch heat exchangers 41 to grip on and the bending lengths of the end portions of each of the branch heat exchangers 41, convenience of the pipe connection operation on the branch heat exchangers 41, and the like. Manufacturing disadvantages to the branch heat exchangers are averted in this manner.

(3) The bend angle α of the first end portion 41b of each of the branch heat exchangers 41 is not more than forty-five degrees. This facilitates positioning the heat exchanger 40 as temporarily assembled so that the axes of the heat exchange tubes 42 to be brazed are oriented in the vertical direction. This facilitates the brazing operation to connect the flow dividing pipes 62 onto the branch heat exchangers 41.

(4) The bend angle β of the second end portion 41c of each of the branch heat exchangers 41 is set to an angle larger than the bend angle α of the first end portion 41b. This is advantageous for maximization of the total longitudinal length of the branch heat exchangers 41. By increasing the total longitudinal length of the branch heat exchangers 41, the heat exchange area of the branch heat exchangers 41 can be increased, thereby increasing the heat exchange area of the heat exchanger 40.

(5) The flow dividing pipes 62 from the flow divider 61 are arranged in a triangular region formed by the outermost straight line 45 and the two leader lines 46 and 47. The outermost straight line 45 is formed by connecting the outermost positions, in the longitudinal direction of the product main body 20, of the first end portions 41b of the branch heat exchangers 41. The two leader lines 46 and 47 are each drawn from the edge of the air passing portion at the first end portion 41b of each of the branch heat exchangers 41 toward the opposite branch heat exchanger 41 at the right angle to the air passing plane. Thus, the flow dividing pipes 62 in a bundle do not block the air flow passing through the branch heat exchangers 41.

(6) The plurality of flow dividing pipes 62 (fourteen of them to be specific) from the flow divider 61 is arranged such that the pipes do not protrude outside the outermost straight line 45 in the longitudinal direction in a planar view. Thus, the air conditioner can be made compact.

(7) Since all of the plurality of refrigerant outlet pipes 63 (seven of them from each of the branch heat exchangers 41 to be specific) from the branch heat exchangers 41 are connected to the one header 64, only a single header 64 is needed instead of two headers that would be normally needed for the two branch heat exchangers 41. Thus, the space needed for the header 64 can be minimized, thereby making the air conditioner compact.

(8) The mechanical fan 30 is located at position in the product main body 20 closer to the second end portions 41c of the branch heat exchangers 41. Because of this, the space between the mechanical fan 30 and the first end portions 41b can be made larger than the space between the mechanical fan 30 and the second end portions 41c. Thus, the larger space can be utilized effectively as a space for purposes such as connection and wiring between the electric component box 71 and electric components. This space is particularly convenient for the connection of electric components, such as the drain pump 68 and the level sensor 67, which are often located near the first end portions 41b of the branch heat exchangers 41.

Second Embodiment

[0058] A second embodiment will now be described with reference to Fig. 8. In a two-way ceiling-mounted air conditioner according to the second embodiment, a decorative panel 10 and a product main body 20 have longitudinal dimensions larger than those in the first embodiment, so that two mechanical fans 30 are provided for improved performance. Other configurations are identical to those in the first embodiment. The two-way ceiling-mounted air conditioner according to the second embodiment will be described with emphasis on differences from the first embodiment. Identical components to those in the first embodiment are indicated with identical reference numerals, and their description will be omitted or simplified.

[0059] In the ceiling-mounted air conditioner according to the second embodiment, the dimensions of a main body casing 21, the decorative panel 10, and a drain pan 50 are changed to increase the longitudinal dimension of the product main body 20 for improved performance as described above. Additionally, branch heat exchangers 41 have longitudinal dimensions larger than those in the first embodiment to correspond to the longitudinal dimensions of the product main body 20. More specifically, intermediate portions 41a of the branch heat exchangers 41 have dimensions larger than those in the first embodiment. First end portions 41b and second end portions, which are bent, have dimensions identical with those in the first embodiment.

[0060] In the ceiling-mounted air conditioner according to the second embodiment, the two mechanical fans 30 are located in the product main body 20 with a longitudinal distance therebetween to improve the performance. A partition wall 35 is located between the two mechanical fans 30 to partition a space at the blow-out side of the mechanical fans 30. The midpoint between the two mechanical fans 30 is positioned closer to the second end portions 41c.

[0061] Because of the configuration described above, the ceiling-mounted air conditioner according to the second embodiment achieves advantages described below in addition to the advantages in the first embodiment described in (1) to (7) above.

(9) The two mechanical fans 30 are arranged with their midpoint positioned closer to the second end portions 41c in the product main body 20. Thus, the space between one of the two mechanical fans 30 and the first end portions 41b is larger than the space between the other mechanical fan 30 and the second end portions 41c. Because of this, the space of the first end portions 41b can be utilized effectively as a space for purposes such as connection and wiring between an electric component box 71 and electric components. This space is particularly convenient for the connection of electric components, such as a drain pump 68 and a level sensor 67, which are often located near the first end portions 41b of the branch heat exchangers 41.

Modifications

[0062] The two-way ceiling-mounted air conditioner according to the invention is not limited to the embodiments described above, and modifications as described below are also viable. The modifications as described below may also be combined as appropriate.

Although the plate fin coils each including the substantially U-shaped heat exchange tubes 42 and the plate fins attached to the heat exchange tubes 42 are described as a specific example of the heat exchangers 40 in the first and second embodiments described above, other types of heat exchanger for air may be used. For example, other types of heat exchanger include a micro-channel heat exchanger including micro-channels constituting a refrigerant passage.

• The bend angle α of the first end portions 41b in the first and second embodiments are most preferably forty-five degrees from the viewpoint of maximizing the total longitudinal length of the branch heat exchangers 41 and facilitating the brazing operation on pipes at the first end portions 41b. The bend angle α, however, may be another angle. The bend angle α is preferably not more than forty-five degrees from the viewpoint of improving the workability of brazing on the pipes.

• The bend angle β of the second end portions 41c in the first and second embodiments is preferably as close to ninety degrees as possible as long as the second end portions 41c each provide a length for a bender to grip on. Thus, the bend angle β in the embodiments described above is not limited to sixty degrees.

• In the first and second embodiments described above, the mechanical fan(s) 30 is/are positioned at a position in the product main body 20 closer to the second end portions 41c. When an electric component box is located between the mechanical fan(s) 30 and the first end portions 41b, such positioning of the mechanical fan(s) 30 in the product main body 20 is preferable since an increase in internal air flow resistance due to wiring or the like for the electric component box does not occur. The invention, however, is not limited thereto.

• In the first and second embodiments described above, the flow dividing pipes 62 from the flow divider 61 are arranged in a triangular region formed by the outermost straight line 45 and the two leader lines 46 and 47. The outermost straight line 45 is formed by connecting the outermost positions, in the longitudinal direction of the product main body 20, of the first end portions 41b of the branch heat exchangers 41. The two leader lines 46 and 47 are each drawn from the edge of the air passing portion at the first end portion 41b of each of the branch heat exchangers 41 toward the opposite branch heat exchanger 41 at the right angle to the air passing plane. The invention, however, is not limited thereto. If the flow dividing pipes 62 are arranged in the triangle as described above, the internal air flow resistance due to the flow dividing pipes 62 is prevented from increasing.

• In the first and second embodiments described above, the indoor inlets 12 are formed into elongated shapes similar to those of the indoor outlets 11 and positioned inside the indoor outlets 11 at the lower surface of the decorative panel 10. The indoor inlets 12, however, may extend over a substantially entire area inside the indoor outlets 11.

• The decorative panel 10 in the first and second embodiments described above has a lower surface formed into a plane. The invention, however, is not limited thereto. For example, the short sides of the decorative panel 10 may have middle portions protruding downward. These protruding portions may form a plane surface thereon extending all along the long side of the decorative panel 10. Inclined surfaces may be formed at both sides of the plane surface and extend all along the long sides of the plane surface. The indoor inlet 12 may extend over the substantially entire area of the plane surface in the middle, and indoor outlets 11 may be provided in the inclined surfaces formed at both sides of the plane surface.

Claims

1. A two-way ceiling-mounted air conditioner having a rectangular shape in a planar view, the air conditioner comprising:

a decorative panel (10) having indoor outlets (11) configured to blow out temperature-controlled air into an interior of a room and an indoor (12) inlet configured to draw in indoor air; and

a rectangular-parallelepiped-shaped product main body (20) accommodating a mechanical fan (30) and heat exchangers (41), the air conditioner being characterized in that

the indoor outlets in the decorative panel are two in number and are formed along opposite long sides of the decorative panel,

the mechanical fan is a centrifugal fan located in the product main body such that the mechanical fan has a rotation axis oriented in a vertical direction,

the heat exchangers include two branch heat exchangers (41) each located between one of the two indoor outlets and the mechanical fan such that the mechanical fan is located between the branch heat exchangers in a planar view,

each of the two branch heat exchangers is divided into a first end portion (41b), an intermediate portion (41a), and a second end portion (41c) in a longitudinal direction, wherein

at the first end portion, a refrigerant passage of the branch heat exchangers is connected to an external refrigerant pipe,

at the second end portion, the refrigerant passage is turned, and

the intermediate portion is arranged in parallel with the indoor outlets, and the first end portions and the second end portions are bent toward the mechanical fan,

characterized in that the first end portions and the second end portions are bent at different angles in relation to the intermediate portion.

2. The ceiling-mounted air conditioner according to claim 1, characterized in that, in relation to a longitudinal extension line of the intermediate portion of the corresponding branch heat exchanger, each first end portion is bent at a bend angle not more than forty-five degrees.

3. The ceiling-mounted air conditioner according to claim 2, characterized in that, in relation to the longitudinal extension line of the intermediate portion of the corresponding branch heat exchanger, the second end portion is bent at a bend angle larger than the bend angle of the first end portion in relation to the longitudinal extension line of the intermediate portion.

4. The ceiling-mounted air conditioner according to any one of claims 1 to 3, characterized in that
the first end portion of each of the branch heat exchangers is connected to flow dividing pipes (62) from a flow divider, and
in a planar view, the flow dividing pipes are arranged in a substantially triangular region formed by an outermost straight line (45) and two leader lines (46, 47), wherein the outermost straight line is formed by connecting outermost positions, in the longitudinal direction of the product main body, of the first end portions of the two branch heat exchangers, the two leader lines are each drawn from an edge of an air passing portion at the first end portion of the corresponding branch heat exchanger toward the opposite branch heat exchanger at a right angle to an air passing plane.

5. The ceiling-mounted air conditioner according to any one of claims 1 to 4, characterized in that the heat exchanger is configured to allow a plurality of refrigerant outlet pipes from the two branch heat exchangers to be connected to one header (64).

6. The ceiling-mounted air conditioner according to any one of claims 1 to 5, characterized in that the mechanical fan is located closer to the second end portion in the longitudinal direction of the product main body,

7. The ceiling-mounted air conditioner according to any one of claims 1 to 5, characterized in that the mechanical fan is one of two mechanical fans (30), which are spaced in the longitudinal direction of the product main body, and a midpoint between the two mechanical fans is closer to the second end portion.

Ansprüche

1. Eine bidirektionale, an einer Decke befestigte Klimaanlage mit einer rechteckigen Form in einer Draufsicht, wobei die Klimaanlage umfasst:

eine dekorative Platte (10) mit Innenraumauslässen (11), die konfiguriert sind, um temperaturgesteuerte Luft in einen Innenraum eines Raums auszublasen, und mit einem Innenraum (12)-Einlass, der konfiguriert ist, um Innenraumluft anzusaugen; und

einen rechteckig-parallelepiped-förmigen Produkthauptkörper (20), der ein mechanisches Gebläse (30) und einen Wärmetauscher (41) aufnimmt, wobei die Klimaanlage dadurch gekennzeichnet ist, dass

die Innenraumauslässe in der dekorative Platte zwei an der Zahl sind und entlang gegenüberliegender langer Seiten der dekorativen Platte ausgebildet sind,

das mechanische Gebläse ein Zentrifugalgebläse ist, das in dem Produkthauptkörper angeordnet ist, sodass das mechanische Gebläse eine Rotationsachse aufweist, die in einer vertikalen Richtung ausgerichtet ist,

der Wärmetauscher zwei Abzweigungswärmetauscher (41) aufweist, die jeweils zwischen einem der zwei Innenraumauslässe und dem mechanischen Gebläse angeordnet sind, sodass das mechanische Gebläse in einer Draufsicht zwischen den Abzweigungswärmetauschern angeordnet ist,

jeder der zwei Abzweigungswärmetauscher in einer Längsrichtung in einen ersten Endabschnitt (41b), einen Zwischenabschnitt (41a) und einen zweiten Endabschnitt (41c) unterteilt ist, wobei

an dem ersten Endabschnitt ein Kältemitteldurchgang des Abzweigungswärmetauschers mit einem externen Kältemittelrohr verbunden ist,

an dem zweiten Endabschnitt der Kältemitteldurchgang gedreht ist und

der Zwischenabschnitt parallel zu den Innenraumauslässen angeordnet ist und die ersten Endabschnitte und die zweiten Endabschnitte zu dem mechanischen Gebläse hin gebogen sind,

dadurch gekennzeichnet, dass

die ersten Endabschnitte und die zweiten Endabschnitte in unterschiedlichen Winkeln in Bezug auf den Zwischenabschnitt gebogen sind.

2. An einer Decke befestigte Klimaanlage nach Anspruch 1, dadurch gekennzeichnet, dass in Bezug auf eine Längserstreckungslinie des Zwischenabschnitts des entsprechenden Abzweigungswärmetauschers jeder erste Endabschnitt in einem Biegewinkel von nicht mehr als fünfundvierzig Grad gebogen ist.

3. An einer Decke befestigte Klimaanlage nach Anspruch 2, dadurch gekennzeichnet, dass in Bezug auf die Längserstreckungslinie des Zwischenabschnitts des entsprechenden Abzweigungswärmetauschers der zweite Endabschnitt in einem Biegewinkel gebogen ist, der größer als der Biegewinkel des ersten Endabschnitts in Bezug auf die Längserstreckungslinie des Zwischenabschnitts ist.

4. An einer Decke befestigte Klimaanlage nach einem der Ansprüche 1 bis 3, dadurch gekennzeichnet, dass
der erste Endabschnitt von jedem der Abzweigungswärmetauscher mit Strömungsteilungsrohren (62) von einem Strömungsteiler verbunden ist und
die Strömungsteilungsrohre in einer Draufsicht in einem in dem Wesentlichen dreieckigen Bereich angeordnet sind, der durch eine äußerste gerade Linie (45) und zwei Führungslinien (46, 47) gebildet ist, wobei die äußerste gerade Linie durch Verbinden von äußersten Positionen der ersten Endabschnitte der zwei Abzweigungswärmetauscher in der Längsrichtung des Produkthauptkörpers gebildet wird, die zwei Führungslinien jeweils von einer Kante eines Luftdurchgangsabschnitts an dem ersten Endabschnitt des entsprechenden Abzweigungswärmetauschers zu dem gegenüberliegenden Abzweigungswärmetauscher hin, in einem rechten Winkel zu einer Luftdurchgangsebene, gezogen werden.

5. An einer Decke befestigte Klimaanlage nach einem der Ansprüche 1 bis 4, dadurch gekennzeichnet, dass der Wärmetauscher konfiguriert ist, um zu ermöglichen, dass eine Vielzahl von Kältemittelauslassrohren von den zwei Abzweigungswärmetauschern mit einem Grund-Sammelrohr (64) verbunden werden kann.

6. An einer Decke befestigte Klimaanlage nach einem der Ansprüche 1 bis 5, dadurch gekennzeichnet, dass das mechanische Gebläse näher an dem zweiten Endabschnitt in der Längsrichtung des Produkthauptkörpers angeordnet ist.

7. An einer Decke befestigte Klimaanlage nach einem der Ansprüche 1 bis 5, dadurch gekennzeichnet, dass das mechanische Gebläse eines von zwei mechanischen Gebläsen (30) ist, die in der Längsrichtung des Produkthauptkörpers beabstandet sind, und ein Mittelpunkt zwischen den zwei mechanischen Gebläsen näher an dem zweiten Endabschnitt ist.

Revendications

1. Climatiseur intégré au plafond de deux manières et ayant une forme rectangulaire en vue planaire, le climatiseur comprenant :

un panneau décoratif (10) ayant des sorties internes (11) configurées pour purger l'air à température contrôlée à l'intérieur d'une pièce et une entrée interne (12) configurée pour aspirer de l'air interne ; et

un corps principal de produit de forme parallélépipédique rectangulaire (20) recevant un ventilateur mécanique (30) et des échangeurs de chaleur (41), le climatiseur étant caractérisé en ce que :

les sorties internes du panneau décoratif sont au nombre de deux et sont formées le long des côtés longs opposés du panneau décoratif,

le ventilateur mécanique est un ventilateur centrifuge situé dans le corps principal du produit de sorte que le ventilateur mécanique ait un axe de rotation orienté dans la direction verticale,

les échangeurs de chaleur comprennent deux échangeurs de chaleur à branches (41) situés chacun entre l'une des deux sorties internes et le ventilateur mécanique de sorte que le ventilateur mécanique soit situé entre les échangeurs de chaleur à branches en vue planaire,

chacun des deux échangeurs de chaleur à branches est divisé en une première partie d'extrémité (41b), une partie intermédiaire (41a) et une seconde partie d'extrémité (41c) dans la direction longitudinale, dans lequel :

dans la première partie d'extrémité, un passage de réfrigérant des échangeurs de chaleur à branches est raccordé à un tuyau de réfrigérant externe,

dans la seconde partie d'extrémité, le passage de réfrigérant est tourné et
la partie intermédiaire est agencée en parallèle avec les sorties internes et les premières parties d'extrémité et les secondes parties d'extrémités sont coudées vers le ventilateur mécanique,

caractérisé en ce que les premières parties d'extrémité et les secondes parties d'extrémité sont coudées selon différents angles par rapport à la partie intermédiaire.

2. Climatiseur intégré au plafond selon la revendication 1, caractérisé en ce que, par rapport à une ligne d'extension longitudinale de la partie intermédiaire de l'échangeur de chaleur à branches correspondant, chaque première partie d'extrémité est coudée selon un angle de coudage qui n'est pas supérieur à quarante-cinq degrés.

3. Climatiseur intégré au plafond selon la revendication 2, caractérisé en ce que, par rapport à la ligne d'extension longitudinale de la partie intermédiaire de l'échangeur de chaleur à branches correspondant, la seconde partie d'extrémité est coudée selon un angle de coudage supérieur à l'angle de coudage de la première partie d'extrémité par rapport à la ligne d'extension longitudinale de la partie intermédiaire.

4. Climatiseur intégré au plafond selon l'une quelconque des revendications 1 à 3, caractérisé en ce que :

la première partie d'extrémité de chacun des échangeurs de chaleur à branches est raccordée à des tuyaux diviseurs d'écoulement (62) venant d'un diviseur d'écoulement et,

en vue planaire, les tuyaux diviseurs d'écoulement sont agencés dans une région sensiblement triangulaire formée par une ligne droite externe (45) et deux lignes directrices (46, 47), dans lequel la ligne droite externe est formée par la liaison de positions externes, dans la direction longitudinale du corps principal du produit, des premières parties d'extrémité des deux échangeurs de chaleur à branches, les deux lignes directrices sont chacune tirées d'un bord d'une partie de passage d'air dans la première partie d'extrémité de l'échangeur de chaleur à branches correspondant vers l'échangeur de chaleur à branches opposé à angle droit avec un plan de passage d'air.

5. Climatiseur intégré au plafond selon l'une quelconque des revendications 1 à 4, caractérisé en ce que l'échangeur de chaleur est configuré pour permettre à une pluralité de tuyaux de sortie de réfrigérant venant des deux échangeurs de chaleur à branches de se raccorder à un collecteur (64).

6. Climatiseur intégré au plafond selon l'une quelconque des revendications 1 à 5, caractérisé en ce que le ventilateur mécanique est situé plus près de la seconde partie d'extrémité dans la direction longitudinale du corps principal du produit.

7. Climatiseur intégré au plafond selon l'une quelconque des revendications 1 à 5, caractérisé en ce que le ventilateur mécanique est l'un de deux ventilateurs mécaniques (30), qui sont espacés dans la direction longitudinale du corps principal du produit, et un point central entre les deux ventilateurs mécaniques est plus proche de la seconde partie d'extrémité.

Drawing