JP3885877B2 - Air conditioner - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an air conditioner.
[0002]
[Prior art]
There are various types of air conditioners. Often installed in Japanese homes are separate types with separate indoor and outdoor units. On the other hand, an integrated air conditioner in which an indoor heat exchange unit and an outdoor heat exchange unit are housed in a single housing is a building that is difficult to place an outdoor unit outside a building, for example, a hotel or a building dense zone Often used in buildings.
[0003]
A small integrated air conditioner that only heats and cools a room is often fitted directly into a window or hole in a wall. On the other hand, a slightly large integrated air conditioner that is responsible for air conditioning in multiple rooms has a deck that protrudes from the wall facing the outside toward the room or a support table placed on the wall of the room. Often, air conditioners are installed on the top. U.S. Pat. No. 6,065,296 describes an example in which a deck is protruded from a ventilation opening provided on a wall and an air conditioner is placed thereon.
[0004]
[Problems to be solved by the invention]
Regardless of whether it is a separate type or an integrated type, if a problem occurs, it is required to deal with it. It is an object of the present invention to provide an air conditioner that is easy to cope with troubles or has regular maintenance.
[0005]
[Means for Solving the Problems]
To achieve the above object, in the present invention, an indoor heat exchange unit comprising an indoor heat exchanger and an indoor blower, an outdoor heat exchange unit comprising an outdoor heat exchanger and an outdoor blower, and a compressor, In the air conditioner that houses a cooling / heating unit comprising : a sirocco fan, a fan casing having an involute curved guide wall surrounding an outer periphery of the sirocco fan, and the sirocco fan And the indoor fan is arranged in parallel so that the suction port faces the indoor heat exchanger, and the outlet of the indoor fan is the guide wall of the involute curve be provided in the end portion, the width of the air outlet is provided to be smaller than the diameter of the sirocco fan, and before a part of said air outlet As well as constituting a part of a guide wall, wherein upon removal of parts made smaller than the diameter of the sirocco fan, by the width of the outlet is larger than the diameter of the sirocco fan, the fan from the air outlet The sirocco fan in the casing can be taken out.
[0006]
According to the said structure, a fan can be maintained, without touching the component arrange | positioned in the front of an air blower.
[0007]
With this embodiment, the air-conditioning unit as well as arranged to be sandwiched the heating means for warming up tufts by said fan casing and said indoor heat exchanger, can be detached the heating means from any of the left and right sides of the housing It was configured as follows.
[0008]
According to the above configuration, since the heating means can be attached / detached from either the left or right side of the housing, the heating means can be attached / detached from either the left or right side even when the air conditioner is installed at the corner of the room.
[0009]
In the present invention, the heating means is fixed by engaging one end of the heating means with the engagement receiving portion in the housing and screwing the other end to any member in the housing. . According to this configuration, the heating means can be fixed with a small number of screws.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
[0014]
The air conditioner 1 has a rectangular parallelepiped housing 10. A method of configuring the housing 10 will be described later. As shown in FIG. 2, the housing 10 houses an air conditioning unit 50 including an indoor heat exchange unit 70 and an outdoor heat exchange unit 120. The housing 10 is pressed from the indoor side to a ventilation port 3 provided in the wall 2 separating the room and the outside. In order to match the height of the ventilation opening and the ventilation opening 3 of the housing 10, the support 5 is placed on the floor 4, and the housing 10 is placed on the support 5.
[0015]
From the upper part of the room, the air conditioning duct 6 falls vertically. A duct 33 protruding from the upper surface of the housing 10 is connected to the air conditioning duct 6. The air conditioning duct 6 is connected to a horizontal air conditioning duct (not shown) at the ceiling of the room, and cool air or warm air is sent to a plurality of rooms through the horizontal air conditioning duct.
[0016]
As described above, the housing 10 has a rectangular parallelepiped shape, and its six surfaces are constituted by the following six panels shown in FIG. That is, the bottom panel 11, the top panel 12, the front panel 13, the back panel 14, the left side panel 15, and the right side panel 16. All of these panels are made of sheet metal, and are fixed to each other by screws and assembled as a housing 10.
[0017]
Of the four panels of the front panel 13, the rear panel 14, the left side panel 15, and the right side panel 16 constituting the four circumferences of the housing 10 even after the housing 10 is assembled, the rear panel facing the wall 2. The three panels except the front panel 13, the left side panel 15, and the right side panel 16 can be detached from the housing 10 independently. Even if one of these three panels is removed, the strength of each panel is designed so that the remaining panel group maintains the form of the housing 10 and can withstand various loads.
[0018]
The back panel 14 has a large rectangular ventilation opening 17 and has a frame shape. The ventilation opening 17 has an area that allows the blowout portion of the outdoor heat exchange unit 120 to be exposed to the outside and secures a suction passage (described later) for sucking air from the outside.
[0019]
A frame-shaped gasket 18 is attached to the inner surface of the back panel 14 so as to surround the ventilation opening 17. As will be described later, the gasket 18 forms an airtight connection with the air conditioning unit 50. In addition, a rectangular loop-shaped projecting portion 19 surrounding the ventilation opening 17 is formed on the rear surface of the rear panel 14 (see FIG. 2). The protrusion 19 enters the ventilation port 3 and prevents air from entering and exiting through the gap between the air conditioner 1 and the wall 2.
[0020]
The front panel 13 is provided with a rectangular ventilation opening 20. The ventilation opening 20 is for sucking room air into the housing 10. A filter 21 (see FIG. 1) is disposed in front of the ventilation opening 20 and filters dust from the air that is sucked. The filter 21 is a rectangular frame in which a filter material is stretched, and is held by a filter receiver 22 provided on the front panel 13.
[0021]
The filter receiver 22 is formed by welding sheet metal L-shaped angles to the left and right side edges of the vent opening 20 facing each other. A dead end portion is formed at the lower end of each angle, and the filter 21 inserted into the filter receiver 22 from above is held at a height matching the vent opening 20.
[0022]
The bottom panel 11 has a tray shape and has a rectangular hole 23 at the front. The rear part of the bottom panel 11 is depressed more than the front part and forms a drain pan 24. A drainage basin 25 having a structure shown in FIG.
[0023]
The drainage basin 25 is a component molded separately from the bottom panel 11 and is fitted into an opening 26 provided in the bottom panel 11 from above. A lid 27 having a water inlet 28 in the center covers the upper surface opening of the water collecting basin 25. A drain hose 30 is connected to the outlet 29 of the catchment basin 25. The drain hose 30 drains the drain to the indoor drain port or the outdoor.
[0024]
Screw-type adjusting legs 31 are provided at the bottom corners of the bottom panel 11 (see FIG. 2). After the housing 10 is placed on the support base 5, the adjustment legs 31 are turned at four locations to adjust the height and to level out.
[0025]
FIG. 7 shows the configuration of the top panel 12. The top panel 12 has a circular opening 32 at a substantially central portion. A cylindrical duct 33 projects from the inside of the housing 10 through the opening 32. The duct 33 is integrally formed with a rectangular duct base 34 using a synthetic resin.
[0026]
The duct base 34 has notches 35 at four corners, and mounting bolts 36 shown in FIG. The mounting bolt 36 is arranged with the axis line vertical, and has two flanges 37, 38 at the lower end with a space in the vertical direction. The duct base 34 is sandwiched between the flanges 37, 38. In this way, it is inserted into the notch 35. The notch 35 has a narrowed entrance so that the inserted mounting bolt 36 does not easily come out.
[0027]
Nuts 39 are fixed to the top panel 12 at four positions surrounding the through holes 32, and mounting bolts 36 are screwed onto the nuts 39 from below. A recess 40 for receiving a fastening tool such as a Phillips screwdriver or a hexagon stick wrench is formed at the upper end of the mounting bolt 36. When the tip of the fastening tool is inserted into the recess 40 and the mounting bolt 36 is rotated, the mounting bolt 36 moves up and down relative to the nut 39, whereby the height of the duct 33 and the duct base 34 changes in the housing 10.
[0028]
A heat insulating plate 41 is inserted between the top panel 12 and the duct base 34. The heat insulating plate 41 is formed of a material having good heat insulating properties such as polystyrene foam. The reason why the heat insulating plate 41 is disposed is to prevent the upper panel 12 from being cooled even when the duct base 34 is cooled by cold air, and to prevent condensation on the surface of the upper panel 12.
[0029]
Next, the structure of the air conditioning unit 50 will be described with reference to FIG. The air conditioning unit 50 includes an indoor heat exchange unit 70 and an outdoor heat exchange unit 120. The refrigeration cycle unit 51 shown in FIG. 9 forms the center of the indoor heat exchange unit 70 and the outdoor heat exchange unit 120.
[0030]
The refrigeration cycle unit 51 includes an indoor heat exchanger 71, an outdoor heat exchanger 121, and a compressor 52. Each element is connected by a metal tube 53. The refrigeration cycle unit 51 includes a four-way valve (not shown) so that the roles of the indoor side heat exchanger 71 and the outdoor side heat exchanger 121 can be switched between cooling and heating.
[0031]
The indoor side heat exchanger 71 and the indoor side blower 72 are combined to form an indoor side heat exchange unit 70. The outdoor heat exchanger 121 is combined with an outdoor fan 122 to form an outdoor heat exchange unit 120. The indoor side heat exchange unit 70 and the outdoor side heat exchange unit 120 are installed and fixed on a tray-shaped base 150.
[0032]
An air guide 54 having a side surface curved in an arc shape is fixed to the upper part of the indoor fan 72. The air guide 54 is made of sheet metal and serves to guide air taken from the outside toward the suction side of the outdoor fan 122.
[0033]
An air guide duct 55 for the indoor fan 72 is provided in front of the air guide 54. As shown in FIG. 11, the air guide duct 55 is formed by fixing four sheet metal members 56, 57, 58, and 59 to the air guide 54, and has a horizontal section rectangle. The air guide duct 55 plays a role of guiding the wind from the indoor fan 72 to the duct 33. In accordance with the area difference between the air blower outlet of the indoor blower 72 and the duct 33, the air guide duct 55 has a shape in which the lower portion is thin but the upper portion is widened toward the end.
[0034]
An electrical box 60 is attached to the front surface of the air guide duct 55 (see FIGS. 2 and 3). A gasket 61 is mounted on the lower surface of the duct base 34 (see FIGS. 2, 3, 7, and 15). The gasket 61 is arranged in a rectangular loop shape like the shape of the upper surface opening of the air guide duct 55.
[0035]
A compressor 52 is disposed in a gap between the indoor heat exchange unit 70 and the outdoor heat exchange unit 120, and is fixed to the base 150 (see FIG. 4). The left side plate 160 and the right side plate 161 cover the gap between the indoor side heat exchange unit 70 and the outdoor side heat exchange unit 120 and the side surface of the outdoor side heat exchange unit 120 (see FIGS. 9 and 12). The upper front corners of the left side plate 160 and the right side plate 161 are rounded in accordance with the curvature of the air guide 54.
[0036]
FIG. 12 shows a situation in which the indoor heat exchange unit 70 and the outdoor heat exchange unit 120 are fixed on the base 150, and the air guide 54 and the left and right side plates 160 and 161 are fixed thereto. The state shown in FIG. 12 is a completely assembled state of the air conditioning unit 50.
[0037]
Next, based on FIGS. 13-20, the detailed structure of the indoor side heat exchange unit 70 is demonstrated.
[0038]
The main components of the indoor side heat exchange unit 70 are an indoor side heat exchanger 71, an indoor side blower 72, and a heating means 73. These all have a rectangular front shape, and are arranged in the order of the indoor heat exchanger 71, the heating means 73, and the indoor blower 72 from the front to the back.
[0039]
As shown in FIG. 14, the indoor fan 72 includes a sirocco fan 80, a motor 81 that rotates the sirocco fan 80, and a fan casing 90. The motor 81 is fixed to the fan casing 90 via a metal mounting frame 82, and the motor shaft 83 protrudes into a fan chamber (described later) of the fan casing 90. The sirocco fan 80 is fixed to the motor shaft 83 with screws (not shown). This screw is provided at a boss portion at the center of the sirocco fan 80 so as to be orthogonal to the motor shaft 83.
[0040]
The fan casing 90 is configured by combining the following parts. That is, the casing body 91, the fan chamber rear plate 92, the fan chamber left guide plate 93, the fan chamber right guide plate 94, and the guide member 95.
[0041]
The casing main body 91 is made of a synthetic resin molded product, and a fan chamber 96 for accommodating the sirocco fan 80 is formed. The fan chamber 96 opens toward the front and top surfaces. A fan chamber rear plate 92, a fan chamber left guide plate 93, and a fan chamber right guide plate 94 are fixed to the inner surface of the fan chamber 96. The fan chamber rear plate 92, the fan chamber left guide plate 93, and the fan chamber right guide plate 94 are made of metal. The guide member 95, the fan chamber left guide plate 93, and the fan chamber right guide plate 94 are combined to form an involute curve guide wall that surrounds the outer periphery of the sirocco fan 80.
[0042]
As described above, the upper surface of the fan chamber 96 is open and serves as the air outlet 97. The inlet of the air guide duct 55 is connected to the air outlet 97 (see FIG. 15). The fan chamber right guide plate 94 constitutes one side of the air outlet 97, and the guide member 95 constitutes the other side of the air outlet 97.
[0043]
The guide member 95 can be detached from the casing body 91 alone. When the guide member 95 is attached, the width of the air outlet 97 is smaller than the diameter D of the sirocco fan 80 (see FIG. 14), and the sirocco fan 80 cannot be extracted from the air outlet 97. After removing the guide member 95, the width of the air outlet 97 becomes W larger than D, and the sirocco fan 80 can be taken out from the air outlet 97.
[0044]
The heating means 73 arranged between the indoor side heat exchanger 71 and the indoor side blower 72 is configured as follows. In FIG. 17, 100 is a metal orifice plate. The orifice plate 100 has a rectangular front shape, and a circular ventilation opening 101 is provided at a position corresponding to the front surface of the sirocco fan 80 (see FIG. 18). The diameter of the ventilation opening 101 is the same as or slightly smaller than the diameter of the suction portion of the sirocco fan 80.
[0045]
A pair of left and right heater mounting plates 102 and 103 are mounted on the front surface of the orifice plate 100. The heater mounting plates 102 and 103 are made of metal L-shaped angles, and are fixed vertically to the left and right side edges of the orifice plate 100. Three heaters 104, 105, 106 are stretched horizontally between the heater mounting plates 102, 103. Each of the heaters 104, 105, 106 is composed of two nichrome wire coils, and is lined up and down at predetermined intervals. The nichrome wire coils are supported by porcelain insulators 107 at various places to prevent contact between the nichrome wire coils and not to contact the orifice plate 100.
[0046]
The upper end of the heater mounting plate 103 is bent horizontally to form a temperature sensing means mounting portion 108. The temperature sensing means 110 attached to the temperature sensing means attaching portion 108 is used to detect heat generated by the heaters 104, 105, 106 and to control energization to the heaters 104, 105, 106.
[0047]
In the present embodiment, the temperature sensing means 110 includes two thermostats 111 and 112 (see FIG. 19). One thermostat 111 detects an increase or decrease in temperature and turns on / off the power to the heaters 104, 105, and 106. The other thermostat 112 stops the operation of the air conditioner 1 when an abnormal temperature is detected.
[0048]
Each of the thermostats 111 and 112 is in a position where the temperature sensing unit is exposed to the heat radiation and the hot air flow from the heaters 104, 105 and 106. A sheet metal container 113 is fixed to the lower surface of the temperature sensing means mounting portion 108 for the thermostat 111 so as to wrap the temperature sensing portion of the thermostat 111.
[0049]
The container 113 is open toward the orifice plate 100, and a vent hole 118 is formed in this portion of the orifice plate 100 (see FIGS. 18 and 20). A portion where the vent 118 is present corresponds to the discharge side of the sirocco fan 80. Therefore, when the sirocco fan 80 rotates, the pressure on the back side of the vent 118 increases, and air flows from the fan chamber 96 into the container 113 through the vent 118. The air that has flowed into the container 113 escapes from a vent 114 (see FIG. 20) provided on the bottom surface of the container 113 to the front side of the orifice plate 100.
[0050]
The heating means 73 is attached as follows. As can be seen in FIG. 16, the base 150 is formed with a protrusion 151 at a slight distance from the front surface of the indoor fan 72. The protrusion 151 extends in the depth direction of the paper surface, and forms an engagement receiving portion 152 between the protrusion 151 and the indoor fan 72. The lower end of the orifice plate 100 is inserted into the engagement receiving portion 152. Then, the upper end of the orifice plate 100 is screwed to the fan casing 90 with a screw (not shown). Since only one end of the orifice plate 100 is screwed in this way, only a small number of screws need be used to fix the heating means 73.
[0051]
The orifice plate 100 is in close contact with the front surface of the fan casing 90 and also serves as a front plate of the fan chamber 96. The counterpart to which the orifice plate 100 is screwed is not limited to the fan casing 90. Any member in the housing 10 need only be able to play a supporting role.
[0052]
After fixing the heating means 73 as described above, the gap between the indoor heat exchanger 71 and the indoor blower 72 is closed with three metal plates shown in FIG. That is, the top plate 115, the left side plate 116, and the right side plate 117. As a result, the air passage from the indoor heat exchanger 71 to the indoor blower 72 is surrounded, and the entire amount of air heated by the heating means 73 is sucked into the indoor blower 72 without leaking outside. It is.
[0053]
Next, based on FIGS. 21-24, the detailed structure of the outdoor side heat exchange unit 120 is demonstrated.
[0054]
The main components of the outdoor heat exchange unit 120 are an outdoor heat exchanger 121 and an outdoor fan 122. These also have a rectangular front shape, and are arranged in the order of the outdoor blower 122 and the outdoor heat exchanger 121 from the front to the back.
[0055]
As shown in FIG. 23, the outdoor blower 122 includes a propeller fan 130, a motor 131 that rotates the propeller fan 130, and a fan casing 140. The motor 131 is fixed to the fan casing 140 via a metal mounting frame 132, and the motor shaft 133 protrudes from the back side of the fan casing 140. Propeller fan 130 is fixed to motor shaft 133 with a nut.
[0056]
The fan casing 140 has a circular ventilation hole 141 that is slightly larger than the diameter of the propeller fan 130, and the propeller fan 130 is disposed therein. A ring 134 is integrally formed with the propeller fan 130. The ring 134 is located on the back side of the ventilation port 141 and has a diameter larger than that of the ventilation port 141. The role of the ring 134 will be described later.
[0057]
A top plate 142 projects from the upper end of the fan casing 140 toward the back side. The top plate 142 covers the outdoor heat exchanger 121. By screwing the top plate 142 to the outdoor heat exchanger 121 with a screw (not shown), the upper ends of the outdoor fan 122 and the outdoor heat exchanger 121 are connected to each other, and the gap between the two is closed.
[0058]
As shown in FIG. 2, there is a gap between the outdoor heat exchange unit 120 and the air guide 54. This gap serves as a suction passage 62 for sucking air from the outside.
[0059]
The role of the ring 134 will be described. The base 150 has a tray shape as seen in FIG. 24, the front part is a drain pan 153 that receives drain from the indoor heat exchanger 71, and the rear part is a drain pan 154 that receives drain from the outdoor heat exchanger 121. It has become. The drain pan 153 is formed by fitting a styrene foam tray into the base 150. The bottom surface of the drain pan 153 is higher than the bottom surface of the drain pan 154, and all the drain received by the drain pan 153 flows into the drain pan 154.
[0060]
The drain pan 154 is formed with a raised portion 155 having a height lower than the bottom surface of the drain pan 153, and an overflow opening 156 is provided on the top surface. That is, the drain forms a puddle having a depth equal to the height of the raised portion 155 in the drain pan 154, then falls from the overflow opening 156 to the drain pan 24 of the bottom panel 11, and is drained from the water collecting tank 25 through the drain hose 30. The
[0061]
Ring 134 immerses its lower end in a puddle of drain pan 154. When the propeller fan 130 rotates, the ring 134 splashes water in the centrifugal direction, and the splash rides on the outdoor heat exchanger 121 on the air current blown from the propeller fan 130 to the outdoor heat exchanger 121. When the cooling operation is performed, the water applied to the outdoor heat exchanger 121 evaporates and takes heat of vaporization from the outdoor heat exchanger 121.
[0062]
A ridge-shaped drain cover 157 is provided in the drain pan 152. The drain cover 157 receives the bottom surface of the indoor heat exchanger 71 and prevents the indoor heat exchanger 71 from contacting the drain pan 153.
[0063]
A freeze prevention valve 158 is provided in the drain pan 154. The freeze prevention valve 158 is normally closed, but opens when the room temperature reaches 5 ° C., and all the water in the drain pan 154 is dropped onto the bottom panel 11 and drained to the outside. And prevent the ice from spreading on the drain pan 154.
[0064]
Next, the installation procedure of the air conditioner 1 will be described.
[0065]
The air conditioner 1 may be shipped in a state in which the housing 10 and the air conditioning unit 50 are combined, or may be shipped by being packed separately on the premise that they are combined on site. In the case of separate packing, the housing 10 may be packed in an assembled state or may be packed in a disassembled state. When the air conditioning unit 50 is separately packaged, it is packed in an assembled state as shown in FIG.
[0066]
When the housing 10 is shipped in a disassembled state, the filter 21, the duct 33, the duct base 34, and the heat insulating plate 41 are added to the bottom panel 11, the top panel 12, the front panel 13, the back panel 14, the left side panel 15, and the right side panel 16. Will be shipped.
[0067]
When the housing 10 is shipped in an assembled state, the unpacked housing 10 may be placed on the support base 5 locally. When shipped in a disassembled state, the bottom panel 11, the top panel 12, the front panel 13, the back panel 14, the left side panel 15, and the right side panel 16 are screwed to each other in a predetermined procedure, and the housing 10 Is mounted on the support base 5.
[0068]
When the housing 10 is placed on the support base 5, one of the three panels of the front panel 13, the left side panel 15, and the right side panel 16 is removed. Which panel is selected depends on local conditions. That is, the panel in the direction in which the air conditioning unit 50 can be easily inserted later is removed.
[0069]
The position of the housing 10 placed on the support base 5 is adjusted so that the protruding portion 19 on the back surface enters the ventilation port 3, and the leveling is performed by adjusting the height by the adjusting legs 31. Inside the housing 10, the duct base 34 is pulled up to the top by the rotation of the mounting screw 36. The air conditioning duct 6 is connected to the duct 33, and the drain hose 30 is connected to the water collecting tank 25.
[0070]
After the connection between the air conditioning duct 6 and the drain hose 30 is completed, the air conditioning unit 50 is inserted into the housing 10. After the insertion, the air conditioning unit 50 is pushed toward the back panel 14, and the back side edges (the top plate 142, the left side plate 160, the right side plate 161, and the back side edge of the base 150) of the air conditioning unit 50 are pressed against the gasket 18. . Thereby, an airtight connection part is formed between the ventilation opening 17 and the air conditioning unit 50. The hermetic connection at this point reduces the leakage of air and leads to effective use of energy.
[0071]
After the air conditioning unit 50 is airtightly connected to the ventilation opening 17, the air conditioning unit 50 is fixed to the housing 10 with screws (not shown).
[0072]
Then, the mounting screw 36 is turned to lower the duct 33 and the duct base 34, and the gasket 61 is brought into close contact with the upper edge of the air guide duct 55. Thereby, the air guide duct 55 and the duct 33 are airtightly connected.
[0073]
Thereafter, the removed panel is screwed to bring the housing 10 into a fully assembled state. Then, the filter 21 is fitted into the filter receiver 22.
[0074]
Next, the operation of the air conditioner 1 will be described.
[0075]
When the operation of the air conditioner 1 is started, the indoor fan 72 and the outdoor fan 122 start to blow air. The indoor fan 72 sucks indoor air into the housing 10 through the filter 21. The sucked indoor air passes through the indoor heat exchanger 71 and the heating means 73 and is then sucked into the indoor blower 72 and blown out from the air outlet 97. The blown air exits from the air guide duct 55 to the duct 33 and is sent to the air conditioning duct 6 from there.
[0076]
The outdoor blower 122 sucks outdoor air into the housing 10 through the suction passage 62. The sucked outdoor air is blown out from the outdoor blower 122 toward the outdoor heat exchanger 121, passes through the outdoor heat exchanger 121, and goes outside.
[0077]
During the cooling operation, the refrigerant that is compressed by the compressor 52 and has a high temperature is sent to the outdoor heat exchanger 121. In the outdoor heat exchanger 121, outdoor air blown by the outdoor blower 122 takes heat of the refrigerant. The refrigerant is cooled and liquefied.
[0078]
The liquefied refrigerant passes through an expansion valve (not shown) and then vaporizes inside the indoor heat exchanger 71 to cool the indoor heat exchanger 71. The indoor air sucked into the housing 10 by the indoor blower 72 is deprived of heat when passing through the indoor heat exchanger 71 and becomes cold. The cool air is sent to a predetermined room through the air conditioning duct 6 to cool the room.
[0079]
During heating operation, the refrigerant is circulated in the reverse direction. The condensed refrigerant is sent to the indoor heat exchanger 71, and the indoor air passing through the indoor heat exchanger 71 is warmed to warm up. The refrigerant evaporates inside the rear outdoor heat exchanger 121 after passing through an expansion valve (not shown), and cools the outdoor heat exchanger 121. When the outdoor blower 122 blows outdoor air to the outdoor heat exchanger 121, heat exchange is performed between the vaporized refrigerant and the outdoor air, and the refrigerant takes heat of the outdoor air. After raising the temperature in this way, the refrigerant returns to the compressor 52.
[0080]
During the heating operation, the heating means 73 is also energized to obtain heat from the indoor heat exchanger 71 and further raise the temperature of the air that has risen to some extent.
[0081]
Depending on the required heating temperature, the heaters 104, 105, 106 are energized as necessary. All the heaters 104, 105, and 106 are energized when the temperature is low or when it is necessary to increase the temperature of the room rapidly immediately after the start of the heating operation.
[0082]
Regardless of the number of heaters used, when the heater is energized, radiant heat and hot air flow strike the temperature sensing means 110. The thermostat 111 detects an increase or decrease in temperature and turns on / off the power to the heaters 104, 105, and 106. The other thermostat 112 stops the operation of the air conditioner 1 when an abnormal temperature is detected.
[0083]
The temperature sensing part of the thermostat 112 on the side where the abnormal temperature is detected is directly exposed to radiant heat and hot air flow. On the other hand, the thermostat 111 on the side that detects an increase or decrease in temperature is only exposed to a hot air stream that enters from the fan chamber 96 through the vent 118 during normal operation.
[0084]
The thermostat 111 is inherently susceptible to the radiant heat of the uppermost heater 104. However, here, the radiant heat is cut by the container 113, and only the airflow entering from the vent 118 is the temperature detection target. This airflow is an airflow in which the air that has passed through the heaters 104, 105, 106 is collected in the fan chamber 96 through the vent opening 101 of the orifice plate 100 and is agitated by the sirocco fan 80. It is uniform. Therefore, regardless of whether the heaters 104, 105, and 106 are all used or when power to any of the heaters is stopped, the thermostat 111 can perform stable temperature detection with little error.
[0085]
When the indoor blower 72 breaks down and the rotation of the sirocco fan 80 stops (fan lock), the flow of airflow from the vent 118 to the container 113 stops. Then, the heat radiation and the hot air current from the heater enter through the vent 114, and heat the temperature sensing part of the thermostat 111. As a result, the thermostat 111 detects an abnormality and turns off the heater.
[0086]
During the cooling operation, the drain dripping from the indoor heat exchanger 71. During the heating operation, drains dripping from the outdoor heat exchanger 121. The drain is received by the drain pan 153 or the drain pan 154 and creates a puddle in the drain pan 154. As described above, the puddle is used for cooling the outdoor heat exchanger 121 during the cooling operation.
[0087]
When a failure such as a failure occurs in the air conditioning unit 50, the panel that is most convenient for taking out the air conditioning unit 50 is removed from the three panels of the front panel 13, the left side panel 15, and the right side panel 16. The air-conditioning unit 50 can be taken out and inspected.
[0088]
If it can be determined that the heating means 73 is out of order, the left side plate 116 or the right side plate 117 is removed, the screw fixing the upper end of the orifice plate 100 is removed, and the lower end of the orifice plate 100 is removed from the engagement receiving portion 152. By removing, the heating means 73 can be removed from either the left or right side surface of the housing 10. Thereby, even when the air conditioner 1 is installed in the corner of the room, the heating means can be easily inspected and repaired. Install in reverse order.
[0089]
When a failure occurs in the sirocco fan 80 of the indoor blower 72, the air outlet 97 becomes an opening having a width W larger than the diameter of the sirocco fan 80 by removing the guide member 95 from the casing body 91. The sirocco fan 80 can be removed from the motor shaft 83 and taken out from the opening to perform necessary maintenance work. Therefore, it is not necessary to touch the components disposed in front of the indoor fan 72, that is, the indoor heat exchanger 71 and the heating means 73.
[0090]
Although one embodiment of the present invention has been described above, various modifications can be made without departing from the spirit of the present invention.
[0091]
【The invention's effect】
The present invention has the following effects.
[0092]
In the present invention, an indoor heat exchange unit comprising an indoor heat exchanger and an indoor blower, an outdoor heat exchange unit comprising an outdoor heat exchanger and an outdoor blower, and a compressor are housed. In the air conditioner housed inside, the indoor blower includes: a sirocco fan, a fan casing having an involute curved guide wall surrounding the outer periphery of the sirocco fan, and a motor for driving the sirocco fan. The indoor fan is arranged side by side so that the suction port faces the indoor heat exchanger, and the outlet of the indoor fan is provided at the end of the guide wall of the involute curve. It becomes, the width of the air outlet is provided to be smaller than the diameter of the sirocco fan, constituting a part of a portion at and the guide wall of the outlet Both when removed parts made smaller than the diameter of the sirocco fan, by the width of the outlet is larger than the diameter of the sirocco fan, retrieve the sirocco fan within the fan casing from the outlet Since it did in this way, a fan maintenance can be performed without touching the component arrange | positioned in the front of an air blower, and it does not take time for a fan maintenance.
[0093]
With this embodiment, the air-conditioning unit as well as arranged to be sandwiched the heating means for warming up tufts by said fan casing and said indoor heat exchanger, can be detached the heating means from any of the left and right sides of the housing Since it comprised in this way, a heating means can be attached or detached from either of the left and right side surfaces of a housing. Even when the air conditioner is installed in the corner of the room, the heating means can be attached and detached from either the left or right side, and there is no problem in inspecting and repairing the heating means.
[0094]
In the present invention, the heating means is fixed by engaging one end of the heating means with the engagement receiving portion in the housing and screwing the other end to any member in the housing. Therefore, the heating means can be fixed with a small number of screws, and the parts cost and assembly cost can be reduced.
[0097]
[Brief description of the drawings]
1 is a perspective view of an air conditioner according to an embodiment of the present invention. FIG. 2 is a vertical sectional view of the air conditioner. FIG. 3 is a partially enlarged view of FIG. 2. FIG. 4 is a horizontal sectional view of the air conditioner. FIG. 5 is an exploded perspective view of the housing. FIG. 6 is a partially enlarged vertical sectional view of the housing. FIG. 7 is an exploded perspective view of the top panel. FIG. 8 is a partially enlarged vertical sectional view of the top panel. FIG. 10 is a perspective view of a refrigeration cycle unit. FIG. 11 is a perspective view of a wind guide and a duct. FIG. 12 is a perspective view of an air conditioning unit in an assembled state. FIG. 13 is an exploded perspective view of an indoor heat exchange unit. Fig. 14 is an exploded perspective view of the indoor fan. Fig. 15 is a vertical sectional view of the air conditioner showing the connection between the indoor fan and the air duct. Fig. 16 is a side view of the indoor heat exchange unit. ] Perspective view of heating means [FIG. 18] Disassembly of heating means FIG. 19 is a perspective view of the temperature sensing means portion. FIG. 20 is a partially enlarged sectional view of the temperature sensing means portion. FIG. 21 is a perspective view of the outdoor heat exchange unit combined with the base. FIG. 23 is an exploded perspective view of an outdoor fan. FIG. 24 is a perspective view of a base.
DESCRIPTION OF SYMBOLS 1 Air conditioner 2 Wall 3 Ventilation opening 4 Floor 5 Support stand 6 Air conditioning duct 10 Housing 11 Bottom panel 12 Top panel 13 Front panel 14 Rear panel 15 Left side panel 16 Right side panel 18 Gasket 24 Drain pan 30 Drain hose 33 Duct 34 Duct Base 50 Air-conditioning unit 70 Indoor heat exchange unit 71 Indoor heat exchanger 72 Indoor air blower 73 Heating means 90 Fan casing 95 Guide member 97 Air outlet 110 Temperature sensing means 111, 112 Thermostat 113 Container 114 Vent 120 Outdoor heat exchange Unit 121 outdoor heat exchanger 122 outdoor blower 150 base 152 engagement receiving portion

Claims (3)

An air conditioning unit including an indoor heat exchanger unit including an indoor heat exchanger and an indoor fan, an outdoor heat exchanger unit including an outdoor heat exchanger and an outdoor fan, and a compressor is housed in the housing. In air conditioner,
The indoor fan is composed of a sirocco fan, a fan casing having an involute curved guide wall surrounding the outer periphery of the sirocco fan on the inner surface, and a motor for driving the sirocco fan.
The indoor fan is arranged side by side so that the suction port faces the indoor heat exchanger, and the outlet of the indoor fan is provided at the end of the guide wall of the involute curve,
A width of the air outlet is provided so as to be smaller than a diameter of the sirocco fan, a part of the air outlet and a part of the guide wall are formed , and a part that is smaller than the diameter of the sirocco fan is removed. was time, the width of the outlet is larger than the diameter of the sirocco fan, an air conditioner, characterized in that from the air outlet and to release the said sirocco fan within the fan casing. Together with the heating and cooling unit is arranged to be held between the heating means for warming up tufts by said fan casing and said indoor heat exchanger, that the heating means is configured to allow removable from any of the left and right sides of the housing The air conditioner according to claim 1, wherein   3. The heating means is fixed by engaging one end of the heating means with an engagement receiving portion in the housing and screwing the other end to any member in the housing. Air conditioner as described in.

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