JP5789633B2 - Air conditioner - Google Patents

Description

  The present invention relates to an air conditioner remote control device (hereinafter referred to as a remote controller) for remotely operating an air conditioner body, and an air conditioner system including the remote controller, and in particular, a function of adjusting room temperature, humidity, and the like. In addition, the present invention relates to a remote controller that can receive indoor information transmitted from an air conditioner body through two-way communication and an air conditioning system including the remote controller.

  Conventionally, air conditioning systems capable of bidirectional communication between the air conditioner body and the remote control are disclosed in Japanese Patent Laid-Open No. 10-340123 (Reference 1) and Japanese Patent Laid-Open No. 6-313610 (Reference 2). There is something that is.

  In the above document 1, by operating a predetermined button provided on the remote controller, the operating state of the currently operating air conditioner body, for example, information such as room temperature, operation mode, and wind direction is directed from the air conditioner body to the remote controller. A remote controller capable of displaying the operating state of the air conditioner main body by being transmitted is disclosed.

  In the remote control described in the above-mentioned document 2, by operating a predetermined button provided inside the opening / closing lid, a signal having a specific diagnosis code is transmitted from the remote control to the air conditioner body, and this signal is received. A remote controller is disclosed in which the operating history information can be obtained without disassembling the air conditioner body by transmitting the operating history information corresponding to this signal to the remote controller.

  Moreover, as a prior art about the display part which displays the driving | running state of an air conditioner main body, the air which displays the driving | running state of an air conditioner main body, or the indoor and outdoor air condition on the liquid crystal display part provided in the air conditioner main body. There are a harmony system (known example 1) and a remote controller (known example 2) that displays indoor temperature and humidity information on a display unit provided in the remote controller.

  In order to create a comfortable indoor environment, not only room temperature but also humidity greatly affects. In recent years, in air conditioners, the feeling that the indoor environment feels comfortable varies from person to person, so it is possible to create not only room temperature but also humidity to create a comfortable indoor environment tailored to each person Realization of an air-conditioning system having

  In the remote controller disclosed in the above-mentioned document 1, changes in the operating state of the air conditioner main body, for example, changes in the operation mode, air volume, and room temperature can be displayed on the remote controller, and these controls can be performed. However, in order to make the indoor environment more comfortable, it is necessary to display the change state of humidity and control the humidity. However, in the remote control described in Document 1, the humidity display and No control is disclosed. For this reason, it is difficult to perform an operation for creating an indoor environment tailored to the user. Furthermore, there is no specific description regarding the external shape of the remote control and the arrangement of the operation buttons in the above-mentioned document 1, and a device for the arrangement and ease of use of the operation buttons has been desired.

  In the remote control disclosed in the above-mentioned document 2, since there is no disclosure about transmitting and displaying the change in the operation state of the air conditioner body to the remote control, the user can change the operation state of the air conditioner body, For example, it is difficult to confirm the change state such as the operation mode, air volume, room temperature, and humidity. Also, in the remote control described in the above-mentioned document 2, the user can only control the room temperature and the operation mode, and the display and control of humidity necessary for creating a more comfortable indoor environment is disclosed. In addition, it is difficult to perform an operation for creating an indoor environment tailored to the user. Furthermore, most of the operation buttons of the remote control described in the above-mentioned document 2 are arranged inside the opening / closing lid, and when selecting the operation mode of the air conditioner body, etc., open the opening / closing lid and press the button. It had to be operated, and troublesome operation of the remote control remained.

  Moreover, in the air conditioning system of the said well-known example 1, since the liquid crystal display part is provided in the air conditioner main body, when confirming a driving | running state or an indoor and outdoor air condition, you have to approach an air conditioner main body. Annoyance remained.

  Furthermore, in the remote control of the above-mentioned known example 2, the indoor temperature and humidity information can be displayed in an image, but since the humidity cannot be controlled, a comfortable indoor environment suitable for the user can be created. It was difficult.

  The objective of this invention is providing the air conditioning apparatus which can perform operation of various operation buttons easily, and can reduce the operation mistake of an operation button.

As means for achieving the above object, an air conditioner according to the present invention includes an air conditioner capable of cooling operation, heating operation and dehumidifying operation, a remote control device for instructing the air conditioner to operate, An air conditioner comprising an indoor temperature detecting means for detecting temperature and an indoor humidity detecting means for detecting indoor humidity, wherein the remote operation device includes a dehumidification button for instructing dehumidification operation, and the remote operation device. A room temperature setting button for setting a room temperature arranged on one side in the width direction of the casing, and a room arranged on the other side of the room temperature setting button in the width direction of the casing of the remote control device. An indoor humidity setting button for setting the humidity, and an instruction button for instructing to display the indoor temperature detected by the indoor temperature detecting means and the indoor humidity detected by the indoor humidity detecting means on the remote control device And the room temperature detected by the room temperature detecting means is displayed on one side in the width direction of the casing of the remote control device in which the room temperature setting button is arranged and detected by the room humidity detecting means. And a display unit for displaying the room humidity on the other side in the width direction of the casing of the remote control device in which the room humidity setting button is arranged .

  ADVANTAGE OF THE INVENTION According to this invention, while being able to operate various operation buttons easily, the air conditioning apparatus which can reduce the erroneous operation of an operation button can be provided.

1 is a schematic configuration diagram of an air conditioner according to an embodiment of the present invention. It is a longitudinal cross-sectional view of the indoor unit which concerns on one Embodiment of this invention. It is a refrigerating cycle figure of the air conditioner concerning one embodiment of the present invention. It is a figure which shows the external appearance of the indoor unit which concerns on one Embodiment of this invention. It is a figure which shows the structure of the front grille of the indoor unit which concerns on one Embodiment of this invention. It is a figure which shows the external appearance of the remote control which concerns on one Embodiment of this invention. It is a figure which shows the external appearance of the remote control which concerns on one Embodiment of this invention. It is a figure which shows the structure of the upper cover which comprises the housing | casing of the remote control which concerns on one Embodiment of this invention. It is a figure which shows the structure of the lower cover which comprises the housing | casing of the remote control which concerns on one Embodiment of this invention. It is a figure which shows the structure of the battery cover which comprises the housing | casing of the remote control which concerns on one Embodiment of this invention. It is a figure which shows the structure of the display part of the remote control which concerns on one Embodiment of this invention. It is a figure which shows the structure of the operation button with a low use frequency provided in the remote control which concerns on one Embodiment of this invention. It is a figure which shows the structure of the operation button with high use frequency provided in the remote control which concerns on one Embodiment of this invention. It is a figure which shows the structure of the opening-and-closing lid | cover of the remote control which concerns on one Embodiment of this invention. It is a block diagram which shows schematic structure of the air conditioner which concerns on one Embodiment of this invention. It is a figure which shows the display state of the display part of the remote control which concerns on one Embodiment of this invention. It is a figure which shows the arrangement | positioning relationship between the operation state display part of the indoor unit which concerns on one Embodiment of this invention, and the operation button of a remote control. It is a figure which shows the structure of the driving | running state display part of the indoor unit which concerns on one Embodiment of this invention. It is a figure which shows the structure of the driving | running state display part of the indoor unit which concerns on one Embodiment of this invention. It is a figure which shows the structure of the driving | running state display part of the indoor unit which concerns on one Embodiment of this invention. It is a figure which shows the structure of the driving | running state display part of the indoor unit which concerns on one Embodiment of this invention. It is a figure which shows the structure of the driving | running state display part of the indoor unit which concerns on one Embodiment of this invention. It is a figure which shows the structure of the driving | running state display part of the indoor unit which concerns on one Embodiment of this invention. It is a flowchart which shows operation | movement of the air conditioner which concerns on one Embodiment of this invention. It is a figure which shows the structure of the transmission / reception part of the indoor unit which concerns on one Embodiment of this invention. It is a front view of the indoor unit which shows other embodiment of this invention. It is a front view of the remote control which shows other embodiment of this invention. It is a figure which shows the structure of the gradation grill which shows other embodiment of this invention.

  Hereinafter, embodiments of the present invention will be described in detail with reference to FIGS.

  1 to 25 show an embodiment of an air conditioning system according to the present invention. First, the schematic structure of the air conditioning system according to the present embodiment will be described with reference to FIG. FIG. 1 is an external view of an air conditioning system according to the present embodiment.

  In FIG. 1, an air conditioning system according to the present invention is attached to an indoor wall surface or the like, and is disposed outside an air conditioner main body (hereinafter referred to as an indoor unit) 100 that adjusts an indoor environment (air conditioning) state. The air conditioner includes an outdoor unit 200 and a remote operation unit (hereinafter referred to as a remote controller) 300 that controls the operation of the air conditioner.

  The indoor unit 100 includes a first suction portion (hereinafter referred to as a front suction grill) 131 provided on the front surface of the horizontally long casing 150 via an indoor fan 109 (see FIG. 2) built in the casing 150. And a second suction section (hereinafter referred to as an upper suction grill) 132 provided at the upper portion, the room air is taken into the casing 150, and heat is exchanged via a built-in heat exchanger (see FIG. 2). Dehumidifying is performed, and the room air is blown out from the air outlet 133 provided at the lower front of the housing 150.

  The outer periphery of the casing 150 is covered with a back cabinet 210 that constitutes the rear part, a decorative panel 220 that constitutes a side surface, and a front panel 230 that constitutes a front surface and includes the front suction grill 131. The length in the height direction has a long shape.

  The indoor fan 109 is provided at approximately the center of the casing 150 so that the longitudinal direction thereof coincides with the longitudinal direction of the casing 150.

  In this embodiment, the front suction grill 131 is provided at the front center portion of the housing 150 at a position close to the indoor fan 109, and the upper suction grill 132 is located above the indoor fan 109. 150 is provided on the upper surface. A flat portion is formed between the front suction grill 131 and the upper suction grill 132, that is, at a position in the upper front portion of the housing 150. Accordingly, the front suction grill 131 is provided at a position where the best suction efficiency is provided, and the operation efficiency is improved while being positioned at the upper portion thereof, and the position where the operation efficiency is less affected than the front suction grill 131. The indoor unit 100 is adapted to the wall surface of the room by leaving the flat surface part in the upper part of the front surface of the casing 150.

  Here, in this embodiment, the front suction grill 131 and the upper suction grill 132 have a grill shape based on a horizontal rail along the longitudinal direction of the casing 150. The front suction grill 131 employs an oblique grill with a dense pitch to make it difficult for the user to see the inside of the casing 150 in the installed state. Further, since the upper suction grill 132 is in a position where it is difficult to see, the opening area is increased to improve the operation efficiency.

  Furthermore, in this embodiment, a gradation grill 140 (see FIG. 5) is formed in the flat portion, the opening area of which continuously or gradually decreases from the front suction grill 131 and conforms to the flat portion. Yes. The gradation grill 140 increases the pitch P2 continuously or stepwise up to the height h2 of the gradation grill 140 without changing the size of the opening 595, or the height h3 of the opening 595 is gradation. It is formed by reducing the height of the grill 140 to the height h2 continuously or stepwise. Accordingly, since the gradation grill 140 formed on the flat surface portion can be formed into a grill shape that is continuous with the flat surface portion from the front suction grill 131, the separation between the front suction grill 131 and the flat surface portion is reduced. Thus, the front suction grill 131 can be made inconspicuous, the suction area can be increased, and the efficiency can be improved. The configuration of the gradation grill 140 will be described later.

  The air outlet 133 is provided with a pair of lateral louvers 134 whose opening and closing angles can be adjusted by a motor (not shown). The opening of the air outlet 133 is concealed when the operation of the indoor unit 100 is stopped, and the air opening is opened during operation. By adjusting the opening / closing angle of the lateral louver 134, the blowout angle can be adjusted in accordance with the operation mode (cooling, heating, dehumidification) of the indoor air blown out from the outlet 133.

  In addition, the indoor unit 100 is provided with a transmission / reception unit 110 that transmits / receives data to / from the remote controller 300 and an operation state display unit 135 that displays an operation state of the indoor unit 100 on the front surface of the casing 150. Yes. In this embodiment, the transmission / reception unit 110 is provided on the side where the electrical components of the indoor unit 100 are arranged, that is, on one side of the air outlet 133 to shorten the wiring, thereby improving the assemblability. In addition, the operation state display unit 135 is provided at a substantially center of the casing 150, that is, between the front suction grill 131 and the outlet 133, thereby improving visibility from the user. Further, the operation state display unit 135 includes a plurality of continuous light sources, and the number of light sources is set step by step in correspondence with the output of the operation state or the difference between the current temperature or humidity with respect to the set temperature or humidity. By lighting it, the user is made to recognize the driving situation in an image. Moreover, various error displays and various status displays are possible by combining the lighting of the plurality of light sources.

  Furthermore, in this embodiment, visibility is improved by providing the operation state display unit 135 with each information display area corresponding to displayed information. In this embodiment, for example, it is divided into a first information display area corresponding to temperature and a second information display area corresponding to humidity (see FIG. 18), and the first information display area and the second information display area are divided into a plurality of areas. The light sources are formed in a bar shape that is arranged in a row, and are arranged in a left and right manner with the vicinity of the central position on the left and right sides of the housing 150 as the center. By forming in this way, it is possible to display temperature and humidity separately while taking a simple form to improve the design effect, and to display the operation output or the temperature difference and humidity difference in a visually easy-to-understand manner. be able to. In addition, the operation state display unit 135 is long and narrow in the left and right direction, and can be efficiently arranged in the space between the blowing unit 133 and the front suction grill 131.

  The outdoor unit 200 includes a compressor, a heat exchanger, and an outdoor fan (not shown) inside. The outdoor unit 200 is connected to the indoor unit 100 via a refrigerant pipe and electric wiring, and can circulate the refrigerant between the two units to perform indoor air conditioning and dehumidifying operation.

  The remote controller 300 includes a transmission / reception device 310 and can transmit various operation instruction signals to the indoor unit 100 and obtain various information from the indoor unit 100. In this embodiment, information from various sensors provided in the indoor unit 100 and the outdoor unit 200, for example, information such as room temperature, humidity, and outdoor temperature, is obtained and obtained in the display unit 320 provided in the remote controller 300. Information can be displayed.

  The remote controller 300 of this embodiment displays the information obtained from the indoor unit 100 or the outdoor unit 200 on the display unit 320 as, for example, clear data as numerical information, and compares the information with the indoor unit. By displaying information set in advance for automatically driving 100 or information input (set) by the user, the operability of setting information input is improved, and the setting information and the obtained information are compared. Visibility can be improved.

  Further, in this embodiment, in order to improve the input property and visibility, the display unit 320 includes an acquisition information display area 320a for displaying the acquisition information, and a setting information display area 320b for displaying setting information. These are divided and provided adjacent to each other, so that the setting information and the obtained information can be easily compared. Further, in the present embodiment, the obtained information display area 320a and the setting information display area 320b are respectively set as a third information display area and a fourth information display area corresponding to the types of setting information and obtained information to be displayed. The input property and the visibility are improved by comparing the information displayed in the third information display area and the fourth information display area. Furthermore, in the present embodiment, by assigning operation buttons with high use frequency related to information displayed in the third information display area and the fourth information display area to the left and right corresponding to the respective information display areas, Operability is improved.

  In particular, in the present embodiment, information related to temperature is displayed in the third information display area, and information related to humidity is displayed in the fourth information display area, and the third information display area and The operability is improved by assigning the temperature-related operation buttons and the humidity-related operation buttons to the left and right corresponding to the fourth information display area. Further, in this embodiment, when the user points the remote controller toward the indoor unit 100, the operation state display unit 135 distributed to the left and right is divided into the information display area and the operation buttons distributed to the left and right of the remote controller. To match.

  The air conditioning system in the present embodiment takes in indoor air from the front suction grill 131 and the upper suction grill 132 by operating the remote controller 300 and operating the indoor unit 100, and this indoor air is exchanged with the outdoor unit 200. Heat exchange is performed using a refrigeration cycle, which will be described later, and indoor air that has been subjected to heat exchange is blown out from the blowout port 133, whereby indoor cooling operation, heating operation, dehumidification operation, and the like can be performed.

  One of the major features of this embodiment is that the suction grill disposed on the front surface of the casing 150 of the indoor unit 100 is connected to the front suction grill 131 and the front suction grill 131, and the opening is opened. This is because it is configured with a gradation grill 140 (see FIG. 5) whose area changes stepwise or continuously. Of course, the front suction grill itself may be processed integrally with the gradation grill 140 as a gradation grill that changes stepwise or continuously. Thereby, designability and installability can be improved while improving operating efficiency.

  Furthermore, another major feature of the present embodiment is that an operation display mechanism that can recognize the driving state as an image in the indoor unit 100 and as clear numerical information in the remote controller 300 is employed. Since the operation display mechanism can exchange information bi-directionally, accurate driving information is obtained on the remote controller 300 side, and the obtained driving information is displayed on the display unit 320 of the remote controller 300. Thereby, when performing a driving operation, the information can be accurately recognized on the remote controller 300 side close to the user as numerical data, and various operations can be performed, and the information is obtained from the indoor unit 100 or the outdoor unit 200. Various types of information can be recognized.

  On the other hand, when no operation is performed with the remote controller 300 or when it is not necessary to obtain detailed information, the driving status display unit 135 of the indoor unit 100 can grasp the driving status as image information.

  Further, in this embodiment, the arrangement of the display unit 320 of the remote controller 300 and the frequently used operation buttons are sorted according to the type of information, and the arrangement is made to coincide with the arrangement of the operation state display unit 135 of the indoor unit 100. Thus, it is possible to improve the operability and visibility of a person who operates toward the indoor unit 100.

  Hereinafter, the air conditioning system according to the present embodiment will be described in detail with reference to FIGS.

  First, the indoor unit 100 will be described in detail with reference to FIGS. 2 is a longitudinal sectional view of the indoor unit 100, FIG. 3 is an apparatus diagram of the refrigeration cycle, FIG. 4 is an external view of the indoor unit 100, and FIG. 5 is a partially enlarged view of the front grille of the indoor unit 100 and a cross-sectional view of the main part thereof. is there.

  In FIG. 2, the casing 150 of the indoor unit 100 includes a resin-molded back cabinet 210, a resin-molded decorative cover 220 provided on the front surface of the back cabinet 210, and a resin provided on the front surface of the decorative cover 220. And a molded front panel 230.

  In the indoor unit 100, basic internal structures such as a once-through indoor fan 109, a heat exchanger, and a drain pan are attached to the inside of the back cabinet 210. The indoor fan 109 is mounted in a horizontal position below the back cabinet 210, with a rotary shaft at one end supported by a fan motor and a rotary shaft at the other end supported by a bearing.

  The heat exchanger includes three heat exchange units 102, 103, and 104. The first heat exchange unit 102 is arranged in a vertical position at the front of the indoor fan 109, and the second heat exchange unit 103, The three heat exchanging units 104 are arranged in a mountain shape behind the upper end of the heat exchanging unit 102 so as to wrap the front part and the upper part of the indoor fan 109. The drain pan 170 is disposed below the heat exchanger, receives dew from the heat exchanger, and discharges it to the outside through a drain nozzle (not shown). Further, the drain pan 180 receives the dew from the third heat exchanging unit 104 and forms the blowout air passage 250 together with the back cabinet 210. On the lower surface of the drain pan 170, a plurality of wind directions in the horizontal direction and the wind direction plates in the vertical direction are attached.

  Here, a stepping motor is attached to one end of the wind direction plate, and the wind direction angle can be automatically changed.

  Now, a basic internal structure such as the indoor fan 109 attached inside the back cabinet 210 is included in the indoor unit 100 by attaching the decorative cover 220. An air purifying filter 260 and the filter 130 are detachably attached to the front surface (left side in the drawing) of the decorative cover 220. Further, the display unit and the light receiving unit (not shown) are attached to the decorative cover 220. The front panel 230 is rotatably supported by the decorative cover on the front surface of the decorative cover 220 via opening / closing hinges provided on both sides of the upper end thereof, and the lower end thereof is attached to be openable.

  In addition, a drain pan 180 that receives dew from the third heat exchange unit 104 is formed on the upper inner wall of the back cabinet 210. Water droplets collected in the drain pan 180 are collected in the drain pan 170 above the blow-out part 133 through a passage (not shown). The drain pan 180 is formed in an arc shape in cross section with the decorative cover 220 that forms the lower inner wall of the back cabinet 210 and the blow-out portion 133, and is disposed in the middle of the indoor unit 100 slightly behind. A rear ventilation surface 250 that wraps the fan 109 is formed. A lower surface portion of the drain pan 170 that receives the dew of the heat exchanger constitutes a front ventilation surface of the blowing portion 133, and a blowing ventilation passage 250 is constituted by the front ventilation surface and the rear ventilation surface.

  Further, the horizontal wind direction plate is rotatably supported at the rear of the lower surface of the drain pan 170 and the lower end of the lower inner wall of the back cabinet 210.

  The second heat exchange unit 103 and the third heat exchange unit 104 combined in a mountain shape are provided with their apexes bent at a connection point Q substantially above the indoor fan 109. The connection point Q is located at a joint between the back cabinet 210 and the decorative cover 220. In this embodiment, the upper surface suction grill 132 is composed of an upper surface front suction grill 132 a formed on the decorative cover 220 and an upper surface rear suction grill 132 b provided on the back cabinet 200. Therefore, the second heat exchanging part 103 constituting the front side of the heat exchanger combined with the mountain shape having a high heat exchange efficiency is located at the top of the mountain shape with the connection point Q having a poor heat exchange efficiency as the top. From the front surface suction grille 132a, the third heat exchanging part 104 at the rear of the mountain shape can efficiently suck indoor air from the upper surface rear suction grille 132b.

  The first heat exchange unit 102, the second heat exchange unit 103, and the third heat exchanger 104 are configured to be thermally separated by a thermal cutting line 124. As will be described in detail with reference to FIG. 3, in this embodiment, a dehumidifying squeezing device 105 that performs a squeezing action during dehumidifying operation is provided, and a second heat exchange unit 103 disposed in a mountain shape at one of the connection ports is provided. A pipe of the third heat exchange unit 104 is connected, and a pipe of the first heat exchange unit 102 is connected to the other connection port of the dehumidifying expansion device 105.

  In the heat exchanger shown in FIG. 2 (the first heat exchanging unit 102, the second heat exchanging unit 103, and the third heat exchanging unit 104), 120 indicated by a circle passes through a plurality of radiating fins. The heat transfer tubes are provided as described above, and are connected by a connection tube (not shown).

  According to the structure of this embodiment, indoor air is filtered from the front suction grill 131, the upper front suction grill 132a, and the upper rear suction grill 132b by the indoor fan 109 as indicated by arrows 91, 92, 93, respectively. The air is sucked into the indoor unit 100, and during the cooling / heating operation, the sucked indoor air is heat-exchanged to cold air or hot air, and during the dehumidifying operation, the first heat exchange unit 102 exchanges heat with the cold air, and is arranged in a mountain shape. The second heat exchanging unit 103 and the third heat exchanging unit 104 separated from the first heat exchanging unit 102 are subjected to heat exchange with warm air, passed through the indoor fan 109, and blown into the room from the outlet 133. The This structure will be further described with reference to FIG.

  In FIG. 3, 500 is a compressor that compresses a variable capacity refrigerant by controlling the rotational speed, 510 is a four-way valve that switches the operation state, 520 is an outdoor heat exchanger, and 530 is an electric expansion that can be fully opened without a throttling action. In the valve, the heat exchanger and the dehumidifying expansion device 105 are added, and these are connected in an annular shape by a connection pipe to constitute a refrigeration cycle. Moreover, in FIG. 3, one Embodiment of the flow-path state of the heat exchanger tube of the said heat exchanger is shown typically.

  The heat exchanger is configured such that the second heat exchange unit 103 and the third heat exchange unit 104 are integrally connected, so that the heat transfer tubes become the two refrigerant flow paths 540 and 550, and further the cutting line. The first heat exchanging section 102 thermally separated by 124 is constituted by two refrigerant flow paths 560 and 570. The refrigerant flow paths 540 and 550 and the two refrigerant flow paths 560 and 570 are connected by connecting pipes 106 and 107 via the dehumidifying throttle device 105. Reference numeral 580 denotes an outdoor fan.

  In the above indoor unit structure and refrigeration cycle, the four-way valve 510 is switched in the same manner as in the cooling operation in the dehumidifying operation, and the dehumidifying expansion device 105 is appropriately throttled to fully open the electric expansion valve 530, whereby the refrigerant is shown by a one-dot chain line. As shown, the compressor 500, the four-way valve 510, the outdoor heat exchanger 520, the electric expansion valve 530, the second heat exchange unit 103 and the third heat exchange unit 104 of the heat exchanger, the dehumidifying expansion device 105, and the heat exchanger 101 The first heat exchange unit 102, the four-way valve 510, and the compressor 500 are circulated in this order. The outdoor heat exchanger 520 is an upstream condenser, and the second heat exchange unit 103 and the third heat exchange unit 104 are heat exchangers. The downstream condenser and the first heat exchange part 102 of the heat exchanger are operated so as to be an evaporator.

  In FIG. 2, when indoor air is flown by the indoor fan 109 as indicated by arrows 91, 92, and 93, the indoor air is cooled and dehumidified by the first heat exchange unit 102 that acts as an evaporator, and at the same time, The second heat exchanging section 103 and the third heat exchanging section 104 serving as a side condenser, that is, a heater are heated, and these air are mixed and blown out into the room.

  In this case, by controlling the rotation speed to control the capacity of the compressor 500 and the blowing capacity of the indoor fan 109 and the outdoor fan 580, the capacity of the cooler and the heater can be adjusted. The temperature can be changed in a wide range. Thus, according to this embodiment, a fine dehumidifying operation can be efficiently performed using the refrigeration cycle.

  Next, the external structure of the indoor unit 100 will be described in detail with reference to FIG. 4A and 4B are external views of the indoor unit 100. FIG. 4A is a front view, FIG. 4B is a right side view, FIG. 4C is a plan view, and FIG. 4D is a bottom view.

  In FIG. 4, the indoor unit 100 is set to have a lateral width W1 of 798 mm, a height H1 of 285 mm, and a depth D1 of 203 mm, and the depth D1 has a laterally long outer dimension smaller than the height H1.

  (C) In the right side view shown in the figure, the indoor unit 100 forms a back cabinet 210 in a box shape, and the upper and lower surfaces of the decorative cover 220 and the front panel 230 are substantially vertically symmetrical and forward when viewed from the side. The front panel 230 formed between the curved surfaces 33 and 34 is formed on the wall surface by forming the curved surface 35 slightly inclined rearward. In the state, the indoor unit 100 can be shown in a compact form adapted to the wall surface.

  Furthermore, since the upper surface is formed by the curved surface 33, the upper surface suction grille 132 can be made inconspicuous in the installed state, and indoor air can be efficiently sucked from the upper front. On the other hand, by forming the lower surface with the curved surface 34, it is possible to give an inclination to the blowing portion 133 by making use of the “surface” that is easy to adjust to the installation environment.

  The indoor unit 100 has a uniform thickness when the front panel 230 is viewed from the side, and has a shape that wraps around the curved surfaces 33 and 34 at the top and bottom. Then, a concave groove that is continuous with the dividing line of the parts of the front panel 230 is formed so that the thickness of the front panel 230 is continuous with the decorative panel 220. As a result, the front panel 230 and the decorative cover 220 are fitted to each other well, and an accent line is formed on a continuous large round curved surface to reduce the sense of depth, thereby further improving the compactness.

  (A) In the front view shown in the drawing, the indoor unit 100 has a compact shape with a built-in indoor fan 109 that has a built-in round shape with the center of both side surfaces secured to improve the internal mounting efficiency. A rounded appearance shape is formed as a whole. Further, the front suction grill 131 is provided at the center of the large curved surface 35 formed on the front surface of the front panel 230, and a lower flat part having an operation state display part 135 is formed below the front suction grill 131, and the upper part is formed at the upper part. An upper flat portion provided with the gradation grill 140 is formed.

  This will be further described with reference to FIGS. First, in FIG. 2, the once-through indoor fan 109 employed in this embodiment can be sucked from the upper side by the casing of the back cabinet 210 and the decorative panel 220 and blown downward. At this time, due to the characteristics of the once-through fan, indoor air can be sucked more efficiently as the position is closer to the indoor fan 109. Here, in this embodiment, the indoor fan 109 is arranged at the center of the vertically long casing 150, the first heat exchange unit 102 is arranged on the front side thereof, and the second heat exchange unit 103 and the third heat exchange unit 103 are arranged on the upper part. The heat exchange unit 104 is arranged in a mountain shape. Accordingly, the indoor air sucked from the first heat exchange unit 102 has the best suction efficiency. However, since the position above the first heat exchange unit 102 is away from the indoor fan 109, the suction efficiency is lowered. Further, at the upper part of the first heat exchanging part 102, there is a connecting part to the second heat exchanger 103 and the third heat exchanging part 104 arranged in a mountain shape on the upper front part, and further, the upper part is a makeup part. Since there is a joint between the panel 220 and the front panel 230, the suction efficiency at the upper front position is lower than that at the lower front.

  On the other hand, since the indoor air sucked from the upper surface suction grill 132 provided in the upper part of the housing 150 is sucked from a position away from the indoor fan 109, the suction efficiency is low. However, since the upper surface suction grill 132 is provided at a position that is difficult for the user to see in the installed state, the suction efficiency can be improved by increasing the opening area of the upper surface suction grill 132.

  As described above, the indoor unit 100 according to this embodiment is provided with the front suction grill 131 having a large opening area and the inside difficult to see in the center of the front portion of the casing 150 having the highest suction efficiency. A gradation grill 140 whose opening area becomes smaller as the suction efficiency is lower is provided at the upper position where the suction efficiency is lower, and an upper suction grill 132 having a large opening area is provided on the upper surface of the housing 150 where the suction efficiency is relatively low. ing.

  This structure will be further described with reference to FIG. In this embodiment, the front suction grill 131 and the gradation grill 140 are composed of a plurality of ribs 590a and 590b whose cross section is based on a horizontal rail. Each of the ribs 590a and 590b is formed in a plate shape in cross section, and the longitudinal direction of the ribs 590a and 590b is oriented in the horizontal direction in the installed state. The end portion 591 is formed so as to be at the upper position in the installed state from the end portion 592a serving as the downstream side Z2. Thereby, when the indoor unit 100 is installed on the wall surface, it is possible to make it difficult for the user to see the inside of the front suction grill 131 and the gradation grill 140.

  In this embodiment, the height of the end portion 592b serving as the downstream side Z2 of each of the ribs 590a and 590b is substantially the same as or higher than the height of the end portion 591 serving as the upstream side Z1. Forming. Accordingly, it is possible to easily remove the mold at the time of resin molding, and it is possible to obtain an effect of making it difficult for the user to see the inside of the front suction grill 131 and the gradation grill 140.

  Moreover, in this embodiment, the size (width and height) of the horizontally long opening 595 formed between the ribs 590a and 590b of the front suction grill 131 and the gradation grill 140 is set to substantially the same size. . The front suction grill 131 that requires an opening area is arranged densely with a small pitch P1 to increase the opening area, and the pitch P2 of the gradation grill 140 is set at the front of the rib 590b between the openings. The gradation effect is produced by forming the height so as to be gradually larger or stepwise larger than the height of the rib 590 of the front suction grill 131.

  As shown in FIG. 5, the ribs 590a and 590b in the present embodiment have a substantially “L-shaped” cross-sectional shape, and are formed with a grill for forming the front grill 131 and the gradation grill 140. Parts 597a and 597b. In particular, in the present embodiment, the gradation grill 140 is formed by changing the grill forming portion 597b provided on the rib 590b continuously or stepwise toward the upper suction grill 132. It is characterized by having. Thereby, the effects as described above can be obtained.

  In the present embodiment, the description has focused on the grill forming portion 597b forming the gradation grill 140, but the present invention is not limited to this. For example, the front grill 131 and the gradation grill 140 are made continuous by changing the grill forming portion 597a provided on the rib 590a continuously or stepwise toward the gradation grill 140. It may be formed as two gradation grills.

  Returning to FIG. 4, in the present embodiment, the size of the front suction grill 131 is set such that the lateral width W2 is 761 mm and the height H2 is 90 mm. The gradation grill 140 is set to have a width W2 of 761 mm and a height H3 of 52.4 mm. As shown in FIG. 5, the height h1 of the opening 595 is 2.5 mm, the pitch P1 of the front suction grill 131 is 5 mm, and the pitch P2 of the gradation grill 140 is 52. The size is continuously increased to 4 mm and stepwise.

  Here, continuous or stepwise means moving from a sparse array to a dense array as a whole. As described above, in this embodiment, the front suction grill 131 having a large opening area is arranged in the center, the lower flat portion formed in the lower portion is made conspicuous, and the gradation grill is formed in the upper flat portion formed in the upper portion. By providing 140, the front suction grill 131 and the upper flat portion are made to conform, and the size of the suction portion of the front suction grill 131 formed on the front panel 230 is made inconspicuous and harmonized with the interior. .

  In the present embodiment, the width W2 of the front suction grill 131 and the gradation grill 140 is set to 761 mm. However, a machine room is provided at the right end of the indoor unit 100, and the front suction grill 131 and the gradation grill 140 extend to the machine room to form the decorative panel 220. The portions of the front suction grill 131 and the gradation grill 140 that extend into the machine room are not opened, and the sizes of the portions where the front suction grill 131 and the gradation grill 140 are actually opened are determined. In the form, it is set to 721 mm.

  In the lower flat portion, a concave inclined surface is formed on the lower side of the front suction grill 131 so that the center hangs downward from both sides, and the operation state display unit 135 is provided in the central portion. . Thereby, the operation state display unit 135 is made conspicuous and the visibility is improved. Further, a transmission / reception unit 110 is provided at a lower portion on one side of the lower plane portion.

  (C) In the plan view shown in the figure, the upper surface front suction grille 132a formed on the upper surface of the decorative cover 220 and the upper surface rear suction grille 132b formed on the upper surface of the back cabinet 210 are a plurality of main components. The shape of the grille is sparsely provided with horizontal bars and reinforcing vertical bars, and a wide casing surface is left in the periphery, so that it is difficult to stand out in the installed state while obtaining a large opening area.

  (D) In the bottom view shown in the figure, the blow-out portion 133 formed on the lower surface of the decorative cover 220 is disposed in the vicinity of a division portion with the front panel 230. The two wind direction plates 6a and 6b have a belt-like shape having a curved surface substantially the same as the large curved surface 34, and conceal the opening of the blowing portion 133 in a closed state, and are continuous with the bottom surface of the indoor unit 100. A large curved surface 34 is formed.

  As described above, the appearance of the indoor unit 100 is based on a round in which the top surface and the bottom surface are large, both side surfaces are narrowed forward through small curved surfaces, and the front four corners are formed in a large round shape. In addition, the front suction grill 131, the upper suction grill 132, the blow-out portion 133, the gradation grill 140, and the operation state display portion 135 are arranged symmetrically with respect to the center. doing. Thus, by making the indoor unit 100 into the above-described external shape, the indoor unit 100 is in a compact form that is easy to fit into the interior and fit into the interior in a state of being installed on the wall.

  Next, the remote controller 300 will be described in detail with reference to FIGS.

  6 and 7 are external views of the remote controller, FIG. 6 (a) is a front view of the remote controller, FIG. 6 (b) is a front view of the remote controller with the opening / closing lid opened, and FIG. 6 (c) is a remote controller 300. 7A is a front view of the remote controller 300, and FIG. 7B is a left side view.

  8, 9, and 10 are diagrams showing each component constituting the casing 301 of the remote controller 300. FIG. 8 is an upper cover constituting the casing 301 of the remote controller 300, FIG. 8 (a) is an internal appearance view of the upper cover, and FIG. 8 (b) is a longitudinal sectional view. FIG. 9 is a lower cover constituting the casing 301 of the remote controller 300, FIG. 9A is an internal sectional view of the lower cover, and FIG. 9B is a longitudinal sectional view. FIG. 10 is a battery lid, FIG. 10 (a) is an internal appearance view of the battery lid, and FIG. 10 (b) is a longitudinal sectional view. 11A and 11B are diagrams showing a liquid crystal substrate constituting the display unit 320, in which FIG. 11A is a front view and FIG. 11B is a longitudinal sectional view.

  12 and 13 are diagrams showing the configuration of the operation buttons. FIG. 12 is a diagram showing the configuration of the operation button and the operation / stop button that are used less frequently, FIG. 12 (a) is a front view, FIG. 12 (b) is a rear view, and FIG. A 'sectional view and Drawing 12 (d) are BB' sectional views. FIG. 13 is a diagram showing the configuration of the frequently used operation buttons provided on the opening / closing lid 302. FIG. 13 (a) is a front view, FIG. 14 (b) is a rear view, and FIG. It is a side view. 14A and 14B are diagrams showing a configuration of the opening / closing lid 302, in which FIG. 14A is an internal appearance view and FIG. 14B is a longitudinal sectional view.

  The operation of the air conditioning system in the present invention is mainly performed by the remote controller 300.

  As shown in FIG. 6A, the remote controller 300 includes a thin, flat, vertically long casing 301, an opening / closing lid 302 provided on a part of a wide surface of the casing 301, and the indoor unit 100. The operation / stop button 303 for operating and stopping the operation, the transmission / reception device 310, the acquisition information display area 320a for displaying the acquisition information, and the setting for displaying the operation state of the air conditioner, the preset temperature, humidity, and the like. The display unit 320 includes an information display area 320b. In this embodiment, the display unit 320 is provided on one side in the longitudinal direction where the transmission / reception device 310 is provided, the operation / stop button 303 having the highest use frequency is provided below the display unit 320, and the opening / closing lid 302 is provided below the display unit 320. The operation buttons having a relatively high use frequency are provided on the surface, and the operation buttons having a low use frequency are provided on the main body side covered with the opening / closing lid 302. Thereby, the operability and visibility that the user can put in the operation posture when the transmission / reception device 310 is directed toward the indoor unit 100 are improved.

  As shown in FIG. 6C, the transmission / reception device 310 includes a transmission unit 310a and a reception unit 310b.

  In this embodiment, a plurality of operation buttons for controlling the indoor environment are provided as frequently used operation buttons provided on the surface of the opening / closing lid 302. As a plurality of operation buttons for controlling the indoor environment, for example, an operation button that is frequently used in the air conditioning operation and an operation button that is frequently used in the dehumidifying operation used in the full season are provided. These operation buttons are, for example, a dehumidifying button 304 for setting a frequently used operation mode, causing the indoor unit 100 to perform a dehumidifying operation, and controlling the humidity according to the temperature difference between the room temperature and the outside air temperature. The “cool / comfort” button 305 for operating the vehicle and the PAM airflow button 306 for automatically adjusting the direction and volume of the air blown from the indoor unit 100 are used as one operation button group, and the most frequently used operation / stop button. It is arranged on the lower side of 303.

  In addition, for example, a humidity setting button 307 for setting the humidity and a room temperature setting button 308 for setting the room temperature are juxtaposed as operation buttons for uniquely setting the temperature and humidity during the air conditioning and dehumidifying operations. The operation mode switching button group is provided below. Thereby, temperature and humidity can be set independently at the same operation level.

  Further, a simple timer setting button that can set a simple timer at bedtime or the like as another frequently used operation button that is not affected by the air conditioning operation and the dehumidifying operation, on the lower surface of the opening / closing lid 302. For example, a good night button 309 and an instruction button for instructing to display the indoor humidity, room temperature, outdoor temperature, and the like in the acquisition information area 320a are provided, for example, a button 340.

  As described above, the remote controller 300 according to this embodiment is configured to display frequently used operation buttons arranged in order of frequency of use on the outer surface of the remote controller 300 while viewing information obtained from the indoor unit 100 or the outdoor unit 200. It is possible to operate by displaying the setting information in the setting information display area 320b.

  In particular, one of the features of the remote controller 300 of this embodiment is that the display unit 320 is divided into two upper and lower stages, and the input information display area 320a and the setting information display area 320b are arranged vertically in the holding posture. In the point. Generally, a user recognizes a sentence and each operation procedure from the top to the bottom like a horizontally written sentence. In this embodiment, using the user's action, an acquisition information display area 320a for displaying basic acquisition information is provided in the upper stage, and a setting information display area 320b is displayed adjacent to the lower position. Furthermore, an operation button is arranged below the operation button.

  Accordingly, the user can input the setting information while recognizing the setting information in a natural manner based on the information obtained from the indoor unit 100 or the outdoor unit 200.

  Another feature of the present embodiment is that the information displayed in the input information display area 320a and the setting information display area 302b and frequently used operation buttons are classified into information types such as this implementation. In the form of, there is a point that is divided into left and right according to the one related to cooling and heating and the one related to dehumidification. In this embodiment, the input information display area 320a and the setting information display area 320b are divided into a temperature display area and a humidity display area, respectively. A certain frequently used operation button is divided into left and right, and operation buttons related to both temperature and humidity are arranged in the center. Thereby, it is possible to reduce the user's search for the operation button and to improve the operability.

  In addition, another feature of the remote controller 300 of this embodiment is that a button 340 is provided on the surface of the opening / closing lid 302. By pressing the button 340, the indoor unit 100 is in operation. The indoor temperature, humidity, and outside air temperature can be displayed in the acquisition information display area 320a. Thereby, since transmission / reception can be performed when necessary without always performing transmission / reception between the indoor unit 100 and the remote controller 300, power consumption of the remote controller 300 can be reduced.

  Further, even when the air conditioning system is not in operation, the room temperature and humidity obtained from the indoor unit 100 and the outdoor temperature obtained from the outdoor unit 200 can be displayed in the obtained information display area 320 by pressing the button 340. Can do. In addition, the dehumidifying button 304, the “cool / quiet” button 305, and the PAM airflow button 306, which are the frequently used operation buttons, are used to switch between an operating mode frequently used during air conditioning and an operating mode mainly based on dehumidifying operation, Alternatively, the temperature setting and humidity setting in each operation mode by the humidity setting button 307 and the room temperature setting button 308, the timer setting at bedtime by the good night button 309, and the guidance button 340 to be used when obtaining information are provided. Since it is provided on the surface of the opening / closing lid 302, the room temperature, humidity, wind direction, air volume, etc. can be easily adjusted according to the frequency of use and operability, and a comfortable indoor space for the user can be created with a simple operation. The air conditioning system can be operated as possible.

  When the opening / closing lid 302 is opened, as shown in FIG. 6B, operation buttons that are relatively infrequently used are provided inside the opening / closing lid 302 (the surface of the upper cover). As operation buttons that are relatively infrequently used, for example, an operation mode 351 for switching the operation mode of the indoor unit 100, for example, cooling operation, heating operation, dehumidification operation, etc., a wind speed switching button 352 for switching the wind speed, and a wind direction for adjusting the wind direction Adjustment buttons 353 and 354, a powerful button 355 for causing the indoor unit 100 to perform a rapid cooling operation or a rapid heating operation, an emptying button 358 for causing the indoor unit 100 to perform an air cleaning operation, a filter button 359 for indicating the degree of filter contamination, A cancel button 360 for canceling the timer setting of the unit 100, a time setting button 361 for setting the time, a reservation button 362 for setting the reserved operation of the indoor unit 100, and a reset button 363 for returning the setting of the remote controller 300 to the initial state, Indoor unit 100 Thailand -A timer button 364 for setting ON / OFF (ON / OFF) of operation, a date / time button 365 for displaying the date and time when pressed when the date and time are set, and the like are arranged. . Here, the wind direction adjustment button 353 adjusts the upper and lower wind directions, and the wind direction adjustment button 354 adjusts the left and right wind directions.

  These operation buttons 351 to 365 having a low use frequency are mainly used for setting the operating state of the air conditioner in detail. Since the operation state set by these operation buttons 351 to 365 is stored in the remote controller 300, it is not necessary to set the operation state again when the air conditioner is operated again. In some cases, it is arranged inside the opening / closing lid 302 (the surface of the upper cover), so that erroneous operation of the operation buttons can be reduced.

  In addition, as operation buttons that are not frequently used, a preheat button 356 for preheating the air conditioner, a humidifier button 357 for controlling a humidifier (not shown) provided separately from the indoor unit 100 in the air conditioning system, and the like. It may be provided.

  In FIG. 7, the remote controller 300 according to the present invention has a thin / flat and vertically long main body shape having a thin depth dimension D and a height dimension H1 longer than the lateral width dimension W1. The remote controller 300 includes a transmission / reception unit 310 at one end in the longitudinal direction, and has a good holding property when the user holds the transmission / reception unit 310 with one hand while facing the transmission / reception unit 110 of the indoor unit 100.

  In the present embodiment, the size of the remote controller 300 is set such that the depth dimension D2 is set to 22 mm, the width dimension W4 is set to 61 mm, and the height dimension H4 is set to 196.5 mm. In addition, the obtained information display area 320a and the setting information display area 320b arranged in the display unit 320 are configured to have the input by setting the width dimension W5 and the height dimensions H5 and H6 to 48 mm, 11 mm, and 49 mm, respectively. The contents displayed in the information display area 320a and the setting information display area 320b can be easily seen. In the present embodiment, the dimensions of the remote controller 300 and the display unit 320 are set to the above dimensions, but are not limited to these dimensions, and may be set to arbitrary dimensions.

  Next, the configuration of the remote controller 300, operation buttons, and display unit 320 according to the present embodiment will be described.

  In the present embodiment, as shown in FIGS. 8 and 9, the casing 301 of the remote controller 300 is composed of an upper cover 401 and a lower cover 402. The upper cover 401 covers the front (front) side of the casing 301, and the lower cover 402 is a division formed on the peripheral side surface of the casing 301 so as to cover the back of the casing 301. It is attached to the upper cover 401 through a groove 390 (see FIG. 7B). The opening / closing lid 302 is attached to the front (front) lower side of the upper cover 401 through a hinge 391 (see FIG. 7B) so as to be opened and closed.

  The upper cover 401 includes a plurality of openings 410 for arranging the operation buttons 351 to 365 that are not frequently used, and an opening 420 for arranging the display unit 320. A battery storage portion 430 for storing a battery is provided below the upper cover 401, and the battery storage portion 430 is covered by a battery lid 700 shown in FIG. The battery lid 700 is attached to the lower cover 402 by fitting a claw 710 with a claw attachment portion 440 of the lower cover 402 and covers the battery storage portion 430.

  For example, as shown in FIG. 11, the display unit 320 is formed by printing on a printing surface 760 of a single liquid crystal substrate 750, and the liquid crystal substrate 750 is connected to the upper cover through the opening 420. It is configured to be attached to 401. An opening 770 to which the operation / stop button 303 is attached is provided below the liquid crystal substrate 750.

  In this embodiment, a normal liquid crystal substrate is used as the liquid crystal substrate 750, but a color liquid crystal substrate may be used instead of the normal liquid crystal substrate. By using a color liquid crystal substrate, a display corresponding to the operation state of the indoor unit 100, for example, a blue display in the cooling operation, a green display in the dehumidification operation, and an orange display in the heating operation The color of the display unit 320 can be changed according to the operating state of the air conditioner, and the operability and visibility can be further improved.

  Next, the configuration of the operation buttons 351 to 365 that are arranged on the upper cover 401 and are not frequently used will be described.

  As shown in FIG. 12, the operation buttons 351 to 365 that are not frequently used are formed of a soft material such as rubber and attached to the first substrate 900. The less frequently used operation buttons 351 to 365 have a conductive material 910 in contact with the first substrate 900 (see FIG. 12B), and any one of the less frequently used operation buttons 351 to 365 is used. When is pressed, the conductive material 910 comes into contact with a predetermined circuit of the first substrate 900, and an operation signal corresponding to the pressed operation button is transmitted. The first substrate 900 to which the operation buttons 351 to 365 that are not frequently used are attached is wired to the liquid crystal substrate 750, a microcomputer (central processing unit) (not shown), a transmission / reception circuit, and the like. Apparatus), positioning ribs 451 to 455 (see FIG. 9A) provided on the inner side of the lower cover 402 including a transmission / reception circuit and the like, and the opening 410 and the opening 420 through the positioning rib. Attached to the upper cover 401.

  Next, the configuration of the frequently used operation buttons 304 to 309 and the button 340 provided on the opening / closing lid 302 will be described with reference to FIGS. 13 and 14.

  The frequently used operation buttons 304 to 309 and the button 340 arranged on the opening / closing lid 302 are formed of a soft material such as rubber, and the shape thereof is viewed from the side as shown in FIG. It has a “T” shape.

  The frequently used operation buttons 304 to 309 and the button 340 are attached to the opening / closing lid 302 through a plurality of openings 820 formed in the opening / closing lid 302 as shown in FIG. The operation buttons 304 to 309 and the button 340 that are frequently used are attached to the opening / closing lid 302 by a back plate 810 attached to the opening / closing lid 302 via positioning ribs 830, 840, 850 formed on the inner side of the 302. Retained.

  The frequently used operation buttons 304 to 309 and the button 340 function when pressed with the open / close lid 302 closed. By pressing one of the frequently used operation buttons 304 to 309 and the button 340 in the state where the opening / closing lid 302 is closed, the operation button 304 to 309 and the button 340 corresponding to the frequency of use are corresponded. A “T-shaped” end portion 805 protrudes from the back plate 810, and the first through the conductive material 910 provided on the operation buttons 351 to 365 that are attached to the upper cover 401 and are not frequently used. An operation signal corresponding to one of the frequently used operation buttons 304 to 309 and the button 340 that is pressed is brought into contact with a predetermined circuit of one substrate 900.

  As shown in FIG. 13C, the room temperature setting button 308 and the humidity setting button 307, which are frequently used operation buttons, are formed in a circular arc shape having a recessed central portion when viewed from the side. An upper button 307a (308a) for raising room temperature and humidity is provided above the arc shape, and a lower button 307b (308b) for lowering room temperature and humidity is provided below the arc shape. Here, the user recognizes the front-rear direction of the remote controller 300 as the vertical direction in a natural holding posture with the display unit 320 facing upward.

  In the present embodiment, using the user's recognition, the longitudinal direction of the room temperature setting button 308 and the humidity setting button 307 is provided in the longitudinal direction of the casing 301 of the remote controller 300, and the display unit side is the up button. By using 307a (308a) and the lower button 307b (308b) on the opposite side, it is possible to improve the operability by allowing the user to operate with natural operations without being aware of the arrangement of the setting buttons.

  Further, as shown in FIG. 13 (a), the upper button 307a (308a) and the lower button 307b (308b) are each formed in an elliptical shape, and are respectively provided with concave portions 830a and 830b indicating directionality. Yes. In the present embodiment, the upper button 307a (308a) is formed so as to protrude from the humidity setting button 307 (room temperature setting button 308), and the lower button 307b (308b) is formed as the humidity setting button 307 (room temperature setting). Button 308). Further, on the surfaces of the upper button 307a (308a) and the lower button 307b (308b), for example, the upper button 307a (308a) has an arrow pointing upward, the lower button 307b ( 308b) is provided with an arrow pointing downward. For this reason, the function can be clearly recognized by the sense and vision of the fingertip of the user.

  In the present embodiment, arrows indicating directionality are used as the recesses 830a and 830b, but the present invention is not limited to this. For example, a triangular shape may be used as the recesses 830a and 830b. In this case, the upper button 307a (308a) is provided with a triangular concave portion whose apex is directed upward, and the lower button 307b (308b) is provided with a triangular concave portion directed downward of the apex. , Can give direction.

  The operation of the air conditioning system in the present invention is mainly performed by the remote controller 300 as described above. The operation of the air conditioning system using the remote controller 300 according to the present invention will be further described with reference to FIGS. 15 and 16. In the present embodiment, a state in which the operation mode is the dehumidifying operation will be described as an example.

  FIG. 15 is a block diagram showing a schematic configuration of an air conditioning system according to the present invention. In FIG. 15, 100 a is a schematic configuration of the indoor unit 100, 200 a is a schematic configuration of the outdoor unit 200, and 300 a is a schematic configuration of the remote controller 300. FIG. 16 shows the display state of the acquisition information display area 320a and the setting information display area 320b. FIG. 16A shows the display state when the indoor unit 100 is stopped, and FIGS. 16B to 16D show the display state. The display state in the operation state of the indoor unit 100, FIGS. 16B to 16D show the display state in the operation state of the indoor unit 100. FIG.

  In FIG. 15, the indoor unit 100 detects an indoor unit control device 601 that controls the operation of the entire indoor unit 100 including the angle adjustment of the horizontal louver 134 and the operation control of the indoor fan 109, and the indoor temperature. Detected by an indoor temperature sensor 602, an indoor humidity sensor 603 that detects indoor humidity, a second receiver 604 that receives a control signal transmitted from the remote controller 300, the indoor temperature sensor 602, and the indoor humidity sensor 603. A second transmitter 605 that transmits the temperature / humidity to the first receiver 611.

  The outdoor unit 200 includes an outdoor unit controller 606 that controls the operation of the entire air conditioner including the operation of the outdoor fan 580 and the control of the outdoor heat exchanger 520, and the like, and an outdoor temperature sensor 607 that detects the outdoor temperature. It has.

  The indoor unit control device 601 and the outdoor unit control device 606 are connected by electric wiring or the like, and the outdoor unit 200 operates in synchronization with the operation of the indoor unit 100.

  The remote control 300 receives a signal from the selection device 608 that selects the operation function selected by the user of the air conditioning system, and a signal that causes the indoor unit 100 to operate. A first transmission unit 610 that receives a signal transmitted from the central processing unit 609 and transmits an operation signal to the indoor unit 100, the indoor temperature sensor 602 or the indoor humidity sensor 603, and the outdoor temperature sensor. And a first receiving unit 611 that receives a signal from 607.

  In the air conditioning system configured as described above, for example, when performing a dehumidifying operation, first, an input signal is selected by pressing a dehumidifying button 304 provided on the surface of the remote control 300 (the surface of the opening / closing lid 302). The operation mode of the dehumidifying operation is selected from the selection device 608. The selection device 608 transmits an operation mode signal for performing the dehumidifying operation to the central processing unit 609, and the central processing device 609 that has received the operation mode signal for performing the dehumidifying operation transmits the indoors via the first transmission unit 610. An instruction to cause the unit 100 to perform the dehumidifying operation is transmitted to the second receiving unit 604 by an infrared signal. Further, the central processing unit 609 transmits an infrared signal to the second reception unit 604 via the first transmission unit 610, and at the same time transmits an operation mode signal for performing the dehumidifying operation to the setting information display area 320b. As shown in FIG. 16B, the display of the setting information display area 320b changes from the display of the stop state of the indoor unit 100 shown in (a) to the display showing that the dehumidifying operation is performed. In the setting information display area 320b, an operation mode indicating the dehumidifying operation, a wind speed, a wind direction, a room temperature / humidity set in advance for performing the dehumidifying operation, and the like are displayed.

  The second receiver 604 receives the infrared signal (operation mode signal) transmitted from the first transmitter 610 (remote controller 300), transmits the received infrared signal to the indoor unit controller 601, and transmits the indoor unit controller. 601 controls each element (refer FIG. 2) which comprises the indoor unit 100 based on an operation mode signal, and performs a dehumidification operation. The indoor unit control device 601 also causes the indoor unit 100 to perform a dehumidifying operation and turns on the display lamp 620 provided on the housing 150 of the indoor unit 100. Furthermore, the indoor unit control device 601 transmits an operation mode signal to the outdoor unit control device 606, and the outdoor unit control device 606, based on the operation mode signal, configures each element constituting the outdoor unit 200 such as the outdoor fan 580 (see FIG. 3). ) To control the dehumidification.

  Here, when the button 340 provided on the remote controller 300 is pressed, room temperature, indoor humidity, outdoor temperature, outdoor humidity, and the like are displayed in the acquisition information display area 320a. More specifically, when the button 340 is pressed once, the room temperature detected by the room temperature sensor 602 and the room humidity detected by the room humidity sensor 603 are displayed in the acquisition information display area 320a (FIG. When the button 340 is further pressed, the outside air temperature detected by the outdoor temperature sensor 607 is displayed in the acquisition information display area 320a (see FIG. 16D).

  As described above, since the remote controller 300 according to the present invention can appropriately display the current room temperature, humidity, and outside temperature by pressing the button 304, the indoor unit 100 according to the displayed room temperature, humidity, and outside temperature. Therefore, energy saving operation of the air conditioning system is possible.

  In the dehumidifying operation described above, the dehumidifying operation is automatically performed at a preset room temperature and humidity by pressing the dehumidifying button 304. However, in the remote controller 300 according to the present invention, the humidity setting button 307 and the By operating the room temperature setting button 308, the room temperature and humidity can be adjusted. Further, when the “cool / comfort” button 305 is pressed, the dehumidifying operation can be performed while controlling the humidity corresponding to the temperature difference between the room temperature and the outside air temperature. As a result, a more comfortable dehumidifying operation can be performed.

  As described above, in the present embodiment, the operation for the dehumidifying operation, in particular, the adjustment of the humidity has been described as an example. Although not adopted in the air conditioning system in the present embodiment, the air conditioning system may be configured so that the humidity can be adjusted by the same operation as the above dehumidifying operation even during cooling operation or heating operation. Good.

  For example, when performing humidity adjustment during cooling operation, first the opening / closing lid 302 is opened, and the operation switching button 351 is operated to switch the operation mode of the air conditioner to cooling operation, which is set in advance to perform the cooling operation. The operation is performed based on the set room temperature and humidity, and the preset room temperature and humidity are displayed in the setting information display area 320b. After the operation mode is switched, the opening / closing lid 302 is closed. During cooling operation, the user operates the humidity setting button 307 and the room temperature setting button 308 so that the room temperature and humidity can be set according to the user's constitution and physical condition. A cooling operation based on humidity may be performed. By pressing the button 340, the current room temperature, humidity, and outside temperature can be displayed. If necessary, the room temperature and humidity can be adjusted by operating the humidity setting button 307 and the room temperature setting button 308. It can be adjusted. Furthermore, by setting the configuration to store the room temperature and humidity set by the user, the cooling operation is performed based on the room temperature and humidity set by the user when the air conditioner is re-cooled. You may do it.

  When the humidity is adjusted during the heating operation, the operation mode of the air conditioner is switched from the cooling operation to the heating operation by opening the opening / closing lid 302 again and operating the operation switching button 351 to perform the heating operation. Therefore, the operation based on the preset room temperature and humidity is performed, and the preset room temperature and humidity are displayed in the setting information display area 320b. After the operation mode is switched, the opening / closing lid 302 is closed. During heating operation, the user operates the humidity setting button 307 and the room temperature setting button 308 so that the room temperature and humidity can be set in accordance with the user's constitution and physical condition. The heating operation may be performed based on this. By pressing the button 340, the current room temperature, humidity, and outside temperature can be displayed. If necessary, the room temperature and humidity can be adjusted by operating the humidity setting button 307 and the room temperature setting button 308. It can be adjusted. Furthermore, by setting the configuration to store the room temperature and humidity set by the user, when the air conditioner is set to the heating operation again, the heating operation is performed based on the room temperature and humidity set by the user. You may do it.

  By setting it as the above structures, more comfortable air_conditionaing | cooling operation and heating operation can be performed. In addition, by adjusting the room temperature and humidity, it is possible to reduce indoor cooling and heating, and energy-saving operation of the air conditioning system is possible.

  Next, a state where the PAM airflow button 306 provided on the remote controller 300 is operated will be described.

  When the air conditioner is performing the above-described dehumidifying operation, cooling operation, or heating operation in accordance with the room temperature and humidity set in advance or the room temperature and humidity set by the user, the PAM airflow button 306 is pressed. Then, the direction of the indoor air blown out from the indoor unit 100 can be changed as the user desires. Specifically, when the PAM airflow button 306 is pressed once, the wind direction of the indoor air blown out from the indoor unit 100 is changed to the wind direction in the standard operation state. When the PAM air flow button 306 is further pressed, the indoor air is blown out from the indoor unit 100 so that the indoor air is concentrated in one place. When the PAM air flow button 306 is pressed again, the indoor air is blown out from the indoor unit 100 so that the indoor air is diffused. Is done.

  As described above, by operating the PAM airflow button 306, the direction of the wind can be changed as the user desires, so that the user can perform a dehumidifying operation, a cooling operation, and a heating operation that are more comfortable for the user. .

  Next, operations that are frequently used, such as the operation state display unit 135 provided on the casing 150 of the indoor unit 100 and the dehumidifying button 304 and the “cool / quiet” button 305 provided on the surface of the remote controller 300. The arrangement relationship with the buttons will be described with reference to FIG.

  In FIG. 17, the operation state display unit 135 is disposed in the center of the casing 150 below the front suction grill 131. The operation state display unit 135 includes a first information display area 135a and a second information display area 135b that are provided symmetrically about the center of the indoor unit 100. The first information display area 135a indicates an operation state during cooling operation or heating operation, and the second information display area 135b indicates an operation state during dehumidification operation.

  As shown in FIG. 17, the remote controller 300 includes various operation buttons 304 to 309 and 340 provided on the surface of the opening / closing lid 302 that are symmetrical about the center of the indoor unit 100. Is provided. Here, looking at the arrangement of the various operation buttons, the dehumidifying button 304, the humidity setting button 307, the good night button 309, and the center of the indoor unit 100 are centered on the right side of the center of the indoor unit 100. On the left side, a PAM airflow button 306, a room temperature setting button 308, and a button 340 are arranged. A “cool / comfort” button 305 for operating the indoor unit 100 while controlling the humidity according to the temperature difference between the room temperature and the outside air temperature is disposed between the dehumidifying button 304 and the PAM airflow button 306. .

  That is, various operation buttons 304 to 309 and 340 that are frequently used provided on the surface of the opening / closing lid 302 have operation buttons related to humidity setting and adjustment on the right side of the center of the indoor unit 100. Operation buttons relating to setting and adjustment of room temperature are arranged on the left side of the indoor unit 100 with the center at the center. A first information display area 135a and a second information display provided on the casing 150 of the indoor unit 100 are arranged. This is consistent with the arrangement of the area 135b.

  Accordingly, various operation buttons provided on the remote controller 300 can be easily operated, and erroneous operation of the operation buttons can be reduced. Moreover, since the visibility of the driving | running state display part 135 can be improved, the driving | running state of an air conditioning system can be confirmed easily.

  Next, the operation state display unit 135 will be described with reference to FIGS. 18 is a diagram showing the configuration of the driving state display unit 135, FIG. 18A is a front view of the driving state display unit 135, and FIG. 18B is a first information display area 135a and a second information display area. It is a figure which shows the structure of 135b. FIG. 19 is a diagram showing a display state of the first information display area 135a, and FIG. 20 is a diagram showing a display state of the second information display area 135b. 21, 22, and 23 are diagrams showing display states of the operation state display unit 135.

  As described above, the operation state display unit 135 includes a first information display area 135a that indicates a cooling operation or a heating operation, and a second information display area 135b that indicates a dehumidifying operation.

  In the present embodiment, as shown in FIGS. 18 to 22, each of the first information display area 135a and the second information display area 135b includes four display lamps each indicating an operation state. These indicator lamps are the deviation of the set value of temperature and humidity from the current value, the reserved state during timer operation, the hot keep state (the room is at a constant temperature and the air conditioner is on standby), the operation Functions such as mode judgment and error message display are provided. Hereinafter, the display lamp will be described.

  First, the four display lamps 181, 182, 183, and 184 provided in the first information display area 135 a will be described with reference to FIG. 19. In the first information display area 135a, as described above, the operation mode of the air conditioner displays the state of the cooling operation or the heating operation, and the cooling operation or the heating operation is instructed by operating the remote controller 300. As a result, the first information display area 135a is turned on, and the operating state is displayed. When the operation mode of the air conditioner is instructed by the remote controller 300, the first information display area 135a is configured to display the operation state of the air conditioner by the four display lamps 181, 182, 183, and 184. Yes.

  In the present embodiment, the first information display area 135a includes four display lamps 181, 182, 183, and 184, but the four display lamps 181, 182, and 183 are started when the air conditioner starts operation. , 184 are not all lit. In the present embodiment, the four display lamps 181, 182, 183, and 184 constituting the first information display area 135 a are turned on by the deviation dt between the preset room temperature and the room temperature in the state in which the operation is instructed. Are configured differently. For example, in the present embodiment, when the deviation dt between the set temperature and the room temperature at the start of operation is larger than 10 ° C. (dt> 10), as shown in FIG. 19A, the display lamps 181, 182, 183 , 184 are all lit, and when the deviation dt is greater than 5 ° C. and 10 ° C. or less (5 <dt ≦ 10), three display lamps 182, 183, 184 are lit as shown in FIG. When the deviation dt is greater than 2 ° C. and 5 ° C. or less (2 <dt ≦ 5), as shown in FIG. 19C, two display lamps 183 and 184 are lit, and the deviation dt is 2 ° C. or less. In the case of (dt ≦ 2), the display lamp 184 is configured to be lit as shown in FIG. In the present embodiment, the display lamps 181, 182, 183, and 184 are indicated by solid lines in the lit state or blinking state, and the broken lines are indicated in the unlit state.

  These display lamps 181, 182, 183, and 184 are configured to change their display in accordance with a change in indoor state (change in room temperature). For example, the display lamps 181, 182, 183, When the room temperature deviation is greater than 5 ° C. and less than or equal to 10 ° C. (5 <dt ≦ 10) from the state where all 184 are lit (dt> 10), the first information display area 135a is displayed. Changes to three displays of display lamps 182, 183, and 184. When the indoor environment (room temperature and humidity) is set, the operation of the air conditioner enters a standby state (hot keep), and the display lamp 184 blinks to indicate that it is in a standby state.

  In the present embodiment, the display lamps 181 to 184 are controlled by the deviation dt between the set temperature and the room temperature, but the display lamps 181 to 184 are controlled by the rotational speed of the compressor 500 (see FIG. 3). Also good.

  Next, the four display lamps 185, 186, 187, and 188 provided in the second information display area 135b will be described with reference to FIG. As described above, the second information display area 135b displays the state of the dehumidifying operation in the air conditioner. By operating the dehumidifying button 304 and instructing the dehumidifying operation, the second information display area 135b is displayed. Lights up and the operating status is displayed.

  When the dehumidifying operation is instructed as the operation mode of the air conditioner by the remote controller 300, the second information display area 135b displays the state of the dehumidifying operation in the air conditioner by the four display lamps 185, 186, 187, 188. It is configured as follows.

  In the present embodiment, the second information display area 135b is composed of four display lamps 185, 186, 187, 188, but at the start of the dehumidifying operation as in the cooling operation or heating operation, When the second information display area 135b is turned on, not all of the four display lamps 185, 186, 187, and 188 are turned on. In the present embodiment, lighting of the display lamps 185, 186, 187, and 188 is configured such that the number of lighting is different depending on the deviation dh between the humidity set in advance and the humidity in the state in which the operation is instructed. For example, in the present embodiment, when the deviation dh between the set humidity at the start of operation and the current humidity is greater than 30% (dh> 30), as shown in FIG. , 187, 188 are all turned on, and the deviation dh is greater than 20% and 30% or less (20 <dh ≦ 30), the display lamps 185, 186, 187, 3 as shown in FIG. When the deviation dh is larger than 10% and 20% or less (10 <dh ≦ 20), as shown in FIG. 20C, two display lamps 185 and 186 are lit, and the deviation dh is In the case of 10% or less (dh ≦ 10), the display lamp 185 is configured to be lit as shown in FIG. In the present embodiment, the display lamps 185, 186, 187, and 188 are indicated by solid lines and are indicated by broken lines in the off state.

  These display lamps 185, 186, 187, 188 are configured to change their display in accordance with a change in indoor state (change in humidity). For example, the display lamps 185, 186, 187, If the humidity deviation dh is greater than 20% and 30% or less (20 <dh ≦ 30) from the state where all 188 are lit (dh> 30), the second information display area 135b The display changes to three displays of display lamps 185, 186, and 187.

  In the present embodiment, the display lamps 185 to 188 are controlled by the deviation dh between the set humidity at the start of operation and the current humidity, but the display lamp 181 depends on the rotational speed of the compressor 500 (see FIG. 3). ~ 184 may be controlled.

  With the configuration as described above, the operation state of the air conditioning system is displayed while being changed stepwise in the cooling operation, the heating operation, and the dehumidifying operation, so that the user checks the operation state display unit 135. Thus, if the number of lighting of the display lamps constituting the operation state display unit 135 is large, the air conditioning system is performing high output operation because the difference in the current temperature or humidity with respect to the set temperature or installation temperature is large. On the contrary, if the number of display lamps is small, the difference is small, indicating that the air conditioning system is operating at a low output. As described above, in this embodiment, the operation status display unit 135 can display the operation status of the air conditioning system by the number of lighting of the display lamp (the size of the lighting display portion) and indirectly. In addition, the current temperature or humidity with respect to the set temperature or humidity can be confirmed.

  Further, by using the button 340 provided on the remote controller 300 in combination, more detailed current room temperature and humidity can be confirmed, for example, as numerical data, so that the room temperature and humidity can be easily adjusted as necessary. It can be carried out.

  Next, the display of the operation state display unit 135 during the timer operation of the air conditioner will be described with reference to FIG. The timer operation is reserved by pressing a timer button 364 provided inside the opening / closing lid 302 of the remote controller 300. When timer reservation is instructed by the timer button 364, as shown in FIG. 21A, the display lamp 184 provided on the rightmost side of the first information display area 135a and the second information display area 135b are displayed. The display lamp 185 provided on the leftmost side blinks for a predetermined time and then turns off (see FIG. 21B). In the present embodiment, the display lamps 181 to 188 are indicated by solid lines in the lit state or blinking state, and the broken lines are indicated in the unlit state.

  In the present embodiment, for example, the predetermined time for which the display lamps 184 and 185 blink is set to 10 seconds. When the timer operation is started, as shown in FIG. 21C, the display lamps 184 and 185 blink for a predetermined time (10 seconds), and then the first information display according to the lighting condition of the display lamp described above. The area 135a is turned on to display the operation state. At this time, the display lamp 185 provided on the leftmost side of the second information display area 135b is also turned on to indicate that it is a timer operation.

  With the configuration as described above, the display lamp blinks for a predetermined time at the time of timer reservation, so that it can be confirmed that the user has instructed timer reservation, and the display lamp 185 is also lit at the start of timer operation. It can be confirmed that the vehicle is operating by making a reservation, and forgetting to turn off the air conditioning system can be reduced.

  In the present embodiment, the predetermined time during which the display lamp blinks is set to 10 seconds. However, the present invention is not limited to this and may be set to an arbitrary time.

  Next, other display functions in the operation state display unit 135 will be described with reference to FIGS. Other display functions include a display during operation mode determination in automatic operation of the air conditioning system, an error message display, and the like.

  FIG. 22 shows a display state of the operation state display unit 135 during the operation mode determination of the air conditioner. As shown in FIG. 22A, the display during operation mode determination is provided on the leftmost side of the display lamp 184 provided on the rightmost side of the first information display area 135a and the second information display area 135b. The display lamp 185 blinks, and after the determination is completed, the operation state display unit 135 is lit according to the above-described display lamp lighting conditions to display the operation state (see FIG. 22B). In the present embodiment, the display lamps 181 to 188 are indicated by solid lines in the lit state or blinking state, and the broken lines are indicated in the unlit state.

  FIG. 23 shows a display state of the operation state display unit 135 when an error occurs in the air conditioner. When an error occurs in the room, the display lamp 188 provided on the rightmost side of the second information display area 135b blinks (see FIG. 23A), and the first information is displayed when an error occurs outdoors. A display lamp 181 provided on the leftmost side of the display area 135a blinks (see FIG. 23B). In the present embodiment, the display lamps 181 to 188 are indicated by a solid line in a blinking state, and indicated by a broken line in an unlit state. The error message is displayed by changing the blinking location, blinking time, and blinking speed according to the type of error, so it is easy to check the error details and error location by looking at the blinking status. Can be done.

  Next, the flow of operation of the air conditioner in the present embodiment will be described with reference to FIG. FIG. 24 is a flowchart showing a flow of operations of the air conditioner in the present embodiment.

  In FIG. 24, the power cord of the indoor unit 100 is inserted into an outlet provided on the wall surface of the room and the main power button (not shown) is turned on, whereby the air conditioner composed of the indoor unit 100 and the outdoor unit 200 is powered. It is in the ON state. In this state, when the user selects the operation mode of the air conditioner with the remote controller 300, the air conditioner operates. First, in step 1000, when the user selects an operation mode by the operation / stop button 303, automatic operation is started based on the setting conditions when the air conditioner was operated last time (step 1010). When it is necessary to set room temperature and humidity during the operation of the air conditioner (step 1020), the room temperature and humidity are set by operating the humidity setting button 307 and the room temperature setting button 308 (step 1030). In step 1040, if the setting of the room temperature and humidity is completed, the operation based on the setting is performed, and the setting information display area 320b displays the setting state of the room temperature and humidity, and the air conditioner is in the setting state. The operation according to is performed (step 1050).

  In step 1000, when the user does not select the operation mode by the operation / stop button 303, the dehumidifying button 304, the “cool / comfort” button 305, or the operation switching button 351 is used to perform the dehumidifying operation, the cooling operation, or the heating operation. And the air conditioner is operated according to the selected operation mode. First, in step 1100, when the dehumidifying operation by the dehumidifying button 304 is selected, the air conditioner starts the dehumidifying operation based on operating conditions such as room temperature and humidity set in advance to perform the dehumidifying operation, and at the same time, In the setting information display area 320b, a display indicating the dehumidifying operation, the set temperature, and the humidity are displayed (step 1110). In step 1120, in the dehumidifying operation, since the operation is performed so that the room is comfortable, it is not particularly necessary to adjust the room temperature and humidity. However, there are individual differences in the room temperature and humidity that feel comfortable, depending on the user's constitution and physical condition, and in some cases it is necessary to adjust the room temperature and humidity. The present invention is characterized in that the room temperature and humidity can be adjusted even during the dehumidifying operation by the humidity setting button 307 and the room temperature setting button 308 disposed on the surface of the opening / closing lid 302.

  When adjusting (setting) the room temperature and humidity, the process proceeds to step 1130, and the room temperature and humidity are adjusted (set) by the humidity setting button 307 and the room temperature setting button 308. Proceed to 1040. In step 1040, if the adjustment (setting) of the room temperature and humidity has been completed, the process returns to step 1110 to perform the dehumidifying operation based on the adjusted room temperature and humidity, and the contents displayed in the setting information display area 320b. However, the display changes to the adjusted (set) room temperature or humidity.

  When the user does not select the dehumidifying operation by the dehumidifying button 304 in step 1100, the operation mode is selected by the “cool / comfort” button 305 or the operation switching button 351, and the air conditioner is selected according to the selected operation mode. Will drive.

  In step 1200, when the operation mode of the air conditioner by the “cool / comfort” button 305 is selected, the operation of the air conditioner, for example, dehumidifying operation or cooling is performed while controlling the humidity according to the temperature difference between the room temperature and the outside temperature. In addition to performing operation, heating operation, etc., the operation state of the air conditioner such as room temperature, humidity, operation mode, etc. is displayed in the setting information display area 320b (step 1210).

  In step 1220, when the operation mode of the air conditioner by the “cool / comfort” button 305 is selected, the temperature and the temperature are set so that the indoor space is in a comfortable state while taking into consideration the temperature difference between the room temperature and the outside air temperature. Since the air conditioner is operated while automatically adjusting the humidity, it is not particularly necessary for the user to adjust (set) the room temperature and humidity with the humidity setting button 307 and the room temperature setting button 308. However, since the comfort felt by the user varies among individuals, it is necessary for the user to adjust the room temperature and humidity. In such a case, the process proceeds to step 1230, and room temperature and humidity are adjusted (set) by the humidity setting button 307 and the room temperature setting button 308. After the room temperature and humidity are adjusted (set), the process proceeds to step 1240. In step 1240, if the adjustment (setting) of the room temperature and humidity is completed, the process returns to step 1210 to perform the dehumidifying operation based on the adjusted room temperature and humidity, and the contents displayed in the setting information display area 320b. However, the display changes to the adjusted (set) room temperature or humidity.

  If the operation mode of the air conditioner by the “cool / comfort” button 305 is not selected in step 1200, the process proceeds to step 1300, the opening / closing lid 302 is opened, and the operation switching button 351 is operated to perform the cooling operation or Select an operation mode such as heating operation.

  In step 1310, when the cooling operation is selected by the operation switching button 351, the cooling operation is performed according to the room temperature and humidity set in advance to perform the cooling operation, and the operation state of the air conditioner and the set room temperature and humidity are set. Is displayed in the setting information display area 320b. When the cooling operation is not selected by the operation switching button 351, the process proceeds to step 1400, and the operation switching button 351 is operated again to select the heating operation. And while performing cooling operation according to the room temperature and humidity preset in order to perform heating operation, the driving | running state of an air conditioner, the set room temperature, and humidity are displayed on the setting information display area 320b.

  If it is necessary to adjust the room temperature or humidity in the cooling operation or the heating operation (step 1330), the process proceeds to step 1340, the room temperature is set by the room temperature setting button 308, and the setting of the room temperature is completed in step 1350. If so, the process returns to step 1320 or 1400 to perform the cooling operation or the heating operation based on the set room temperature and humidity, and the operation mode and the set room temperature and humidity are displayed in the setting information display area 320b.

  As described above, according to the present invention, it is possible to adjust the room temperature of the air conditioner that operates according to the preset operating conditions by instructing the operation button according to the sense of the user. It is possible to create a more comfortable indoor environment.

  Although the main power button (not shown) is normally in an ON state, the main power button can be turned off according to the season to cut off standby power of the air conditioner.

  In the cooling operation or heating operation in the present embodiment, the humidity is not adjusted as in the dehumidifying operation described above. However, the humidity may be adjusted as necessary. When the humidity can be adjusted in the cooling operation or the heating operation, the room temperature and the humidity are adjusted in steps 1330 and 1340, and after the adjustment, the normal cooling operation or heating operation is performed.

  Next, the transmission / reception unit 110 of the indoor unit 100 according to the present embodiment will be described with reference to FIG.

  25A and 25B are diagrams illustrating the configuration of the transmission / reception unit 110 of the indoor unit 100. FIG. 25A is an outline of an external view of the display unit 110, and FIG. 25B is a partial view of the indoor unit 100. FIG. As shown in FIG. 25, the transmission / reception unit 110 includes two transmission units 111 a and 111 b and one reception unit 112. The operation mode signal transmitted from the remote controller 300 is received by the receiver 112, and the received operation mode signal is transmitted to the indoor unit control device 601, and the indoor unit 100 and the outdoor unit 200 are operated according to the operation mode signal. In operation, the indoor temperature sensor 602 and the indoor humidity sensor 603 start measuring indoor temperature and humidity.

  Here, when the button 340 provided on the remote controller 300 is pressed, a signal is transmitted to the indoor unit control device 601 via the receiving unit 112, and the indoor unit control device 601 transmits the signal according to the transmitted signal. Information on room temperature and humidity at the present time (when the button 340 is pressed) is received from the indoor temperature sensor 602 and the indoor humidity sensor 603, and is transmitted to the remote controller 300 from the transmitter 111a or the transmitter 111b. In the display area 320a, the room temperature and humidity at the present time (when the button 340 is pressed) are displayed. Then, the room temperature and humidity can be adjusted by viewing the displayed room temperature and humidity and operating the humidity setting button 307 or the room temperature setting button 308 as necessary.

  With such a configuration, the room temperature and humidity can be confirmed by the user, and the room temperature or humidity can be adjusted as necessary, so that the room temperature or humidity can be adjusted according to the user's constitution and physical condition. It can be set to create a more comfortable indoor space.

  Next, another embodiment of the operation state display unit 135 provided in the indoor unit 100 will be described with reference to FIG. FIG. 26 is a front view showing another embodiment of the indoor unit 100, and FIG. 26 (a) is a diagram in which the operation state display unit 135 is concentrated and provided along one side of the indoor unit 100. (B) The figure shows the operation state display unit 135 distributed on both sides of the indoor unit 100, and (c) the figure shows the operation state display unit 135 concentrated on one side of the blowing unit 133 of the indoor unit 100. Is. In this embodiment, the transmission / reception unit 110 is provided on the side where the electrical components of the indoor unit 100 are arranged, that is, on one side of the air outlet 133, thereby shortening the wiring, thereby improving the assemblability.

  Furthermore, in this embodiment, the operation state display unit 135 is configured by two information display areas, and the two information display areas are, for example, the first information display area 135a corresponding to the temperature and the first information display area 135a corresponding to the humidity. 2 information display area 135b.

  (A) In the embodiment shown in the figure, the first information display area 135a and the second information display area 135b constituting the operation state display unit 135 are concentrated on one side where the electrical components of the indoor unit 100 are arranged. ing. Furthermore, in this embodiment, a pair of vertically long and bar-shaped operation state display sections 135 are arranged along the longitudinal direction of the electrical component. Thereby, the large operation state display part 135 with favorable visibility can be arrange | positioned using the dead space of the indoor unit 100 effectively. Moreover, since the two display units of the pair of operation state display units 135 are arranged in parallel, it is possible to grasp the state while comparing the temperature and the humidity.

  Further, in the embodiment of FIG. 6B, the vertically long and strip-shaped first information display area 135a and second information display area 135b are distributed along the end portions on both sides of the front surface of the indoor unit 100. It is a thing. According to this embodiment, it is possible to arrange the large operating state display unit 135 with good visibility by effectively using the dead space of the indoor unit 100. Moreover, since the two display areas are divided into left and right, it is possible to grasp the state of temperature and humidity without confusion.

  Further, in the embodiment shown in (c), the first information display area 135a and the second information display area 135b constituting the operation state display unit 135 are arranged together with the transmission / reception unit 110 on one side of the outlet 133. It is. Thereby, since the operation state display part 135 and the said transmission / reception part 110 can be arrange | positioned close to electrical goods, assembly property can be improved.

  Next, another embodiment of the remote controller will be described with reference to FIG. FIG. 27 is a front view of a remote controller according to another embodiment. The remote controller of this embodiment is an auxiliary sub-remote controller 950 that can be easily operated by an elderly person or a child and is paired with the main remote controller 300.

  The sub-remote controller 950 also includes a display unit 320 that displays various types of information obtained from the indoor unit 100 and the outdoor unit 200. The sub-remote controller 950 is characterized by including the display unit 320 and buttons (the cooling button 231 and the dehumidifying button 232) in which the operation start function is integrated into the three operation modes, which are main functions, and each function is independent. And a heating button 233). Since the display unit 320 of the sub-remote controller 950 in the present embodiment has the same configuration as the display unit 320 of the remote controller 300, detailed description thereof is omitted.

  The sub-remote controller 950 in the present embodiment includes a thin and flat vertically long casing 301. The display unit 320 is provided on a wide surface of the casing 301, and the main functions of the air conditioner are provided below the display section 320. An operation switch for operation is provided. The operation switch includes a cooling button 231, a dehumidifying button 232, and a heating button 233 that directly operate the corresponding operation mode by pressing this button, a stop button 303 that stops the operation in the three operation modes, and the humidity setting. The button 307, the room temperature setting button 308, a good night button 309, and a button 340 are also provided.

  According to this embodiment, the operation start function is integrated with the three operation modes, which are the main functions of the air conditioner 1, and each function is independent (the cooling button 231, the dehumidifying button 232 and the heating button 233. ), It is possible to directly select the operation function to be used in one operation. In addition, since the stop button is provided independently, erroneous operation can be reduced. And according to this embodiment, since the operation function is limited and provided, each operation button is made independent and large and has a wide space, so that erroneous operations can be reduced. Thus, according to this air conditioner 1, the two remote controllers can be used properly according to the user's preference.

  Next, with reference to FIG. 28, another embodiment relating to the gradation grill 140 will be described.

  In the above-described embodiment, the front suction grill 131 is provided at the front portion of the casing 150 having the highest suction efficiency, and the suction efficiency is lowered at the upper portion of the front suction grill 131 (the distance from the fan is increased). Although an embodiment has been described in which the gradation grill 140 having a small opening area is provided and efficient operation is possible while harmonizing with the interior, the present invention is not limited to this. For example, the front suction grill 131 and the gradation grill 140 may be formed as one continuous grill, and the pitch of each grill or the size of each opening in the vertical direction may be reduced continuously or stepwise. Good.

  FIG. 28 shows a state in which the front suction grill 131 and the gradation grill 140 are formed as one continuous gradation grill 140a, and the pitch of each gradation grill 140a is changed stepwise or continuously. FIG. 4A is a diagram showing a state in which the pitch of the gradation grill 140a is changed in three stages, FIG. 5B is a diagram showing a state in which the pitch of the gradation grill 140a is changed in two stages, and FIG. It is a figure which shows the state which changed the pitch of the said gradation grill 140a continuously.

  (A) The gradation grill 140a shown in the figure includes a first grill 1401a in which the grill pitch is set to P3, a second grill 1402a in which the grill pitch is set to P4, and a third grill in which the grill pitch is set to P5. It is composed of three stages 1403a. Here, the pitch P3 of the first grill 1401a is formed at equal intervals, and the pitches P4 and P5 of the second grill 1402a and third grill 1403a are also formed at equal intervals, respectively.

  (B) The gradation grill 140a shown in the figure is composed of two stages: a first grill 1401b in which the grill pitch is set to P6, and a second grill 1402b in which the grill pitch is set to P7. The pitch P6 of the first grill 1401b and the pitch P7 of the second grill 1402b are formed at equal intervals, as described with reference to FIG.

  (C) The gradation grill 140a shown in the figure is configured by continuously changing the pitch of the grill 1405 from Pa to Pm, for example.

  Even if the gradation grill 140a is configured as shown in FIG. 28, the same effect as that of the gradation grill 140 described above can be obtained. Further, in the present embodiment, one grill (gradient grill 140a) in which the front suction grill 131 and the gradation grill 140 are continuous is shown, but the configuration shown in FIG. 28 may be a structure of the gradation grill 140 alone. .

  DESCRIPTION OF SYMBOLS 100 ... Indoor unit, 102 ... 1st heat exchange part, 103 ... 2nd heat exchange part, 104 ... 3rd heat exchange part, 105 ... Dehumidifying throttle device, 106 ... Connection pipe, 107 ... Connection pipe, 109 ... Indoor fan DESCRIPTION OF SYMBOLS 110 ... Transmission / reception part, 111a ... Transmission part, 111b ... Transmission part, 112 ... Reception part, 130 ... Filter, 131 ... Front suction grille, 132 ... Upper suction grille, 133 ... Outlet, 134 ... Side louver, 135 ... Operation State display section, 135a ... first information display area, 135b ... second information display area, 140 ... gradient grill, 140a ... gradient grill, 150 ... housing, 170 ... drain pan, 180 ... drain pan, 181 ... display lamp, 182 ... Display lamp, 183 ... Display lamp, 184 ... Display lamp, 185 ... Display lamp, 186 ... Display lamp, 187 ... Display lamp 188 ... Indicator lamp 200 ... Outdoor unit 210 ... Back cabinet 220 ... Decorative panel 230 ... Front panel 231 ... Cooling button 232 ... Dehumidifying button 233 ... Heating button 250 ... Blow air vent, 260 ... Air cleaning filter, 300 ... remote control, 302 ... open / close lid, 303 ... run / stop button, 304 ... dehumidification button, 305 ... "cool / comfort" button, 306 ... PAM airflow button, 307 ... humidity setting button, 308 ... room temperature setting 309 ... Good night button, 310 ... Transmission / reception device, 320 ... Display unit, 320a ... Obtained information display area, 320b ... Setting information display area, 340 ... Help button, 351 ... Operation switching button, 352 ... Wind speed switching button, 353 ... Wind direction switching button, 354 ... Wind direction switching button, 355 ... Powerful button 356 ... Preheating button, 357 ... Humidifier button, 358 ... Emptying button, 359 ... Filter button, 360 ... Cancel button, 361 ... Time setting button, 362 ... Reservation button, 363 ... Reset button, 364 ... Timer button, 365 ... Date / Time button, 390 ... Dividing groove, 391 ... Hinge, 401 ... Upper cover, 402 ... Lower cover, 410 ... Opening, 420 ... Opening, 430 ... Battery storage part, 440 ... Claw mounting part, 451 ... Positioning rib , 452 ... Positioning rib, 453 ... Positioning rib, 454 ... Positioning rib, 455 ... Positioning rib, 500 ... Compressor, 510 ... Four-way valve, 520 ... Outdoor heat exchanger, 530 ... Electric expansion valve, 540 ... Refrigerant flow path, 550: Refrigerant flow path, 560: Two refrigerant flow paths, 570: Two refrigerant flow paths, 580: Outdoor fan, 590a: Rib, 59 0b ... ribs, 591 ... upstream end, 592a ... downstream end, 592b ... downstream end, 595 ... opening, 597a ... grill forming part, 597b ... grill forming part, 601 ... indoor unit control Device, 602 ... Indoor temperature sensor, 603 ... Indoor humidity sensor, 604 ... Second receiver, 605 ... Second transmitter, 606 ... Outdoor unit controller, 607 ... Outdoor temperature sensor, 608 ... Selection device, 609 ... Central processing Device: 610: first transmission unit, 611: first reception unit, 620: display lamp, 700: battery cover, 710: nail, 750: liquid crystal substrate, 760: printing surface, 770: opening, 810: back plate, 820 ... Opening part, 830 ... Positioning rib, 840 ... Positioning rib, 850 ... Positioning rib, 900 ... First substrate, 910 ... Conductive material, 950 ... Sub remote control, 1401a ... First 1 grill, 1401b ... 1st grill, 1402a ... 2nd grill, 1402b ... 2nd grill, 1403a ... 3rd grill, 1405 ... grill, Q ... connection point, Z1 ... upstream side, Z2 ... downstream side.

Claims (3)

Air conditioner capable of cooling operation, heating operation and dehumidifying operation, remote control device for instructing the air conditioner to operate, indoor temperature detecting means for detecting indoor temperature, and indoor humidity detection for detecting indoor humidity an air conditioning apparatus provided with a means,,
The remote control device includes
A dehumidifying button for instructing dehumidifying operation;
A room temperature setting button for setting a room temperature arranged on one side in the width direction of the casing of the remote control device;
A room humidity setting button for setting a room humidity disposed in the width direction of the casing of the remote control device and on the other side of the room temperature setting button;
An instruction button for instructing to display the indoor temperature detected by the indoor temperature detecting means and the indoor humidity detected by the indoor humidity detecting means on the remote control device;
The room temperature detected by the room temperature detection means is displayed on one side in the width direction of the casing of the remote control device on which the room temperature setting button is arranged, and the room humidity detected by the room humidity detection means is displayed. An air conditioner comprising: a display unit configured to display on the other side in the width direction of the casing of the remote control device in which the indoor humidity setting button is arranged. Cooling operation, a heating operation and a dehumidifying operation capable air conditioner, an air conditioning apparatus provided with a remote control device, the instructing operation with respect to the air conditioner,
The air conditioner includes an indoor temperature detecting means for detecting the indoor temperature and an indoor humidity detecting means for detecting the indoor humidity,
The remote control device includes a dehumidifying button for instructing dehumidifying operation,
A room temperature setting button for setting a room temperature disposed on one side in the width direction of the casing of the remote control device; and a width direction of the casing of the remote control device on the other side of the room temperature setting button. Indoor humidity setting button to set the indoor humidity, and
An instruction button for instructing to display the indoor temperature detected by the indoor temperature detecting means and the indoor humidity detected by the indoor humidity detecting means on the remote control device;
The room temperature detected by the room temperature detection means is displayed on one side in the width direction of the casing of the remote control device on which the room temperature setting button is arranged, and the room humidity detected by the room humidity detection means is displayed. An air conditioner comprising: a display unit configured to display on the other side in the width direction of the casing of the remote control device in which the indoor humidity setting button is arranged. According to claim 1 or 2, wherein the dehumidification button, the indoor humidity setting button arranged housing air conditioner arranged on the other side in the width direction of the remote control device.

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