ES2705061T3 - Operating system and operating method for air conditioning device - Google Patents

Abstract

An operating system for an air conditioning device for operating an indoor unit (12) including a plurality of air outlets (50) that blow air the temperature of which is adjusted to an air conditioning region (A), and adjusting portions (51) each of which is provided to correspond to each of the air vents (50), with the adjusting portions adjusting at least one of a blowing direction of air from the air vents. (50) and existence / non-existence of blowing, and an operating device (60) that receives an instruction for an operation of the adjustment portions (51), the operating system is characterized in that it also comprises a device for obtaining images (61) taking an image (G1) of the air conditioning region (A) such that a user located in the air conditioning region (A) is included in the image; and wherein the operating device (60) includes: an exposure unit (64); an image generating part (66) that generates an operating image (S1) by overlapping the image (G1) of the air conditioning region (A) taken by the imaging device (61) with an image (G2 ) of the plurality of air outlets (50); an exposure control part (68) allowing the exposure unit (64) to expose the operating image (S1); and a selection receiving part (67) receiving selection of an air outlet (50) in the operating image (S1) displayed on the exposure unit (64) in order to identify the air outlet (50) provided with the adjustment portion (51) serving as the object to be handled.

Description

DESCRIPTION

Operating system and operating method for air conditioning device

Technical field

The present invention relates to an operating system and an operating method for an air conditioning device.

Background of the technique

The following Patent Literature 1 describes an indoor unit connected to a roof, the indoor unit includes four air outlets that blow air to four sides. In that indoor unit, the air whose temperature is adjusted is fed to a wide range of an interior by blowing the air respectively from the air outlets, so that a temperature inside can be efficiently adjusted. In each of the four air outlets of this indoor unit a fin (adjustment portion) is provided which adjusts the blowing direction of the air in the up and down direction, and the fins can be operated independently. In this indoor unit, a remote control is provided that receives an operation to individually actuate the fins.

In the vicinity of the respective air vents in the indoor unit of the Patent Bibliography 1, different sign portions are provided to each other, and in the remote control there is provided an exposure portion which exposes in correspondence with the sign portions of the air exits. Specifically, the sign portions indicating respectively "□", "□□", "□□□" and "□□□□" are provided in the vicinity of the four air vents, and indications of "□", " □□ "," □□□ "and" □□□□ "corresponding to these are displayed in the exposure portion of the remote control. By selecting the indication of the remote control corresponding to the sign portion of the air outlet, a user can operate the fin provided in the air outlet.

In addition, Patent Literature 2 discloses an air conditioning system having an air conditioning controller. Indoor machines in the air conditioning system supplies air conditioning to the interior of a building by means of a plurality of supply openings. A current arrangement of the interior of the building includes a plurality of target areas for air conditioning. When the operating panel receives from the layout screen the selection of the target air conditioning areas that require the supply of the air conditioner by the indoor machines or the air conditioning target areas that do not require the supply of air conditioning, a determining portion of the air conditioning control device determines a wind direction pattern based on the result of the selection of the target air conditioning zones.

Appointment list

[Patent bibliography]

Patent Bibliography 1: Japanese Patent Not Examined Publication No. 2011-94924

Patent Bibliography 2: JP 4715947 B2

Compendium of the invention

Technical problem

In the technique described in the Patent Bibliography 1, for example, in a case where the fins are operated in such a way that wind is blown (or not blown) directly on the user himself, the user is first required to identify the Air outlet that blows air towards it, and approach the indoor unit to confirm the portion of sign connected to the air outlet. Then, the user has to move to a position of the remote control, select the indication corresponding to the sign portion, and then operate the flap. Therefore, an operation to adjust the blowing direction of the air is extremely problematic.

An object of the present invention is to provide an operating system and method of operation for an air conditioning device that can easily identify an air outlet provided with an adjustment portion that serves as the object to be operated and immediately adjust the direction of air blowing and the like.

Solution to the problem

The present invention is an operating system for an air conditioning device for operating an indoor unit that includes a plurality of air exits that blow air whose temperature is adjusted to an air conditioning region, and adjustment portions each one of which is provided to correspond to each of the air outlets, with the adjustment portions that adjust at least one of the direction of air blowing from the air outlets and existence / non-existence of blow, the system of operation includes an imaging device that takes an image of the air conditioning region, and an operating device that receives an operation for actuating the adjustment portions, wherein the operating device includes an exposure unit, an image generating part that generates an operating image by overlapping the image of the air conditioning region taken by the imaging device with an image of the plurality of air outlets, an exposure control part that allows the exposure unit to display the operation image; and a selection receiving part that receives selection of an air outlet in the operating image displayed in the exposure unit in order to identify the air outlet provided with the adjustment portion that serves as the object to be handled.

According to the above configuration, when the imaging device takes the image of the air conditioning region, a user located in the air conditioning region is included in the image. Thus, in the operating image generated by overlaying the image with the image of the air vents, a positional relationship between the user and the air vents is obvious at a glance. Therefore, the user can easily distinguish in the operating image the air outlet that blows the air towards it and select the air outlet in the operating image. Thus, there is no need for a task to confirm sign portions connected to an indoor unit as in the conventional art, so that an operation of the adjustment portion can be performed immediately.

In the above configuration, preferably, the indoor unit is connected to a ceiling, and the imaging device takes an image of the air conditioning region from the side of the indoor unit to the lower side.

With this type of configuration, the image of the entire region of air conditioning can be favorably taken.

Preferably, the exposure control part allows the exposure unit to display the image of the air conditioning region while splitting into divided regions corresponding to the respective air outlets.

With this type of configuration, the user can more easily distinguish the air outlet that blows the air towards him and more easily select the air outlet.

The selection receiving part can receive a contribution of an identified position in the air conditioning region corresponding to the air outlet, and sensitive temperature information in the identified position.

When the identified position is obtained in the air conditioning region (such as a user's location) and the temperature sensitive information in the location (temperature information that the user feels physically such as "heat" or "cold"), in which you can dictate the direction in which you have to blow the air from the air outlet to the identified location. For example, when the user feels "heat" at the time of cooling operation, the air blowing direction can be adjusted in such a way that fresh wind is blown directly on the user's position (identified position). As in the previous configuration, by providing the identified position in the air conditioning region and the sensitive temperature information in the position identified to the operating device, even when the user does not directly instruct the air blowing direction, the Appropriate blowing direction can be determined automatically on the side of the indoor unit.

Preferably, in a case where the plurality of indoor units are provided in a room, the image generation part synthesizes the plurality of operating images according to the actual arrangement of the plurality of indoor units and generates an entire image of operation, and the exposure control part allows the exposure unit to display the entire image of operation on a screen.

In a case where the plurality of indoor units is provided in a room, there is sometimes a case in which air is blown to the user from the air vents of two or more indoor units. In this case, the adjustment portions may have to be operated not only on one air outlet but also on two or more air outlets. In the above configuration, in a state according to the actual arrangement of the indoor units, a whole operating image is generated by synthesizing the plurality of operating images, and this entire operating image is displayed on a display of the exposure unit . Thus, the air outlets of the plurality of indoor units can be selected on a screen.

The present invention is an operating method for an air conditioning device for operating an indoor unit that includes a plurality of air exits that blow air whose temperature is adjusted to an air conditioning region, and adjustment portions each one of which is provided to correspond to each of the air outlets, with the adjustment portions adjusting at least one of the direction of air blowing from the air outlets and existence / non-existence of blowing, the method of operation includes a step of obtaining images to take an image of the air conditioning region, an image generating step to generate an operating image by overlaying the image of the air conditioning region taken in the step of obtaining images with an image of the plurality of air outlets, an exposure stage for exposing the operating image generated in the step of generating an image in an exposure unit of an exposure device, and a selection receiving step for receiving the selection of an air outlet in the operating image displayed in the exposure unit in order to identify the air outlet provided with the adjustment portion that serves as the object to be handled.

By this type of operating method, as well as the above description, the user can easily distinguish in the operating image the air outlet that blows the air towards it and select the air outlet in the operating image. Therefore, there is no need for a task to confirm sign portions connected to an indoor unit as in the conventional art, so that an operation of the adjustment portion can be performed immediately.

Advantageous effects of the invention

According to the present invention, the air outlet provided with the adjusting portion serving as the object to be handled can be easily identified and the air blowing direction and the like can be adjusted immediately.

BRIEF DESCRIPTION OF THE DRAWINGS

[FIG. 1] Figure 1 is a schematic configuration diagram of an air conditioning device in which an operating system according to a first embodiment of the present invention is adopted.

[FIG. 2] Figure 2 is a schematic side sectional view of an indoor unit.

[FIG. 3] Figure 3 is a plan view in which a decoration panel of the indoor unit is seen from the inside side (side of an air conditioning region).

[FIG. 4] Figure 4 is a sectional view of a part of an air air outlet.

[FIG. 5] Fig. 5 is a block diagram showing a configuration of the operating system for the air conditioning device.

[FIG. 6] Figure 6 is a schematic view showing an exposure content in an exposure unit.

[FIG. 7] Fig. 7 is a schematic view showing an exposure content in an exposure unit in a second embodiment of the present invention.

[FIG. 8] Figure 8 is a schematic view showing an exposure content in an exposure unit in a third embodiment of the present invention.

Description of realizations

Later in this specification, embodiments of the present invention will be described, with reference to the drawings.

[First embodiment]

Figure 1 is a schematic configuration diagram of an air conditioning device in which an operating system according to a first embodiment of the present invention is adopted.

An air conditioning device 10 is a split type air conditioning device , and mainly has an outdoor unit 11, an indoor unit 12, and a liquid side communication pipe 13 and a water side communication pipe. gas 14 connecting the outdoor unit 11 and the indoor unit 12, and these form a vapor compression type refrigerant circuit 15.

The outdoor unit 11 is installed on an exterior or the like, and mainly includes a compressor 21, a four-way selector valve 22, an outdoor heat exchanger 23, an expansion valve 24, a side-stop valve, liquid 25, and a gas side stop valve 26.

The compressor 21 is a mechanism that sucks and compresses a gaseous refrigerant at low pressure to make a gaseous refrigerant under high pressure, and then discharges the gaseous refrigerant. Like this compressor 21, a closed type compressor can be adopted in which a scroll type rotary type compression element or something similar accommodated in a housing is driven by a compressor motor 21a. In the compressor motor 21a, the number of rotations thereof (that is, the operating frequency) can be changed by inverter control. In this way, capacity control of the compressor 21 can be performed.

The four-way selector valve 22 is a valve for switching the direction of a refrigerant flow at the time of switching a cooling operation and a heating operation. The four-way selector valve 22 connects a discharge side of the compressor 21 and a gas side end of the outdoor heat exchanger 23 and connects the gas side stop valve 26 and a suction side of the compressor 21 in the operating moment cooling (refer to the solid lines of the four-way selector valve 22 in Figure 1). The four-way selector valve 22 connects the discharge side of the compressor 21 and the gas side stop valve 26 and connects the gas side end of the outdoor heat exchanger 23 and the suction side of the compressor 21 in the operating moment heating (check the discontinuous lines of the valve four-way selector 22 in Figure 1).

The outdoor heat exchanger 23 is a heat exchanger that functions as a heat radiator (condenser) of the refrigerant at the time of operation by cooling and functioning as a refrigerant evaporator at the time of operation by heating. A liquid side end of the outdoor heat exchanger 23 is connected to the expansion valve 24 and the gas side end is connected to the four way selector valve 22.

The expansion valve 24 of the present embodiment is an electric expansion valve whereby a high pressure liquid refrigerant whose heat has already been released in the outdoor heat exchanger 23 can be decompressed before being fed to a heat exchanger of interior 42 (described later) at the time of operation by cooling, and a high-pressure liquid refrigerant whose heat has already been released in the indoor heat exchanger 42 can be decompressed before being fed to the outdoor heat exchanger 23 at the time of operation heating.

The liquid side stop valve 25 and the gas side stop valve 26 are valves provided in connection ports to external devices and pipes (specifically, the liquid side communication pipe 13 and the side communication pipeline). of gas 14). The liquid side stop valve 25 is connected to the expansion valve 24. The gas side stop valve 26 is connected to the four way selector valve 22. The outdoor unit 11 is provided with an outdoor fan 27 to suck exterior air into the housing, supply the outdoor air to the outdoor heat exchanger 23, and then discharge the air to an exterior of the housing.

The outdoor heat exchanger 23 is a heat exchanger that releases heat from the refrigerant, or evaporates it, the outdoor air serving as the cooling source or heat source. As an outdoor fan 27, a propeller fan is adopted which will be driven by an outdoor fan motor 27a. In the outdoor fan motor 27a, the number of rotations thereof (that is, the operating frequency) can be changed by an inverter device. In this way, an air volume of the outdoor fan 27 can be controlled.

The outdoor unit 11 has an outdoor control unit 28 which controls actions of parts forming the outdoor unit 11. The outdoor control unit 28 has a microcomputer, a memory and the like for controlling the outdoor unit 11, and sends and receives a control signal and the like to and from an indoor control unit 43 (described later) of the indoor unit 12.

The liquid side communication pipe 13 is connected to the liquid side stop valve 25, and is used to guide the coolant out to an exterior of the outdoor unit 11 from an outlet of the outdoor heat exchanger 23 which it functions as a heat radiator (condenser) of the refrigerant at the time of operation by cooling, and is used to introduce the refrigerant to an inlet of the outdoor heat exchanger 23 which functions as a refrigerant evaporator from the outside of the outdoor unit 11 in the moment of operation heating up.

The gas side communication pipe 14 is connected to the gas side stop valve 26, and is used to introduce the refrigerant to the suction side of the compressor 21 from the outside of the outdoor unit 11 at the time of operation cooling, and is used to guide the coolant out to the exterior of the outdoor unit 11 from the discharge side of the compressor 21 at the time of operation by heating.

The indoor unit 12 is installed in an indoor ceiling, a wall, or the like, and mainly has an indoor fan 41 and the indoor heat exchanger 42. The indoor fan 41 is formed to suck indoor air that serves as the object to be conditioned, allows air to pass through the indoor heat exchanger 42, and then blows the air to an exterior of the indoor unit 12. The indoor fan 41 has an indoor fan motor 41a and a paddle wheel 41b coupled to the indoor fan motor 41a to be driven and rotated. The paddle wheel 41b is a paddle wheel having turbo blades. In the indoor fan motor 41a, the number of rotations thereof (that is, the operating frequency) can be changed by inverter control. In this way, an air volume of the indoor fan 41 can be controlled.

The indoor heat exchanger 42 is a heat exchanger which functions as an evaporator of the refrigerant at the time of operation by cooling and which functions as a heat radiator (condenser) of the refrigerant at the time of operation by heating. The indoor heat exchanger 42 is connected to the liquid side communication pipe 13 and the gas side communication pipe 14 by means of a refrigerant pipe.

The indoor unit 12 has the indoor control unit 43 which controls actions of parts forming the indoor unit 12. This indoor control unit 43 has a microcomputer, a memory and the like for controlling the indoor unit 12, and it can send and receive a control signal and the like to and from the outdoor control unit 28 of the outdoor unit 11. The indoor control unit 43 and the outdoor control unit 28 form a control unit that performs control of operation and the like of the air conditioning device The air conditioning device 10 includes an operating device 60 for performing operations such as starting / stopping an operation, and adjusting a temperature, a volume of air, and the wind direction. This operating device 60 is connected to be in communication with the indoor control unit 43 by means of communication means. The operating device 60 forms the operating system for the air conditioning device 10 together with an imaging device 61 which is described later. The operating device 60 of the present embodiment is formed by a general personal computer (hereinafter also referred to as "PC") which includes a CPU, a memory and the like. It should be noted that communication between the operating device 60 and the indoor control unit 43 via the communication means can be cable communication using a LAN cable or the like or it can be wireless communication using a wireless LAN or the like.

Figure 2 is a schematic side sectional view of the indoor unit. Figure 3 is a plan view in which a decoration panel of the indoor unit is seen from the inside side (side of an air conditioning region). Figure 4 is a sectional view of a part of an air outlet of the air.

The indoor unit 12 of the present embodiment is of the roof embedded type that is installed inside a roof. This indoor unit 12 has a housing 44 which accommodates various constituent members within as shown in Figure 2. The housing 44 is formed by a main housing body 45 disposed within the roof, and a decoration panel 46 disposed on the side lower of the main housing body 45 and disposed along a lower surface of a roof 54.

The main housing body 45 is formed in the form of a box whose lower surface is open, and the indoor heat exchanger 42 and the indoor fan 41 are disposed therein. The decoration panel 46 is a body in the form of a square plate made of synthetic resin or metal, fixed to a lower end portion of the main housing body 45. In the center of the decoration panel 46 a suction port 47 is formed which sucks air, and around the suction port 47 a plurality of air outlets 50 that blow the air are formed. As shown in Figure 3, the suction port 47 is formed to a square shape in a plan view, and the suction port 47 is provided with a suction grille 48 and a suction filter 49.

As shown in Figure 2, the indoor fan 41 is disposed above the suction port 47, and the indoor fan motor 41a thereof is connected and fixed to an upper plate 45a of the main housing body 45. The indoor heat exchanger 42 is arranged to surround the indoor fan 41. On the lower side of the indoor heat exchanger 42 a drain pan 52 is provided, and in the center of the drain pan 52 a port is provided of bell 53 guiding a flow of air from the suction port 47 to the indoor fan 41.

When the indoor fan 41 is activated, the air is sucked from the suction port 47, and in a process of passing through the indoor heat exchanger 42 at an outer periphery of the suction port, heat exchange is performed between the air and the refrigerant. The air after the heat exchange flows downward along an inner surface 45b of the main housing body 45, and is blown from the air outlets 50. Dew condensation water generated in the indoor heat exchanger 42 is received by the drain pan 52 on the underside thereof, and discharged to the outside by means of a water discharge path (not shown).

As shown in Figure 3, the air outlets 50 are provided in four points, and are formed to be thin and long along outer sides of side portions of the suction port 47 formed in a square shape. In each of the air outlets 50 there is provided a fin (adjustment portion; adjustment vane) 51 which adjusts the direction of blowing of the air and existence / non-existence of blowing. The flap 51 is a plate-shaped member formed to be thin and long substantially along an inner edge of the air outlet 50, and is supported by a substantially horizontal support stem 51b (refer to FIG. 4) disposed a along the longitudinal direction thereof to be tilting in the up and down direction. The vane 51 is driven and tilted in the up and down direction by a vane motor 51a (refer to figure 3) and adjusts the blowing direction of the air according to an angle of oscillation thereof.

As shown in Figure 4 (a), the flap 51 can bring the air outlet 50 to a substantially closed state in a substantially horizontal posture (P5), to stop blowing air from the air outlet 50 as much as possible. possible (to suppress a quantity of blowing in a state in which little air leakage is allowed). As shown in Figure 4 (b), the flap 51 can adjust the direction of air blowing by changing the position around the support stem 51b. In the fin 51 of the present embodiment, the posture can be changed in five stages from P0 to P4. Along with the substantially horizontal posture P5 shown in Fig. 4 (a), the posture can be changed in six stages in total at the fin 51. It should be noted that the posture of the fin 51 can be formed to be adjusted without stages, or the substantially horizontal posture P5 of the vane 51 in which the blowing of the air is stopped can be omitted.

As shown in Figure 4 (b), in the present embodiment, when the posture of the vane 51 is established to be P0, the air is blown in the substantially horizontal direction along the lower surface of the roof 54 from the air outlet 50. When the posture of the wing 51 is established to be P4, the air is blown in the direction substantially directly downward. When the posture of the vane 51 is set to be from P1 to P3, the air is blown in the oblique direction which is between the substantially horizontal direction and the direction substantially directly down.

Next, the operating system for operating the flap 51 according to a user's request will be described in detail.

Figure 5 is a block diagram showing a configuration of the operating system for the air conditioning device.

The operating system of the present embodiment includes the operating device 60 connected to the indoor unit 12 and the camera (imaging device) 61 provided in the indoor unit 12. This camera 61 includes for example elements for obtaining images mounted on a substrate such as a CMOS and a CCD, and provided on an outer peripheral portion of the decoration panel 46, the suction grid 48, or the like. An image acquisition range of the camera 61 is established in such a way that an image is taken of the entire region of air conditioning of an interior centered on the indoor unit 12. The image taken by the camera 61 is sent to the device of operation 60 from the indoor control unit 43 by means of a communication cable.

The operating device 60 is for providing an operation instruction for the flap 51, and includes a control unit 63, an exposure unit 64 and a delivery unit 65. The control unit 63 includes an arithmetic unit such as a CPU and a storage unit such as a memory. With the arithmetic unit executing a program registered in the storage unit, various functions can be exercised. The control unit 63 of the present embodiment includes an image generation portion 66, a selection reception portion 67, and an exposure control portion 68 as operating portions thereof.

The image generation part 66 has a function to generate a predetermined operating image using an image of the air conditioning region taken by the camera 61. The exposure control part 68 controls and allows the exposure unit 64 to expose the operating image generated by the image generation part 66. The exposure unit 64 can be formed for example by a liquid crystal monitor or a CRT monitor, and is connected to the control unit 63 by means of a digital interface. output (not shown).

Figure 6 is a schematic view showing an exposure content in the exposure unit.

By overlaying a photographed image G1 of an air conditioning region A taken by the camera 61 with an image G2 of the indoor unit 12 including the air outlets 50, an operation image S1 is formed. That is, the operation image S1 is an image expressing the entire region of air conditioning A in a form that also includes the indoor unit 12. The photographed image G1 of the air conditioning region A includes desks D disposed at the air conditioning region A and M users on the desktop D. The image G2 can be an imaginary image such as an illustration expressing the indoor unit 12 and the air outlets 50. However, the G2 image can be an photographed image in which an image of the decoration panel 46 is taken separately from the bottom surface side. In any case, the image G2 is an image that the camera 61 is unable to take. In the present embodiment, an indication of a numerical value of an established temperature ("23 ° C" in the example shown in the figure) is also included in the G2 image.

In the operating image S1, partition lines L are provided which split the air conditioning region A for regions (divided regions) B respectively corresponding to the air outlets 50. By means of the partition lines L, in which it is possible to capturing the region B in the air conditioning region A a temperature or the like is adjusted mainly by the air blown from the air outlet 50. Therefore, when viewing the operation image S1, a position of the user M and the D-desk and a relation between the position and the air outlet 50 that blows the air towards the position are obvious at a glance.

The selection reception part 67 has a reception selection function (designation) of the air outlet 50 in the operation image S1 exposed in the exposure unit 64 in order to identify the air outlet 50 provided with the fin 51 which serves as an object to be handled. The air outlet 50 may be selected using the delivery unit 65. The delivery unit 65 may be formed by a mouse, a keyboard, or the like connected to the control unit 63.

Later in this specification, a specific method for selecting the air outlet 50 will be described.

As shown in Fig. 6, in the exposure unit 64, an exposure region W1 is provided to expose the operation image S1 as well as an exposure region W2 to expose a sensitive temperature icon (sensitive temperature designation image). ). This sensitive temperature icon includes an "o" icon that indicates a user's "heat" sensitive temperature, and an "•" icon that indicates a sensitive "cold" temperature of the user. In order to provide the sensitive temperature of the user to the operating device 60, in a case where the user feels cold, the user drags and releases (later in this memory, it is simply referred to as "dragging") the icon "•" to its position (for example, on the desktop D), and in a case in which the user feels heat, the user drags the "o" icon to his position.

By this operation, in the first place, the air outlet 50 corresponding to the divided region B to which the sensitive temperature icon is drawn is identified as the air outlet 50 provided with the fin 51 which serves as the object to be handled, and is received by the selection receiving part 67 of the control unit 63. In addition, information on a position in the divided region B to which the sensitive temperature icon is drawn and a type of the sensitive temperature icon (• oo) it is received by the selection receiving part 67 of the control unit 63.

By means of the position to which the sensitive temperature icon is dragged, an interior location can be identified in which the temperature must be adjusted. By the type of the sensitive temperature icon (• or o), it can be dictated in which way the direction of blowing of the air to the location has to be adjusted. The selection receiving part 67 sends the information about the received air outlet 50 and the information about the position to which the sensitive temperature icon and the type thereof is drawn to the indoor control unit 43, and the unit The interior control 43 controls and operates the fin 51a based on this information.

For example, during cooling operation, in a case where the user located in a position that is the furthest from the indoor unit 12 in one of the divided regions B in the operating image S1 drags the "cold" icon to its position, the selection receiving part 67 of the control unit 63 receives selection of the air outlet 50 corresponding to the divided region B and also receives and sends the dragged position of the sensitive temperature icon and the type thereof to the indoor control unit 43. The indoor control unit 43 adjusts the flap 51 in an almost horizontal position such as the positions P3 to P5 in figure 4 and the like based on the information received from the selection receiving part 67. In this way, the air can be blown in such a way that cold wind is not directly delivered to the user located in the remote position of the indoor unit 12, so that a user can be adjusted Peripheral rte of the user to have an appropriate temperature. The indoor control unit 43 can adjust not only the blowing direction of the air from the air outlet 50 but also a blow temperature and an air volume according to the type of the sensitive temperature icon.

It should be noted that in a case in which several users drag different temperature sensitive icons in one of the divided regions B in the operation image S1, the wind direction can be adjusted by a majority decision. For example, when the number of the user who drags the "cold" icon in one of the divided regions B is greater than the number of the user who drags the "hot" icon, the "cold" icon having priority, it can be adjust the position of the fin 51 for the position of the user that drags the "cold" icon. In a case in which several users drag different temperature sensitive icons several times, the posture of the fin 51 can be adjusted taking precedence the sensitive temperature icon which is the most frequently dragged.

The operating device 60 can be formed by a particular PC installed inside or can be formed by a PC that the user is using on the desktop. In the latter case, the user can operate the indoor unit 12 from the PC he is using. Thus, the user is not required to get up from a seat and move for the operation.

The operating device 60 can be installed not in the interior which is the air conditioning region but in other outdoor locations such as a control room for controlling air conditioning and the like. In this case, the indoor unit 12 can be operated remotely by the outdoor operating device 60. An indoor state can be monitored from the control room or the like by the photographed image G1 taken by the camera 61. This is, the camera 61 can be used as a monitoring camera.

As an icon of sensible temperature you can prepare not only two types of icons "heat" and "cold" but also various types of icons. For example, by adding a sensitive temperature icon such as "slightly hot", "slightly cold" or something similar, a finer setting of the temperature (adjustment of the blowing direction) can be allowed. By clicking (selecting) on the indication of the temperature set in the operating image S1 with the mouse or something similar, a change in the set temperature can be allowed.

The photographed image G1 taken by the camera 61 can be a still image or a moving image. In the case of still image, the operation image S1 is preferably updated appropriately by taking the photographed image G1 at predetermined time intervals (such as intervals of several minutes or intervals of several hours). In the case in which the photographed image is the moving image, the indoor state can be captured in real time.

[Second embodiment]

Figure 7 is a schematic view showing an exposure content in an exposure unit in a second embodiment of the present invention.

In the present embodiment, in the case where a plurality of indoor units 12 are provided in a room, operations of the fins 51 of the plurality of indoor units 12 can be received by an operation image S2.

Specifically, as well as the first embodiment, an image generation part 66 of a control unit 63 first generates an operation image S1 by synthesizing a photographed image G1 taken by a camera 61 for each of the indoor units 12 and an image G2 of the indoor unit 12. The image generation part 66 synthesizes the plurality of operating images S1 according to the actual arrangement of the plurality of indoor units 12 and generating an operating image (entire operating image) S2. An exposure control portion 68 of the control unit 63 exposes the entire operation image S2 generated by the image generation portion 66 in an exposure region W1 of an exposure unit 64.

Therefore, as well as the first embodiment, when the user drags a sensitive temperature icon on the entire operation image S2, a selection receiving part 67 receives the selection of an air outlet 50 corresponding to a dragged position or something similar, so that the blowing direction of the air can be adjusted from this air outlet 50. In the present embodiment, adjacent divided regions B of the operating images S1 are not clearly separated from one another, and the divided regions overlap. substantially in the vicinity of a boundary between both divided regions B. Therefore, in a case where the user is located at a position in the middle of the plurality of indoor units 12, and when the sensitive temperature icon is entrained to a user position in the entire operation image S2, the selection receiving part 67 receives the selection of the air outlets 50 of the plurality of indoor units 12. In this way, the plurality of fins 51 of the air outlets 50 can be adjusted at the same time, so that more optimal air conditioning can be performed.

[Third realization]

Figure 8 is a schematic view showing an exposure content in an exposure unit in a third embodiment of the present invention.

In the first and second previous embodiments (refer to Figures 6 and 7), the sensitive temperature icon is exposed in an exposure region w 2 in the exposure unit 64. However, in the present embodiment, the image designation posture G30 to G35 to directly designate fin postures 51 are exposed at the site of the sensitive temperature icon. Specifically, in an exposure region W2, six position designation images G30 to G35 are displayed indicating the positions P0 to P5 of the fin 51 shown in Figure 4.

A selection receiving part 67 of the present embodiment receives selection of an air outlet 50 by designating the air outlet 50 in an operating image S1 or a divided region B corresponding to the air outlet 50 by the user using a mouse or something similar. The user himself can determine the position of the fin 51 provided in the air outlet 50 by designating any of the posture designation images G30 to G35 in the exposure region W2. That is, although the air blowing direction (flap posture 51) is automatically determined on the side of the indoor control unit 43 by providing information on the position of the user and the sensitive temperature in the first and second embodiments. , the air blowing direction can be adjusted according to the user's preference in the present embodiment. Thus, a degree of freedom of operation can be increased.

The present invention is not limited to the above embodiments but can be appropriately modified within the scope of the invention described in the claims.

For example, although air is blown on four sides from the four air outlets 50 in the indoor unit 12 of the previous embodiments, the air can be blown in two directions from two air outlets 50. Alternatively, air can be blown in two directions. be blown from three or five or more air outlets 50. Although the indoor unit 12 of the above embodiments is of the roof embedded type, the indoor unit may be of a ceiling suspended type or a wall-connected type.

The adjustment portions of the previous embodiments are formed by the fins 51 that adjust the direction of air blowing from the air outlets 50 in the up and down direction. However, the adjustment portions can be formed by grids (adjustment strips) that adjust the blowing direction in the left and right direction or the like.

The indoor heat exchanger 42 of the indoor unit 12 may be able to adjust the temperatures of the air blown from the air outlets 50 individually. The indoor fan 41 may be able to adjust the air volumes of the air blown from the air outlets 50 individually.

The operating device 60 may include a touch panel type exposure unit. In this case, the exposure unit is also used as a contribution unit. The operating device 60 can be formed by a tablet terminal, or in addition to the conventional example, it can include an exposure panel (exposure unit) and an operation button (delivery unit) or it can be formed by a remote control .

List of reference signs

12: INTERIOR UNIT 50: AIR OUTPUT

51: FIN (LOT OF ADJUSTMENT)

60: OPERATING DEVICE

61: CHAMBER (DEVICE FOR OBTAINING IMAGES) 64: EXPOSURE UNIT

66: PART OF IMAGE GENERATION

67: PART OF SELECTION RECEPTION

A: AIR CONDITIONING REGION

B: DIVIDED REGION

G1: IMAGE OF THE AIR CONDITIONING REGION G2: IMAGE OF THE AIR EXIT

S1: OPERATING IMAGE

S2: ENTIRE IMAGE OF OPERATION

Claims (6)

An operating system for an air conditioning device for operating an indoor unit (12) including a plurality of air outlets (50) that blow air whose temperature adjusts to an air conditioning region (A ), and adjustment portions (51) each of which is provided to correspond to each of the air outlets (50), with the adjustment portions that adjust at least one of a direction of air blowing from the outlets. of air (50) and existence / non-existence of blowing, and an operating device (60) that receives an instruction for an operation of the adjustment portions (51), the operating system is characterized in that it further comprises a device for obtaining images (61) that takes an image (G1) of the air conditioning region (A) so that a user located in the air conditioning region (A) is included in the image; and where The operating device (60) includes: an exposure unit (64); an image generation part (66) that generates an operation image (S1) by overlapping the image (G1) of the air conditioning region (A) taken by the imaging device (61) with an image (G2) ) of the plurality of air outlets (50); an exposure control part (68) that allows the exposure unit (64) to display the operation image (S1); Y a selection receiving part (67) receiving selection of an air outlet (50) in the operating image (S1) exposed in the exposure unit (64) in order to identify the air outlet (50) provided with the adjustment portion (51) that serves as the object to be handled. 2. The operating system for an air conditioning device according to claim 1, wherein the indoor unit (12) is connected to a ceiling, and the imaging device (61) takes an image of the air conditioning region (A) from one side of the indoor unit (12) to one side lower. 3. The operating system for an air conditioning device according to claim 1 or 2, wherein the exposure control part (68) allows the exposure unit (64) to display the image (G1) of the air conditioning region (A) while parting in divided regions (B) respectively corresponding to the air outlets ( fifty). 4. The operating system for an air conditioning device according to any one of claims 1 to 3, wherein the selection receiving part (67) receives a contribution from an identified position in the air conditioning region (A) corresponding to the air outlet (50), and sensitive temperature information in the identified position. 5. The operating system for an air conditioning device according to any one of claims 1 to 4, wherein in a case where the plurality of indoor units (12) are provided in a room, the image generation part (66) synthesizes the plurality of operation images (S1) according to the actual arrangement of the plurality of indoor units (12) and generates a whole operation image (S2), and the control part of exposure (68) allows the exposure unit (64) to display the entire operation image (S2) on a screen. 6. An operating method for an air conditioning device for operating an indoor unit (12) including a plurality of air outlets (50) that blow air whose temperature is adjusted to an air conditioning region (A ), and adjustment portions (51) each of which is provided to correspond to each of the air outlets (50), with the adjustment portions that adjust at least one of a direction of air blowing from the outlets. of air (50) and existence / non-existence of blowing, the operating method is characterized in that it comprises: a step of obtaining images to take an image of the air conditioning region (A) so that a user located in the air conditioning region (A) is included in the image; Y an image generation step for generating an operation image (S1) by overlaying the image (G1) of the air conditioning region (A) taken in the image acquisition step with an image (G2) of the plurality of air outlets (50); an exposure step to allow an exposure unit (64) of an operating device (60) to display the operation image (S1) generated in the image generation step; Y a selection receiving stage for receiving the selection of an air outlet (50) in the operating image (S1) exposed in the exposure unit (64) in order to identify the air outlet (50) provided with the portion of adjustment (51) that serves as the object to be handled.