JP2005016862A - Indoor panel for air conditioner, and air conditioner - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To control the air flow in a proper state in accordance with an operation mode of an air conditioner by an indoor panel. <P>SOLUTION: A suction port 3 and a blowout port 4 of the indoor panel 2 are respectively provided with a suction temperature sensor 16 and a blowout temperature sensor 17. The sucked air temperature and the blowout air temperature respectively detected by the suction temperature sensor 16 and the blowout temperature sensor 17 are compared to judge the operation mode of the air conditioner, and an air flow changing means 52 is adjusted by the independent control at an indoor panel 2 side. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an indoor panel of an air conditioner that performs indoor air conditioning, and an air conditioner to which the indoor panel is mounted.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, as an air conditioner that air-conditions a relatively large indoor space such as a store or a restaurant, there are a ceiling-embedded or ceiling-suspended air conditioner provided with a plurality of air outlets.
[0003]
For example, in a ceiling-embedded air conditioner, a casing is embedded in a ceiling portion, and an indoor panel is attached to a lower end opening of the casing. In the indoor panel, a suction port is formed in the vicinity of the center portion, and a plurality of air outlets are formed on the outer periphery of the suction port. The air outlet is provided with a wind direction adjusting means for adjusting the air direction of the blown air. Furthermore, a fan and a heat exchanger are provided in the casing, and when the air conditioner is in operation, the temperature of the indoor air sucked from the suction port by the fan is adjusted by the heat exchanger. The air whose temperature has been adjusted is adjusted to a predetermined wind direction by the wind direction adjusting means, and is supplied into the room through the air outlet.
[0004]
In such an air conditioner, for example, the operation mode is switched by an external input means such as a remote controller. And based on the information input into this external input means, optimal control of a temperature adjustment capability or a wind direction adjustment means is performed (refer patent document 1).
[0005]
[Patent Document 1]
JP 2000-10497 A
[0006]
[Problems to be solved by the invention]
By the way, in such an air conditioner, when this panel is replaced, for example, to clean or deteriorate the indoor panel, or to improve the air flow of the blown air (for example, improvement of the wind direction adjusting means), the replaced indoor panel is a model. Due to changes and model differences, it may differ from the original control specifications. In particular, when the control specification of the wind direction adjusting means of the replaced panel is different from the existing one, there is a possibility that the wind direction adjusting means cannot be controlled by the existing external input means as described in Patent Document 1. . In this case, since airflow control according to a predetermined operation mode cannot be performed, a predetermined function of the air conditioner is lost, and the comfort of the indoor space is impaired.
[0007]
The present invention has been made in view of the above points, and an object of the present invention is to ensure that optimal airflow control according to the operation mode of the air conditioner can be reliably performed on the indoor panel even when the panel is replaced. That is.
[0008]
[Means for Solving the Problems]
According to the present invention, a suction temperature sensor (16) and a blowout temperature sensor (17) are respectively provided in a suction port (3) and a plurality of blowout ports (4) formed in the indoor panel (2) of the air conditioner. The detected temperature of these suction / blow-off temperature sensors (16, 17) is compared, and the adjustment of the wind direction adjusting means (52) according to the operation mode such as cooling, heating, cooling / heating thermo-off operation of the air conditioner is performed on the indoor panel. (2) This is performed by the original control on the side.
[0009]
Specifically, in the first aspect of the present invention, a suction port (3) and a plurality of air outlets (4) are formed in an indoor panel (2) attached to the air conditioner, and the air outlet (4). Is based on an indoor panel of an air conditioner provided with a wind direction adjusting means (52) for adjusting the wind direction of the blown air supplied from the blower outlet (4).
[0010]
And in this indoor panel (2), the suction temperature sensor (16) for detecting the temperature of the suction air suck | inhaled by this suction inlet (3) is arrange | positioned in the vicinity of the said suction inlet (3), A blowout temperature sensor (17) for detecting the temperature of the blown air is disposed in the vicinity of the blowout outlet (3), and the detected temperatures of the suction temperature sensor (16) and the blowout temperature sensor (17) are compared. Thus, an operation mode including a cooling operation, a heating operation, and a cooling / heating thermo-off operation of the air conditioner to which the indoor panel (2) is mounted is detected, and the air direction adjusting means (52) is adjusted according to the operation mode. Means (53) are provided.
[0011]
In the first aspect of the present invention, the suction temperature sensor (16) and the blowout temperature sensor (17) are respectively provided in the vicinity of the suction port (3) and the blowout port (4) formed in the indoor panel (2). Is provided. And while detecting the temperature of the suction air introduce | transduced into a suction inlet (3) by the said suction temperature sensor (16), it is supplied to indoor space from a blower outlet (4) by the said blowout temperature sensor (17). Detect the temperature of the blown air. Further, the temperature of the intake air and the temperature of the blown air are compared by the control means (53) provided in the indoor panel (2). On the other hand, in the air conditioning apparatus main body to which the indoor panel (2) is attached, when switching between the cooling operation, the heating operation, and the cooling / heating thermo-off operation is performed, the control means (53) controls the temperatures of the intake air and the blown air. By comparison, the operation mode of the air conditioner main body is detected, and the wind direction adjusting means (52) is adjusted according to the operation mode. Therefore, the optimal airflow control according to the operation mode of the air conditioner body can be performed.
[0012]
In addition, the air flow control according to the operation mode is performed by the air conditioner using the suction / blowout temperature sensors (16, 17), the wind direction adjusting means (52), and the control means (53) provided in the indoor panel (2). It is done independently of the main body. Therefore, for example, even when the indoor panel of an existing air conditioner is replaced to improve the dirt on the panel or the airflow, it is possible to prevent a situation where optimal airflow control cannot be performed due to a difference in control specifications of the airflow direction adjusting means. it can. That is, when the indoor panel is replaced, by applying the indoor panel (2), it is possible to reliably give the existing air conditioner an optimal airflow control function in accordance with the operation mode.
[0013]
According to a second aspect of the present invention, in the indoor panel (2) of the air conditioner according to the first aspect, the control means (53) is adapted to adjust the wind direction so that the temperature distribution of the indoor air becomes uniform during the cooling / heating thermo-off operation. The adjusting means (52) is adjusted.
[0014]
According to the second aspect of the present invention, when it is determined that the air conditioner is performing the cooling / heating thermo-off operation by comparing the suction / blowing temperature by the suction / blowing temperature sensor (16, 17), the control means (53). Thus, the wind direction adjusting means (52) is adjusted so that the temperature distribution of the indoor air becomes uniform.
[0015]
By the way, the cooling / heating thermo-off operation is performed when a predetermined air-conditioning effect is obtained and air-conditioning in the room is no longer necessary during cooling and heating operations. Here, when the cooling or heating operation is switched to the cooling / heating thermo-off operation, the blown air that has been subjected to the predetermined temperature adjustment from the outlet (4) is changed to the blown air that has not been temperature-adjusted. For this reason, at the time of switching to the cooling / heating thermo-off operation, uneven temperature distribution tends to occur in the indoor space, and a person existing in the room feels uncomfortable due to the uneven temperature distribution.
[0016]
In the present invention, during the cooling / heating thermo-off operation, the air direction adjusting means (52) blows air so as to make the temperature distribution of the room air uniform, so that uneven temperature distribution in the room space can be prevented.
[0017]
According to a third aspect of the present invention, in the indoor panel (2) of the air conditioner according to the first or second aspect, the wind direction adjusting means (52) adjusts the wind direction of the blown air along the first swinging direction. The first flap (12) that can be changed, and the second flap (13) that can change the wind direction of the blown air along a second swing direction that is substantially orthogonal to the first swing direction. It is characterized by being. Here, for example, in the case of an indoor panel of a ceiling-embedded air conditioner, the wind direction adjusting means (52) includes a vertical flap that adjusts the airflow in the left-right direction and a horizontal flap that adjusts the airflow in the up-down direction. can do.
[0018]
In this invention of Claim 3, a wind direction adjustment means (52) comprises a 1st flap (12) and a 2nd flap (13), and the blowing air supplied from a blower outlet (4) is more The wind direction can be adjusted over a wide range. More specifically, the first flap (12) freely adjusts the wind direction in the first swing direction, and the second flap (13) is a second swing orthogonal to the first swing direction. Adjust the wind direction freely in the direction. Therefore, the blown air supplied from the blower outlet (4) can be finely adjusted over a wider range. Therefore, a more extensive and precise air flow control function can be given to the indoor panel (2).
[0019]
Further, during the cooling / heating thermo-off operation, when the air is blown so as to make the temperature distribution of the room air uniform, the efficiency of the homogenization can be improved by swinging the first and second flaps (12, 13). it can.
[0020]
The invention according to claim 4 is the radiation temperature detection means for scanning the indoor space and detecting the distribution of the radiation temperature in the indoor panel (2) of the air conditioner according to any one of claims 1 to 3. The air outlet adjusting mechanism (10) for adjusting the air volume of the blown air is provided at the air outlet (4), and the control means (53) is detected information of the radiation temperature detecting means (51). Based on the above, the air volume adjusting mechanism (10) and the air direction adjusting means (52) are adjusted.
[0021]
According to the fourth aspect of the present invention, the indoor panel (2) is provided with radiation temperature detecting means (51) for scanning the indoor space and detecting the distribution of the radiation temperature. Then, the wind direction adjusting means (52) and the air volume adjusting mechanism (10) provided at the outlet (14) are adjusted according to the distribution characteristics of the radiation temperature in the indoor space detected by the radiation temperature detecting means (51). To do. Therefore, the air flow control function in consideration of the temperature distribution in the indoor space and the position of the person can be given to the indoor panel (2).
[0022]
According to a fifth aspect of the present invention, in the indoor panel (2) of the air conditioner according to the fourth aspect, the control means (53) sets the scanning frequency of the radiation temperature detecting means (51) to the indoor panel (2). The frequency is changed to the optimum frequency according to the operation mode of the air conditioner to which is attached. Here, the radiation temperature detecting means (51) changes the scanning frequency to the optimum frequency so as to scan the indoor space continuously or intermittently or not according to the operation mode of the air conditioner. can do.
[0023]
In the invention according to claim 5, since the scanning frequency of the radiation temperature detecting means (51) is controlled by the control means (53) to the optimum frequency in accordance with the operation mode of the air conditioner, the radiation temperature detecting means ( 51) can be minimized. Therefore, the driving durability of the radiation temperature detecting means (51) can be improved.
[0024]
The invention described in claim 6 is premised on an air conditioner in which an indoor panel is attached to the opening of the casing (1).
[0025]
And this air conditioning apparatus is characterized by the said indoor panel being comprised by the indoor panel (2) of any one of Claim 1 to 5.
[0026]
In the invention according to claim 6, since the indoor panel (2) according to any one of claims 1 to 5 is attached to the air conditioner, the air conditioner is independently provided on the indoor panel (2) side. Optimal airflow control according to the operation mode of the apparatus is possible.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, Embodiment 1 of the present invention will be described in detail with reference to the drawings.
[0028]
1 and 2 show an indoor unit (Z) of the air conditioning apparatus according to the first embodiment. This indoor unit (Z) is a ceiling-embedded air conditioner embedded in a ceiling (50) of a room.
[0029]
The indoor unit (Z) includes a rectangular box-like casing (1) embedded in the upper side of the ceiling (50), and a rectangular flat plate-like room mounted from the indoor side to the lower end opening of the casing (1). And a panel (2). In the indoor panel (2), a suction port (3) having a rectangular opening is formed so as to be positioned at the center thereof. Further, four long rectangular outlets (4) are formed on the outer periphery of the suction port (3). The air outlets (4) are arranged in the indoor panel (2) so that each air outlet (4) is substantially parallel to the outer edge of the indoor panel and surrounds the inlet (3).
[0030]
Moreover, the centrifugal fan (6) is installed in the upper part of the suction inlet (3) in the casing (1). A heat exchanger (5) is installed on the outer peripheral side of the centrifugal fan (6) so as to surround the centrifugal fan (6). Further, a bell mouth (7) is disposed between the centrifugal fan (6) and the suction port (3). Moreover, the suction grill (8) and the filter (9) are attached to the suction port (3). On the other hand, an air outlet channel (14) having a long rectangular cross section extending upward from the air outlet (4) is formed in the upper part of the air outlet (4). In this blowout flow path (14), the air volume adjusting mechanism (10), which will be described in detail later, and the first flap (12) (vertical flap) and the second flap (13) that constitute the air direction adjusting means (52) ( Horizontal flap).
[0031]
The suction port (3) is provided with a suction temperature sensor (16) for measuring the temperature of the suction air. On the other hand, the outlet (4) is provided with an outlet temperature sensor (17) for measuring the temperature of the outlet air supplied to the indoor space. In addition, an infrared sensor (15) which is a radiation temperature detecting means (51) for measuring the radiation temperature of the indoor space is disposed at one corner of the lower surface side (indoor exposed portion) of the indoor panel (2). .
[0032]
The control part (18) which is the control means (53) to which the detection information of the suction temperature sensor (16), the blowing temperature sensor (17), and the infrared sensor (15) is input is the inner circumference of the suction port (3). It is installed on the side. The control unit (18) controls the air volume adjusting mechanism (10), the vertical flap (12), and the horizontal flap (13) based on the detection information.
[0033]
Next, each component of the indoor unit (Z) described above will be described in detail.
[0034]
The air volume adjusting mechanism (10) is for adjusting the air volume of the blown air supplied from the air outlet (4). The air volume adjusting mechanism (10) includes a pair of distribution shutters (11, 11) as shown in FIGS. The pair of distribution shutters (11, 11) are formed so as to extend along the long side of the horizontal cross section of the blowout flow path (14), and are respectively disposed on both wall sides of the long side. As shown in FIG. 3, one end of the pair of distribution shutters (11, 11) is engaged with a guide groove (25) formed in the vertical direction along the side wall of the blowout flow path (14). . On the other hand, as shown in FIGS. 3 and 4, the other end of the distribution shutter (11, 11) is a pair of racks meshed on both radial sides of the gear (28) that is rotationally driven by the motor (29). 27, 27).
[0035]
With the above configuration, when the gear (28) is selectively rotated in both the forward and reverse directions by the motor (29), the air volume adjusting mechanism (10) has the pair of racks (27, 27) engaged therewith. Move in opposite directions. Along with the movement of the pair of racks (27, 27), the pair of distribution shutters (11, 11) move in the vertical direction along the guide groove (25), and the respective inclinations are inclined. Change the angle. And by the tilt of this shutter (11, 11), the extension amount to the center side of the blowing channel (14), that is, the opening area of the blowing channel (14) can be increased or decreased.
[0036]
In the configuration of the air volume adjusting mechanism (10) described above, for example, when the maximum air volume is set, the pair of distribution shutters (11, 11) of the outlet flow path (14) are both close to an upright posture and the length of the outlet flow path (14) is long. It becomes the state accommodated near a side wall, and the opening area of the said blowing flow path (14) is expanded. Therefore, the amount of blown air supplied from the blower outlet (4) is increased by the centrifugal fan (6). On the other hand, at the time of setting the minimum air volume, for example, the pair of distribution shutters (11) of the blowing channel (14) are both in a horizontal posture, and the opening area of the blowing channel (14) is reduced. Therefore, the amount of blown air supplied from the blower outlet (4) is reduced by the centrifugal fan (6). Thus, the amount of blown air can be freely adjusted by changing the inclination angle of the distribution shutter (11) of the blowout flow path (14).
[0037]
The air volume adjusting mechanism (10) is provided corresponding to each of the air outlets (4, 4,...), And these air volume adjusting mechanisms (10) are independently operated and controlled. The The operation control of the air volume adjustment mechanism (10) is performed by the control means (53) based on the detection information of the suction temperature sensor (16), the blowout temperature sensor (17), and the infrared sensor (15). This is performed by a certain control unit (18).
[0038]
The vertical flap (12) adjusts the wind direction of the blown air supplied from the blower outlet (4) in the first swing direction (long side direction (left-right direction) at the opening of the blower outlet (4)). belongs to. The said vertical flap (12) has a some plate body (55) of the shape along the vertical cross section of the blowing flow path (14), as shown in FIG. The plate body (55) is arranged in parallel at a predetermined interval in the outlet flow path (14) in a posture substantially perpendicular to the opening surface of the outlet (4). Further, a first support shaft (23) for supporting the plate body (55) is provided between the plate body (55) and the wall surface near the suction port (3) of the blowout flow path (14). It has been. With this configuration, the plate body (55) is in a state in which the inclination angle is variable in the left-right direction around the first support shaft (23). The vertical flap (12) is provided with a link bar (24) for connecting the plate body (55). The link bar (24) is installed by connecting the plurality of plate bodies (55) substantially parallel to the long side of the opening of the air outlet (4). Moreover, the 1st motor (30) connected with the end of this link bar (24) is installed near the one side short side in the said blowing flow path (14). With this configuration, when the first motor (30) is driven, the link bar (24) swings left and right in the outlet channel (14), and the plate body (55) is moved to the first support shaft (23). The tilt angle is changed in the left-right direction around the center. Therefore, the blown air from the blower outlet (4) can be adjusted in the left-right direction. In addition, the plate body (55) continuously swings left and right by repeating forward and reverse rotations of the first motor (30). In this case, the blown air supplied from the blower outlet (4) can be swung in the left-right direction and discharged.
[0039]
In addition, the said vertical flap (12) is provided in each of the said blower outlet (4, 4, ...), and these vertical flaps (12) are provided for each blower outlet (4, 4, ...). Independently and individually controlled. Further, the operation control of the vertical flap (12) is performed by a control unit which is the control means (53) based on detection information of the suction temperature sensor (16), the blowout temperature sensor (17), and the infrared sensor (15). (18).
[0040]
The horizontal flap (13) adjusts the wind direction of the blown air supplied from the blower outlet (4) in the second swing direction (vertical direction from the blower outlet (4) toward the outer periphery of the indoor panel (2)). Is to do. The said horizontal flap (13) is comprised with the strip | belt board material which has a shape where a pair of both sides curved, as shown in FIG. The horizontal flap (13) is formed to extend in the lateral direction so that the curved sides of the pair are close to the left and right side surfaces of the blowing channel (14). A second support shaft (56) for supporting the horizontal flap (13) is provided at the upper ends of both ends of the horizontal flap. The horizontal flap (13) is in a state in which the inclination angle is variable in the vertical direction around the second support shaft (56). Moreover, the 2nd motor (31) as shown in FIG. 7 is connected with one side of the said 2nd spindle (56) in the casing (1). With this configuration, when the second motor (31) is driven, the inclination angle of the horizontal flap (13) is changed in the vertical direction about the second support shaft (56). Therefore, the blown air from the blower outlet (4) can be adjusted in the vertical direction.
[0041]
Further, the horizontal flap (13) continuously swings up and down by repeating forward and reverse rotations of the second motor (31). In this case, the blown air supplied from the blower outlet (4) can be swung in the vertical direction and discharged.
[0042]
In addition, the said horizontal flap (13) is provided corresponding to each of the said blower outlets (4, 4, ...), and these horizontal flaps (13) are controlled interlockingly. Therefore, when the second motor (31) rotates by a predetermined amount, the inclination angles of the horizontal flaps (13, 13,...) Are changed to the same angle, and the air blown from the outlet (4, 4,...) Is the same. It is adjusted to the wind direction. Further, the operation control of the horizontal flap (13) is performed by a control unit which is the control means (53) based on detection information of the suction temperature sensor (16), the blowout temperature sensor (17), and the infrared sensor (15). (18).
[0043]
The suction temperature sensor (16) is for measuring the temperature of the suction air sucked from the room into the suction port (3) by the centrifugal fan (6). As shown in FIG. 2, the suction temperature sensor (16) is attached to the casing wall surface of the control unit (18) so that the suction air temperature can be measured.
[0044]
The blowing temperature sensor (17) is for measuring the temperature of the blowing air supplied from the inside of the casing (1) into the room through the blowing port (4) by the centrifugal fan (6). This blowing temperature sensor (17) is attached to the wall surface of the blowing channel (14) so that the blowing air temperature can be measured.
[0045]
The infrared sensor (15) detects the radiant heat from the indoor wall surface, the floor surface, or a human body or the like as the radiant temperature in a state where the indoor unit (Z) is installed on the ceiling, and detects this with respect to the current indoor temperature. The information is for output to the control unit (18). As shown in FIGS. 1 and 2, the infrared sensor (15) is disposed in a sensor mounting hole (19) in the vicinity of a corner portion on the outer peripheral side of the indoor panel (2). The infrared sensor (15) includes a scanning mechanism (20). The scanning mechanism (20) includes a first scanning motor (21) having a horizontal axis and a second scanning motor (22) having a vertical axis. Therefore, the infrared sensor (15) can be rotated by a predetermined angle about the horizontal axis by the first scanning motor (21), and can be rotated by 360 ° C. about the vertical axis by the second scanning motor (22). With this configuration, the infrared sensor (15) can detect radiant heat in most areas of the indoor space as a radiant temperature.
[0046]
Further, as the infrared sensor (15), for example, a single element type sensor that integrally detects the entire detection target range, or a one-dimensional array element that performs detection for each divided region by dividing the detection target range in one direction. A two-dimensional array element type sensor that divides the detection target range into two orthogonal directions and performs detection for each divided region is suitable.
[0047]
Furthermore, the infrared sensor (15) virtually divides the indoor space radially into four areas centering on the indoor unit (Z) when detecting the indoor radiation temperature (the temperature or temperature distribution of a human body or the like). The radiant temperature in each area is detected. Therefore, the detection information on the radiation temperature of each area detected by the infrared sensor (15) is used as a control factor for controlling the wind direction adjusting means (52) and the air volume adjusting mechanism (10). 18).
[0048]
-Modification of the embodiment-
In addition, the structure of the indoor panel (2) in this embodiment is good also as the following structures.
[0049]
In the present embodiment, the air volume adjusting mechanism (10) includes a distribution shutter (11) that tilts with the wall side in the outlet channel (14) as a fulcrum, as shown in FIG. Then, one end of the distribution shutter (11) is swung up and down along the guide groove (25) by driving the motor (29), and the opening area of the outlet (4) is enlarged and reduced to reduce the amount of blown air. The air volume is adjusted. However, this air volume adjusting mechanism (10) may have the following structure, for example.
[0050]
The air volume adjusting mechanism (10) shown in FIG. 5 is configured such that a pair of distribution shutters (11, 11) can be advanced and retracted in the short side direction at the upper part of the outlet flow path (14). The pair of distribution shutters (11, 11) is advanced and retracted by the rotation of the motor (29) through the rack (27, 27) and the gear (28) meshing with the rack (27, 27). At this time, the distribution shutter (11, 11) moves horizontally along the guide groove (26) formed horizontally in the short side direction of the blowout flow path (14). Also in the configuration of the air volume adjusting mechanism (10), the air volume of the blown air can be adjusted by enlarging or reducing the opening area of the air outlet (14) by the rotation of the motor (29).
[0051]
The air volume adjusting mechanism (10) shown in FIG. 6 includes one distribution shutter (11), and supports one end of the distribution shutter (11) closer to one wall side in the upper part of the blowout flow path (14). The shutter (11) is configured to be tiltable. The distribution shutter (11) is tilted up and down by a motor (29) through a gear (28). Also in the configuration of the air volume adjusting mechanism (10), the air volume of the blown air can be adjusted by enlarging or reducing the opening area of the air outlet (14) by the rotation of the motor (29).
[0052]
In the present embodiment, the horizontal flaps (13, 13,...) Provided at the air outlets (4, 4,...) Are connected to each other as shown in FIG. The tilt angle is changed in conjunction with (31), and the vertical wind direction is adjusted. However, as shown in FIG. 8, the horizontal flaps (13, 13,...) Are individually provided with second motors (31, 31,...), And the second motors (31, 31,...) The horizontal flaps (13, 13,...) May be controlled independently. In this case, the airflow control in the room can be performed by independently adjusting the airflow direction of the air supplied from the air outlets (4, 4,...) To the optimum airflow direction.
[0053]
-Operation control-
Next, in particular, the airflow control among the operation controls in the air conditioner will be described in detail.
[0054]
In this air conditioner, the control unit (18) provided in the indoor panel (2) performs cooling, heating, cooling / heating thermo-off operation (temperature adjustment is paused, only air blowing based on the temperature difference between the suction temperature and the blowing temperature. ) Is detected, and airflow control is performed according to each operation state. Moreover, the said control part (18) detects the radiation temperature of the indoor space (W) which is air-conditioning object space with an infrared sensor (15), and performs airflow control also using the detected radiation temperature.
[0055]
<Area setting for air-conditioning space>
First, the area setting of the indoor space (W) will be described before specific control.
[0056]
In this embodiment, as shown in FIG. 9, the indoor space (W) is virtually divided into four areas (A) to (D) corresponding to the air outlets (4) of the indoor unit (Z). It is divided into. And based on the measured temperature detected by the infrared sensor (15) for each area (A) to (D), the average radiation temperature for each area (A) to (D) of the indoor space (W) or the indoor space The overall average radiation temperature of (W) is obtained. Further, as indicated by black circles (●) in FIG. 9, a high temperature portion existing in each of the areas (A) to (D) of the indoor space (W) is detected as a human body position, and this is also reflected in the control. I am doing so.
[0057]
In this area setting, it is not always necessary to divide the indoor space (W) into four areas (A) to (D) as described above. For example, as shown in FIG. The control based on the eight areas (A) to (H) may be performed by further dividing ˜ (D). As the number of areas is increased in this way, precise control can be performed accordingly.
[0058]
<Wind direction adjustment operation>
Next, the wind direction adjustment operation in the indoor panel (2) will be described.
[0059]
First, the operation of the air volume adjustment mechanism (10) will be described.
[0060]
When the air flow control mechanism (10) performs airflow control, the opening degree of the outlet (4) that is the maximum load is 100% and the opening degree of the outlet (4) that is the minimum load is 0%. Can determine the opening degree by proportional distribution. For example, FIG. 11 showing an example during cooling is an example in which the area (A) is 100%, the area (B) is 67%, the area (C) is 33%, and the area (D) is 0%. However, even if the setting is 0%, the air volume adjusting mechanism (10) is not fully closed, so about half the air volume when fully opened flows.
[0061]
Next, the operation of the vertical flap (12) will be described with reference to FIG. 12 showing an example of cooling (a number in the figure indicates the radiation temperature (° C.)).
[0062]
The vertical flap (12), for example, subdivides each area (A) to (D) into a large number of small areas, compares the radiation temperature of each small area, and airflows in the direction of greater load (position of the human body). Is set to point. In the example of FIG. 12, the wind direction is set in the direction where the radiation temperature is 30 ° C. in the area (A). In area (B), the vertical flap (12) is set to swing between small areas of 28 ° C. and 29 ° C., and is fixed at the center in area (C). Furthermore, in the area (D), since the high load portions exist at both ends of the area, the entire area is controlled to swing (all swings).
[0063]
The horizontal flap (13) basically interlocks at the four outlets (4). However, when the four flaps are independently movable, the wind direction is individually controlled.
[0064]
<Two modes of airflow control>
Next, two modes of airflow control will be described. One is a temperature equalization mode and the other is a spot air conditioning mode. These two modes are adjusted by the control unit (18) according to the operation state of the air conditioner (cooling, heating, cooling / heating thermo-off operation, etc.). It is switched automatically.
[0065]
The temperature equalization mode is an airflow control mode that equalizes the temperature of the indoor space (W) over the entire area, and whether there is a person in each of the areas (A) to (D), or the suction temperature It is executed when the load is large.
[0066]
FIG. 13 is an example during cooling, and shows a case where a person is present in each of the areas (A) to (D). In this example, one person exists in area (A), two persons exist in area (B), and one person exists in each of areas (C) and (D). The average radiation temperature is 28 ° C. in area (A), 27 ° C. in area (B), and 26 ° C. in areas (C) and (D), but each area (A) to (D) However, when there is a person, the airflow is controlled so as to make the temperature of the indoor space (W) uniform regardless of the heat load.
[0067]
In this mode, the opening degree of the air volume adjusting mechanism (10) is determined so that the air volume in the area increases as the average radiation temperature in the area increases during cooling. The vertical flap (12) performs a full swing operation in the areas (A), (B), and (C), and when there is a high load portion as in the area (D), the vertical flap (12) is partially centered on the high load portion. Swing motion. The horizontal flap (13) is based on a horizontal balloon. With the above settings, in the temperature uniformization mode, the temperature of the entire indoor space (W) is made uniform by blowing out the air volume according to the average radiation temperature of each area (A) to (D) over a wide range.
[0068]
FIG. 14 shows an example in which a person is not present in all the areas (A) to (D), but the indoor space (W) is heavily loaded (the suction temperature is high). Also in this case, the air volume adjusting mechanism (10) is set according to the average radiation temperature of each area (A) to (D), and the vertical flap (12) is the area (A), (B), (C). When there is a high load portion as in area (D), the swing operation is performed on the high load portion. And the temperature of the whole indoor space (W) is equalize | homogenized by blowing off the airflow according to the average radiation temperature of each area (A)-(D) to a wide range.
[0069]
The operation in the temperature uniform mode is also performed when the cooling / heating thermostat is off. At this time, since the temperature inside the room is not adjusted, all the air volume adjusting mechanisms (10) of the respective outlets (4) are set to 100% opening, the vertical wind direction is set to a horizontal blowing or swing, and the left and right wind directions are set to all swings. .
[0070]
Next, the spot air-conditioning mode is an airflow control mode that intensively air-conditions a part of the indoor space (W), and is executed when there is an area where no person exists and the suction temperature load is small.
[0071]
In the spot air-conditioning mode of the cooling operation shown in FIG. 15, the airflow is controlled so that air is blown out toward the person. Specifically, in the air volume adjusting mechanism (10), the opening degree in the manned blowing direction in the areas (B) and (D) is 100%, and the opening degree in the unmanned blowing direction in the areas (A) and (C) is 0%. Set to Further, in the area (B) where a plurality of people exist, the vertical flap (12) swings entirely, and in the area (D) where only one person exists, the vertical flap (12) swings partially around the direction where the person is present. To do. In areas (A) and (C) where no people are present, the vertical flap (12) is fixed at the center. Further, the horizontal flap (13) is set in the horizontal blowing direction. In the spot air-conditioning mode of the cooling operation, the airflow is concentrated in the direction in which the person is present so that the cool air is directly supplied to the person's surroundings.
[0072]
In the spot air-conditioning mode of the heating operation shown in FIG. 16, the airflow is controlled so as to blow out air in a direction where there is no person, contrary to the cooling operation. Specifically, in the air volume adjusting mechanism (10), the opening degree in the manned blowing direction in the areas (B) and (D) is 0%, and the opening degree in the unmanned blowing direction in the areas (A) and (C) is 100%. Set. The vertical flap (12) is set in a direction avoiding people in the areas (B) and (D) where people are present, and is fixed at the center in the areas (A) and (C) where no people are present. The horizontal flap (13) is basically based on the bottom balloon when the four are interlocked. However, when the four horizontal flaps (13) are independently movable, the manned direction is a horizontal balloon.
[0073]
In the spot air-conditioning mode of the heating operation, the indoor air can be agitated by concentrating the airflow in a direction where no one is present, and hot air can be indirectly supplied to the surroundings of the person. This is to prevent the occupants from feeling uncomfortable due to the draft during heating operation.
[0074]
In the spot air-conditioning mode, the set temperature is automatically increased by 2 ° C during cooling operation, and the set temperature is automatically decreased by 2 ° C during heating operation. Do. This is because such an operation is adopted because if the airflow is concentrated in a part of the indoor space (W), it is considered that the comfort does not decrease much even if the temperature is changed to about 2 ° C. to the energy saving side. .
[0075]
<Control details>
Next, specific control contents will be described with reference to the flowcharts shown in FIGS.
[0076]
In step ST1 of FIG. 17, automatic operation is performed with the start of operation of the air conditioner. The automatic operation is performed based on the set temperature at the previous operation when the apparatus is simply turned on, and based on the set temperature when a new temperature is set at the same time as the power is turned on.
[0077]
During operation, in order to perform airflow control according to the operating state of the air conditioner, in step ST2, the suction temperature detected by the suction temperature sensor (16) and the blowout temperature detected by the blowout temperature sensor (17) Determine the temperature difference. And when the temperature difference of suction temperature and blowing temperature is higher than 5 degreeC, step ST3-step ST5 (cooling airflow control) is performed, and when the temperature difference of suction temperature and blowing temperature is lower than -5 degreeC, step ST6 to step ST8 (heating airflow control) are executed. Moreover, when the said temperature difference is between that (-5 degreeC or more and 5 degrees C or less), step ST9 (thermo-off airflow control) is performed.
[0078]
When the suction temperature is higher than 5 [deg.] C. compared to the blowing temperature, the radiation temperature is obtained by scanning each area (A) to (D) of the indoor space (W) with the infrared sensor (15) in step ST3. In step ST4, a cooling airflow control subroutine is executed. In step ST5, it is determined whether or not the temperature difference between the suction temperature and the blowout temperature is 3 ° C. or less. If the temperature difference is greater than 3 ° C., steps ST3 to ST5 are repeated, while the temperature difference is 3 ° C. or less. If it is, it is determined that the thermostat is off, and the process proceeds to step ST9 to execute airflow control when the thermostat is off.
[0079]
If the suction temperature is lower than −5 ° C. compared to the blowout temperature as a result of the determination in step ST2, each area (A) of the indoor space (W) is detected by the infrared sensor (15) in step ST6. After scanning (D) and detecting the radiation temperature, a heating airflow control subroutine is executed in step ST7. In step ST8, it is determined whether or not the temperature difference between the suction temperature and the discharge temperature is -3 ° C or higher. If the temperature difference is smaller than -3 ° C, steps ST6 to ST8 are repeated, while the temperature difference is -3 ° C or higher. If it is, it is determined that the thermostat is off, and the process proceeds to step ST9 to execute airflow control when the thermostat is off.
[0080]
The airflow control at the time of thermo-off performed in step ST9 is airflow control in the temperature uniformization mode. Specifically, the air volume ratio (opening) is set to “large (100%)” for all the outlets (4), the vertical wind direction is set to “horizontal” or “swing”, and the left and right wind directions are set to “all”. Set to Swing. By doing so, it is possible to make the indoor space (W) uniform temperature over the entire area.
[0081]
Thereafter, as described in the table of FIG. 20, detection of the radiation temperature by the infrared sensor (15) is stopped in step ST10, and the process returns to step ST2. When the thermo is off, only air is blown without adjusting the temperature, and it is not necessary to detect the radiation temperature. Therefore, the infrared sensor (15) is not scanned. Then, it returns to step ST2 and detects again the temperature difference of suction temperature and blowing temperature, and repeats airflow control according to the temperature difference.
[0082]
(Cooling airflow control)
Next, the cooling airflow control subroutine shown in step ST4 of FIG. 17 will be described with reference to FIG.
[0083]
In this flow, first, in step ST11, as the suction temperature load determination, it is determined whether the suction temperature is higher than 26 ° C. or lower than 26 ° C. If it is 26 ° C. or lower, it is determined in step ST12 whether or not there is a person in each of the areas (A) to (D). When people are unevenly distributed (in the indoor space (W), there are areas where people exist and areas where people do not exist), air current control in the spot air conditioning mode is performed in steps ST13 to ST20. Further, when it is determined in step ST11 that the suction temperature is higher than 26 ° C., and in step ST12, people are scattered in the indoor space (W) (there is a person in each area (A) to (D)). Air flow control in the temperature equalization mode is performed in steps ST21 to ST28.
[0084]
That is, the control unit (18) switches the air flow control mode to the spot air-conditioning mode when the suction temperature load in the blowing direction is equal to or lower than a predetermined level (26 ° C.) and the proportion of the human body is equal to or lower than the predetermined level. When it is detected that the suction temperature load in the blowing direction is higher than a predetermined level (26 ° C.) or the ratio of the human body is greater than or equal to a predetermined level (a person is present in each area (A) to (D)) The airflow control mode is controlled to switch to the temperature uniform mode. As described above, the control unit (18) is configured to perform the temperature uniformization mode and the spot air conditioning mode according to the ratio of the presence of the human body and the size of the suction temperature load in each of the areas (A) to (D) of the indoor space (W). Control to switch between.
[0085]
In the spot air conditioning mode, first, in step ST13, the number of the air outlet (4) is set to “1”, and the first air outlet (4) is controlled. Specifically, in step ST14, it is determined whether or not there is a person in the area corresponding to the air outlet (4). If there is no person, the process proceeds to step ST15. If there is a person, the process proceeds to step ST16. In step ST15, the air volume ratio is set to “small (0%)” in the area where no person exists, the vertical wind direction is set to “horizontal”, and the horizontal wind direction is set to “center”. On the other hand, in step ST16, the air volume ratio is set to “large (100%)” and the vertical wind direction is set to “horizontal” for an area where people are present. The left / right wind direction is set to “person's direction” when there is one person in the area, and set to “all swings” when there are a plurality of persons in the area.
[0086]
Thereafter, in step ST17, “1” is added to the number of the air outlet (4), and in step ST18, the operations in steps ST14 to ST17 are repeated until the number of the air outlet (4) becomes “4”. As described above, the airflow control becomes, for example, the state shown in FIG.
[0087]
When the control is completed for all the four outlets (4), the process proceeds to step ST19 to perform automatic capacity control based on the recommended set temperature. As described above, this control is energy saving operation control performed by automatically increasing the set temperature by 2 ° C. In spot air-conditioning mode for air-conditioning operation, airflow is concentrated in the direction where people are present, so even if the air temperature is set slightly higher, it is considered that comfort does not decrease so much. Driving is possible.
[0088]
After that, as described in the table of FIG. 20, in step ST20, the infrared sensor (15) is set to continuously detect the radiation temperature, and the process returns to the flow of FIG. In the spot air conditioning mode, the infrared sensor (15) is continuously scanned because the importance of the temperature distribution and the human position information in each area (A) to (D) is large.
[0089]
On the other hand, in the temperature equalization mode, first, in step ST21, the number of the air outlet (4) is set to “1”, and the first air outlet (4) is controlled. Specifically, in step ST22, the air volume ratio is set in proportion to the radiation temperature for each of the areas (A) to (D), and the vertical wind direction is set horizontally. In step ST23, it is determined whether the difference in radiation temperature in the blowing direction is large or small. If small, the left and right wind directions are set to all swings in step ST24. If the difference in radiation temperature in the blowing direction is large (there is a high load portion), the process proceeds to step ST25, and the left and right wind directions are set to swing within a predetermined range with the high load portion as the center.
[0090]
Thereafter, in step ST26, “1” is added to the number of the outlet (4), and in step ST27, the operations of step ST22 to step ST26 are repeated until the number of the outlet (4) becomes “4”. As described above, the airflow control becomes, for example, the state shown in FIGS.
[0091]
When the airflow control is completed for all the four outlets (4), as shown in the table of FIG. 20, the process proceeds to step ST28 so that the infrared sensor (15) senses intermittently every 15 minutes. Then, the process returns to the flowchart of FIG. The reason why scanning is performed intermittently in this temperature equalization mode is that the vertical flap (12) is set as a swing in this mode to stir the air, which is important for temperature distribution and human position information. This is because the degree is small.
[0092]
(Heating airflow control)
Next, the heating airflow control subroutine shown in step ST7 of FIG. 17 will be described with reference to FIG.
[0093]
In this flow, first, in step ST31, it is determined whether or not there is a person in each of the areas (A) to (D). When people are unevenly distributed (in the indoor space (W), there are areas where people exist and areas where people do not exist), air current control in the spot air conditioning mode is performed in steps ST32 to ST41. When it is determined in step ST31 that people are scattered in the indoor space (W) (people are present in each area (A) to (D)), the temperature is uniform in steps ST42 to ST49. Air flow control is performed.
[0094]
In the spot air conditioning mode, first, the number of the air outlet (4) is set to “1” in step ST32, and the first air outlet (4) is controlled. Specifically, in step ST33, it is determined whether or not there is a person in the area corresponding to each outlet (4). If there is no person, the process proceeds to step ST34, and if there is a person, the process proceeds to step ST35. In step ST34, the air volume ratio is set to “large (100%)”, the vertical wind direction is set to “down”, and the left and right wind directions are set to “center” in an area where no person exists. On the other hand, in step ST35, the air volume ratio is set to “small (0%)” and the vertical wind direction is set to “horizontal” or “down” for an area where people are present. For the left and right wind direction, set the direction to avoid people.
[0095]
Thereafter, in step ST36, “1” is added to the number of the outlet (4), and in step ST37, the operations of step ST33 to step ST36 are repeated until the number of the outlet (4) becomes “4”. As described above, the airflow control becomes, for example, the state shown in FIG.
[0096]
When the control is completed for all the four outlets (4), the process proceeds to step ST38. In step ST38, it is determined whether or not the radiation temperature in the blowing direction in which a person exists is lower than the total average radiation temperature. When the determination result is “NO”, the surroundings of the person are relatively hot. In this case, the suction temperature load is determined in step ST39. When the load is small (when the suction temperature is higher than 23 ° C.), the process proceeds to step ST40 to perform automatic capacity control based on the recommended set temperature, and then proceeds to step ST41. . Note that the automatic capacity control in step ST40 is energy-saving operation control performed by automatically lowering the set temperature by 2 ° C. as described above.
[0097]
On the other hand, when the determination result in step ST38 is "YES" (when there is a window around the person), the person's surroundings are cold, so step ST40 can be skipped without reducing the ability. Proceed to ST41. Also, when it is determined in step ST39 that the suction temperature load is large (suction temperature is 23 ° C. or less), the process proceeds to step ST41 without reducing the capability by skipping step ST40.
[0098]
In step ST41, as shown in the table of FIG. 20, the infrared sensor (15) is set to continuously perform sensing so that the control can be performed while recognizing the radiation temperature distribution. Return to the flowchart.
[0099]
In the above spot air-conditioning mode, air currents are concentrated in a direction where no one is present, and the air is stirred to warm the indoor space (W) as a whole, thereby preventing the discomfort caused by the draft from being given to the person.
[0100]
On the other hand, in the temperature equalization mode, first, the number of the air outlet (4) is set to “1” in step ST42, and the first air outlet (4) is controlled. Specifically, in step ST43, the air volume ratio is set in proportion to the radiation temperature for each outlet (4), and the vertical air direction is set horizontally. In step ST44, it is determined whether the difference in radiation temperature in the blowing direction is large or small. If small, the left and right wind directions are set to all swings in step ST45. If the difference in radiation temperature in the blowing direction is large, the process proceeds to step ST46, and the left and right wind directions are set to a swing operation centered on the low temperature part.
[0101]
Thereafter, in step ST47, “1” is added to the number of the outlet (4), and in step ST48, the operations of step ST43 to step ST47 are repeated until the number of the outlet (4) becomes “4”. As described above, the airflow control becomes, for example, the state shown in FIGS.
[0102]
When the control is completed for all the four outlets (4), the process proceeds to step ST49. And it sets so that sensing of an infrared sensor (15) may be performed intermittently every 15 minutes, and it returns to the flowchart of FIG.
[0103]
-Effect of the embodiment-
According to this embodiment, the following effects are exhibited.
[0104]
In the present embodiment, the intake air sensor (16) and the blown air sensor (17) are provided in the indoor panel (2), and the operation of the air conditioner is performed by the temperature difference between the sucked air temperature and the blown air temperature detected by these. Optimal airflow control of the indoor panel (2) according to the mode is performed.
[0105]
More specifically, the control unit (18) provided in the indoor panel (2) detects the temperature of the intake air (corresponding to the room temperature) detected by the intake temperature sensor (16) during the operation of the air conditioner. The temperature difference from the temperature of the blown air detected by the blowout temperature sensor (17) (corresponding to the indoor set temperature of the air conditioner body) is determined.
[0106]
In step ST5 immediately after the start of automatic operation, when the temperature difference between the intake air and the blown air is higher than 5 ° C., the airflow control of the indoor panel (2) shifts to the cooling airflow control (step ST4). In this case, since the room temperature is relatively higher than the indoor set temperature of the air conditioner body, the air conditioner body is normally performing a cooling operation. Therefore, the indoor panel (2) performs cooling airflow control according to the cooling operation of the air conditioner body.
[0107]
When the temperature difference between the intake air and the blown air is lower than −5 ° C., the airflow control of the indoor panel (2) shifts to the heating airflow control (step ST7). In this case, since the room temperature is relatively lower than the indoor set temperature of the air conditioner body, the air conditioner body is normally performing a heating operation. Therefore, the indoor panel (2) performs heating airflow control according to the heating operation of the air conditioner body.
[0108]
Furthermore, when the temperature difference between the intake air and the blown air is 5 ° C. or less and −5 ° C. or more, the air flow control of the indoor panel (2) shifts to the thermo-off air flow control (step ST9). In this case, since the room temperature is relatively close to the indoor set temperature of the air conditioner body, the air conditioner body is normally performing a cooling / heating thermo-off operation. Therefore, the indoor panel (2) performs thermo-off airflow control according to the cooling / heating thermo-off operation of the air conditioner body.
[0109]
As described above, the operation mode of the air conditioner main body is determined by comparing the detected temperatures of the suction / blow-out temperature sensors (16, 17) provided in the indoor panel (2) with the control unit (18), The panel (2) can perform airflow control according to this operation mode independently of the air conditioner body.
[0110]
Moreover, the airflow control performed by the indoor panel (2) is performed by the vertical flap (12), the horizontal flap (13), and the air volume adjusting mechanism (10) provided at the air outlet (4). For this reason, at the time of each airflow control of the indoor panel (at the time of cooling airflow control, heating airflow control, and thermo-off airflow control), optimal and precise airflow control corresponding to the operation mode of the air conditioner can be performed. Therefore, the air conditioner can be provided with the indoor panel (2) that can further improve the comfort.
[0111]
Further, in the present embodiment, during the cooling / heating thermo-off operation, the horizontal flap (13) of the indoor panel (2) is set to “horizontal” or “swing”, the vertical flap (12) is set to “full swing”, and the air volume adjusting mechanism (10) The air flow rate is controlled by the control unit (18) so that the air volume ratio becomes “large”. Therefore, since the temperature distribution of the indoor air is made uniform, uneven temperature distribution in the indoor space can be prevented and the comfort of a person existing in the room can be improved.
[0112]
Moreover, in this embodiment, the infrared sensor (15) for detecting indoor radiation temperature is provided in an indoor panel (2), and based on the detection information of this infrared sensor (15), optimal by a control part (18). Airflow control is performed. More specifically, the control unit (18) determines whether to move to the spot air conditioning mode or the temperature uniformization mode based on the thermal load in the indoor space detected by the infrared sensor (15) and the human position information, and the horizontal flap. (13) The vertical flap (12) and the air volume adjusting mechanism (10) are optimally adjusted. Therefore, precise airflow control according to the temperature distribution in the indoor space is possible, and the air conditioner can be provided with the indoor panel (2) excellent in comfort and energy saving.
[0113]
Furthermore, in this embodiment, the scanning frequency of the infrared sensor (15) is changed by the control unit (18) according to the operation mode of the air conditioner and the air flow control mode of the indoor panel (2). More specifically, as shown in FIG. 20, in the temperature equalization mode during cooling or heating operation, airflow control is performed so that the air in the entire indoor space is agitated. The infrared sensor (15) scans at intervals of 15 minutes. On the other hand, in the spot air-conditioning mode during cooling or heating operation, airflow control is performed with the highest priority given to the presence of people in the indoor space. Scanning is performed automatically. Furthermore, during the cooling / heating thermo-off operation, only the air is blown without adjusting the temperature, and it is not necessary to detect the radiation temperature, so the infrared sensor (15) does not scan.
[0114]
As described above, the infrared sensor (15) performs scanning at an optimum frequency according to each operation mode and performs predetermined airflow control. For this reason, it can prevent making the operation time of an infrared sensor (15) longer than necessary, and can improve the driving | running durability of an infrared sensor (15).
[0115]
Other Embodiments of the Invention
The present invention may be configured as follows with respect to the above embodiment.
[0116]
In the said embodiment, the infrared sensor (15) and the air volume adjustment mechanism (10) are provided in the indoor panel (2), and the airflow control according to indoor space is performed. However, the infrared sensor (15) and the air volume adjusting mechanism (10) are not necessarily provided in the indoor panel (2). In this case, for example, the indoor panel (2) includes a suction temperature sensor (16) and a blowout temperature sensor (17), a wind direction adjusting means (52) including a vertical flap (12) and a horizontal flap (13), and a control. A control unit (18) as means (53) is provided. And based on the temperature difference detected by the said suction temperature sensor (16) and the blowing temperature sensor (17), the vertical flap (12) according to the operation mode of the air conditioner with which this indoor panel (2) was mounted | worn The horizontal flap (13) is controlled by the control unit (18). Even in this configuration, since the airflow control is performed by the indoor panel (2) alone, for example, when the indoor panel (2) is replaced, it is possible to prevent the wind direction adjusting means from being disabled due to a difference in control specifications. .
[0117]
【The invention's effect】
According to the first aspect of the present invention, the suction temperature sensor (16) and the blowout temperature sensor (17) are provided in the vicinity of the suction port (3) and the blowout port (4) formed in the indoor panel (2), respectively. And are provided. And this indoor panel (2) is mounted | worn by the control means (53) by the temperature comparison with the suction air and the blowing air which were each detected by this suction temperature sensor (16) and the blowing temperature sensor (17). The operation mode of the air conditioner is detected and the wind direction adjusting means (52) is adjusted. Therefore, optimal airflow control according to the operation mode (cooling, heating, cooling / heating thermo-off operation) of the air conditioner body can be performed. Here, all the components for detecting the operation mode of the air conditioner and performing optimal airflow control are provided in the indoor panel (2). For this reason, even when the indoor panel is replaced, it is possible to prevent the optimum airflow control from being disabled due to a difference in control specifications such as the wind direction adjusting means. Therefore, by installing this indoor panel (2) on an existing air conditioner, it is possible to reliably give an optimal air flow control function in accordance with the operation mode.
[0118]
For example, in the case of group control in which a plurality of air conditioners are controlled by a single remote controller, the air direction of each air conditioner is controlled to be the same, so airflow control according to the load status of each air conditioner is possible. It may not be possible. On the other hand, in the present invention, in each air conditioner, since the wind direction can be adjusted by independent control of the indoor panels (2, 2,...), Airflow control according to the load condition of these air conditioners is possible.
[0119]
According to the second aspect of the present invention, during the cooling / heating thermo-off operation, the control means (53) adjusts the air direction adjusting means (52) so that the temperature distribution of the room air is made uniform. For this reason, uneven temperature distribution in the indoor space can be prevented, and comfort can be prevented from being impaired even during the cooling / heating thermo-off operation.
[0120]
According to the third aspect of the present invention, the wind direction adjusting means (52) can change the wind direction of the blown air along the first swinging direction, and the wind direction of the blown air can be changed as described above. The second flap (13) can be changed along a second swinging direction orthogonal to the first swinging direction. With this configuration, the blown air supplied from the blower outlet (4) can perform finer airflow control over a wider range. Therefore, the airflow control changed according to the operation mode can be performed more precisely, and the comfort of the air conditioner to which the indoor panel (2) is attached can be improved.
[0121]
According to the fourth aspect of the present invention, the indoor panel (2) is provided with the radiation temperature detecting means (51), and the control means (53) controls the airflow based on the detection information of the radiation temperature detecting means (51). Like to do. For this reason, the optimal airflow control function corresponding to the temperature distribution in the indoor space can be provided in the indoor panel (2). Further, since the air outlet adjustment mechanism (10) for adjusting the air volume of the blown air is provided at the air outlet (4), air flow control can be performed more precisely, and the air conditioner in which the indoor panel (2) is mounted is provided. The comfort and energy saving of the device can be improved.
[0122]
In addition, when a plurality of air conditioners are installed indoors, air flow control is performed according to the load situation and temperature distribution in the vicinity of these air conditioners by the indoor panels (2, 2,...) Of each air conditioner. be able to. For this reason, even when a plurality of air conditioners are installed indoors, indoor comfort and energy saving can be improved.
[0123]
According to the invention described in claim 5, the scanning frequency of the radiation temperature detecting means (51) is changed to the optimum frequency according to the operation mode of the air conditioner by the control means (53). For this reason, the scanning time of the radiation temperature detecting means (51) can be minimized. Therefore, the driving durability of the radiation temperature detecting means (51) can be improved.
[0124]
According to the sixth aspect of the present invention, since the indoor panel (2) of the present invention is attached to the air conditioner, optimal airflow control according to the operation mode of the air conditioner is possible, and the comfort of the air conditioner is improved. And energy savings can be improved.
[Brief description of the drawings]
FIG. 1 is a schematic perspective view of an indoor unit of an air conditioner according to the present embodiment.
FIG. 2 is an enlarged cross-sectional view of a main part of the indoor unit of the air conditioner according to the present embodiment.
FIG. 3 is an enlarged cross-sectional view of a main part of the air volume adjusting mechanism according to the present embodiment.
FIG. 4 is a bottom view of a main part of the indoor unit of the air conditioner according to the present embodiment.
FIG. 5 is an enlarged cross-sectional view of a main part showing a first modification of the air volume adjusting mechanism according to the present embodiment.
FIG. 6 is an enlarged cross-sectional view of a main part showing a second modification of the air volume adjusting mechanism according to the present embodiment.
FIG. 7 is a schematic bottom view showing a horizontal flap structure according to the present embodiment.
FIG. 8 is a schematic bottom view showing a modification of the horizontal flap structure according to the present embodiment.
FIG. 9 is an explanatory diagram showing a detection range in an indoor space of the infrared sensor according to the present embodiment.
FIG. 10 is an explanatory diagram showing a modification of the detection range in the indoor space of the infrared sensor.
FIG. 11 is an explanatory diagram showing an example of a wind direction adjusting operation during a cooling operation according to the present embodiment.
FIG. 12 is an explanatory diagram showing an example of a wind direction adjusting operation during cooling operation according to the present embodiment.
FIG. 13 is an explanatory diagram showing an example of a wind direction adjusting operation in a temperature uniformization mode during cooling operation.
FIG. 14 is an explanatory diagram showing an example of a wind direction adjusting operation in a temperature uniformization mode during cooling operation.
FIG. 15 is an explanatory diagram showing an example of a wind direction adjusting operation in a spot air conditioning mode during cooling operation.
FIG. 16 is an explanatory diagram showing an example of a wind direction adjusting operation in a spot air conditioning mode during a heating operation.
FIG. 17 is a flowchart showing airflow control content that is the basis of the indoor panel according to the present embodiment;
FIG. 18 is a flowchart showing the contents of airflow control during cooling operation of the indoor panel according to the present embodiment.
FIG. 19 is a flowchart showing air flow control contents during heating operation of the indoor panel according to the present embodiment.
FIG. 20 is an explanatory diagram showing the scanning frequency of the infrared sensor according to the present embodiment.
[Explanation of symbols]
(2) Interior panel
(3) Suction port
(4) Air outlet
(10) Air volume adjustment mechanism
(12) First flap
(13) Second flap
(15) Infrared sensor
(16) Suction temperature sensor
(17) Air temperature sensor
(18) Control unit
(51) Radiation temperature detection means
(52) Wind direction adjusting means
(53) Control means

Claims (6)

An air inlet (3) and a plurality of air outlets (4) are formed, and air direction adjusting means (52) for adjusting the air direction of the air supplied from the air outlet (4) is formed in the air outlet (4). Is an indoor panel of an air conditioner provided with
A suction temperature sensor (16) for detecting the temperature of the suction air sucked into the suction port (3) is disposed in the vicinity of the suction port (3),
In the vicinity of the outlet (3), an outlet temperature sensor (17) for detecting the temperature of the outlet air is arranged,
By comparing the detected temperatures of the suction temperature sensor (16) and the blowout temperature sensor (17), an operation mode comprising a cooling operation, a heating operation, and a cooling / heating thermo-off operation of the air conditioner to which the indoor panel (2) is mounted is provided. An indoor panel (2) of an air conditioner comprising a control means (53) for detecting and adjusting the wind direction adjusting means (52) according to the operation mode. In the indoor panel (2) of the air conditioning apparatus of Claim 1,
The control means (53) adjusts the air direction adjusting means (52) so that the temperature distribution of the room air becomes uniform during the cooling / heating thermo-off operation, the indoor panel (2) of the air conditioner. In the indoor panel (2) of the air conditioning apparatus according to claim 1 or 2,
The wind direction adjusting means (52) has a first flap (12) capable of changing the wind direction of the blown air along the first swing direction, and the wind direction of the blown air is substantially orthogonal to the first swing direction. An indoor panel (2) of an air conditioner comprising a second flap (13) that can be changed along a second swinging direction. In the indoor panel (2) of the air conditioning apparatus of any one of Claims 1-3,
It has radiation temperature detection means (51) for scanning the indoor space and detecting the distribution of radiation temperature,
The air outlet (4) is provided with an air volume adjusting mechanism (10) for adjusting the air volume of the air blown,
The control means (53) adjusts the air volume adjusting mechanism (10) and the wind direction adjusting means (52) based on the detection information of the radiation temperature detecting means (51), and the indoor panel of the air conditioner (2). In the indoor panel (2) of the air conditioning apparatus of Claim 4,
The control means (53) changes the scanning frequency of the radiation temperature detection means (51) to an optimum frequency according to the operation mode of the air conditioner on which the indoor panel (2) is mounted. Interior panel (2). An air conditioner in which an indoor panel is attached to an opening of a casing (1),
The said indoor panel is comprised with the indoor panel (2) of any one of Claim 1 to 5, The air conditioning apparatus characterized by the above-mentioned.

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