JP2019011903A - Air conditioner - Google Patents

Abstract

To provide an air conditioner in which an infrared sensor can be inexpensively installed without being limited by an installation position of an indoor unit.SOLUTION: An air conditioner includes an indoor temperature sensor provided in an indoor unit so as to detect an indoor temperature, an infrared sensor substrate 4c provided in the indoor unit and having a plurality of fixed type infrared sensors for detecting a temperature in an indoor region on the substrate, and a control section for controlling a wind direction on the basis of the indoor temperature and a detection temperature of the infrared sensor. A spindle 20 is provided on one of the infrared sensor substrate 4c and a casing of the indoor unit, and a receiving hole into which the spindle 20 is inserted is provided on the other. The spindle 20 and the receiving hole have engagement portions engaged with each other, and the infrared sensor substrate 4c is fixed to the casing at a predetermined angle by the engagement portions.SELECTED DRAWING: Figure 5

Description

  The present invention relates to an air conditioner.

  In recent air conditioners, air conditioning control is performed using various sensors. Patent Document 1 uses an infrared sensor having a plurality of elements on the top and bottom for detecting temperature, scans the infrared sensor in a certain range on the left and right, acquires a thermal image of the room, and acquires the plurality of acquired thermal images. It describes that a specific area such as the distance to the wall and floor and the installation position of the air conditioner body is determined from the data, and the wind is sent by controlling the vertical and horizontal wind directions.

  In Patent Document 2, a plurality of infrared sensors provided in the air conditioner main body and an indoor visual field observed from the air conditioner main body are divided into a plurality of regions, and the infrared rays that have arrived from each region for each region. Means for condensing the light into the corresponding infrared sensor, means for detecting the temperature of each area from the output of each infrared sensor, and an air conditioner corresponding to the temperature of each area detected by this means And means for controlling the blowing direction of the airflow blown out from the main body.

  Patent Document 3 discloses an air conditioner body that air-conditions a room, a multi-element infrared sensor that is provided in the air conditioner body and detects the amount of infrared rays emitted from each area in the room by changing the direction, An air conditioning control device that controls at least one of the wind direction, the air temperature, and the air volume of the air conditioner body in accordance with the amount of infrared radiation emitted from each multi-element infrared sensor, and the operation of the air conditioning control device. When a switch corresponding to the multi-element infrared sensor provided on the remote control is input, the air conditioning control device changes each area in the room according to the temperature difference of the infrared emission amount detected from each area. Air conditioning is described.

Japanese Patent No. 5236093 Japanese Patent Publication No. 7-88957 Japanese Patent No. 3975853

  In Patent Document 1, an infrared sensor having a plurality of elements on the upper and lower sides for detecting temperature is scanned by a motor to a certain range on the left and right, and a thermal image in the room is acquired to control the wind direction. There are a plurality of motor drives which are not advantageous in terms of cost. On the other hand, Patent Documents 2 and 3 are systems that do not scan the infrared sensor, which is advantageous in terms of cost compared to Patent Document 1.

  However, considering that the installation position of the indoor unit of the air conditioner is not limited to the center of the wall and is arranged on the left and right, the multi-element infrared sensor shown in Patent Document 3 is a variable detection means for detecting the direction of the infrared sensor. Although it is necessary to change, the specific description of the detection variable means has not been made sufficiently, and there is a problem as to whether it can be configured at low cost.

  This invention is invention for solving the said subject, Comprising: It aims at providing the air conditioner which can arrange | position an infrared sensor cheaply, without being limited to the installation position of an indoor unit.

  In order to achieve the object, an air conditioner of the present invention includes an indoor temperature sensor that is provided in an indoor unit and detects a room temperature, and a fixed infrared sensor that is provided in the indoor unit and detects the temperature of an indoor area. A plurality of infrared sensor substrates on the substrate, and a controller that controls the air direction based on the indoor temperature and the detection temperature of the infrared sensor, and the first support shaft portion is provided on one of the infrared sensor substrate and the housing of the indoor unit. And the other is provided with a first receiving hole into which the first support shaft portion is inserted, and the first support shaft portion and the first receiving hole engage with each other. The engagement portion 21 and the recess engagement portion 31 form an engagement portion), and the infrared sensor substrate is fixed to the housing at a predetermined angle by the first engagement portion. Features. Other aspects of the present invention will be described in the embodiments described later.

  According to the present invention, the infrared sensor can be disposed at a low cost without being limited to the installation position of the indoor unit.

It is an external appearance front view which shows the indoor unit of the air conditioner in 1st Embodiment. It is an external appearance perspective view which shows the indoor unit of the air conditioner in 1st Embodiment. It is a longitudinal cross-sectional view which shows the normal blowing state of an air conditioner. It is a longitudinal cross-sectional view which shows the horizontal blowing state of an air conditioner. It is an external appearance front view which shows an infrared sensor board | substrate. It is explanatory drawing which shows the detail of the engaging part by an infrared sensor board | substrate and a housing side. It is explanatory drawing which shows the installation position of an indoor unit. It is explanatory drawing which shows the viewing angle in the vertical space cross section of the infrared sensor in case an indoor unit is a center. It is explanatory drawing which shows the viewing angle in the horizontal space cross section of the infrared sensor in case an indoor unit is a center. It is explanatory drawing which shows the viewing angle in the horizontal space cross section of the infrared sensor in case an indoor unit is left. It is explanatory drawing which shows the viewing angle in the horizontal space cross section of the infrared sensor in case an indoor unit is the right. It is a flowchart which shows the operation control in 1st Embodiment. It is an external appearance front view which shows the indoor unit of the air conditioner in 2nd Embodiment. It is an external appearance perspective view which shows the indoor unit of the air conditioner in 2nd Embodiment. It is explanatory drawing which shows the horizontal person detection area | region of a person detection sensor in case an indoor unit is a center. It is explanatory drawing which shows the horizontal person detection area | region of a person detection sensor in case an indoor unit is right. It is a flowchart which shows the operation control in 2nd Embodiment. It is a figure which shows the structure of the control part of an air conditioner. It is explanatory drawing which shows the other viewing angle in the horizontal space cross section of an infrared sensor in case an indoor unit is a center.

DESCRIPTION OF EMBODIMENTS Embodiments for carrying out the present invention will be described in detail with reference to the drawings as appropriate.
<< first embodiment >>
Drawing 1 is an appearance front view showing the indoor unit of the air harmony machine in a 1st embodiment. FIG. 2 is an external perspective view showing the indoor unit of the air conditioner in the first embodiment. The indoor unit 1 of the air conditioner includes an infrared sensor left 4a and an infrared sensor right 4b, which are fixed one-element infrared sensors capable of detecting temperature at the center. The left and right space temperatures in the installation room are detected by the infrared sensor left 4a and the infrared sensor right 4b.

  Each infrared sensor described above is, for example, a thermopile sensor. The thermopile sensor is a thermal type infrared sensor that generates a thermoelectromotive force according to the amount of incident energy when receiving infrared rays emitted from an object. The absolute amount (temperature) of the energy can be detected. While the pyroelectric infrared sensor (pyro) detects a change in temperature due to the pyroelectric effect, that is, a differential output, this thermopile sensor can detect the absolute amount of temperature due to the thermoelectromotive force effect.

  The indoor unit 1 detects the space temperature of a predetermined area in the room with the infrared sensor left 4a and the infrared sensor right 4b, and detects the ambient temperature of the indoor unit 1 of the air conditioner with the room temperature sensor 2 (room temperature sensor). Wind direction control is performed using the detection result. The air heat-exchanged by the indoor heat exchanger 8 (see FIG. 3) is controlled in air direction by the up-and-down air direction plate 5 and the left and right air direction plates 6 and is blown out from the air outlet 10. The room temperature sensor 2 is, for example, a pyroelectric infrared sensor.

  FIG. 3 is a longitudinal sectional view showing a normal blowing state of the air conditioner. FIG. 4 is a longitudinal sectional view showing a horizontal blowing state of the air conditioner. The indoor unit 1 includes an up / down wind direction plate 5, a left / right wind direction plate 6, an air inlet port 7, an indoor heat exchanger 8, an indoor fan 9, an air outlet port 10, electrical components (including a control unit 80 (see FIG. 18)), Various sensors and the like are accommodated in the housing 11.

  The indoor heat exchanger 8 has a plurality of heat transfer tubes, heats the indoor air taken into the indoor unit by the indoor fan 9 with the refrigerant flowing through the heat transfer tubes, and cools, heats, etc. Is configured to do. The heat transfer pipe communicates with the refrigerant pipe described above and constitutes a part of a known refrigerant cycle. The indoor fan 9 can adjust the wind speed.

  The left and right wind direction plates 6 are rotated forward and backward by a left and right wind direction plate motor (not shown) with a base end side of the rotation shaft provided at the lower portion of the indoor unit 1 as a fulcrum. And the front end side of the left-right wind direction board 6 has faced the indoor side, By this, the front end side of the left-right wind direction board 6 can operate | move so that it may shake in a horizontal direction. The vertical wind direction plate 5 is rotated forward and backward by a vertical wind direction plate motor (not shown) with rotation shafts provided at both longitudinal ends of the indoor unit 1 as fulcrums. Thereby, the front end side of the up-and-down wind direction board 5 can be operated so as to swing in the up-and-down direction.

  When the indoor fan 9 rotates, the indoor unit 1 takes in indoor air into the indoor unit 1 through the air suction port 7 and the filter, and exchanges heat with the indoor heat exchanger 8. Thereby, the air after the heat exchange is cooled or heated by the indoor heat exchanger 8. The air after the heat exchange is guided to the air blowing air passage. Furthermore, the air guided to the air blowing air passage is sent out from the air blowing port 10 to the outside of the indoor unit 1 to air-condition the room. When the air after the heat exchange is blown into the room from the outlet 10, the horizontal wind direction is adjusted by the left and right wind direction plates 6, and the vertical wind direction is adjusted by the upper and lower wind direction plates 5.

  FIG. 18 is a diagram illustrating a configuration of a control unit of the air conditioner. The sensor unit is provided in each of the indoor unit 1 and the outdoor unit. The sensor unit includes a room temperature sensor 2, a humidity sensor, a clock, an infrared sensor left 4a, an infrared sensor right 4b, an outside air temperature sensor, a compression temperature sensor, a refrigerant pipe temperature sensor, and the like.

  The control unit 80 includes an air conditioning control unit 81, a storage unit 82, and the like. The control unit 80 is provided in an electrical component (in the electrical component box), and based on information from the remote controller and the sensor unit via the transmission / reception unit, the indoor fan 9, the left / right wind direction plate 6, and the up / down wind direction plate of the indoor unit 1. 5 etc. are controlled. Further, the control unit 80 controls an outdoor unit compressor, a propeller fan, and the like.

  The storage unit 82 includes, for example, a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. Then, a program stored in the ROM is read out by a CPU (Central Processing Unit) of the control unit 80, expanded in the RAM, and executed.

  FIG. 5 is an external front view showing the infrared sensor substrate. The infrared sensor substrate 4c is a rectangular substrate, and infrared sensors (infrared sensor left 4a, infrared sensor right 4b) are disposed near both ends in the longitudinal direction of the infrared sensor substrate 4c, and the infrared sensor substrate 4c is located near the center in the longitudinal direction. A support shaft portion 20 that supports the infrared sensor substrate 4c is provided in the short direction. The infrared sensor left 4a and the infrared sensor right 4b need not be driven by a motor, and are fixed to the housing 11 (see FIG. 3) by the support shaft portion 20 in a state of being fixed to the infrared sensor substrate 4c, and perform space temperature detection. It has a structure. In FIG. 5, the infrared sensor left 4a and the infrared sensor right 4b are arranged apart from each other in the longitudinal direction of the infrared sensor substrate 4c, but may be arranged close to each other.

  6A and 6B are explanatory views showing details of the infrared sensor substrate and the housing side engaging portion, FIG. 6A is an overall view of the engaging portion, and FIG. 6B is a support shaft portion having a convex engaging portion. (C) is sectional drawing of the receiving hole which has a recessed part engaging part. The support shaft portion 20 has a convex portion engaging portion 21 (engaging portion) that protrudes in a rib shape and extends in the vertical direction. A receiving hole 30 into which the support shaft portion 20 is inserted is provided on the housing 11 side. The receiving hole 30 has a plurality of concave engaging portions 31 (engaging portions) into which the convex engaging portions 21 are inserted. The receiving hole 30 has a recess engaging portion 31 at a predetermined angle from the OX axis. The recess engaging portion 31 is, for example, 15 degrees and 30 degrees on the right side from the OX axis, and 15 degrees and 30 degrees on the left side.

  In FIG. 6, although the example which provided the spindle part 20 in the infrared sensor board | substrate 4c side was demonstrated, it is not necessarily limited to this. For example, the support shaft portion 20 may be provided on the housing 11 side, and the receiving hole 30 may be provided on the infrared sensor substrate 4c side. In other words, an engagement portion may be formed between the support shaft portion 20 and the receiving hole 30.

  In the present embodiment, one of the infrared sensor substrate 4c and the housing 11 of the indoor unit 1 is provided with a support shaft portion 20 (first support shaft portion), and the other is a receiving hole 30 into which the support shaft portion 20 is inserted. (First receiving hole) is provided, and an engaging part (first engaging part) is formed between the support shaft part 20 and the receiving hole 30. The infrared sensor substrate 4c can be fixed at a predetermined angle with respect to the casing 11 by the engaging portion described above.

  In addition, when the installation position of the indoor unit 1 is within a predetermined distance from the side wall (for example, within Xm, X = 1), the infrared sensor substrate 4c is rotated by the engaging part 11 by rotating the support shaft part 20. Fixed to. Specifically, after the installation operator manually disengages the engaging portion once and rotates the supporting shaft portion 20 appropriately based on the predetermined distance X, the supporting shaft portion 20 receives the receiving hole 30. Engage with. As a result, the direction of the infrared sensor substrate 4c fixed to the support shaft portion 20 is changed. Thereby, the detection range by an infrared sensor (infrared sensor left 4a, infrared sensor right 4b) can be set appropriately.

  The infrared sensor substrate 4c has a dip switch (not shown) that can be turned ON / OFF corresponding to the recess engaging portion 31 shown in FIG. When the support shaft portion 20 of the infrared sensor substrate 4c is fixed to the receiving hole 30, the installation operator may turn on a dip switch corresponding to a predetermined angle.

  Specifically, the dip switch numbers are L2, L1, SS, R1, and R2 corresponding to 30 degrees on the left side, 15 degrees on the left side, 0 degrees on the left side, 15 degrees on the right side, and 30 degrees on the right side from the OX axis. In this case, when the dip switch number is SS, the control unit 80 determines the swing range (swing range) of the left and right wind direction plates 6 based on the detection ranges of the infrared sensor left 4a and the infrared sensor right 4b shown in FIG. It is determined. Similarly, when the dip switch number is L2, the control unit 80 determines the swing range (swing range) of the left and right wind direction plates 6 based on the detection ranges of the infrared sensor left 4a and the infrared sensor right 4b shown in FIG. It is determined. Similarly, when the dip switch number is R2, the control unit 80 determines the swing range (swing range) of the left and right wind direction plates 6 based on the detection ranges of the infrared sensor left 4a and the infrared sensor right 4b shown in FIG. It is determined.

  In addition, in FIG. 6, although the front-end | tip of the convex part engaging part 21 is circular, it is not necessary to limit to this. For example, when the convex portion engaging portion 21 has a triangular shape, the receiving hole 30 may have a plurality of concave portion engaging portions 31 corresponding to the shape of the convex portion engaging portion 21.

  The infrared sensor substrate 4c of the present embodiment can be appropriately disposed on the housing 11 at an appropriate angle by an installation operator based on the installation position of the indoor unit 1. The arrangement method will be described below.

  FIG. 7 is an explanatory diagram showing the installation position of the indoor unit, where (a) shows the case of the left, (b) shows the case of the center, and (c) shows the case of the right side. The indoor space includes a wall 51, a ceiling 52 (see FIG. 8), a floor 53, a wall 54 (see FIG. 8) that is a facing surface of the wall 51, and walls 55 and 56 as side walls of the wall 51. As shown in FIG. 7, the indoor unit 1 is roughly divided into a case of the left installed from the wall 55, a case of the center, and a case of the right installed from the wall 56, as shown in FIG. The viewing angle of the infrared sensor (infrared sensor left 4a, infrared sensor right 4b) in such a case will be described with reference to FIGS.

  FIG. 8 is an explanatory diagram showing a viewing angle in a vertical space section of the infrared sensor when the indoor unit is in the center. FIG. 9 is an explanatory diagram showing the viewing angle in the horizontal space section of the infrared sensor when the indoor unit is in the center. In the example shown in FIG. 8, the infrared sensor has a viewing angle of 69 degrees below and 35 degrees above the horizontal direction. In addition, in FIG. 9, when the direction 61 b is when it is directly in front of the indoor unit 1, the infrared sensor left 4 a has a viewing angle of 77 degrees, and the region from the direction 61 b to the direction 65 b (left space (first space (first space Space) area) can be detected. The infrared sensor right 4b has a viewing angle of 77 degrees, and can detect a region from the direction 61b to the direction 66b (region of the right space (second space)).

  FIG. 10 is an explanatory diagram showing the viewing angle in the horizontal space section of the infrared sensor when the indoor unit is on the left. In the case of FIG. 10, in FIG. 6, the installation operator rotates the support shaft portion 20 to the right by 30 degrees and fixes it to the receiving hole 30. For this reason, the infrared sensor left 4a can detect a region from the direction 65a to the direction 61a (left space (first space) region), and the infrared sensor right 4b can detect a region from the direction 61a to the direction 66ay ( The right space (second space) region) can be detected. The direction 66ay is included in the front surface of the indoor unit 1. Thereby, the infrared sensor can detect the right space and the left space almost equally. In FIG. 10, the shaded area is a blind spot in the detection area of the infrared sensor right 4b.

  FIG. 11 is an explanatory diagram showing a viewing angle in a horizontal space section of the infrared sensor when the indoor unit is on the right. In the case of FIG. 11, in FIG. 6, the installation operator rotates the support shaft portion 20 to the left by 30 degrees and fixes it to the receiving hole 30. Therefore, the infrared sensor left 4a can detect a region from the direction 65cy to the direction 61c (region of the left space (first space)), and the infrared sensor right 4b can detect a region from the direction 61c to the direction 66c ( The right space (second space) region) can be detected. Thereby, the infrared sensor can detect right space and left space substantially equally. In FIG. 11, the shaded area is a blind spot in the detection area of the infrared sensor left 4a.

  FIG. 12 is a flowchart showing the operation control in the first embodiment. The air conditioner control unit 80 (see FIG. 18) controls the air conditioner according to the control flow shown in FIG. 12, depending on whether or not the control is performed using the infrared sensor left 4a and the infrared sensor right 4b, particularly at the start of the cooling operation. .

  First, at the start of operation, each infrared sensor is already positioned so as to be in a predetermined visual field range. When the cooling operation is started, the control unit 80 proceeds to step S1, and controls the up / down air direction plate motor (not shown) so that the up / down air direction plate 5 becomes the normal operation position or the user set position shown in FIG. Subsequently, in step S2, the control unit 80 determines whether or not the control setting using the infrared sensor left 4a and the infrared sensor right 4b is performed. When there is no control setting (step S2, no), the process proceeds to step S12, and the control unit 80 sets the left and right wind direction plates 6 to the normal operation position or the user set position and proceeds to step S11 to perform the continuous operation. When the stop selection is made at step S11 (step S11, Yes), the operation is stopped. When the stop selection is not made (step S11, No), the process returns to step S2 to repeat the control flow.

  When there is a control setting in step S2, the control unit 80 uses the space temperatures detected by the infrared sensor left 4a and the infrared sensor right 4b, and performs control to compare the left and right space temperatures. If “left> right + N ° C.”, the process proceeds to step S4. If “| left−right | ≦ N ° C.”, the process proceeds to step S5. If “right> left + N ° C.”, the process proceeds to step S6. “N ° C.” used here is a parameter whose setting can be changed. For example, “N ° C.” will be described as “5 ° C.”.

  When the process proceeds to step S4, the control unit 80 performs left / right wind direction / left direction priority control. That is, the control unit 80 changes the swing speed when the left and right wind direction plates 6 are swung in the full width and moved from the center to the left direction to ½ to 1/10 of the normal swing speed, and focuses the air flow to the left direction. To do. When the process proceeds to step S6, the control unit 80 performs the right / left wind direction / right direction priority control. That is, conversely, the control unit 80 changes the swing speed when operating from the center to the right direction to 1/2 to 1/10 of the normal swing speed, and blows the air in the right direction.

  When the process proceeds to step S5, the control unit 80 performs the left / right wind direction full width swing control. That is, the control unit 80 swings the left and right wind direction plates 6 at the normal swing speed. As a result, the entire left and right are blown uniformly.

  When a predetermined time (a parameter that can be arbitrarily set) elapses after the transition from step S4 to step S5 to step S6, the control unit 80 here sets the indoor space temperature after, for example, “60 minutes” to the infrared sensor left 4a and the infrared sensor right 4b. To determine whether “| left-right | ≦ M ° C.” is satisfied (step S7). If “| left-right | ≦ M ° C.” is satisfied (step S7, Yes), the process proceeds to step S8. If not satisfied (step S7, No), the process proceeds to step S3. “M ° C.” used here is a parameter whose setting can be changed. For example, “M ° C.” is described as “3 ° C.”.

  If “| Left-Right | ≦ 3 ° C.” is not established in Step S7, the process returns to Step S3, and again proceeds from Steps S3 to S4 and from Steps S5 to S6 to Step S7 after a certain period of time. Works at a different time than the first time. For example, the fixed time after the second time is “30 minutes”.

  When step S7 is established, the process proceeds to step S8, where the control unit 80 checks the ambient temperature with the room temperature sensor 2 and determines whether or not the set temperature has been reached. If the set temperature has been reached (step S8, Yes), the process returns to step S9. If the set temperature has not been reached (step S8, No), the process returns to step S3 to perform a repeated operation.

  When the set temperature is reached and the process proceeds to step S9, the control unit 80 performs up / down wind direction ceiling direction control. That is, the control unit 80 moves the up / down wind direction plate 5 from the normal operation position shown in FIG. 3 to a horizontal position shown in FIG. Air is blown from the air outlet 10 in the horizontal direction or upward in the indoor space, and the process proceeds to step S10 synchronously, the left and right wind direction plates 6 are fixed at the center position, and the process proceeds to step S11.

  When a certain time (a parameter that can be arbitrarily set, for example, “60 minutes”) elapses after the transition to step S11, control is performed so that the space temperature is reconfirmed, and the process returns to step S2 and repeats the operation until stopped. Such an operation is the process of the first embodiment.

<< Second Embodiment >>
FIG. 13: is an external appearance front view which shows the indoor unit of the air conditioner in 2nd Embodiment. FIG. 14 is an external perspective view showing an indoor unit of an air conditioner according to the second embodiment. Compared with the first embodiment, the second embodiment further includes a human detection sensor 3 that detects the presence or absence of a person. The indoor unit 1 of the air conditioner performs wind direction control using detection results of the infrared sensor left 4a, the infrared sensor right 4b, the room temperature sensor 2, and the human detection sensor 3.

  The human detection sensor 3 is a pyroelectric infrared sensor using a pyroelectric element, for example. The pyroelectric element is an element that detects light including infrared rays by the pyroelectric effect. The pyroelectric effect is a phenomenon in which the electric charge charged on the surface of a ceramic having spontaneous polarization (such as lead zirconate titanate (PZT)) increases or decreases with changes in temperature. The pyroelectric element uses light simply as a heat source, and the wavelength dependency of the element itself is low. Therefore, it is possible to easily select a necessary wavelength by an externally prepared filter. Another feature is that it is inexpensive.

  The human detection sensor 3 also has a support shaft portion 20 (second support shaft portion) as in FIG. The support shaft part 20 has a convex part engaging part 21 protruding in a rib shape. On the housing 11 side, a receiving hole 30 (second receiving hole) into which the support shaft part 20 is inserted is provided. The receiving hole 30 has a plurality of concave engaging portions 31 (second engaging portions) into which the convex engaging portions 21 (second engaging portions) are inserted. The receiving hole 30 has a recess engaging portion 31 at a predetermined angle from the OX axis. The recess engaging portion 31 is, for example, 15 degrees and 30 degrees on the right side from the OX axis, and 15 degrees and 30 degrees on the left side. The orientation of the human detection sensor 3 is usually changed by an installation operator.

  FIG. 15 is an explanatory diagram illustrating a horizontal human detection region of the human detection sensor when the indoor unit is in the center. The human detection sensor 3 can detect a person in the region from the direction 75b to the direction 76b.

  FIG. 16 is an explanatory diagram illustrating a horizontal human detection region of the human detection sensor when the indoor unit is on the right. In the case of FIG. 16, the support shaft portion 20 is rotated 15 degrees to the left in FIG. 6 and fixed to the receiving hole 30. For this reason, the human detection sensor 3 can detect the area | region from the direction 75c to the direction 76c, and can detect a person about the whole indoor space by this. 16 shows the case where the indoor unit 1 is on the right, the same applies to the case where the indoor unit 1 is on the left.

  One of the human detection sensor 3 and the housing 11 of the indoor unit 1 according to the present embodiment is provided with a support shaft portion 20 (second support shaft portion), and the other is a receiving hole 30 into which the support shaft portion 20 is inserted. A second receiving hole) is provided, and the support shaft part 20 and the receiving hole 30 have an engaging part (second engaging part) that engages with each other. The human detection sensor 3 can be fixed at a predetermined angle with respect to the housing 11 by the second engagement portion.

  FIG. 17 is a flowchart showing the operation control in the second embodiment. In FIG. 17, steps S13 to S15 are added as compared to FIG. The same elements as those in the first embodiment shown in FIG.

  In step S8, when the set temperature is reached and the process proceeds to step S13, the control unit 80 checks the presence or absence of a person in the region shown in FIG. 15 or FIG. 16, for example. When it is determined that there is a person (step S13, yes), the process proceeds to step S14, and the operation is continued by setting the up / down wind direction plate 5 to the driving position (predetermined position based on the detection result of the person) or the user setting position. .

  Then, the control unit 80 continues the operation for a certain time (a parameter that can be arbitrarily set). Here, for example, after “30 minutes” have elapsed, the control unit 80 again performs the presence / absence check operation in the region shown in FIG. 15 or FIG. 16 (step S15). If it is determined that there is also a person (step S15, yes), the process returns to step S14 to repeat this operation. If it is determined that there is no person (No at Step S15), the process proceeds to Step S9.

  The air conditioner of the present embodiment further includes a human detection sensor 3 that detects a person, and when the room temperature reaches a set temperature set by the user, the control unit 80 detects the person using the human detection sensor 3. When not, the up-and-down air direction plate 5 that changes the air direction from the air outlet 10 in the up-and-down direction can be directed horizontally or above the indoor space.

  In the embodiment described above, a plurality of fixed-type infrared sensors (infrared sensor left 4a, infrared sensor right 4b) are arranged close to each other in the longitudinal direction of the infrared sensor substrate 4c (see FIG. 5). As an example, it has been explained that the temperature of an indoor area is detected. However, the present invention is not limited to this. For example, an example in the case where a fixed infrared sensor is disposed apart from both ends in the longitudinal direction of the infrared sensor substrate 4c (see FIG. 5) will be described with reference to FIG.

  FIG. 19 is an explanatory diagram illustrating another viewing angle in the horizontal space section of the infrared sensor when the indoor unit is in the center. In FIG. 19, the infrared sensor left 4a and the infrared sensor right 4b are separated by a distance D. Assuming that the direction 61b is in front of the indoor unit 1, the infrared sensor left 4a has a viewing angle of 77 degrees, and an area from the direction 61bR to the direction 65bL (an area of the left space (first space)). Can be detected. The infrared sensor right 4b has a viewing angle of 77 degrees, and can detect a region (region of the right space (second space)) from the direction 61bL to the direction 66bR.

  As described above, the air conditioner of the present embodiment includes an indoor temperature sensor (for example, room temperature sensor 2) that is provided in the indoor unit 1 and detects the indoor temperature, and a fixed type that is provided in the indoor unit 1 and detects the temperature of the indoor region. An infrared sensor substrate 4c having a plurality of infrared sensors (for example, infrared sensor left 4a and infrared sensor right 4b) on the substrate, and a control unit 80 for controlling the wind direction based on the room temperature and the detected temperature of the infrared sensor. The supporting shaft part 20 is provided in one of the infrared sensor substrate 4c and the housing 11 of the indoor unit 1, and the receiving hole 30 into which the supporting shaft part 20 is inserted is provided in the other. Engagement portions (projection engagement portion 21 and recess engagement portion 31) are formed between the support shaft portion 20 and the receiving hole 30, and the infrared sensor substrate 4c is attached to the housing 11 by the engagement portion. And fixed at a predetermined angle. According to the present embodiment, the infrared sensor can be disposed at a low cost without being limited to the installation position of the indoor unit 1. In addition, if the installation operator performs the installation of the infrared sensor when installing the indoor unit 1, the user of the air conditioner does not need to change the installation of the infrared sensor.

1 Indoor unit 2 Room temperature sensor (Indoor temperature sensor)
3 Human detection sensor (person detection means)
4a Infrared sensor left 4b Infrared sensor right 4c Infrared sensor board 5 Vertical wind direction plate 6 Left and right wind direction plate 7 Air intake port 8 Heat exchanger 9 Blower fan 10 Air outlet port (outlet)
11 Housing 20 Supporting shaft portion (first supporting shaft portion, second supporting shaft portion)
21 convex part engaging part (1st engaging part, 2nd engaging part)
30 receiving holes (first receiving hole, second receiving hole)
31 recess engaging part (first engaging part, second engaging part)
80 Control unit

Claims (7)

An indoor temperature sensor provided in the indoor unit for detecting the indoor temperature;
An infrared sensor substrate having a plurality of fixed infrared sensors provided on the indoor unit for detecting the temperature of a predetermined area in the room;
A controller that controls the air direction based on the indoor temperature and the temperature detected by the infrared sensor,
One of the infrared sensor substrate and the housing of the indoor unit is provided with a first support shaft, and the other is provided with a first receiving hole into which the first support shaft is inserted.
The first support shaft portion and the first receiving hole have first engaging portions that engage with each other;
The infrared sensor substrate is fixed at a predetermined angle with respect to the housing by the first engaging portion. When the installation position of the indoor unit is within a predetermined distance from the side wall,
The air conditioner according to claim 1, wherein the infrared sensor substrate is fixed to the housing by the first engagement portion by rotating the first support shaft portion. The infrared sensor substrate is a rectangular substrate, the infrared sensor is disposed in the vicinity of both ends in the longitudinal direction of the substrate, and the first support shaft portion is disposed in the short direction near the center in the longitudinal direction. It has. The air conditioner of Claim 1 characterized by the above-mentioned. The infrared sensor is a sensor that detects a region of the first space and a region of the second space in the room,
In the cooling operation, when the absolute value of the temperature difference between the first space and the second space exceeds a predetermined value, the control unit intensively air-conditions the higher temperature space, and the temperature difference The air conditioner according to claim 1, wherein when the absolute value of is equal to or less than the predetermined value, the first space and the second space are air-conditioned equally. When the room temperature reaches a set temperature set by the user,
The air conditioner according to claim 4, wherein the control unit directs an up-and-down air direction plate that changes an air direction from an air outlet of the indoor unit in an up-and-down direction horizontally or above the indoor space. The air conditioner further includes a human detection sensor for detecting a person,
When the room temperature reaches a set temperature set by the user,
The control unit directs an up-and-down air direction plate that changes an air direction from an outlet of the indoor unit in an up-and-down direction horizontally or above an indoor space when no person is detected by the human detection sensor. Item 5. An air conditioner according to Item 4. One of the human detection sensor and the housing of the indoor unit is provided with a second spindle, and the other is provided with a second receiving hole into which the second spindle is inserted.
The second support shaft portion and the second receiving hole have a second engaging portion that engages with each other,
The air conditioner according to claim 6, wherein the human detection sensor is fixed at a predetermined angle with respect to the housing by the second engagement portion.

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