JP2019094855A - Electric fan and air-conditioning system - Google Patents

Abstract

To provide an electric fan and an air-conditioning system, excellent in user-friendliness in sleeping, and also capable of efficiently feeding air to a user.SOLUTION: An electric fan (1) comprises a ventilation unit for feeding air to the outside; a movable body (4) having human body detection means capable of detecting a human body; driving means of operating the movable body (4) in a swingable manner; and control means capable of setting a sleeping mode as an operational mode. The sleeping mode comprises human position detection operation of detecting a position of a sleeping person (300) by swinging the movable body (4) within a range of a first angle (α), and swingable ventilation operation of feeding air toward the sleeping person in a state of swing the movable body (4) within a range of a second angle (β) smaller than the first angle (α).SELECTED DRAWING: Figure 4

Description

  The present invention relates to a fan and an air conditioning system.

  The fan disclosed in the following Patent Document 1 is configured to detect the transition to the sleep state of the user and reduce the air volume by the infrared sensor (6) which is a body temperature detection means provided on the support (4) There is. In addition, the inside of a parenthesis is a code in patent documents 1.

JP, 2014-66151, A

  In the technology of Patent Document 1, the user must adjust the orientation of the fan before going to bed so that the infrared sensor (6) can detect the body temperature of the user while going to bed, so usability is necessarily Not good.

  The present invention has been made to solve the above-described problems, and it is an object of the present invention to provide a fan and an air conditioning system that can be efficiently blown to the user while being easy to use at bedtime. Do.

A fan according to the present invention sets a sleep mode as an operation mode, a movable body having a blower for sending wind to the outside, a human body detection means capable of detecting a human body, a drive means for oscillating the movable body, and an operation mode. In the sleeping mode, a person position detecting operation for detecting the position of the sleeping person by swinging the movable body in the range of the first angle, and the movable body from the first angle Also includes a swing and blow operation that blows air to a sleeping person while swinging at a small second angle range.
Further, the air conditioning system according to the present invention includes an air conditioner and a fan, the air conditioner includes a human body detection unit capable of detecting the position of a sleeping person, and the fan sends the wind to the outside. A movable body having an air blower, a driving means for swinging the movable body, a control means capable of setting a sleep mode as an operation mode, and a communication means for receiving information on the position of a sleeping person from an air conditioner And the sleeping mode includes a swing air blowing operation for blowing air to a person sleeping while swinging the movable body.

  ADVANTAGE OF THE INVENTION According to this invention, while being easy to use at bedtime, it becomes possible to ventilate efficiently with respect to a user.

FIG. 1 is a side view of a fan according to Embodiment 1; FIG. 1 is a side view of a fan according to Embodiment 1; FIG. 2 is a block diagram showing a configuration of a control system of a fan according to Embodiment 1. It is a top view for demonstrating the example of operation | movement of the fan in sleep mode. It is a figure which shows an example of the change of a sleep state in from a person's sleeping to waking up. It is a flowchart which shows the operation example at the time of the sleeping mode of the fan by Embodiment 1. FIG. 5 is an explanatory drawing showing an example of a detection result of a human position detection operation in Embodiment 1. FIG. FIG. 14 is a diagram showing another example of operation in the bedtime mode of the electric fan according to the first embodiment. FIG. 10 is a side view of the inside of a bedroom provided with an air conditioning system according to a second embodiment. FIG. 7 is a block diagram showing a configuration of a control system of an air conditioning system according to a second embodiment.

  Hereinafter, embodiments will be described with reference to the drawings. The same or corresponding elements in the drawings are denoted by the same reference numerals, and redundant description will be simplified or omitted. The present disclosure can include any combination of configurations that can be combined among the configurations described in the following embodiments.

Embodiment 1
1 and 2 are side views of a fan 1 according to the first embodiment. FIG. 3 is a block diagram showing a configuration of a control system of the fan 1 according to the first embodiment. The fan 1 of the present embodiment shown in these figures is of a type generally called a living fan. The fan in the present disclosure is not limited to such a type called a living fan, and is also applicable to various fans such as, for example, a fan called a tower type. In the following description, in principle, the vertical, horizontal, front and back directions are specified based on the installation state of the fan 1.

  As shown in FIG. 1, the fan 1 includes a pedestal 2, a support 3 and a movable body 4. The pedestal portion 2 is a portion to be placed on the installation surface. The installation surface is, for example, a floor surface or the like on which the fan 1 is installed. The support 3 is fixed to the upper surface of the pedestal 2. The support 3 is a vertically elongated columnar member. The pedestal portion 2 has a sufficient size in the front and rear direction and the left-right direction so that the support portion 3 and the movable body 4 provided on the pedestal portion 2 can be stably supported.

  The movable body 4 includes a fan 4a, a fan motor 4b, a front guard 4c, a rear guard 4d, and a human body detection sensor 4e. The fan 4a in the present embodiment is an axial flow fan having a propeller-like shape. The fan motor 4b rotates the fan 4a. The fan 4a is connected to the output shaft of the fan motor 4b. The fan 4a corresponds to a blower that sends the wind to the outside. The fan motor 4b can adjust the rotational speed of the fan 4a. The higher the rotational speed of the fan 4a, the higher the air volume.

  The front guard 4c covers the fan 4a from the front. The rear guard 4d covers the fan 4a from behind. That is, the fan 4a is provided so as to be housed inside the front guard 4c and the rear guard 4d. The front guard 4c and the rear guard 4d have a circular shape in a front view according to the outer shape of the fan 4a. The front guard 4c and the rear guard 4d may each have, for example, a circular wedge shape. At least a portion of the front guard 4c and the rear guard 4d may have a lattice-like or net-like shape.

  In the illustrated configuration, the human body detection sensor 4e is attached to the upper portion of the rear guard 4d. Alternatively, the human body detection sensor 4e may be attached to the top of the front guard 4c. The human body detection sensor 4e corresponds to human body detection means capable of detecting a human body. Although the human body detection sensor 4 e may be disposed below the movable body 4, it is desirable to dispose the human body detection sensor 4 e above the movable body 4 as illustrated. By arranging the human body detection sensor 4e on the upper part of the movable body 4, it is possible to more reliably prevent the obstacle of the human body detection sensor 4e from being blocked by an obstacle between the fan 1 and the user.

  The fan motor 4 b is disposed inside the motor storage unit 5. The motor storage portion 5 is connected to the upper portion of the support portion 3 via the left and right swing motor 6. The left and right swing motor 6 corresponds to drive means for swinging the movable body 4. When the left and right swing motor 6 is driven, the movable body 4 and the motor storage portion 5 integrally swing. The “swing movement” is an operation to change the direction of the movable body 4 in the lateral direction, that is, in the lateral direction. In the “swing movement”, the movable body 4 rotates around a rotation axis along the vertical direction or a rotation axis oblique to the vertical direction. In the illustrated configuration, the rotation axis of the movable body 4 by the left and right swing motor 6 is a direction along the vertical direction. Further, although the rotation axis of the movable body 4 by the left and right swing motor 6 substantially coincides with the position of the center of the support 3, the positions of both may be shifted.

  The human body detection sensor 4e is fixed to the other part of the movable body 4 without an actuator. When the movable body 4 swings by the left and right swing motor 6, the human body detection sensor 4e also swings together.

  The fan 1 of the present embodiment further includes a vertical movement motor 7. The vertical movement motor 7 is disposed inside the motor storage unit 5. The vertical movement motor 7 has a rotation axis along a direction perpendicular to the paper surface of FIGS. 1 and 2, that is, a rotation axis along a horizontal direction. When the vertical movement motor 7 is operated, the movable body 4 rotates about the rotation axis of the vertical movement motor 7. The vertical movement motor 7 corresponds to a second drive unit that moves the movable body 4 so that the angle in the air blowing direction with respect to the horizontal surface changes. The blowing direction is a direction in which the air flow is blown out from the movable body 4. In the present embodiment, the center line of the fan 4a corresponds to the blowing direction.

  The state shown in FIG. 1 corresponds to the state in which the center line of the fan 4a is horizontal, that is, the state in which the air blowing direction is horizontal. FIG. 2 shows a state where the movable body 4 is directed obliquely upward by the vertical movement motor 7. In the state of FIG. 2, the blowing direction is obliquely upward with respect to the horizontal plane. Although not shown, it may be possible to turn the movable body 4 obliquely downward by the vertical movement motor 7, that is, to make the air blowing direction obliquely downward with respect to the horizontal plane.

  The central axis of the field of view of the human body detection sensor 4 e may be parallel to the air blowing direction from the movable body 4. Alternatively, the center line in the blowing direction from the movable body 4 may coincide with the central axis of the field of view of the human body detection sensor 4 e. In the present embodiment, when the direction of the movable body 4 is changed by the vertical movement motor 7, the angle of the central axis of the field of view of the human body detection sensor 4e with respect to the horizontal plane can be changed.

  The fan 1 further includes an operation unit 8 and a control unit 9. In the illustrated example, the operation unit 8 is disposed on the upper surface of the pedestal 2, and the control unit 9 is disposed below the operation unit 8 and inside the pedestal 2. The operation unit 8 includes a switch operated by the user. The operation unit 8 may include a display for displaying information. The operation unit 8 may include a touch screen having the functions of the operation unit and the display. The control unit 9 corresponds to a control unit that controls the operation of the fan 1. The user can input the operation, stop, setting of the operation mode, and the like of the fan 1 to the control unit 9 by operating the operation unit 8.

  As shown in FIG. 3, the fan 1 according to the present embodiment further includes a temperature and humidity sensor 10 that detects the temperature and humidity in the room. The fan motor 4 b, the human body detection sensor 4 e, the left and right swing motor 6, the vertical movement motor 7, the operation unit 8, and the temperature and humidity sensor 10 are electrically connected to the control unit 9. Although not shown, the fan 1 may include a remote control device capable of wireless communication with the control unit 9. The user can remotely control the fan 1 using the remote control device. In addition, the operation unit 8 may be removable from the pedestal 2, and the operation unit 8 may be configured to be usable as a remote control device. Further, for example, the portable information terminal 100 such as a smartphone or a tablet terminal and the control unit 9 may communicate with each other, and the portable information terminal 100 may be usable as a user interface of the fan 1. In that case, the portable information terminal 100 and the control unit 9 may be able to communicate via the network.

  The human body detection sensor 4e detects at least one of the position and the movement of a person without contact. The fan 1 may include, for example, at least one of an infrared sensor, a radio wave sensor such as a Doppler sensor, a camera, an infrared camera, a thermography, and an ultrasonic radar as the human body detection sensor 4e. The human body detection sensor 4e may be capable of detecting at least one of human movement, heartbeat, pulsation, pulsation and respiration. The control unit 9 can detect, for example, the position of the sleeping person, the range in which the sleeping person is present, and whether the person is in the sleeping state or the like, using the information detected by the human body detection sensor 4e. When detecting that a person is in the sleep state, the control unit 9 may further detect the depth of the sleep.

  The control unit 9 includes, for example, a processing circuit including at least one processor and at least one memory. Each function of the control unit 9 may be realized by software, firmware, or a combination of software and firmware. Software and / or firmware may be described as a program. At least one of the software and the firmware may be stored in at least one memory. At least one processor may implement each function of the control unit 9 by reading and executing a program stored in at least one memory. At least one memory may include non-volatile or volatile semiconductor memory, magnetic disk, and the like. The processing circuit of the control unit 9 may be, for example, a single circuit, a complex circuit, a programmed processor, a processor programmed in parallel, an application specific integrated circuit (ASIC), a field-programmable gate array (FPGA), or a combination thereof. It may be something.

  The control unit 9 stores, for example, the temperature and humidity in the room detected by the temperature and humidity sensor 10, the detection result detected by the human body detection sensor 4e, and the like in the memory. In addition, the memory of the control unit 9 is also used as a working memory when the processor performs various arithmetic processing.

  The control unit 9 can set the sleep mode as the operation mode. The sleep mode is an operation mode when a person going to bed uses the fan 1. FIG. 4 is a plan view for explaining an example of the operation of the fan 1 in the sleep mode. FIG. 4 is a view of the person 300 sleeping on the bed 200 and the fan 1 as viewed from above. The sleeping bed 200 is, for example, a bed or a futon. In the example of FIG. 4, the fan 1 is placed at a lateral position with respect to the bed 200 and the sleeping person 300, but it goes without saying that the position at which the fan 1 is placed is not limited to this. For example, the fan 1 may be placed in the direction in which the foot of the sleeping person 300 is facing.

  The sleep mode includes a person position detection operation for detecting the position of the sleeping person 300 and a swing and blow operation for blowing air toward the sleeping person 300. In the human position detection operation, the control unit 9 detects the position of the sleeping person 300 by the human body detection sensor 4 e while causing the movable body 4 to swing in the range of the first angle α by the left and right swing motor 6. When the movable body 4 swings, the human body detection sensor 4e provided on the movable body 4 also swings, so that the field of view of the human body detection sensor 4e is scanned in the left-right direction. Therefore, according to the human position detection operation, the sleeping person 300 can be reliably caught in the field of view of the human body detection sensor 4e, so that the position of the sleeping person 300 can be detected reliably.

  The second angle β is an angle smaller than the first angle α. In the swing and blow operation, the control unit 9 blows the movable body 4 toward the sleeping person 300 while swinging the movable body 4 in the range of the second angle β by the left and right swing motor 6. At this time, the control unit 9 determines the range of the second angle β in accordance with the position of the sleeping person 300 detected by the person position detecting operation.

  The first angle α may be an angle corresponding to the maximum movable range of the movable body 4 by the left and right swing motor 6 or may be smaller than the angle. By setting the angle corresponding to the maximum movable range of the movable body 4 to the first angle α, the position of the sleeping person 300 can be detected more reliably. In the example of FIG. 4, the first angle α is an angle smaller than 180 degrees, but the first angle α may be 180 degrees or more or 360 degrees.

According to the present embodiment, the following effects can be obtained.
Since the position of the sleeping person 300 can be automatically detected, the user does not have to finely adjust the orientation of the fan 1 before entering the bed 200. Therefore, the usability is good.
Since the human body detection sensor 4e can be oscillated by using the left and right swing motor 6, it is not necessary to separately provide an actuator for scanning the field of view of the human body detection sensor 4e. Therefore, the structure can be simplified and the manufacturing cost can be reduced.
In the swing and blow operation, since the air is blown toward the sleeping person 300, it is possible to suppress the useless blowing in the direction in which there are no people. For this reason, efficient ventilation is possible. If the wind is continuously applied to the sleeping person 300 without swinging the blowing direction, there is a possibility that the sleeping person 300 may become too cold, which may result in cold sleep. On the other hand, in the swinging and blowing operation, the position where the wind hits in the body of the sleeping person 300 changes, which is advantageous in reliably preventing excessive cooling of the body.

  At the time of the human position detection operation, the control unit 9 may rotate the fan 4a or may stop the fan 4a. If the fan 4a is rotated at the time of the human position detection operation, it is possible to apply a wind to the sleeping person 300 even before the start of the swing and blow operation. Power consumption of the fan motor 4b can be suppressed if the fan 4a is stopped at the time of the human position detection operation.

  At the time of the human position detection operation, the control unit 9 may detect the position of the sleeping person 300 while adjusting the direction of the movable body 4 by the vertical movement motor 7. By doing so, the sleeping person 300 can be reliably caught by the field of view of the human body detection sensor 4 e, so the position of the sleeping person 300 can be detected more reliably. Moreover, at the time of swing and blow operation, the angle of the blow direction with respect to the horizontal surface can be adjusted to a more appropriate angle.

  The control unit 9 may determine the position of the sleeping person 300 based on the surface temperature distribution of the human body or the like detected by the human body detection sensor 4e. In addition, during execution of the sleeping mode, the control unit 9 goes to sleep according to the surface temperature distribution of the body of the sleeping person 300 or the body movement of the sleeping person 300 detected by the human body detection sensor 4e. The sleep state of the person 300 may be determined. In the sleep mode, the control unit 9 adjusts the air blowing direction based on information detected using the human body detection sensor 4 e and information such as the indoor temperature and humidity detected by the temperature and humidity sensor 10. It may be controlled to blow air more efficiently without waste.

  Here, the sleep state will be described. FIG. 5 is a diagram showing an example of a change in sleep state from when a person starts sleeping until he wakes up. FIG. 5 shows the relationship between the sleep depth indicating the depth of sleep and the movement of the body. The height of the vertical line indicating body movement indicates the size of body movement. High vertical lines indicate large movements.

  As shown in FIG. 5, between a person's onset of sleep and the next awakening, sleep depths 1, 2, 3, 4 are shifted in order of depth 1, 2, 3, 4 and then sleep depth 3 The sleep cycle of transitioning to 1, 2, 1 REM sleep is usually repeated in about 90 minutes. In addition, the sleeping time from when a person starts sleeping until waking up is a relatively deep first half time zone (hereinafter referred to as "first half sleep") and a relatively late second half time zone It can be considered separately (hereinafter referred to as “the second half of sleep”). In the first half of sleep, sleep is deep and relatively insensitive to external stimuli such as air flow and temperature and humidity. On the other hand, in the second half of sleep, sleep is shallow, sleep depths 3 and 4 are less likely to occur, and it becomes easy to respond to external stimuli. The deeper the sleep, the less the body movement. Therefore, the control unit 9 can estimate the sleep state of the sleeping person 300 from the frequency of the body movement detected using the human body detection sensor 4 e, for example.

  The control unit 9 may be, for example, as follows. The control unit 9 stores the time when the human body detection sensor 4 e detects the body movement of the sleeping person 300. And the control part 9 compares the total frequency | count of the body movement which generate | occur | produced in the past fixed time, and the threshold value for discriminate | determining a sleep state, and estimates a sleep state from the comparison result. Further, the control unit 9 compares the time width in which the body movement is detected, that is, the time from when the body movement is detected to the next time the body movement is detected, with the threshold, and estimates the sleep state from the comparison result. May be Alternatively, the control unit 9 may estimate the sleep state by another method. As described above, the control unit 9 can determine whether the sleep of the sleeping person 300 has shifted from the first half of the relatively deep sleep state to the second half of the relatively shallow sleep state.

  Next, an example of the operation of the fan 1 according to the first embodiment will be further described. FIG. 6 is a flowchart showing an operation example of the electric fan 1 in the sleep mode according to the first embodiment. The user can place the fan 1 at a position where the wind can reach the bed 200 and operate the operation unit 8 to start the operation in the sleep mode. In addition, the user may start the operation in the sleep mode by remotely operating the fan 1 with the remote control device or the portable information terminal 100 in a state where the user enters the bed 200.

  When the sleep mode is started, the control unit 9 first detects the temperature and humidity of the room by the temperature and humidity sensor 10 in step S1 so as to obtain an appropriate air volume according to the detected temperature and humidity of the room. , And the air volume by the fan 4a and the fan motor 4b.

  Next, the control unit 9 causes the movable body 4 to swing in the range of the first angle α by the left and right swing motor 6 as step S2, and performs sensing by the human body detection sensor 4e as step S3. Detect the position of In this example, the processes of steps S2 and S3 correspond to the human position detection operation.

  FIG. 7 is an explanatory drawing showing an example of the detection result of the human position detection operation in the first embodiment. Hereinafter, with reference to FIG. 7, an example of a detection result of the human position detection operation will be described. FIG. 7 corresponds to a map showing the temperature distribution of the region including the bed 200 detected by the human position detection operation. In the example shown in FIG. 7, it is assumed that the human body detection sensor 4e has an infrared sensor array (not shown) in which a plurality of infrared sensors are arranged in the vertical direction. Each infrared sensor can receive infrared light from the range of viewing angles and detect the temperature in the range of viewing angles. The detected temperature of each infrared sensor corresponds to each cell in FIG. 7. The control unit 9 records the detection temperature of each infrared sensor while scanning the detection range by the infrared sensor array of the human body detection sensor 4e with the left and right swing motor 6 in the left and right direction, as shown in FIG. The temperature distribution of the area including bed 200 can be mapped.

  Since summertime room temperature is typically considered to be in the range of 20 ° C. to 30 ° C., human body temperature can be considered to be higher than room temperature. In the example of FIG. 7, white cells indicate relatively low temperature regions, and hatched cells indicate relatively high temperature regions. The control unit 9 determines that a relatively low temperature area indicated by a white cell is an area indicating room temperature, that is, an area that is not a human body. In addition, the control unit 9 determines that a relatively high temperature area indicated by the hatched cells corresponds to the area occupied by the human body, that is, the sleeping person 300. For example, as described above, the control unit 9 can specify the position of the sleeping person 300 and the area occupied by the sleeping person 300.

  Returning to the flowchart of FIG. 6, the description will be continued. When the human position detection operation is finished, the control unit 9 blows air toward the sleeping person 300 while causing the movable body 4 to swing in the range of the second angle β by the left and right swing motor 6 as step S4. Swing air blowing operation. In the swing and blow operation, the following may be performed. The control unit 9 may adjust the size and the range of the second angle β based on the information detected in the human position detection operation. The control unit 9 may adjust the size and range of the second angle β so that the wind hits the entire body of the sleeping person 300. Alternatively, the control unit 9 may adjust the size and range of the second angle β such that the wind hits only a partial region of the sleeping person's 300 body.

  In the swing and blow operation, the control unit 9 adjusts the size and range of the second angle β so as to blow toward the sleeping person's 300 body while avoiding the sleeping person's 300 head. It is also good. That is, the control unit 9 sets the size of the second angle β such that the wind does not directly hit the head of the sleeping person 300 as much as possible and the wind directly hits the body other than the head of the sleeping person 300. And the range may be adjusted. Generally, a person's head promotes heat radiation if the air does not have a feeling of blowing, but if the air volume is such that it feels like wind, it interferes with sleep or promotes dryness, which also affects respiration. There is a possibility of getting out. By avoiding the head of the sleeping person 300 and blowing air, such an event can be more reliably prevented, and the usability is further improved.

  The control unit 9 can specify the position of the head of the sleeping person 300 as follows, for example. The face is exposed while the body is covered by clothes or bedding. For this reason, the temperature detected from the surface of the face is considered to be higher than the temperature detected from the surface of the body. Therefore, in the example shown in FIG. 7, it is possible to identify the area with the highest temperature among the high-temperature areas as the position of the head of the sleeping person 300. Alternatively, by making the resolution of the mapping of the temperature distribution higher than the example shown in FIG. 7, the shape of the whole body of the sleeping person 300 can be detected more accurately, and the head of the sleeping person 300 from the whole body shape. The position of can be identified. When the human body detection sensor 4e is provided with an infrared camera or thermography, the position of the head of the sleeping person 300 should be specified from the image of the whole body of the sleeping person 300 taken by the infrared camera or thermography. Can.

  In the present embodiment, the control unit 9 performs sleep detection that determines the sleep state of the sleeping person 300 at step S5 in the middle of the swing and blow operation. As described above, the control unit 9 can determine the sleep state of the sleeping person 300 based on, for example, the body movement detected by the human body detection sensor 4e. In step S5, the control unit 9 determines whether or not the sleep of the sleeping person 300 has shifted from the first half of relatively deep sleep to the second half of relatively shallow sleep. If the sleep of the sleeping person 300 is in the first half of sleep and has not yet shifted to the second half of the sleep, the control unit 9 returns to step S3 and continues the human position detection and the swing air blowing operation. Since the position of the sleeping person 300 may change the position of sleeping due to body movement, the position of the sleeping person 300 is detected again by detecting the position of the person in step S3, and the movement of the sleeping person 300 is performed. Thus, the size and range of the second angle β can be readjusted. Further, the control unit 9 may execute the human position detecting operation by the swinging operation in the range of the first angle α again so as to return from step S5 to step S2. Thereby, even when the position of the sleeping person 300 moves largely, the position of the sleeping person 300 can be detected more reliably.

  In step S5, the control unit 9 may perform as follows. The control unit 9 detects the body movement of the sleeping person 300 by the human body detection sensor 4e, and determines the sleep state. When the body movement speed for a certain period of time is smaller than a predetermined threshold, or when the magnitude of body movement is smaller than a predetermined threshold, the control unit 9 determines that the sleeping state of the sleeping person 300 is the first half of sleep Determine that there is. The body movement repeats growing and disappearing as shown in FIG. The control unit 9 determines the progress of sleep of the sleeping person 300 by detecting the body movement by the human body detection sensor 4e. After a while, when the body motion number detected by the human body detection sensor 4e becomes larger than the threshold or the magnitude of the body movement becomes larger than the threshold, the controller 9 sleeps. It is determined that the sleep state of the person 300 is shallow, and it is determined that the second half of the sleep has shifted.

  If the sleep state of the sleeping person 300 shifts to the second half of the sleep, the control unit 9 ends the swing and blow operation, proceeds to step S6, and reduces the air volume. This makes it possible to prevent the sleep of the user (sleeping person 300) whose sleep has become shallow by shifting to the second half of the sleep. In step S6, the swinging operation by the left and right swing motor 6 may be stopped to maintain the blowing direction in a fixed direction.

  Next, at Step S7, the control unit 9 detects the position of the sleeping person 300 again by the human body detection sensor 4e. Subsequently, at Step S8, the control unit 9 performs a person-friendly air blowing operation. In this human-friendly air-blowing operation, the control unit 9 moves the movable body 4 upward as shown in FIG. Blow air. As a result, the circulation of air throughout the room can be obtained, so that the user can get hot without disturbing the sleep of the user (sleeping person 300) whose sleep has become shallow in the second half of sleep. It becomes possible to prevent feeling.

  As a modified example of the person-friendly air blowing operation of step S8, the direction in which the air blowing direction does not directly hit the sleeping person 300 instead of the movable body 4 being directed upward by the vertical movement motor 7 The direction of the movable body 4 may be changed by the left and right swing motor 6 so that Even in that case, an effect similar to the above effect can be obtained.

Following the process of step S8, the control unit 9 determines whether or not to end the operation in the sleep mode at step S9, and stops the operation of the fan 1 at step S12 when the operation in the sleep mode is ended. . In step S9, the end of the operation in the sleep mode is determined, for example, as follows.
When the user performs an operation to stop the operation of the fan 1 on the operation unit 8, the remote control device, or the portable information terminal 100, it is determined that the operation in the sleep mode is ended.
If it is determined that a preset end time (for example, 8 hours) has elapsed since the start of the sleep mode operation, it is determined that the sleep mode operation is to be ended.
When the wake-up time set in advance is reached, it is determined that the operation in the sleep mode is ended.
The position of the user is detected by the human body detection sensor 4e, and it is determined whether the user wakes up, and when the user wakes up, it is determined that the operation in the sleep mode is ended.

  When it is determined in step S9 that the driving in the sleep mode is not finished yet, the control unit 9 directs the human body detection sensor 4e to the person 300 who is sleeping, and the body movement of the person 300 sleeping in step S10. To determine whether the sleeping person 300 beats a turn. If it is determined that the sleeping person 300 does not turn over, the control unit 9 repeats the process after step S7 to perform a person-friendly air blowing operation.

  On the other hand, when it is determined that the sleeping person 300 beats a turn, the control unit 9 performs a ventilation operation for people as step S11. In the air blowing operation for people, the control unit 9 controls the direction of the movable body 4 so as to blow air toward the body of the sleeping person 300. The sleeping person 300 may feel hot and knock over if there is a fever between the body and the bedding. Therefore, when the sleeping person 300 beats a turn, the user blows air toward the sleeping person's 300 body, thereby reducing the heat felt by the sleeping person 300. Is possible. As in this example, when the posture of the sleeping person 300 changes in the sleep mode, it is possible to improve the comfort of the sleeping person 300 by changing at least one of the blowing direction and the air flow rate. It becomes.

  After continuing the person-directed air-blowing operation at step S11 for a predetermined time, the control unit 9 shifts from the person-directed air-blowing operation to the person-oriented air-blowing operation again by repeating the processes after step S7.

  As described above, according to the present embodiment, the position of the sleeping user is detected by the human body detection sensor 4e provided in the fan 1, and the sleeping state is determined to match the status of the user. By performing the air blowing, it is possible to perform the air blowing control more precisely than the air blowing control in the air conditioner. In addition to energy saving as compared with air conditioners, it is also advantageous for preventing cold from falling asleep, and can provide users with good quality sleep. In addition, since the human body detection sensor 4e is installed on the movable body 4, the human body can be detected in a wide area without requiring a separate drive mechanism, so that it can be configured inexpensively.

  FIG. 8 is a diagram showing another operation example of the electric fan 1 in the sleep mode according to the first embodiment. When in the sleep mode, the control unit 9 may perform control based on the operation example shown in FIG. 8 instead of the operation example shown in the flowchart of FIG. In the operation example of FIG. 6, the blowing direction and the air flow rate are changed according to the progress of sleep and the presence or absence of turning over, but in the operation example shown in FIG. Change the blowing direction and the air volume accordingly.

  Hereinafter, an operation example shown in FIG. 8 will be described. In FIG. 8, the progress stages of sleep are divided into three stages of “the first half of sleep”, “the second half of sleep”, and “nearly getting up”. The method by which the control unit 9 determines the transition from the first half of sleep to the second half of sleep is as described above. As a method for the control unit 9 to determine the transition from the second half of sleep to the near getting up, for example, when the user's body movement further increases or increases, it may be determined as being near getting up; If the wake-up time is near, it may be determined that the wake-up is approaching. The column of "turnover" in FIG. 8 indicates the control content when it is detected that the user has turned over. On the other hand, the "normal" column shows the control contents when the user does not turn over. In the column of "wind direction", "あ て" means swing air blowing operation or air blowing operation for people, "よ" means people blowing air blowing, and "OFF" means stop the fan 4a. "Large", "medium" and "small" in the column of "air volume" mean each step in the case of adjusting the rotational speed of the fan 4a in three steps. Furthermore, in the example of FIG. 8, the room temperature is in the range of 22 ° C. to 25 ° C., the case in which the room temperature is in the range of 25 ° C. to 28 ° C., and the case where the room temperature is 28 ° C. or more. Change the direction and air flow.

  It goes without saying that the human's thermal sensation changes according to the room temperature. In addition, since it is considered that there are both a user who uses the fan 1 with the air conditioner and a user who uses the fan 1 without using the air conditioner, the fan 1 is used under various room temperatures. It is considered to be When not used in combination with an air conditioner, it is also conceivable that the room temperature becomes, for example, a heat environment of 28 ° C. or higher. In a hot environment of 28 ° C. or more, it is considered that sleep users feel hot and awakening increases. Therefore, in the example of FIG. 8, when the room temperature is 28 ° C. or higher, the swing air blowing operation or the person-oriented air blowing operation is performed in the second half of sleep even if there is no turning over. Thereby, in the case of a heat environment of 28 ° C. or more, it is possible to reliably reduce the heat felt by the user in the second half of sleep. On the other hand, when the room temperature is 25 ° C. or lower, it is considered that there is a person who feels cold when performing the air blowing operation in the second half of sleep. Therefore, in the example of FIG. 8, when there is no turning over in the second half of sleep, the fan 4 a is stopped when the room temperature is 25 ° C. or less.

  Further, in the example of FIG. 8, information on indoor humidity may be further used for control. In the sleep mode, the user can sleep better by changing at least one of the blowing direction and the air volume according to the room information on the room temperature and / or humidity and the sleeping state of the sleeping person 300. It will be more advantageous in providing

  A user interface is provided that allows the user to customize at least one of the blowing direction and the air volume in the sleeping mode, and the control unit 9 adjusts at least one of the blowing direction and the air volume in the sleeping mode according to the information received from the user interface May be For example, when the portable information terminal 100 such as a smartphone downloads a dedicated application, the portable information terminal 100 may be usable as the user interface. Alternatively, the operation unit 8 or the remote control device of the fan 1 may have the function of the user interface. There are individual differences in thermal sensation, and thermal sensation also differs depending on the difference in bedding or nightwear. Therefore, by allowing the user to customize at least one of the blowing direction and the air volume in the sleep mode, it is possible to perform more appropriate control corresponding to the individual difference of the user. In the above user interface, for example, the user can select each item by a pull-down menu, or can set each setting for each sleep progression stage, or set each setting for each time zone interval You may be able to When the portable information terminal 100 can be used as the user interface, the operation unit 8 and the remote control device do not need to have the above functions. Therefore, the operation switches of the operation unit 8 and the remote control device can be reduced. .

  In addition, the control unit 9 may transmit information on the sleep state detected using the human body detection sensor 4e as sleep information to the user interface, and the sleep information may be displayed on the display of the user interface. . Sleep information includes, for example, bedtime, wake-up time, sleep depth, and sleep efficiency. By doing so, it becomes possible for the user to confirm daily sleep information and to be useful for health management.

  In addition, when the user detected by the human body detection sensor 4 e is a child in the sleep mode, the control unit 9 takes into consideration that the surface area of the body is smaller than in the case of an adult user. You may control so that a wind volume may become low. For example, in the example illustrated in FIG. 7, the control unit 9 may determine that the user is a child when the area of the high temperature part corresponding to the area of the human body is smaller than the threshold.

Second Embodiment
Next, Embodiment 2 will be described with reference to FIGS. 9 and 10, but differences from Embodiment 1 described above will be mainly described, and the description of the same or corresponding portions will be simplified or I omit it.

  FIG. 9 is a side view of the inside of a bedroom provided with an air conditioning system according to a second embodiment. FIG. 10 is a block diagram showing a configuration of a control system of the air conditioning system according to the second embodiment. As shown in these drawings, the air conditioning system of the present embodiment includes an air conditioner 11 and a fan 12.

  As shown in FIG. 9, the air conditioner 11 is attached to the wall 401 of the bedroom 400 at a position close to the ceiling 402. In the bedroom 400, a bed 500 is placed. The air conditioner 11 includes a human body detection sensor 13. The human body detection sensor 13 corresponds to a human body detection unit capable of detecting the position of the person 600 sleeping on the bed 500. The human body detection sensor 13 has the same configuration as the human body detection sensor 4 e of the first embodiment. Since the human body detection sensor 13 provided in the air conditioner 11 is at a high position, a wide space can be captured in the field of view without changing the direction of the human body detection sensor 13.

  Alternatively, the air conditioner 11 includes an actuator (not shown) that changes the direction of the human body detection sensor 13, and changes the direction of the human body detection sensor 13 using the actuator to obtain the human body detection sensor 13 over the entire bedroom 400. The field of view may be scanned. Alternatively, the human body detection sensor 13 may be attached to a movable louver (not shown) included in the air conditioner 11, and the field of view of the human body detection sensor 13 may be scanned by moving the movable louver.

  As shown in FIG. 10, the air conditioner 11 includes at least an air conditioning function unit 14 capable of performing cooling, a control unit 15 for controlling the operation of the air conditioning function unit 14 and the like, and an operation unit 16 operated by a user. And a temperature / humidity sensor 17 for detecting room temperature and humidity. The air conditioning function unit 14 may be capable of performing heating and dehumidification. The control unit 15 of the air conditioner 11 can wirelessly communicate with the remote control device of the air conditioner 11 or the portable information terminal 100.

  The control unit 9 of the fan 12 includes communication means capable of communicating with the control unit 15 of the air conditioner 11. Further, the fan 12 has the same configuration as the fan 1 of the first embodiment except that the human body detection sensor 4 e and the temperature and humidity sensor 10 are not provided. The air conditioner 11 and the fan 12 can communicate with each other to share various data, so the air conditioner 11 and the fan 12 can operate in cooperation with each other. The controller 9 of the fan 12 may be capable of wireless communication with the portable information terminal 100.

  The control unit 15 of the air conditioner 11 controls the position of the sleeping person 600, the range occupied by the sleeping person 600, and the sleeping state of the sleeping person 600 in the same manner as the first embodiment using the human body detection sensor 13. And the depth of sleep etc. can be detected. The control unit 9 of the fan 12 receives the detected information from the control unit 15 of the air conditioner 11. The control unit 9 of the fan 12 operates in the sleep mode based on the received information. For example, in the sleep mode, the control unit 9 of the fan 12 shakes the movable body 4 and blows the air toward the sleeping person 600 based on the information on the position of the sleeping person 600. You may In addition, the control unit 9 of the fan 12 may perform the same operation as that of the first embodiment.

  Thus, according to the second embodiment, the same effect as the first embodiment can be obtained. Further, by providing the human body detection sensor 13 in the air conditioner 11 at a high position, it is advantageous for looking over the entire room at a wide directional angle. Furthermore, since room temperature adjustment that can not be performed by the fan 12 alone can also be performed, it is possible to provide the user with better sleep.

  The control unit 15 of the air conditioner 11 detects the position of the fan 12 and also detects the position information of the sleeping person 600 detected by the human body detection sensor 13 with the position information in the coordinate system as viewed from the position of the fan 12. It may be transmitted to the control unit 9 of the fan 12 after coordinate conversion as described above. For example, when the human body detection sensor 13 includes a camera, the position of the fan 12 can be detected by processing an image captured by the camera.

  In the embodiment described above, although the fan having the fan and the fan motor in the movable body swingingly operating with respect to the pedestal portion has been described, for example, the fan and the fan motor are mounted on the pedestal portion in the present disclosure. It is also possible to apply to a fan that is provided with a blower that has a nozzle that sends out the wind to the outside and that is provided on the movable body that oscillates and that blows the air flow generated by the fan of the pedestal through the duct of the movable body. It is.

Reference Signs List 1 fan, 2 pedestals, 3 columns, 4 movable bodies, 4a fans, 4b fan motors, 4c front guards, 4c rear guards, 4e human body detection sensors, 5 motor storage units, 6 left and right swing motors, 7 vertical motion motors , 8 operation unit, 9 control unit, 10 temperature and humidity sensor, 11 air conditioner, 12 fan, 13 human body detection sensor, 14 air conditioning function unit, 15 control unit, 16 operation unit, 17 temperature and humidity sensor, 100 mobile information terminal, 200 beds, 300 sleeping people, 400 bedrooms, 401 walls, 402 ceilings, 500 beds, 600 sleeping people

Claims (13)

A movable body having a blower for sending wind to the outside, and a human body detection means capable of detecting a human body;
Drive means for oscillating the movable body;
Control means capable of setting a sleep mode as an operation mode;
Equipped with
In the sleep mode, a person position detection operation for detecting the position of a sleeping person by swinging the movable body in a range of a first angle, and a second angle smaller than the first angle An electric fan including an oscillating air blowing operation for blowing air to the sleeping person while oscillating in a range of.   The fan according to claim 1, wherein the fan blows air toward the body of the sleeping person while avoiding the head of the sleeping person in the swing and blow operation.   The fan according to claim 1, wherein the control unit can determine a sleep state of the sleeping person.   The control means is capable of determining whether or not the sleep of the sleeping person has shifted from a relatively deep sleep first half to a relatively low sleep second sleep. The fan according to any one of the preceding claims.   The fan according to claim 4, wherein when the first half of the sleep shifts to the second half of the sleep, at least one of a blowing direction and an air volume is changed.   The electric fan according to claim 4, wherein when transitioning from the first half of the sleep to the second half of the sleep, the air volume to the sleeping person is reduced or the air is blown in a direction not directly hitting the sleeping person.   The air conditioner according to any one of claims 3 to 6, wherein, in the sleep mode, at least one of a blowing direction and an air volume is changed according to room information on at least one of room temperature and humidity and a sleeping state of the sleeping person. A fan according to any one of the items.   The fan according to any one of claims 1 to 7, wherein the sleeping mode includes a person-friendly air blowing operation to blow air in a direction that does not directly hit the sleeping person. A second driving means for moving the movable body so as to change an angle of a blowing direction with respect to a horizontal surface;
The fan according to any one of claims 1 to 7, wherein the sleeping mode includes a person-oriented air blowing operation for blowing air to a space above the sleeping person.   The fan according to any one of claims 1 to 9, wherein in the sleep mode, when the posture of the sleeping person changes, at least one of a blowing direction and an air volume is changed.   The control means adjusts at least one of the blowing direction and the air flow rate in the sleeping mode according to the information received from the user interface that allows the user to customize at least one of the air blowing direction and the air flow rate in the sleep mode. The fan as described in any one of claim | item 10. An air conditioner,
With a fan,
Equipped with
The air conditioner comprises a human detection means capable of detecting the position of a sleeping person,
The fan is
A movable body having a blower that sends out wind to the outside;
Drive means for oscillating the movable body;
Control means capable of setting a sleep mode as an operation mode;
Communication means for receiving information from the air conditioner regarding the position of the sleeping person;
Equipped with
An air conditioning system including a swing and blow operation in which the sleeping mode blows air to the sleeping person while swinging the movable body.   13. The apparatus according to claim 12, wherein the control means adjusts at least one of the blowing direction and the air flow rate in the sleeping mode according to the information received from the user interface that allows the user to customize at least one of the air blowing direction and the air flow rate in the sleep mode. Air conditioning system.

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