FIELD OF THE INVENTION
[0001] The present invention relates to an air conditioner that controls an outdoor unit
in accordance with the number of people in a room detected by an infrared sensor,
for example.
BACKGROUND OF THE INVENTION
[0002] With a prior-art air conditioner, when air conditioning is automatically turned ON
by a timer or on the basis of schedule data set in advance, a detection operation
for presence of a human body is performed by a radiation sensor disposed in an indoor
unit, and when no human body is present, air-conditioning capacity is saved to an
efficient region and controlled so that an indoor temperature gradually reaches a
set temperature (Patent document No. 1, for example). With another prior-art air conditioner,
a detection operation for the presence of a human body is performed by an infrared-ray
detecting portion which determines for each part of a room if a human body is present
or not depending on a temperature difference of said part of the room compared to
the general room temperature (Patent document No. 2).
SUMMARY OF THE INVENTION
[0004] With the prior-art air conditioner, while it is being detected that a human body
is not present, an operating frequency of a compressor is set in a high operating
efficiency state such as 60 Hz, for example, and operation control according to the
number of people is not executed.
[0005] The present invention was made in order to solve the above problem and has an object
to provide an air conditioner that controls an operation of a compressor in accordance
with presence of people or the number of people in a room in which an indoor unit
is installed.
[0006] An air conditioner according to the present invention is provided with an outdoor
unit having a compressor, an indoor unit connected to the outdoor unit via an extended
pipeline, a human detection sensor, a remote controller, an indoor control section
that starts the human detection sensor when an instruction to detect a human body
is received from the remote controller, generates an image of the inside of the room
on the basis of detection information of the human detection sensor, determines whether
a human body is present or not from the image, determines the number of the people
if a human body is present, and calculates an operating frequency on the basis of
information of the determination result, and an outdoor control section that controls
the compressor on the basis of the operating frequency calculated by the indoor control
section.
[0007] In the present invention, the human detection sensor is started when an instruction
to detect a human body is received from the remote controller, an image of the inside
of the room is generated on the basis of the detection information of the human detection
sensor, it is determined if a human body is present or not from the image, the number
of people is determined as well when a human body is present, and the operating frequency
of the compressor is calculated on the basis of the information of the determination
result. As a result, as compared with the prior-art case in which the operating frequency
of the compressor is controlled on the basis of temperature information, required
cooling/heating capacity can be provided earlier, and thus, comfort felt by human
beings can be improved, excess or shortage of the capacity can be solved as soon as
possible, and energy can be saved.
BRIEF DESCRIPTION OF THE DRAWINGS
[0008]
Fig. 1 is a schematic diagram illustrating an entire configuration of an air conditioner
illustrating an embodiment of the present invention;
Fig. 2 is a perspective view illustrating an appearance of an indoor unit of the air
conditioner according to the embodiment of the present invention;
Fig. 3 is a sectional view illustrating a side face of the indoor unit in Fig. 2 in
a cut-away manner;
Fig. 4 is a perspective view illustrating an installation example of the indoor unit
in Fig. 2;
Figs. 5 are flowcharts illustrating an operation of the air conditioner according
to the embodiment of the present invention;
Fig. 6 is a correlation diagram between a detected number of people and a required
operating frequency of a compressor in the embodiment of the present invention; and
Fig. 7 is a correlation diagram between the detected number of people and a required
maximum operating frequency of the compressor in the embodiment of the present invention.
DESCRIPTION OF THE PREFERRED EMBODIMENTS
[0009] Fig. 1 is a schematic diagram illustrating an entire configuration of an air conditioner
according to an embodiment of the present invention, Fig. 2 is a perspective view
illustrating an appearance of an indoor unit of the air conditioner according to the
embodiment of the present invention, Fig. 3 is a sectional view illustrating a side
face of the indoor unit in Fig. 2 in a cut-away manner, and Fig. 4 is a perspective
view illustrating an installation example of the indoor unit in Fig. 2.
[0010] The air conditioner in Embodiment 1 is, as shown in Fig. 1, composed of an indoor
unit X, an outdoor unit Y, a remote controller Z, a liquid extended pipeline A and
a gas extended pipeline B that connect the indoor unit X and the outdoor unit Y, a
communication line C wired between the remote controller Z and an indoor control section
X1 of the indoor unit X and between the indoor control section X1 and an outdoor control
section Y1 of the outdoor unit Y, respectively, and an infrared sensor 5 (See Fig.
2), for example, which is a human detection sensor. The above-described indoor unit
X is installed mainly in a building or is embedded in a ceiling, for example (See
Fig. 4). It was described above that the remote controller Z and the indoor control
section X1 are connected to each other by the communication line C, but information
transmission/reception may be conducted via radio communication therebetween. The
infrared sensor 5 is disposed on a decorative panel 2 of the indoor unit X, to be
described later.
[0011] When an operation instruction (cooling operation, heating operation, dehumidification
operation and the like) is received from the remote controller Z, the indoor control
section X1 transmits the operation instruction to the outdoor control section Y1 of
the outdoor unit Y and also drives a fan motor 6, which will be described later, on
the basis of the operation instruction. Also, when an instruction to detect a human
body from the remote controller Z such as an instruction to start an initial operation
after an installation of this air conditioner or an instruction to obtain a background
image inside the room, for example, is received, the indoor control section X1 starts
the infrared sensor 5, generates a heat image inside the room on the basis of detection
information of the infrared sensor 5 and stores the heat image as a background image.
[0012] Also, when an instruction to detect a human body from the remote controller Z or
an instruction to start an energy-saving operation, for example, is received after
the background image was obtained, the indoor control section X1 starts the infrared
sensor 5 and generates a heat image inside the room on the basis of the detection
information of the infrared sensor 5. Then, the indoor control section X1 determines
whether a human body is present or not by comparing the heat image with the background
image inside the room stored in advance and determines the number of people if a human
body is present and calculates an operating frequency of the compressor of the outdoor
unit Y on the basis of the information of the determination result. The determination
of the number of human bodies and the calculation of the operating frequency will
be described in detail when an operation is described.
[0013] When an operation instruction from the remote controller Z is received through the
indoor control section X1, the outdoor control section Y1 controls the compressor
with the operating frequency according to the operation instruction and when the operating
frequency calculated by the indoor control section X1 is received, the outdoor control
section Y1 controls the compressor on the basis of the operating frequency. That is,
the more the operating frequency is increased, the higher the rotation speed of the
compressor is raised, while the more the operating frequency is decreased, the lower
the rotation speed of the compressor is lowered. In the above-described outdoor unit
Y, a heat exchanger, an expansion valve and the like are disposed in addition to the
above-described compressor.
[0014] An appearance of the indoor unit X is, as shown in Fig. 2, composed of a box-shaped
cabinet 1, the decorative panel 2 in a square shape disposed below the cabinet 1,
a square-shaped inlet 3b disposed at the center of the decorative panel 2, four rectangular
blow-out ports 3a disposed in the decorative panel 2 so as to surround the inlet 3b,
and wind-direction flaps 4 that are disposed on the blow-out ports 3a and change the
wind direction in the vertical direction. On a lower face at a corner of the decorative
panel 2, the infrared sensor 5 is mounted.
[0015] In the cabinet 1 of the indoor unit X, as shown in Fig. 3, a fan motor 6 having a
load shaft directed downward arranged at the center of the top face of the cabinet
1, a turbo fan 7 mounted on the load shaft of the fan motor 6, a heat exchanger 8
arranged so as to surround the turbo fan 7, an inner cover 9 arranged so as to surround
the heat exchanger 8, a drain pan 10 installed below the heat exchanger 8 and receiving
condensed water generated during heat exchange, and a temperature sensor 13 that detects
a temperature of air sucked through the inlet 3b are disposed. The above-described
inner cover 9 is provided to insulate the air heat-exchanged by the heat exchanger
8 from outside the unit, and the heat exchanger 8 and the drain pan 10 constitute
an air path on an outer periphery of the heat exchanger 8. The air path communicates
with the blow-out port 3a. Below the drain pan 10, an opening portion communicating
with the inlet of the turbo fan 7 is disposed.
[0016] On the inlet 3b of the decorative panel 2, an air filter 11 that prevents intrusion
of dusts and the like into the unit and a grill 12 that supports the air filter 11
and also functions as a blind are disposed. Moreover, between the air filter 11 and
the turbo fan 7, a bell mouth 14 that introduces sucked air into the turbo fan 7 smoothly
is disposed.
[0017] The above-described infrared sensor 5 is composed of a multi-eye infrared sensor
or a plurality of infrared sensors and installed within a sensor case 5b. The sensor
case 5b is contained in a housing 5a having an outer shape of a substantially cone
formed at one corner of a decorative panel 2 and mounted on the vertical direction
axis of a motor 5c, capable of rotating in 360 degrees. The infrared sensor 5 is composed
of a plurality of detection sections, and the detection sections are exposed from
a hole 5d disposed in a projection portion of the housing 5a and arranged in parallel
with a normal line of a circle of the hole 5d.
[0018] Subsequently, an operation on the basis of a human body detection of the infrared
sensor 5 in the air conditioner configured as above will be described using Fig. 5.
Description on a basic operation of the air conditioner will be omitted.
[0019] Figs. 5 are flowcharts illustrating an operation of the air conditioner according
to the embodiment of the present invention. Fig. 5A is a flowchart when obtaining
a background image inside the room in which the indoor unit X is installed, and Fig.
5B is a flowchart illustrating detection of the number of people present in the same
room and calculation of the operating frequency of the compressor according to the
number of people.
[0020] When start of an initial operation is detected from a switch operation of the remote
controller Z (S1), the indoor control section X1 rotates the infrared sensor 5 by
360 degrees at a rate of approximately once in several minutes to several seconds
by a motor driving force (S2). At this time, the indoor control section X1 generates
a two-dimensional heat image on the basis of detection information (indoor information)
of the infrared sensor 5 obtained by a trajectory axis by the rotation and the axis
in the alignment direction of the infrared sensor 5 (S3) and stores it as a background
image (S4). The background image may be obtained either during the operation of the
air conditioner or during the stop thereof.
[0021] When start of an energy-saving operation is detected from the switch operation of
the remote controller Z after the background image was obtained (S11), the indoor
control section X1 rotates the infrared sensor 5 once as described above (S12) and
generates the two-dimensional heat image on the basis of the detection information
of the infrared sensor 5 obtained at this time (S13). Then, the indoor control section
X1 obtains a difference between the two-dimensional heat image and the background
image stored in advance (S14) and performs grouping of pixels from the difference
so as to sort out an image assumed to be an object (S15).
[0022] The indoor control section X1 determines whether an average temperature T of the
sorted-out image portion is a threshold value Ta or more and a threshold value Tb
or less (S16). If the average temperature T is not within the range, the indoor control
section X1 determines that a human body is not present in the room, and proceeds to
determine whether there is a subsequent grouping or not (S19). Also, if the average
temperature T is the threshold value Ta or more and the threshold value Tb or less,
the indoor control section X1 determines whether the number of pixels in that portion
is a threshold value Sa or more (S17). If the number of pixels is less than the threshold
value Sa, the indoor control section X1 determines that there is no human body in
the room and proceeds to determine whether there is another grouping or not similarly
to the above (S19). If it is determined that the number of pixels is the threshold
value Sa or more, the indoor control section X1 determines that there is a human body
in the room (S18) and determines whether there is a subsequent grouping or not (S19).
[0023] The indoor control section X1 repeats the above-described operation if there is a
subsequent grouping (S16 to S19) and performs this operation until there is no more
subsequent grouping. The indoor control section X1 confirms the number of people from
the confirmed human bodies when the operation is repeatedly performed (S20). Then,
the indoor control section X1 calculates an operating frequency Hzm of the compressor
required from the outdoor unit Y by a formula determined in advance according to the
number of people (S21), transmits the operating frequency Hzm to the outdoor control
section Y1 via the communication line C (S22), and operates the compressor of the
outdoor unit Y by the operating frequency Hzm (S23).
[0024] As described above, in this embodiment, when start of the energy saving operation
is detected, the infrared sensor 5 is started, a heat image is generated on the basis
of the detection information of the infrared sensor 5, and the heat image is compared
with the background image stored in advance so as to determine whether a human body
is present or not. Then, if the human body is present, the number of people is determined,
the operating frequency is calculated on the basis of the information of the determination
result, and the compressor is controlled by the operating frequency. As a result,
as compared with the case in which the operating frequency of the compressor is controlled
on the basis of the temperature information, required cooling/heating capacity can
be provided earlier, and thus, comfort felt by human beings is improved, excess or
shortage of the capacity can be solved as soon as possible, and energy saving can
be realized.
[0025] In this embodiment, the operating frequency of the compressor is determined in accordance
with the number of people present in the room as shown in Fig. 6, but not limited
to that. For example, as shown in Fig. 7, it may be so configured that the number
of people is divided into three stages, that is, 0 people, 1 to 10 people, and 10
people or more, the maximum value of the operating frequency of the compressor in
each case is determined in advance, which one of the three stages is specified from
the number of people on the basis of the detection by the infrared sensor 5 and the
maximum frequency value is determined, and the compressor of the outdoor unit Y is
operated by the maximum frequency value.
[0026] The following contents are also performed at the same time in order to further save
energy. After the number of people in the target room is detected using the infrared
sensor, a set temperature of the remote controller Z is changed in accordance with
the number of people. For example, suppose that a user has set the set temperature
at 27°C during cooling. Subsequently, the number of people in the target indoor space
is detected using the infrared sensor 5, the temperature is raised by 2°C in the case
of 0 people, the temperature is raised by 1°C in the case of 1 to 10 people, and the
temperature is left as it is in the case of 10 people or more, and the result is transmitted
to the outdoor control section Y1 of the outdoor unit Y via the communication line
C. This mode is made effective only if the user has selected an energy saving operation
by the remote controller Z.
DESCRIPTION OF THE NUMERALS
[0027]
X: indoor unit, X1: indoor control section, Y: outdoor unit, Y1: outdoor control section,
Z: remote controller, A: liquid extended pipeline, B: gas extended pipeline, C: communication
line, 1: cabinet, 2: decorative panel, 3a: blow-out port, 3b: inlet, 4: wind-direction
flap, 5a: housing, 5b: sensor case, 5c: motor, 5d: hole of housing, 6: fan motor,
7 turbo fan, 8: heat exchanger, 9: inner cover, 10: drain pan, 11: air filter, 12:
grill, 13: temperature sensor, 14: bell mouth.
1. An air conditioner comprising:
an outdoor unit (Y) having a compressor;
an indoor unit (X) connected to said outdoor unit(Y) via an extended pipeline;
a human detection sensor;
a remote controller (Z); characterised by an indoor control section (X1) that starts said human detection sensor when an instruction
to detect a human body is received from said remote controller (Z), generates an indoor
image on the basis of detection information of the human detection sensor, determines
whether a human body is present or not from the image and also determines the number
of people when the human body is present, and calculates an operating frequency on
the basis of information of the determination results; and
an outdoor control section (Y1) that controls said compressor on the basis of the
operating frequency calculated by said indoor control section (X1).
2. The air conditioner of claim 1, wherein
said indoor control section (X1) starts said human detection sensor when an instruction
to detect a human body is received from said remote controller (Z), generates an indoor
image on the basis of detection information of the human detection sensor, determines
whether a human body is present or not by comparing the image with a background image
of the inside of a room stored in advance and also determines the number of people
when the human body is present, and calculates an operating frequency of said compressor
on the basis of information of the determination results.
3. The air conditioner of claim 2, wherein
said indoor control section (X1) starts said human detection sensor when an instruction
from said remote controller (Z) is an instruction to obtain the background image of
the inside of the room, generates an indoor image on the basis of the detection information
of the human detection sensor and stores the image as a background image.
4. The air conditioner of any one of claims 1 to 3, wherein
said indoor control section (X1) changes the indoor temperature set by said remote
controller (Z) in accordance with the determined number of people.
5. The air conditioner of any one of claims 1 to 4, wherein
said indoor control section (X1) changes the maximum operating frequency of said compressor
in accordance with the determined number of people.
6. The air conditioner of any one of claims 1 to 5, wherein
said human detection sensor is a multi-eye infrared sensor or a plurality of infrared
sensors.
1. Klimaanlage, enthaltend:
eine Außenbereichseinheit (Y) mit einem Kompressor;
eine Innenbereichseinheit (X), die mit der Außenbereichseinheit (Y) über eine verlängerte
Rohrleitung verbunden ist;
ein Sensor zur Erkennung von Menschen;
eine Fernbedienung (Z);
charakterisiert durch
einen Innenbereichssteuerabschnitt (X1), der besagten Sensor zur Erkennung von Menschen
startet, wenn eine Anweisung zum Erkennen eines menschlichen Körpers von besagter
Fernbedienung (Z) empfangen wird, ein Innenbereichsbild auf der Grundlage von Erfassungsinformationen
des Sensors zur Erkennung von Menschen erzeugt, aus dem Bild bestimmt, ob ein menschlicher
Körper vorhanden ist oder nicht, und auch die Anzahl der Personen bestimmt, wenn der
menschliche Körper anwesend ist, und eine Betriebsfrequenz auf der Basis von Informationen
der Bestimmungsergebnisse berechnet; und
einen Außenbereichssteuerabschnitt (Y1), der besagten Kompressor auf der Basis der
durch den Innenbereichssteuerabschnitt (X1) berechneten Betriebsfrequenz steuert.
2. Klimaanlage nach Anspruch 1, wobei der Innenbereichssteuerabschnitt (X1) den Sensor
zur Erkennung von Menschen startet, wenn eine Anweisung zum Erfassen eines menschlichen
Körpers von besagter Fernbedienung (Z) empfangen wird, ein Innenbereichsbild auf der
Grundlage von Erfassungsinformationen des Sensors zur Erkennung von Menschen bestimmt,
durch Vergleichen des Bildes mit einem Hintergrundbild des Inneren eines im Voraus
gespeicherten Raums bestimmt, ob ein menschlicher Körper vorhanden ist oder nicht,
und auch die Anzahl von Personen bestimmt, wenn der menschliche Körper vorhanden ist,
und eine Betriebsfrequenz von besagtem Kompressor auf der Grundlage von Informationen
der Bestimmungsergebnisse berechnet.
3. Klimaanlage nach Anspruch 2, wobei der Innenbereichssteuerabschnitt (X1) den Sensor
zur Erkennung von Menschen startet, wenn eine Anweisung von besagter Fernbedienung
(Z) eine Anweisung zum Erlangen des Hintergrundbildes des Inneren des Raums ist, ein
Bild des Innenraums auf der Grundlage der Erfassungsinformation des Sensor zur Erkennung
von Menschen erzeugt und das Bild als ein Hintergrundbild speichert.
4. Klimaanlage nach einem der Ansprüche 1 bis 3, wobei besagter Innenbereichssteuerabschnitt
(X1) die durch die Fernbedienung (Z) eingestellte Innentemperatur entsprechend der
bestimmten Anzahl von Personen ändert.
5. Klimaanlage nach einem der Ansprüche 1 bis 4, wobei besagter Innenbereichssteuerabschnitt
(X1) die maximale Betriebsfrequenz des Kompressors gemäß der bestimmten Anzahl von
Personen ändert.
6. Klimaanlage nach einem der Ansprüche 1 bis 5, wobei der Sensor zur Erkennung von Menschen
ein Multi-Augen-Infrarotsensor oder eine Vielzahl von Infrarotsensoren ist.
1. Climatiseur comprenant :
une unité extérieure (Y) qui présente un compresseur ;
une unité intérieure (X) connectée à ladite unité extérieure (Y) par l'intermédiaire
d'une canalisation étendue ;
un détecteur de présence humaine ;
un dispositif de commande à distance (Z) ;
caractérisé par :
une section commande intérieure (X1) qui met en marche ledit détecteur de présence
humaine quand une instruction visant à détecter un corps humain, est reçue en provenance
dudit dispositif de commande à distance (Z), qui génère une image intérieure sur la
base des informations de détection du détecteur de présence humaine, qui détermine
si un corps humain est présent ou non à partir de l'image, et qui détermine également
le nombre de personnes lorsque le corps humain est présent, et qui calcule une fréquence
de fonctionnement sur la base des informations des résultats de la détermination ;
et
une section commande extérieure (Y1) qui commande ledit compresseur sur la base de
la fréquence de fonctionnement calculée par ladite section commande intérieure (X1).
2. Climatiseur selon la revendication 1, dans lequel :
ladite section commande intérieure (X1) met en marche ledit détecteur de présence
humaine quand une instruction visant à détecter un corps humain, est reçue en provenance
dudit dispositif de commande à distance (Z), génère une image intérieure sur la base
des informations de détection du détecteur de présence humaine, détermine si un corps
humain est présent ou non en comparant l'image avec une image stockée à l'avance de
l'arrière-plan de l'intérieur d'une pièce, et détermine également le nombre de personnes
lorsque le corps humain est présent, et calcule la fréquence de fonctionnement dudit
compresseur sur la base des informations des résultats de la détermination.
3. Climatiseur selon la revendication 2, dans lequel :
ladite section commande intérieure (X1) met en marche ledit détecteur de présence
humaine quand une instruction en provenance dudit dispositif de commande à distance
(Z) est une instruction visant à obtenir l'image de l'arrière-plan de l'intérieur
de la pièce, génère une image intérieure sur la base des informations de détection
du détecteur de présence humaine, et stocke l'image en tant qu'image de l'arrière-plan.
4. Climatiseur selon l'une quelconque des revendications 1 à 3, dans lequel :
ladite section commande intérieure (X1) modifie la température intérieure fixée par
ledit dispositif de commande à distance (Z) selon le nombre de personnes déterminé.
5. Climatiseur selon l'une quelconque des revendications 1 à 4, dans lequel :
ladite section commande intérieure (X1) modifie la fréquence de fonctionnement maximum
dudit compresseur selon le nombre de personnes déterminé.
6. Climatiseur selon l'une quelconque des revendications 1 à 5, dans lequel :
ledit détecteur de présence humaine est un détecteur infrarouge à plusieurs yeux,
ou une pluralité de détecteurs infrarouges.