JP2008281239A - Indoor environment control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an indoor environment control system capable of efficiently and ergonomically controlling indoor environments such as air-conditioning and lighting in a building and the like according to arrangement of a man in the building. <P>SOLUTION: This indoor environment control system is composed of a plurality of RFID tags t1-t4 respectively storing personal ID information, a plurality of RFID tag readers R1-R6 disposed corresponding to a plurality of areas 1-6 constituting a region in a certain indoor region in a state that detection ranges D1-D6 respectively cover the areas, detecting signals from the RFID tags t1-t4 and reading out the ID information, and controllers MC and C1-C4 controlling the indoor environment by each area on the basis of a result of reading-out of the RFID tag readers R1-R6. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to an indoor environment control system for automatically controlling an indoor environment such as air conditioning and lighting in a building such as a building, and more specifically, detecting an arrangement of people in a building using an ID tag. The present invention relates to a system for realizing energy saving by efficiently and ergonomically managing the indoor environment in a building.

As a system for managing air conditioning and lighting in a building, for example, a building management system disclosed in JP-A-2-85986 has been proposed. In this system, when a person working at a workplace in a building stamps on a time recorder or an ID card reader at the time of leaving or working, the control unit compares the stamped information with information stored in advance, Based on this, the air conditioning and lighting in the building are controlled.
Japanese Patent Laid-Open No. 2-85986

  However, the conventional system only manages the air conditioning and lighting in the entire workplace, and the air conditioning and lighting in the entire workplace is turned on even when there are people in a limited area in the workplace. Therefore, the energy saving effect is poor. Further, even if air conditioning equipment and lighting equipment are individually arranged for each area, it is very troublesome to manually operate the switches of each equipment and equipment.

  The present invention has been made in view of such a conventional situation, and the problem to be solved by the present invention is that an indoor environment such as air conditioning and lighting in a building is efficiently used according to the arrangement of people in the building. It is to provide an indoor environment control system that can be controlled ergonomically and ergonomically.

  The indoor environment control system according to the first aspect of the present invention is provided corresponding to an ID tag storing personal ID information and at least one area constituting the area within a certain area in the interior, and its detection The range covers the area, an ID tag reading unit that detects a signal from the ID tag and reads ID information, and a control unit that controls the indoor environment of the area based on the reading result of the ID tag reading unit I have.

  According to the first aspect of the present invention, when a person enters an area in an indoor area while carrying the ID tag, the ID tag reading means provided in the area detects a signal from the ID tag. Read ID information. Thereby, in the indoor area, information (presence information) such as in which area people are present, how many people are present, and who is in which area is input to the control means. The control means controls the indoor environment of the area based on the reading result of the ID tag reading means. That is, for example, the control means turns on air conditioning and lighting only for an area where a person is present, and adjusts the temperature, humidity, illuminance, and the like of the area according to the number of people. In this way, the indoor environment in the building can be controlled efficiently and ergonomically.

  In the invention of claim 2, the ID information includes any one or more information of an individual identification number, gender, age or characteristic.

  In this case, the control means adjusts the temperature, humidity, illuminance, etc. of the area where the person is present according to the individual identification number, gender, age or characteristics read by the ID tag reading means.

  If the ID information is the gender of the individual, for example, an ID tag reading means provided near the entrance of the toilet or changing room reads the gender of the approaching person, and for men or women depending on the gender The lighting and air conditioning of either room are turned on. In addition, when the ID information is an individual's age, when the age read by the ID tag reading means is equal to or higher than a predetermined age, for example, the air conditioning is adjusted to be weak so that the air conditioning is not too effective. The Furthermore, when the ID information is a personal characteristic (for example, whether it is hot or cold), the air conditioning is adjusted according to the personal characteristic read by the ID tag reading means.

  The ID tag is preferably an RFID (radio frequency identification) tag as described in the invention of claim 3, more preferably an active tag among the RFID tags as described in the invention of claim 4. Is good.

  In the case of this active RFID tag, since the battery is built in and emits radio waves by itself, the reception distance can be increased. In addition, a sensor can be attached by incorporating a battery, whereby the indoor environment can be finely adjusted in real time according to a change in the environment where the active RFID tag is placed.

  In the invention of claim 5, the ID tag is an ID tag with a sensor provided with a temperature sensor, a humidity sensor or an optical sensor.

  In this case, as described above, the indoor environment can be finely adjusted in real time according to changes in the environment (temperature, humidity, illuminance) in which the ID tag exists.

  As described above, the indoor environment is any one of indoor temperature, humidity, illuminance, and the like, but these two or more environmental elements may be combined (invention of claim 6). reference).

  In the invention of claim 7, the ID tag reading means further detects the signal intensity or the signal arrival time from the ID tag.

  In this case, in the reading result of each ID tag reading means, the person carrying the ID tag is moving or staying in the same place depending on whether the signal intensity changes or the signal arrival time changes. Therefore, the indoor environment can be adjusted according to the movement of such a person. In this case, since the reading result of each ID tag reading means (that is, the difference in signal strength or signal arrival time), the position coordinates of the person carrying the ID tag can be accurately calculated. More detailed indoor environment control can be performed.

  In the invention of claim 8, the air conditioner provided corresponding to the area is provided, and the control means turns on the air conditioner according to the number of people in the area based on the reading result of the ID tag reading means. The air conditioner is turned on or off, or the air conditioner is strengthened or weakened.

  In this case, air-conditioning equipment is driven only in the area where people are present, so that not only can the air-conditioning in the building be efficiently managed to achieve energy saving, but there are many people in the area. If the air volume of the air-conditioning equipment is increased, the air volume will be weakened if there are not many people. Therefore, the air-conditioning in the building can be managed more efficiently and further energy saving can be realized.

  In the invention of claim 9, the area includes a plurality of air conditioners provided corresponding to the areas, and the control means is based on the reading result of each ID tag reading means, Each air conditioner is controlled so as to strengthen the air conditioning of the air conditioner in an area with relatively many people and weaken the air conditioner of the air conditioner in an area with relatively few people.

  In this case, since the air volume is increased only for the air conditioner in an area where there are many people, the air conditioning in the building can be efficiently managed to realize energy saving.

  In the invention of claim 10, the air conditioner provided corresponding to the area is provided, and the control means air-conditions the air conditioner in the area where the person is moving based on the reading result of the ID tag reading means. The air conditioner is controlled so as to weaken the air conditioning of the air conditioner in areas where people are not moving.

  In this case, since the air volume is increased only for the air conditioner in the area where the person is moving, the air conditioning in the building can be efficiently managed to realize energy saving.

  In the eleventh aspect of the present invention, the lighting device provided corresponding to the area is provided, and the control device turns on the lighting device in the area where there is a person and turns off the lighting device in the area where there is no person. Control the lighting fixtures.

  In this case, since the lighting apparatus only in the area where people are present is turned on, it is possible to efficiently manage the lighting in the building and realize energy saving.

  In the invention of claim 12, the lighting fixture has a dimming function, and the control device controls the lighting fixture to adjust the luminance (luminous intensity) of the lighting fixture in accordance with the illuminance of the area.

  In this case, since the brightness of the luminaire is adjusted according to the illuminance of each area, the lighting in the building can be managed in real time and energy saving can be realized.

  In invention of Claim 13, a lighting fixture is a LED lighting fixture, and a control apparatus adjusts the brightness | luminance of a LED lighting fixture according to the illumination intensity of an area, or adjusts the color temperature of a LED lighting fixture according to a season. As such, the LED lighting fixture is controlled.

  In this case, since the brightness of the LED luminaire is adjusted according to the illuminance of the area, the lighting in the building can be managed in real time and energy saving can be realized. Further, in this case, the color temperature of the LED lighting apparatus is adjusted according to the season, for example, by setting the color light of the LED lighting apparatus to a cold fluorescent color in summer and a warm daylight color in winter. An ergonomically comfortable indoor environment can be realized.

  In the invention of claim 14, priority is given to each individual's ID information, and when there are a plurality of people in the same area, the control means The indoor environment is controlled.

  In this case, the indoor environment of the area is controlled based on the priority of the ID information, that is, for example, giving priority to elderly people, so that finer adjustment is possible.

  According to a fifteenth aspect of the present invention, the area further comprises sensor means for detecting the presence of a person in the area by a method different from the ID tag reading means, and the control means displays the detection result of the sensor means. Based on the control.

  According to the fifteenth aspect of the present invention, even when the reading result from the ID tag reading means is defective, the indoor environment of the area can be controlled to compensate for the defect by the detection result of another sensor means. .

  As described above, according to the indoor environment control system of the present invention, when a person carrying an ID tag enters a certain area in an indoor area, the ID tag reading means in the area outputs a signal from the ID tag. Detecting and reading the ID information, and based on the reading result (for example, how many people are in which area, who is in which area, etc.), the control means is the indoor environment for each area (for example, temperature, humidity, Illuminance, etc.) is controlled, so that the indoor environment in the building can be controlled efficiently and ergonomically according to the arrangement of people in the building.

Embodiments of the present invention will be described below with reference to the accompanying drawings.
FIGS. 1 to 6 are diagrams for explaining an indoor environment control system according to an embodiment of the present invention. FIG. 1 shows a certain area inside a building to which the indoor environment control system according to the embodiment is applied. FIG. 2 is a schematic plan view showing an example in which the area of FIG. 1 is divided into six areas, FIG. 3 is a detailed view of FIG. 1, and FIG. 4 is for calculating an accurate position of a person in the area. FIG. 5 is a schematic block diagram of this system, and FIG. 6 is a flowchart for explaining a control flow by this system.

  As shown in FIG. 1, an example in which the indoor environment control system according to the present embodiment is applied to a region 2 surrounded by an alternate long and short dash line in a building 1 will be described. The area 2 is an open space (that is, one continuous space) that is not partitioned by a partition wall or the like. For example, as shown by a one-dot chain line in FIG. 2, the area 2 is divided into six areas (1) to (6). ).

  As shown in FIGS. 1 and 3, RFID (radio frequency identification) tag readers R <b> 1 to R <b> 6 serving as ID tag readers are respectively arranged in the centers of the areas (1) to (6). Each of the RFID tag readers R1 to R6 is attached to the center of the ceiling in each area. These RFID tag readers R1 to R6 are devices for receiving radio waves emitted from RFID tags t1 to t4 as ID tags and reading individual ID information stored in the RFID tags t1 to t4, respectively. is there. 1 and 3, the detection ranges of the RFID tag readers R1 to R6 are indicated by circles D1 to D6, and the detection ranges D1 to D6 indicate the areas (1) to (6) (FIG. 2). Each substantially covers. In the example shown in FIGS. 1 and 3, the RFID tag t1 is located within the detection range D1 of the RFID tag reader R1, and the RFID tags t2 to t4 are located within the detection ranges D3 and D4 of the RFID tag readers R3 and R4. is doing.

In the example shown in FIG. 4, the RFID tag t5 is located in the detection ranges D1, D2, and D3 of the RFID tag readers R1, R2, and R3. In this case, the RFID tag readers R1, R2, and R3 detect the intensity (signal intensity) or the reception time (signal arrival time) of the radio wave emitted from the RFID tag t5, respectively, thereby obtaining the accurate position coordinates of the RFID tag t5. The distances d ₁ , d ₂ , and d ₃ from the tag readers R1, R2, and R3 can be used to easily calculate by the three-point distance measuring method.

  In both the examples of FIGS. 1 and 4, when the intensity of the signal from the RFID tag received by the RFID tag reader is changed or when the signal arrival time is changed, the RFID tag is carried. On the contrary, if there is no change in signal strength or signal arrival time, it can be seen that the person carrying the RFID tag stays in the same place.

  The RFID tag stores one or more pieces of information such as an individual identification number (ID number), gender, age, or characteristics. As the RFID tag, an active tag is preferable. In the case of this active RFID tag, since the battery is built in and emits radio waves by itself, the reception distance can be increased. In addition, the built-in battery makes it possible to attach sensors such as temperature / humidity sensors and optical sensors, which changes the environment (temperature, humidity, illuminance, etc.) in which the active RFID tag is placed. Accordingly, the indoor environment (any one of indoor temperature, humidity, illuminance, etc., or a combination of two or more thereof) can be finely adjusted in real time.

  As shown in FIG. 2, in the area 2, the air conditioner A1 is arranged at the center of the areas (1) and (2), the air conditioner A2 is arranged at the center of the areas (3) and (4), and the area (5) And air conditioner A3 is arrange | positioned in the center of (6). Each air conditioner A1, A2, A3 is attached to the ceiling of each area. In addition, LED lighting L1 is provided on the ceilings of the areas (1) and (2), LED lighting L2 is provided on the ceilings of the areas (3) and (4), and LED lighting is provided on the ceilings of the areas (5) and (6). L3 is provided. Here, each LED illumination L1, L2, L3 is, for example, one in which a large number of multi-chip illumination lamps each composed of three colors of red (R), green (G), and blue (B) are used. .

  FIG. 5 is a schematic block diagram of this indoor environment control system. As shown in the figure, this system is controlled by a main controller (personal computer) MC. Controllers C1 to C4 are connected to the main controller MC, respectively.

  RFID tag readers R1 to R6 are connected to the controller C1. These RFID tag readers R1 to R6 have a receiving device that receives radio waves emitted from the RFID tags t1 to t4.

  Air conditioners A1, A2, and A3 are connected to the controller C2. The controller C3 is connected to the LED illumination L1 via the LED power supply circuit P1, is connected to the LED illumination L2 via the LED power supply circuit P2, and is connected to the LED illumination L3 via the LED power supply circuit P3. Each LED power supply circuit P1, P2, P3 incorporates a color temperature device so that each LED illumination L1, L2, L3 emits a desired color temperature. Various sensors such as illuminance sensors S1 and S2 and temperature and humidity sensors S3 and S4 are connected to the controller C4.

Next, the indoor environment control method by this system is demonstrated using the flowchart of FIG.
When the program starts, initial settings such as initializing data of the main controller MC and the controllers C1, C2, and C3 are first made. At this time, the main controller MC further reads the seasonal data indicating whether the current is spring, summer, autumn, or winter, the temperature / humidity data from the temperature / humidity sensor provided in the room, or the illuminance data from the illuminance sensor. Reading is also performed.

  Next, when a person carrying the RFID tag enters the area 2 (FIG. 1), the RFID tag readers R1 to R6 receive radio waves from the RFID tag, and each received ID tag signal is input to the controller C1. . Here, since the RFID tag has a temperature / humidity sensor and an optical sensor, sensor signals from these sensors are also input to the controller C1.

  In the example shown in FIGS. 1 and 3, the RFID tag reader R1 receives radio waves from the RFID tag t1, and the RFID tag readers R3 and R4 receive radio waves from the RFID tags t2, t3, and t4. Accordingly, in this case, the ID tag signal and sensor signal of the RFID tag t1 are input from the RFID tag reader R1 to the controller C1, and the ID tag signals and sensor signals of the RFID tags t2, t3, and t4 are input to the RFID tag reader R3. And R4. At this time, presence information that the person carrying the RFID tag t1 exists in the vicinity of the RFID tag reader R1, and the person carrying the RFID tags t2, t3, and t4 exists between the RFID tag readers R3 and R4. Also input.

  Next, the controller C1 outputs each ID information and each sensor information obtained from each RFID tag reader R1 to R6 to the main controller MC. The main controller MC creates an air conditioner (AC) drive control signal based on the obtained ID information, sensor information, and temperature / humidity data, and outputs it to the controller C2. The controller C2 drives and controls the air conditioners A1, A2, and A3 based on the input AC drive control signal.

The AC drive control signal created by the main controller MC is created according to the following rules.
i) Turn on air conditioners in areas where people are present, and turn off air conditioners in areas where people are absent.
ii) If the number of people in the area where the air conditioner is located exceeds the set number of people, increase the air conditioner air conditioner (that is, make the air flow “strong”). On the contrary, if the number of persons is less than the set number of people, the air conditioning of the air conditioner is weakened (that is, the air volume is set to “weak”).
iii) When the person in the area where the air conditioner is located is moving, increase the air conditioner air conditioner (that is, make the air volume “strong”). On the other hand, if the person stays in the same place, the air conditioning of the air conditioner is weakened (that is, the air volume is “weak”).
iv) When priority is given to ID information, priority is given priority over the above ii) and iii).

  In the example shown in FIG. 1 and FIG. 3, one person exists in the areas (1) and (2) of the area 2, and three persons exist in the areas (3) and (4). ) And (6), since no person is present, the air conditioners A1 and A2 are turned on and the air conditioner A3 is turned off according to the law i). In this case, since the air conditioner is driven only in the area where people are present, the air conditioner in the building can be efficiently managed to realize energy saving.

  Also, in this example, when the set number of people in the area is two, the number of people in areas (1) and (2) is less than the set number of people, and the number of people in areas (3) and (4) is less than the set number of people. Therefore, according to the law ii), the air volume of the air conditioner A1 is set to “weak” and the air volume of the air conditioner A2 is set to “strong”. In this way, energy can be realized by efficiently managing the air conditioning in the building. However, in this case, if the persons in the areas (1) and (2) are moving, the air volume of the air conditioner A1 is also set to “strong” according to the law iii). As a result, the air conditioning in the building can be managed more efficiently.

  Further, in this case, when priority is given to the ID information of the three persons in the areas (3) and (4), the above rules ii) and iii) are prioritized. Drive control of the air conditioner A2 is performed according to the priority order. For example, when the ID information to which priority is given is the age of an individual, when a person over a certain age is included, the air conditioning is adjusted to be weak so that the air conditioning is not too effective. In addition, when the ID information to which the priority is given is an individual characteristic (for example, whether it is hot or cold), the air conditioning is adjusted so that the air conditioning of the air conditioning is weak.

  In the example shown in FIG. 4, there is one person in areas (1) and (2) of area 2, and there are persons in areas (3) and (4) and areas (5) and (6). Since only the air conditioner A1 is turned on and the air conditioners A2 and A3 are turned off according to the law i). Further, according to the law ii), the air volume of the air conditioner A1 is set to “weak”. However, in this case, if the persons in the areas (1) and (2) are moving, the air volume of the air conditioner A1 is set to “strong” according to the law iii).

  In FIG. 6, the main controller MC creates an LED drive control signal based on the obtained ID information, sensor information, season data, and illuminance data, and outputs it to the controller C3. The controller C3 drives and controls the LED power supply circuits P1, P2, and P3 based on the input LED drive control signal.

The LED drive control signal created by the main controller MC is created according to the following law.
i) Turn on LED lighting in areas where people are present, and turn off LED lighting in areas where people are absent. At this time, the brightness of the LED illumination is adjusted according to the illuminance of the area.
ii) Based on the seasonal data, the color temperature is adjusted by controlling the color temperature device of the LED lighting so that the summertime is a fluorescent color and the wintertime is a daylight color.
iii) When the number of people in the area where the LED lighting is provided exceeds the set number of people, the brightness of the LED lighting is increased. On the contrary, if the number of persons is less than the set number, the brightness of the LED is lowered.
iv) When priority is given to ID information, priority is given priority over iii) above.

  In the example shown in FIGS. 1 and 3, there are one person in the areas (1) and (2) of the area 2 and three persons in the areas (3) and (4). ) And (6), since no person is present, the LED lights L1 and L2 are turned on and the LED light L3 is turned off according to the law i). In this case, since LED lighting is turned on only in an area where people are present, it is possible to efficiently manage the lighting in the building and realize energy saving. Moreover, the brightness | luminance of LED illumination L1 and L2 is adjusted at this time according to the illumination intensity of an area. That is, for example, when external light is inserted into the area and the illuminance is bright, the luminance is lowered. As a result, it is possible to manage the lighting in the building in real time and to realize energy saving.

  Further, according to the rule ii), the color temperature is adjusted so that the LED lights L1 and L2 are fluorescent in summer and daylight in winter. As a result, it is illuminated in a cool color in the summer and in a warm color in the winter, providing a comfortable space for people in the area, so an ergonomically comfortable indoor environment Can be realized.

  Also, in this example, when the set number of people in the area is two, the number of people in areas (1) and (2) is less than the set number of people, and the number of people in areas (3) and (4) is less than the set number of people. Therefore, according to the law iii), the brightness of the LED illumination L1 is set low, and the brightness of the LED illumination L2 is set high.

  In this case, if the set number of people in the area is four, the number of people in the areas (3) and (4) is also smaller than the set number of people. Is set lower, but at this time, if priority is given to the ID information of the three persons in the areas (3) and (4), it takes precedence over the above rule iii). Thus, the drive control of the LED illumination L2 is performed according to the priority order. For example, when the ID information to which priority is given is the age of an individual, the brightness is set to be high so that characters apart can be seen well when a person over a certain age is included. .

  In the example shown in FIG. 4, there is one person in areas (1) and (2) of area 2, and there are persons in areas (3) and (4) and areas (5) and (6). Therefore, according to the law i), only the LED illumination L1 is turned on and the LED illuminations L1 and L2 are turned off. Further, the luminance of the LED illumination L1 is lowered according to the law ii).

  According to the present embodiment, when a person enters an area in a building while carrying the RFID tag, the RFID tag reader in the area detects the signal from the RFID tag and reads the ID information. As a result, information (presence information) such as in which area people are present, how many people are present, and who is in which area is input to the main controller MC. The main controller MC controls the indoor environment for each area based on the presence information. That is, the main controller MC turns on air conditioning and lighting only for an area where a person is present, and adjusts the temperature, humidity, illuminance, and the like of the area according to the number of persons, the gender, age, and characteristics of the person. In this way, the indoor environment in the building can be controlled efficiently and ergonomically.

  In this system, the control flow shown in FIG. 6 is repeated every certain time (for example, 1 minute). Thus, depending on the current position information of the person carrying the RFID tag (who is in which area, how many people are in each area, whether or not people are moving, etc.) The indoor environment such as lighting can be controlled in real time.

  In the above-described embodiment, a sensor-equipped RFID tag including a temperature / humidity sensor or an optical sensor is used as the RFID tag. Therefore, indoors according to changes in the environment (temperature, humidity, illuminance, etc.) in which the RFID tag is placed. The environment can be finely adjusted in real time.

  In the above embodiment, since the RFID tag reader reads the signal strength or signal arrival time from the RFID tag, the person carrying the RFID tag moves depending on whether the signal strength changes or the signal arrival time changes. The indoor environment can be adjusted according to the movement of the person. In this case, the position coordinates of the person carrying the RFID tag can be accurately calculated based on the reading result of each RFID tag reader (that is, the difference in signal strength or signal arrival time). Environmental control can be performed.

  In the said Example, since the indoor environment of an area can be controlled based on the priority of ID information, a finer adjustment is attained.

  In the above embodiment, the case where there are a plurality of areas constituting the area inside the building has been described as an example. However, the application of the present invention is not limited to this, and one area may be used.

  In the above-described embodiment, the case where the RFID tag reader is provided only on the ceiling (and therefore in the same plane) to realize the three-point ranging method has been described as an example. However, the position between the ceiling and the floor (and therefore a position other than the same plane). The RFID tag reader may be further provided so that the four-point ranging method can be realized, and the position coordinates of the RFID tag may be calculated three-dimensionally.

  In the above-described embodiment, the case where an RFID tag is used as an RFID tag has been described as an example. However, the present invention also applies to the case where an ID tag using a wireless LAN, ultrasonic wave, GPS, or the like is used. The same applies.

  In the above-described embodiment, an example in which the presence of a person in the area is detected only by the RFID tag reader is shown. However, in the application of the present invention, a person in the area is detected by a method different from the RFID tag reader. Sensor means may be further provided, and the control means may perform control based on the detection result of the sensor means.

  That is, for example, by combining with a so-called human sensor (such as a pyroelectric sensor) that detects a human temperature as a sensor means, for example, when a person leaves the RFID tag off the body and leaves the place, Even if the RFID tag reader detects a problem with the RFID tag, it is determined that the person is not in the place because the human sensor does not detect the person. It becomes possible to control appropriately.

  In the above-described embodiment, an example in which the present system is applied to a normal workplace or a conference room has been shown (see FIG. 3), but the present invention can also be applied to a toilet or a changing room. In this case, by using the gender of the individual read as ID information, the RFID tag reader provided in the vicinity of the entrance of the toilet or changing room reads the gender of the approaching person, so that it can be used for gentlemen according to their gender. Alternatively, lighting and air conditioning in one of the women's rooms are turned on, and lighting and air conditioning are controlled in each room.

  In the said Example, although the example using LED lighting was shown, you may make it use lighting fixtures other than LED lighting as a lighting fixture, In this case, what has a light control function is preferable. .

1 is a schematic plan view showing an area inside a building to which an indoor environment control system according to an embodiment of the present invention is applied. FIG. 2 is a schematic plan view showing a state where the region of FIG. 1 is divided into six areas. FIG. 2 is a detailed view of FIG. 1. It is a figure for demonstrating the method for calculating the exact position of the person in an area. It is a schematic block diagram of this system. It is a flowchart for demonstrating the control flow by this system.

Explanation of symbols

1: Building 2: Area (1) to (6): Area

t1 to t5: RFID tags R1 to R6: RFID tag reader (ID tag reading means)
D1 to D6: Detection range A1 to A3: Air conditioner (air conditioner)
L1-L3: LED lighting (certification instrument)
P1 to P3: LED power supply circuit S1, S2: Illuminance sensor S3, S4: Temperature / humidity sensor C1 to C4: Controller (control means)
MC: Main controller (control means)

Claims (15)

An indoor environment control system,
An ID tag storing personal ID information;
An ID provided corresponding to at least one area constituting the area in a certain indoor area, the detection range covers the area, and a signal from the ID tag is detected to read the ID information Tag reading means;
Control means for controlling the indoor environment of the area based on the reading result of the ID tag reading means;
Indoor environment control system with. In claim 1,
The ID information includes any one or more information of an individual identification number, gender, age or characteristics,
An indoor environment control system characterized by that. In claim 1,
The ID tag is an RFID tag;
An indoor environment control system characterized by that. In claim 3,
The RFID tag is an active tag;
An indoor environment control system characterized by that. In claim 1,
The ID tag is a sensor-equipped ID tag including a temperature sensor, a humidity sensor, or an optical sensor.
An indoor environment control system characterized by that. In claim 1,
The indoor environment is any one or two or more environmental elements of indoor temperature, humidity or illuminance,
An indoor environment control system characterized by that. In claim 1,
The ID tag reading means further detects the signal intensity or signal arrival time from the ID tag,
An indoor environment control system characterized by that. In claim 1,
The control unit includes an air conditioner provided corresponding to the area, and the control unit turns on or off the air conditioner according to the number of people in the area based on the reading result of the ID tag reading unit. The equipment air conditioning is strengthened or weakened,
An indoor environment control system characterized by that. In claim 1,
The area includes a plurality of air conditioners provided corresponding to each area, and the control means is an area having a relatively large number of people based on the reading result of each ID tag reading means. Each air conditioner is controlled so as to weaken the air conditioner in areas with relatively few people.
An indoor environment control system characterized by that. In claim 1,
Air conditioning equipment provided corresponding to the area is provided, and the control means strengthens the air conditioning of the air conditioning equipment in the area where the person is moving based on the reading result of the ID tag reading means, and the person moves The air conditioner is controlled to weaken the air conditioner in the area that is not
An indoor environment control system characterized by that. In claim 1,
The lighting device is provided corresponding to the area, and the control device controls each lighting device to turn on the lighting device in the area where there is a person and to turn off the lighting device in the area where there is no person. ing,
An indoor environment control system characterized by that. In claim 11,
The lighting fixture has a dimming function, and the control device controls the lighting fixture to adjust the luminance of the lighting fixture according to the illuminance of the area.
An indoor environment control system characterized by that. In claim 11,
The lighting fixture is an LED lighting fixture, and the control device adjusts the brightness of the LED lighting fixture according to the illuminance of the area, or adjusts the color temperature of the LED lighting fixture according to the season. Controlling LED lighting fixtures,
An indoor environment control system characterized by that. In claim 1,
Priorities are assigned to the ID information of each individual, and the control means controls the indoor environment of the area based on the priorities when there are a plurality of persons in the same area. ,
An indoor environment control system characterized by that. In claim 1,
Sensor means provided in the area for detecting the presence of a person in the area by a method different from the ID tag reading means,
The control means is controlled based on the detection result of the sensor means.
An indoor environment control system characterized by that.

Images