JP2021046983A - Environment control system - Google Patents

Abstract

To provide an environment control system advantageous to improvement of at least one of comfort, productivity and work efficiency of persons in an indoor space.SOLUTION: An environment control system can control an operation of a ventilation device that ventilates an indoor space (work space 100). The environment control system includes: surface temperature detection means (surface temperature sensor 3) capable of detecting surface temperatures of articles in the indoor space; determination means for determining temperatures of human bodies in the indoor space (persons 50 in the indoor space) on the basis of information on the surface temperatures detected by the surface temperature detection means; and control means enabling the ventilation device to execute an efficiency improvement operation for changing the ventilation amount of the ventilation device on the basis of a determination result obtained by the determination means.SELECTED DRAWING: Figure 1

Description

The present invention relates to an environmental control system.

Patent Document 1 describes an air conditioner capable of sending conditioned air suitable for the human body. This air conditioner acquires the spatial information of the room with a sensor, determines the range in which the human body exists from the spatial information acquired by the sensor, and analyzes the spatial information in the determined range of the human body to analyze the spatial information of the human body. Determine the state. After that, airflow control or temperature control suitable for the determined state of the human body, that is, the position of the head or feet of the human body or the posture of the human body is performed.

Japanese Unexamined Patent Publication No. 2012-42113

In the invention of Patent Document 1, airflow control or temperature control by an air conditioner is executed, but there is still room for improvement in improving the indoor environment more comprehensively.

The present invention has been made to solve the above-mentioned problems, and provides an environmental control system that is advantageous in improving at least one of comfort, productivity, and workability of a person in a room. The purpose is to provide.

The environmental control system according to the present invention operates an air conditioner having at least one air outlet that blows air into the room and a wind direction changing means that can change the direction in which air is blown from the air outlet, and ventilates the room. It is an environmental control system that can control the operation of the ventilation device, and is based on the surface temperature detecting means that can detect the surface temperature of objects in the room and the surface temperature information detected by the surface temperature detecting means in the room. The determination means for determining the position of the upper body and the temperature of the upper body of the human body, and the ventilation volume of the ventilation device while controlling the wind direction changing means so that air is blown from the outlet toward the upper body based on the determination result of the determination means. It is provided with a control means capable of causing the air conditioner and the ventilation device to execute an efficiency improving operation for changing the above based on the determination result of the determination means.
Further, the environmental control system according to the present invention is an environmental control system capable of controlling the operation of a ventilation device that ventilates the room, and is a surface temperature detecting means capable of detecting the surface temperature of an object in the room and a surface temperature detecting means. It is possible to cause the ventilation device to perform a determination means for determining the temperature of the human body in the room based on the surface temperature information detected by the above and an efficiency improving operation for changing the ventilation volume of the ventilation device based on the determination result of the determination means. It is provided with a possible control means.

According to the present invention, it is possible to provide an environmental control system that is advantageous in improving at least one of comfort, productivity, and workability of a person in a room.

It is a side view which shows typically the structure of the work space where the environmental control system of Embodiment 1 is used. It is a perspective view of the indoor unit of the air conditioner of Embodiment 1. FIG. It is a figure which shows the internal structure of the louver provided in the indoor unit of the air conditioner of Embodiment 1. FIG. It is sectional drawing of the ventilation apparatus main body in Embodiment 1. FIG. It is a perspective view of the heat exchange element mounted inside the ventilation apparatus main body shown in FIG. It is a block diagram which shows the structure of the control system of the environmental control system of Embodiment 1. FIG. It is a flowchart which shows the operation example of the environmental control system of Embodiment 1.

Hereinafter, embodiments will be described with reference to the drawings. The common or corresponding elements in the drawings are designated by the same reference numerals to simplify or omit the common description.

Embodiment 1.
1 to 6 show the configuration of the environmental control system according to the first embodiment. FIG. 1 is a side view schematically showing the configuration of a work space 100 in which the environmental control system of the first embodiment is used. FIG. 2 is a perspective view of the indoor unit 1 of the air conditioner according to the first embodiment. FIG. 3 is a diagram showing an internal structure of a louver included in the indoor unit 1 of the air conditioner according to the first embodiment. FIG. 3 shows the internal structure of the portion A surrounded by the broken line in FIG. FIG. 4 is a cross-sectional plan view of the ventilation device main body 40 according to the first embodiment. FIG. 5 is a perspective view of the heat exchange element 47 mounted inside the ventilation device main body 40 shown in FIG. FIG. 6 is a block diagram showing a configuration of a control system of the environmental control system of the first embodiment.

The environmental control system according to the present embodiment has the comfort, productivity, suppression of deterioration in workability, or comfort, productivity, of the occupant 50 who is a person in the work space 100 as shown in FIG. It improves workability. The work space 100 is, for example, the internal space of one room. As shown in FIG. 1, there are a plurality of occupants 50 in the work space 100 as an example. In the state shown in FIG. 1, the occupant 50 is working at the desk 53 as an example. The work space 100 may be a space in which only one occupant 50 can exist. Further, in the following description, the work space 100 may be referred to as "indoor".

The environmental control system according to the present embodiment can control the operation of the air conditioner that harmonizes the air in the work space 100 and the operation of the ventilation device that ventilates the inside of the work space 100. The air conditioner can perform an air conditioning operation including a cooling operation for blowing cold air, a heating operation for blowing warm air, and a blowing operation for blowing normal temperature air. The ventilation device can perform a ventilation operation in which carbon dioxide or contaminated air in the work space 100 is discharged to the outside and fresh air is supplied into the work space 100 from the outside. Further, the air conditioner and the ventilation device according to the present embodiment can execute the efficiency improving operation. The efficiency improving operation is an operation that is advantageous in improving at least one of the comfort, productivity, and workability of the occupant 50. Workability corresponds to work efficiency when the occupant 50 is working. A detailed description of the efficiency improvement operation will be described later.

The air conditioner includes an indoor unit 1. In the present disclosure, the indoor unit 1 is also referred to as the main body of the air conditioner. As shown in FIG. 1, the indoor unit 1 is installed on the ceiling surface 54 of the room in which the work space 100 is formed, as an example. The indoor unit 1 of the air conditioner may be configured to be installed on the floor surface 51 or the wall surface 52, for example.

As an example, as shown in FIG. 1, the environmental control system according to the present embodiment can control the operation of two indoor units 1 installed in one work space 100. The number of the air conditioner and the indoor unit 1 whose operation is controlled in the environmental control system according to the present disclosure may be only one or any plurality of them.

An outdoor unit is connected to the indoor unit 1 via a pipe through which a refrigerant flows. The illustration of the piping and the outdoor unit is omitted in this disclosure. Further, the illustration of each device constituting the refrigeration cycle required for the air conditioner to execute the air conditioning operation and the blower fan for blowing air into the work space 100 is also omitted in the present disclosure. Each device constituting the refrigeration cycle includes, for example, a heat exchanger, a compressor, and the like.

As shown in FIG. 2, the indoor unit 1 includes a housing 30. The housing 30 of the indoor unit 1 is formed in a box shape having a substantially rectangular parallelepiped shape. A rectangular or square lower surface panel 31 is provided below the housing 30 of the indoor unit 1. A suction port 5 is formed on the lower surface panel 31. The suction port 5 is an opening for taking in air from the outside into the housing 30. As an example, the suction port 5 is arranged in the center of the lower surface panel 31 as shown in FIG.

Further, the lower surface panel 31 is formed with an air outlet 20. The air outlet 20 is an opening for discharging air from the inside of the housing 30 to the outside. In the present embodiment, the lower surface panel 31 is formed with four outlets 20 as an example. As shown in FIG. 2, the four outlets 20 are arranged around the suction port 5. Each of the four outlets 20 is provided along each side of the lower surface panel 31. As described above, the air conditioner according to the present disclosure includes a main body in which the air outlet 20 is formed.

As shown in FIGS. 1, 2 and 3, the indoor unit 1 includes upper and lower louvers 2 and left and right louvers 4. The upper and lower louvers 2 and the left and right louvers 4 are provided at each of the air outlets 20. The upper and lower louvers 2 are for adjusting the vertical blowout angle of the air blown out from the blowout port 20. The left and right louvers 4 are for adjusting the blowing angle of the air blown out from the air outlet 20 in the left-right direction.

The upper and lower louvers 2 are members having a rectangular plate shape. One end of the upper and lower louvers 2 is rotatably attached to a portion of the edge portion of the air outlet 20 on the central side of the lower surface panel 31. By rotating the vertical louver 2 around this one end, the vertical blowing angle of the air blown from the air outlet 20 is changed.

The left and right louvers 4 are composed of a plurality of members having a rectangular plate shape. The plurality of members having a rectangular plate shape are arranged so as to be perpendicular to the longitudinal direction of the air outlet 20. One end of the left and right louvers 4 is rotatably attached to the inner portion of the edge of the air outlet 20. By rotating the left and right louvers 4 around one end, the angle of air blown out from the air outlet 20 in the left-right direction is changed.

The upper and lower louvers 2 and the left and right louvers 4 configured as described above are examples of wind direction changing means capable of changing the direction in which air is blown out from the air outlet 20. The air conditioner in the present embodiment can blow air in various directions by changing the combination of the directions of the upper and lower louvers 2 and the directions of the left and right louvers 4.

Further, when the vertical louver 2 is oriented most upward, the air outlet 20 is closed by the vertical louver 2. The air conditioner in the present embodiment can stop the air blowing from some of the outlets by blocking some of the outlets 20 with the upper and lower louvers 2. is there.

Inside the housing 30, an air passage leading from the suction port 5 to the air outlet 20 is formed. A heat exchanger and a blower fan (not shown) are installed in the air passage leading from the suction port 5 to the air outlet 20. The heat exchanger heats or cools the air by exchanging heat between the air flowing through the air passage and the refrigerant. Whether the air is heated or cooled by the heat exchanger depends on the type of air conditioning operation performed by the air conditioner. The heat exchanger heats or cools the air to adjust the temperature, humidity, etc. of the air and generate conditioned air. Specifically, during the heating operation, the heat exchanger heats the air. During the cooling operation, the heat exchanger cools the air. Further, during the ventilation operation, the air that has passed through the heat exchanger is generated as conditioned air at room temperature.

The blower fan is for generating an air flow from the suction port 5 to the air outlet 20 in the air passage inside the housing 30. When the blower fan operates, air is sucked in from the suction port 5 and air is blown out from the air outlet 20.

The air sucked from the suction port 5 passes through the air passage inside the housing 30 of the indoor unit 1 in the order of the heat exchanger and the blower fan. The air that has passed through the blower fan, that is, the conditioned air, is blown out from the outlet 20. During the heating operation, warm air is blown out from the outlet 20. During the cooling operation, cold air is blown out from the air outlet 20. During the blowing operation, the air at room temperature is blown out from the air outlet 20. At this time, the direction in which the air is blown out from the outlet 20 is adjusted by the upper and lower louvers 2 and the left and right louvers 4 arranged on the leeward side of the blower fan. Air conditioners can blow air of different temperatures in different directions.

As shown in FIG. 2, a surface temperature sensor 3 is attached to the lower surface panel 31. The surface temperature sensor 3 has, for example, a plurality of thermopile arranged in one direction. Each of the plurality of thermopile has an element capable of receiving infrared rays and detecting temperature individually. Then, the surface temperature sensor 3 can operate so as to change the direction orthogonal to the above-mentioned one direction of the plurality of thermopile. The surface temperature sensor 3 can detect the surface temperature of an object within a preset target range by scanning each of a plurality of thermopile arranged in one direction. It is desirable that this target range covers the entire work space 100.

The surface temperature sensor 3 may have an SOI diode type uncooled infrared image sensor. "SOI" is an abbreviation for "Silicon On Insulator". When the surface temperature sensor 3 is of the SOI diode type, a silicon diode is used for the sensor unit. Therefore, the SOI diode type surface temperature sensor 3 can be manufactured on a semiconductor manufacturing line, and has an advantage that the production cost is low. The SOI diode type surface temperature sensor 3 can also detect the surface temperature of an object within a preset target range, like the surface temperature sensor 3 having a plurality of thermopile. As described above, any type of sensor is used for the surface temperature sensor 3.

The surface temperature sensor 3 acquires information on the surface temperature of an object in a non-contact manner. With the above configuration, the surface temperature sensor 3 scans the target range and acquires the surface temperature distribution data within the target range. The surface temperature distribution data is also called thermal image data. The detection result of the surface temperature sensor 3, that is, the surface temperature distribution data within the target range is processed by the controller unit 6 or the like described later. As a result, the positions of the floor surface 51 and the wall surface 52 of the room in which the work space 100 is formed, the presence or absence of obstacles such as the desk 53 in the work space 100, and the presence or absence of a heat source including the occupant 50 are detected.

As shown in FIG. 1, the surface temperature sensor 3 may be attached to the ceiling surface 54 as a separate sensor instead of the lower surface panel 31. In this case, when a plurality of indoor units 1 are installed, it is desirable that they are installed at an intermediate distance between the indoor units 1.

Next, the ventilation device will be described. The ventilation device includes a ventilation device main body 40, an exhaust duct 42 for guiding indoor air to the ventilation device main body 40, an outdoor exhaust duct 43 for discharging indoor air from the ventilation device main body 40 to the outside, and fresh air from the outside. It includes an outdoor air supply duct 44 that leads to the ventilation device main body 40, and an air supply duct 41 that supplies fresh air into the room from the ventilation device main body 40. As shown in FIG. 1, as an example, the ventilation device is installed on the ceiling surface 54 of the room in which the work space 100 is formed. The ventilation device main body 40 may be configured to be installed in the lower part of the floor surface 51 or in the wall surface 52, for example.

As an example, the environmental control system according to the present embodiment can control the operation of one ventilation device as shown in FIG. The number of the ventilator and the ventilator main body 40 whose operation is controlled in the environmental control system according to the present disclosure may be one or any plurality of ventilators. Further, a plurality of air supply ducts 41 or a plurality of exhaust ducts 42 may be connected to one ventilation device main body 40.

As shown in FIG. 4, an air supply fan 45, an exhaust fan 46, and a heat exchange element 47 are installed inside the ventilation device main body 40. As shown in FIG. 5, the heat exchange element 47 is configured by alternately laminating flat plate-shaped heat exchange paper 47a and support paper 47b having a corrugated structure. The heat exchange paper 47a partitions between the air supply flow path and the exhaust flow path. The heat exchange paper 47a contributes to heat exchange between supply air and exhaust air. The support paper 47b supports the heat exchange paper 47a. The plurality of support papers 47b are arranged so that the longitudinal directions of the groove-shaped recesses in the corrugated structure are perpendicular to each other between the two support papers 47b adjacent to each other with the heat exchange paper 47a interposed therebetween. A plurality of air supply flow paths are formed in parallel between the heat exchange paper 47a and the support paper 47b on one side of the heat exchange paper 47a. A plurality of exhaust flow paths are formed in parallel between the heat exchange paper 47a and the support paper 47b on the other side. When viewed from a direction perpendicular to the surface of the heat exchange paper 47a, the air supply flow path and the exhaust flow path are orthogonal to each other. When air flows through these flow paths, the air supply that contacts one surface of the heat exchange paper 47a and the exhaust that contacts the other surface of the heat exchange paper 47a do not mix with each other, and the heat exchange paper 47a Exchange heat through. That is, the heat of the air having the higher temperature of the supply air and the exhaust is transferred to the air on the opposite side of the heat exchange paper 47a through the heat exchange paper 47a. In this way, heat is exchanged between the supply air passing through the heat exchange element 47 and the exhaust air.

The indoor air is sucked into the exhaust duct 42 from the indoor air suction port 48 installed on the ceiling surface 54 by the exhaust fan 46, and is guided to the inside of the ventilation device main body 40. After that, the air in the room passes through the heat exchange element 47. At the same time, the fresh outdoor air is guided to the inside of the ventilation device main body 40 by the air supply fan 45 through the outdoor air supply duct 44. After that, the fresh outdoor air passes through the heat exchange element 47. At this time, the indoor air and the outdoor fresh air circulate so as to intersect with each other through the heat exchange element 47, and only heat is exchanged through the heat exchange element 47. After that, the indoor air passes through the exhaust fan 46 and is discharged to the outside from the outdoor exhaust duct 43. The fresh outdoor air passes through the air supply fan 45 and the air supply duct 41, and is supplied indoors from the air supply port 49 installed on the ceiling surface 54. In the present embodiment, by using a ventilation device having a heat exchange element 47, heat can be exchanged between the cold air at the time of cooling or the warm air at the time of heating in the room and the fresh air outdoors. As a result, it is possible to reliably reduce the load of cooling or heating.

Next, with reference to FIG. 6, the configuration of the control system of the environmental control system of the present embodiment will be described. As shown in FIG. 6, the environmental control system of the present embodiment includes a controller unit 6. The controller unit 6 is provided in the indoor unit 1 of the air conditioner as an example.

The controller unit 6 controls the operation of the surface temperature sensor 3. Further, as described above, the controller unit 6 processes the surface temperature distribution data output from the surface temperature sensor 3. The controller unit 6 includes, for example, an information acquisition unit 7, a position determination unit 8, a site determination unit 9, a temperature determination unit 10, and an activity amount determination unit 11.

The information acquisition unit 7 acquires the surface temperature distribution data output from the surface temperature sensor 3. The position determination unit 8 determines the position of an object within the target range based on the surface temperature distribution data acquired by the information acquisition unit 7. The object for which the position determination unit 8 determines the position includes, for example, a resident 50, a floor surface 51, a wall surface 52, a desk 53, and the like. The position determination unit 8 determines the positions of these objects from the difference in surface temperature, the distribution shape of the surface temperature, and the like.

As described above, the surface temperature sensor 3 scans within the target range to acquire surface temperature distribution data. The surface temperature distribution data obtained by performing the scanning once by the surface temperature sensor 3 is recorded in, for example, the position determination unit 8. After that, the surface temperature sensor 3 scans the target range again and acquires the surface temperature distribution data again. The surface temperature distribution data acquired again is recorded in the position determination unit 8. The plurality of surface temperature distribution data acquired by the surface temperature sensor 3 are recorded in time series. The position determination unit 8 determines whether or not an object within the target range has moved by comparing the plurality of surface temperature distribution data.

When the work space 100 is an office or the like, it is considered that the object moving in the work space 100 is the human body of the occupant 50. The position determination unit 8 determines an object that has moved within the target range as a human body by comparing a plurality of surface temperature distribution data recorded in time series.

Further, it is considered that the obstacles such as the desk 53, the floor surface 51 and the wall surface 52 in the work space 100 do not move for a certain period of time and exist at fixed positions. The position determination unit 8 may record in advance the position information of obstacles such as a desk 53 and objects that do not move for a certain period of time such as a floor surface 51 and a wall surface 52. The position determination unit 8 may determine the position of the human body of the occupant 50 based on the position information of the object that does not move for a certain period of time recorded in advance and the surface temperature distribution data acquired by the surface temperature sensor 3.

Further, the part determination unit 9 determines the body part of the occupant 50 based on the surface temperature distribution data acquired by the information acquisition unit 7. Specifically, the site determination unit 9 first specifies the shape of the portion showing the temperature distribution of the surface temperature of the occupant 50 based on the information on the position of the occupant 50 determined by the position determination unit 8. ..

Generally, in the work space 100, the occupant 50 is considered to be standing or sitting. Therefore, the part determination unit 9 determines the upper circular part as the head and the lower part as the body part among the parts showing the temperature distribution of the surface temperature of the occupant 50. In the present embodiment, the “body part” refers to a part of the body of the occupant 50 other than the head. The part determination unit 9 may determine the head and body based on not only the shape but also the difference in surface temperature for each part, and the head and body may be determined based on the data accumulated in advance. May be determined. In this way, the part determination unit 9 divides the part showing the temperature distribution of the surface temperature of the occupant 50 into two parts, a head part and a body part.

Further, the site determination unit 9 determines the range of the upper half of the portion showing the temperature distribution of the surface temperature of the occupant 50 as the position of the upper body of the occupant 50. In the present embodiment, the "upper body" includes the above-mentioned head and the upper part of the body part.

The temperature determination unit 10 determines the head temperature, which indicates the temperature of the head of the occupant 50, based on the surface temperature distribution data acquired by the information acquisition unit 7, the determination result of the site determination unit 9, and the like. As an example, the temperature determination unit 10 determines the average temperature or the maximum temperature of the entire range determined as the head by the part determination unit 9 as the head temperature.

Further, in the present embodiment, the temperature determination unit 10 determines the body temperature indicating the temperature of the body of the occupant 50, the surface temperature distribution data acquired by the information acquisition unit 7, the determination result of the site determination unit 9, and the like. Judgment is based on. As an example, the temperature determination unit 10 determines the average temperature or the maximum temperature of the entire range determined as the body part by the part determination unit 9 as the body part temperature. Further, the temperature determination unit 10 determines the average temperature or the maximum temperature of the entire range determined as the upper body by the site determination unit 9 as the upper body temperature indicating the temperature of the upper body of the occupant 50. For the determination of the body temperature and the upper body temperature, for example, an algorithm or the like in consideration of clothing or the like may be used.

The activity amount determination unit 11 is either one of the temperature information of the human body of the occupant 50 determined by the temperature determination unit 10 and the information regarding the movement of the position of the occupant 50 determined by the position determination unit 8. Based on both, the amount of activity of the occupant 50 is determined. The activity determination unit 11 calculates or estimates, for example, at least one of METs, EX (exercise) = METs × time, number of steps, walking speed, calories burned, and calories burned per hour. Therefore, the activity amount of the occupant 50 may be determined.

The greater the amount of activity, the higher the temperature of the human body of the occupant 50. Utilizing this fact, the activity amount determination unit 11 may determine that the higher the temperature of the human body of the occupant 50, the greater the amount of activity. As an example, the activity amount determination unit 11 may determine that the higher the upper body temperature of the occupant 50, the greater the activity amount. Upper body temperature more accurately reflects the amount of activity. Therefore, by using the upper body temperature, the amount of activity can be determined with higher accuracy. However, the activity amount determination unit 11 may determine the activity amount by using the head temperature or the body temperature other than the upper body, or may determine the activity amount by using the temperature of the whole body of the occupant 50. Good.

It is considered that the more the position of the occupant 50 moves, the longer the walking distance of the occupant 50 and the greater the amount of activity of the occupant 50. Taking advantage of this, the activity amount determination unit 11 may determine that the more the position of the occupant 50 moves, the greater the activity amount.

The surface temperature sensor 3 configured as described above is an example of a surface temperature detecting means capable of detecting the surface temperature of an object within the target range. Further, the controller unit 6 including the information acquisition unit 7, the position determination unit 8, the site determination unit 9, the temperature determination unit 10, and the activity amount determination unit 11 is a target based on the surface temperature information detected by the surface temperature detecting means. This is an example of a determination means for determining the positions of the head and upper body of the human body within the range and the temperatures of the head and upper body. The configuration of the determination means according to the present disclosure is not limited to the configuration of the controller unit 6 in the present embodiment. The determination means according to the present disclosure may determine the positions of the head and upper body of the human body and the temperatures of the head and upper body within the target range by any method.

The determination results by the position determination unit 8, the part determination unit 9, the temperature determination unit 10, and the activity amount determination unit 11 pass through the information processing unit 12 and the control unit 13, and then the upper and lower louver control units 14 and the left and right louver control units of the air conditioner. It is transmitted to 15 and the ventilation damper control unit 16 and the ventilation fan control unit 17 of the ventilation device.

The vertical louver control unit 14 controls the operation of the vertical louver 2 to change the direction in which air is blown out from the air outlet 20. Specifically, the vertical louver control unit 14 electrically controls a device such as a motor (not shown) for moving the vertical louver 2. The left-right louver control unit 15 controls the operation of the left-right louver 4 to change the direction in which air is blown out from the air outlet 20. Specifically, the left-right louver control unit 15 electrically controls a device such as a motor (not shown) for moving the left-right louver 4.

An air supply damper (not shown) is provided in the air supply port 49 in which the ventilation device blows out fresh air from the outside into the room. The ventilation damper control unit 16 controls the opening degree of the air supply damper. The ventilation damper control unit 16 electrically controls a device such as a motor (not shown) for moving the air supply damper. As a result, the amount of fresh air from the outside flowing into the room is changed. The ventilation fan control unit 17 controls the rotation speed of the air supply fan 45 and the rotation speed of the exhaust fan 46 of the ventilation device. Specifically, the ventilation fan control unit 17 electrically controls devices such as a motor (not shown) that drives each of the air supply fan 45 and the exhaust fan 46.

The information processing unit 12 is an air conditioner based on the information on the position of the human body within the target range detected by the surface temperature sensor 3 and the controller unit 6, the information on the part of the human body, and the information on the temperature distribution of the human body. And determine the control content of the ventilation system. The control unit 13 outputs specific control commands to each of the upper / lower louver control unit 14, the left / right louver control unit 15, the ventilation damper control unit 16, and the ventilation fan control unit 17 according to the control contents determined by the information processing unit 12. .. The upper / lower louver control unit 14 controls the operation of the upper / lower louver 2 in accordance with a control command from the control unit 13. The left / right louver control unit 15 controls the operation of the left / right louver 4 in accordance with a control command from the control unit 13. The ventilation damper control unit 16 controls the opening degree of the air supply damper of the air supply port 49 according to the control command from the control unit 13. The ventilation fan control unit 17 controls the rotation speeds of the air supply fan 45 and the exhaust fan 46 according to the control command from the control unit 13.

The information processing unit 12, the control unit 13, the vertical louver control unit 14, the left and right louver control unit 15, the ventilation damper control unit 16, and the ventilation fan control unit 17 configured as described above are examples of control means.

As described above, the environmental control system according to the present embodiment can improve the comfort, productivity, and workability of the occupant 50. The productivity and workability efficiency improvement operation is for suppressing a decrease in the productivity and workability efficiency of the occupant 50 in the work space 100 or improving the productivity and workability efficiency of the occupant 50. It is an operation. The operation for improving the efficiency of productivity and workability is the operation of lowering the temperature of the head of the occupant 50 by blowing air toward the head of the occupant 50 by the indoor unit 1 of the air conditioner. It is an operation to supply fresh air to the room by a ventilation device according to the number of people and the amount of activity. At the time of performing the productivity and workability efficiency improving operation, the air conditioner performs a cooling operation or a blowing operation. That is, in the present embodiment, the air conditioner blows cold air or normal temperature air from the air outlet 20 at the time of executing the operation for improving the efficiency of productivity and workability. By such an efficiency improving operation, the comfort of the occupant 50 is also improved at the same time.

An air conditioner and a ventilator that perform operations for improving productivity and workability will be described with reference to FIG. In the configuration example shown in FIG. 1, two indoor units 1, an indoor air suction port 48 of a ventilation device, and an air supply port 49 are installed on the ceiling surface 54. Of these two indoor units 1, the indoor unit 1 on the left side is also referred to as an indoor unit 1a. Further, of the two indoor units 1, the indoor unit 1 on the right side is also referred to as an indoor unit 1b.

Further, among the plurality of outlets 20 of the indoor unit 1a, the outlet 20 on the left side in FIG. 1 is also referred to as an outlet 20a. Of the plurality of outlets 20 of the indoor unit 1a, the outlet 20 on the right side in FIG. 1 is also referred to as an outlet 20b. Of the plurality of outlets 20 of the indoor unit 1b, the outlet 20 on the left side in FIG. 1 is also referred to as an outlet 20c. Of the plurality of outlets 20 of the indoor unit 1b, the outlet 20 on the right side in FIG. 1 is also referred to as an outlet 20d.

Further, in FIG. 1, four upper and lower louvers 2 are shown. These four upper and lower louvers 2 are also referred to as upper and lower louvers 2a, upper and lower louvers 2b, upper and lower louvers 2c, and upper and lower louvers 2d, respectively, in order from the left side. The upper and lower louvers 2a change the direction in which air is blown out from the outlet 20a. The upper and lower louvers 2b change the direction in which air is blown out from the outlet 20b. The upper and lower louvers 2c change the direction in which air is blown out from the outlet 20c. The upper and lower louvers 2d change the direction in which air is blown out from the outlet 20d.

In the configuration example shown in FIG. 1, three occupants 50 are shown in the work space 100. These three occupants 50 are also referred to as occupants 50a, occupants 50b, and occupants 50c, respectively, in order from the left side. During the operation for improving the efficiency of productivity and workability, the vertical louver control unit 14 and the left and right louver control unit 15 are in the room from the air outlet 20 to the head of the occupant 50a, the head of the occupant 50b, and the room. The upper and lower louvers 2 and the left and right louvers 4, which are examples of the wind direction changing means, are controlled so that the air is blown toward the head of the person 50c.

The upper and lower louvers 2a closest to the occupant 50a change the vertical wind direction so that the wind hits the head of the occupant 50a from the air outlet 20a closest to the occupant 50a. The upper and lower louvers 2b and the upper and lower louvers 2c, which are close to the occupant 50b, change the vertical wind direction so that the wind hits the head of the occupant 50b from the outlet 20b and the outlet 20c. The upper and lower louvers 2d closest to the occupant 50c change the vertical wind direction so that the wind hits the head of the occupant 50c from the air outlet 20d closest to the occupant 50c.

In this way, the upper and lower louvers 2 closest to the occupant 50 among the plurality of upper and lower louvers 2 change the vertical wind direction so that air is blown from the air outlet 20 toward the head of the occupant. The upper and lower louvers 2 change the vertical wind direction so that air is blown from the outlet 20 closest to the occupant 50 among the plurality of outlets 20 toward the head of the occupant 50. Further, although not shown in FIG. 1, the left and right louvers 4 are also directed from the outlet 20 closest to the occupant 50 among the plurality of outlets 20 toward the head of the occupant 50, similarly to the upper and lower louvers 2. Change the left and right wind direction so that the air is blown out. In the upper and lower louvers 2 and the left and right louvers 4, which are examples of the wind direction changing means, air is blown from the outlet 20 closest to the occupant 50 among the plurality of outlets 20 toward the head of the occupant 50. Is controlled.

During the productivity and workability efficiency improvement operation, the ventilation system is controlled together with the air conditioner. That is, the ventilation device supplies fresh air into the room from the air supply port 49 and discharges the indoor air sucked from the indoor air suction port 48 to the outside according to the number of people in the room 50 and the amount of activity. Be controlled. At this time, based on the information detected by the surface temperature sensor 3, the position of the occupant 50, the number of occupants 50, the body part of the occupant 50, the activity amount of the occupant 50, and the like are determined. , The indoor unit 1 of the air conditioner and the ventilation device are controlled based on the determination result.

Next, with reference to FIG. 7, a specific example of the operation flow of the environmental control system according to the present embodiment will be described. FIG. 7 is a flowchart showing an operation example of the environmental control system of the first embodiment.

First, the surface temperature sensor 3 scans the target range to detect the occupants 50 in the work space 100, in other words, the human body in the work space 100 (step S101). As described above, the position of the human body is determined by the position determination unit 8 based on the surface temperature distribution data acquired by the surface temperature sensor 3.

Next, the number of occupants 50 in the work space 100 is determined based on the determination result of the position of the human body detected in step S101 (step S102). At the same time, the part determination unit 9 determines the part of the human body detected in step S101 (step S103). As described above, the site determination unit 9 divides the detected human body into two parts, a head and a body part. Then, based on the determination result of the site determination unit 9, the detected head temperature and body temperature of the human body are determined by the temperature determination unit 10 (step S104).

After the process of step S104 described above, the temperature determination unit 10 determines whether the head temperature is equal to or higher than a certain temperature (step S105). If the head temperature is not above a certain temperature, scanning by the surface temperature sensor 3 is performed again. When the head temperature is equal to or higher than a certain temperature, the above-mentioned efficiency improving operation is executed by the air conditioner and the ventilation device (step S106). In other words, when the head temperature is above a certain temperature, the upper and lower louvers 2 and the left and right louvers, which are examples of the wind direction changing means, are blown out from the air outlet 20 of the indoor unit 1 toward the head of the human body. 4 is controlled, and the amount of fresh air supplied into the room from the air supply port 49 and the amount of indoor air discharged to the outside from the indoor air suction port 48 are increased. At this time, the amount of fresh air supplied into the room from the air supply port 49 and the amount of the indoor air discharged to the outside from the indoor air suction port 48 are set based on the result of determining the number of people in step S102.

By performing the efficiency improving operation by the air conditioner and the ventilation device, the cold air or the normal temperature air hits the head of the occupant 50, and the ventilation volume is increased. As a result, the temperature of the head changes. In the present embodiment, the head temperature and the body temperature of the occupant 50 exposed to cold air or normal temperature air are continuously determined while the efficiency improving operation is performed.

When the efficiency improving operation is started, the temperature determination unit 10 determines whether or not the head temperature is lower than the body temperature by a specified temperature (step S107). This specified temperature is set as, for example, a temperature in the range of 0.5 ° C. to 2.0 ° C. If the head temperature is not lower than the body temperature by the specified temperature, the efficiency improvement operation is continued. When the head temperature becomes lower than the body temperature by the specified temperature, the efficiency improvement operation ends. In summary, in the present embodiment, the control means performs an efficiency improving operation until the temperature of the head of the human body within the target range is lower than the temperature of the body of the human body by a specified temperature. To execute.

By operating as described above, the environmental control system according to the present embodiment can keep the sensible temperature of the occupant 50 neutral while lowering the head temperature of the occupant 50. The environmental control system according to the present embodiment can put the occupant 50 in a state in which the head temperature is lower than the body temperature by a specified temperature, that is, a so-called "head cold foot fever". The state of "head cold foot fever" is a state in which the efficiency of productivity and workability is improved. In this way, the environmental control system according to the present embodiment supports the suppression of the decrease in the productivity and workability efficiency of the occupant 50 and the improvement of the productivity and workability efficiency of the occupant 50. ..

The efficiency improving operation may be executed until the temperature of the head of the human body within the target range is lowered by the specified temperature from the initial head temperature. The initial head temperature is set, for example, as the head temperature of the human body at the time when the human body is detected in step S101 or as the head temperature at the time when the efficiency improving operation is started. Also in this example, by lowering the head temperature of the occupant 50 by a specified temperature, the decrease in productivity and workability efficiency of the occupant 50 is suppressed. Alternatively, the productivity and workability efficiency of the occupant 50 is improved.

In the configuration example shown in FIG. 1, in the work space 100, there may be a plurality of occupants 50 for one upper and lower louver 2. In this case, the air conditioner may sequentially execute the efficiency improving operation for the plurality of occupants 50. One upper and lower louver 2 faces a plurality of occupants 50 in order. For example, the air conditioner performs an efficiency improving operation until the head temperature of the first occupant 50 is lower than the body temperature by a specified temperature, and then improves the efficiency with respect to the second occupant 50. Perform the action. Wind is applied to the heads of the plurality of occupants 50 in order.

At this time, the order in which the wind is applied, that is, the priority of the human body to be the target of the efficiency improving operation, may be determined based on the surface temperature distribution data acquired by the surface temperature sensor 3. For example, the air conditioner may perform efficiency improving operations on a plurality of human bodies in descending order of head temperature. As a result, the head of the occupant 50 whose head temperature has become high is preferentially cooled. Further, when the work space 100 is an office or the like, an island may be formed by a plurality of occupants 50. In this case, as an example, the air conditioner may perform efficiency improving operations on each island in descending order of the average temperature of the head temperature of the occupants 50 on each island.

Further, the wind speed and the air volume of the wind blown out from the outlet 20 during the efficiency improving operation may be constant or may fluctuate irregularly. Further, the wind direction of the wind blown from the outlet 20 during the efficiency improving operation may be constant or irregularly swayed. That is, the upper and lower louvers 2 and the left and right louvers 4 may swing during the efficiency improving operation. Since the wind blown from the air outlet 20 fluctuates during the efficiency improvement operation, the feeling of wind contact of the occupant 50 is suppressed, and the comfort of the occupant 50 is increased.

The surface temperature detecting means according to the present disclosure is not limited to the above-mentioned surface temperature sensor 3. The surface temperature detecting means may be, for example, a wearable contact type sensor worn on the body of the occupant 50 or the like.

Further, the controller unit 6, which is an example of the determination means, may be provided outside the air conditioner and the ventilation device, for example. Further, the functions of the determination means and the control means may be realized by, for example, a server on the cloud. The operation of the environmental control system may be controlled by a server or the like on the cloud. As a result, the control load in the air conditioner and the ventilation device itself is suppressed. In addition, the interlocking of a plurality of air conditioners and a plurality of ventilation devices becomes easier.

Further, the number of air conditioner outlets 20 and the number of indoor air suction ports 48 and air supply ports 49 of the ventilation device according to the present disclosure are not limited to the examples shown in the present embodiment, and may be any number. Good.

In the environmental control system according to the embodiment shown above, the angles and operations of the upper and lower louvers 2 and the left and right louvers 4, which are examples of the wind direction changing means, and the air volume of the ventilation device are the surface temperature sensors, which are examples of the surface temperature detecting means. It is controlled based on the surface temperature information detected by 3. The upper and lower louvers 2 and the left and right louvers 4 are controlled so that air is blown toward the head of the occupant 50. By doing so, the environmental control system according to the above embodiment more reliably constructs an environment that supports the work of the occupant 50, and improves the productivity and workability efficiency of the occupant 50. Can be improved.

In the above description, an example in which the wind direction changing means is controlled so that air is blown toward the head of the occupant 50 during the efficiency improving operation has been described, but instead of this example, the occupant is in the room. The wind direction changing means may be controlled so that the air is blown toward the upper body of the person 50. At that time, the wind direction changing means may be controlled so that the air is blown from the air outlet 20 closest to the upper body of the occupant 50 among the plurality of air outlets 20 toward the upper body. By doing so, an effect similar to the above-mentioned effect can be obtained.

In the present embodiment, the ventilation device is based on the information of one or both of the position of the upper body and the temperature of the upper body of the occupant 50 determined by the controller unit 6 at the time of the efficiency improvement operation. Ventilation volume can be changed. According to the information, it is possible to determine whether the amount of carbon dioxide emitted from the occupant 50 is large or small. Therefore, by changing the ventilation volume of the ventilation device based on the information, it is possible to surely prevent an increase in the carbon dioxide concentration in the room. As a result, it is advantageous in improving the comfort, productivity, and workability of the occupant 50. The method of changing the ventilation volume of the ventilation device may be a method in which the ventilation fan control unit 17 changes the operating speed or the operating frequency of at least one of the air supply fan 45 and the exhaust fan 46, or the ventilation damper control unit 16 supplies air. The opening degree of the damper may be changed, or both methods may be used in combination.

At the time of the efficiency improvement operation, the larger the number of occupants 50 determined by the controller unit 6, the larger the ventilation volume of the ventilation device may be controlled. As a result, it is possible to more reliably prevent an increase in the carbon dioxide concentration in the room, which is more advantageous in improving the comfort, productivity, and workability of the occupant 50.

At the time of the efficiency improving operation, the higher the upper body temperature, the body temperature, or the head temperature of the occupant 50 determined by the controller unit 6, the larger the ventilation volume of the ventilation device may be controlled. Since it can be determined that the higher the body temperature of the occupant 50, the greater the amount of activity of the occupant 50, it is considered that the amount of carbon dioxide emitted from the occupant 50 is large. Therefore, the higher the upper body temperature, the body temperature, or the head temperature, the more surely the increase in the carbon dioxide concentration in the room can be prevented by increasing the ventilation volume of the ventilation device. As a result, it becomes more advantageous in improving the comfort, productivity, and workability of the occupant 50. When there are a plurality of occupants 50, the above is based on a statistically processed value (for example, an average value) of the upper body temperature, body temperature, or head temperature of the plurality of occupants 50. Control may be performed.

In the efficiency improving operation, the ventilation volume of the ventilation device may be controlled to increase as the position of the occupant 50 determined by the controller unit 6 moves more. It can be judged that the more the position of the occupant 50 moves, the longer the walking distance of the occupant 50 is, and the greater the amount of activity of the occupant 50. Therefore, it is considered that the amount of carbon dioxide emitted from the occupant 50 is large. Be done. Therefore, it is possible to more reliably prevent an increase in the carbon dioxide concentration in the room by increasing the ventilation volume of the ventilation device as the position of the occupant 50 moves more. As a result, it becomes more advantageous in improving the comfort, productivity, and workability of the occupant 50. When there are a plurality of occupants 50, the above control may be executed based on a statistically processed value (for example, an average value) of the movement amount of the positions of the plurality of occupants 50. ..

The ventilator described in this embodiment corresponds to a first-class ventilator that uses a fan for both air supply and exhaust. In the present disclosure, the ventilation device is not limited to the first-class ventilation device, and may be, for example, a second-class ventilation device that uses a fan for air supply and does not use a fan for exhaust, or uses a fan for exhaust. A third-class ventilation device that is used and does not use a fan for air supply may be used. In the case of the third-class ventilation device, outside air can flow into the room through a gap in the room structure.

In the present embodiment, an example in which the environmental control system executes the efficiency improving operation on both the air conditioner and the ventilation device has been described, but the environmental control system according to the present disclosure performs at least the above-mentioned efficiency improving operation on the ventilation device. It may be the one that is executed against the air conditioner, and may not be the one that does not control the air conditioner. In this case, the environmental control system causes the ventilation device to perform an efficiency improving operation of changing the ventilation volume of the ventilation device based on the information of the temperature of the human body of the occupant 50 determined by the surface temperature sensor 3 and the controller unit 6. .. According to the information on the temperature of the human body of the occupant 50, it is possible to accurately determine whether the amount of carbon dioxide emitted from the occupant 50 is large or small. Therefore, by changing the ventilation volume of the ventilation device based on the information, it is possible to surely prevent an increase in the carbon dioxide concentration in the room. As a result, it is advantageous in improving the comfort, productivity, and workability of the occupant 50.

1 Indoor unit, 1a Indoor unit, 1b Indoor unit, 2 Vertical louver, 2a Vertical louver, 2b Vertical louver, 2c Vertical louver, 2d Vertical louver, 3 Surface temperature sensor, 4 Left and right louver, 5 Suction port, 6 Controller, 7 Information acquisition unit, 8 position determination unit, 9 part determination unit, 10 temperature determination unit, 11 activity determination unit, 12 information processing unit, 13 control unit, 14 vertical louver control unit, 15 left and right louver control unit, 16 ventilation damper control Unit, 17 Ventilation fan control unit, 20 outlet, 20a outlet, 20b outlet, 20c outlet, 20d outlet, 30 housing, 31 bottom panel, 40 ventilation system body, 41 air supply duct, 42 for exhaust Duct, 43 Outdoor exhaust duct, 44 Outdoor air supply duct, 45 Air supply fan, 46 Exhaust fan, 47 Heat exchange element, 47a Heat exchange paper, 47b Support paper, 48 Indoor air suction port, 49 Air supply port, 50 Room Person, 50a resident, 50b resident, 50c occupant, 51 floor, 52 wall, 53 desk, 54 ceiling, 100 work space

Claims (8)

The operation of the air conditioner having at least one air outlet for blowing air into the room and the wind direction changing means capable of changing the direction in which the air is blown from the air outlet, and the operation of the ventilation device for ventilating the room. A controllable environmental control system
A surface temperature detecting means capable of detecting the surface temperature of an object in the room,
A determination means for determining the position of the upper body of the human body and the temperature of the upper body in the room based on the surface temperature information detected by the surface temperature detecting means.
Based on the determination result of the determination means, the wind direction changing means is controlled so that air is blown from the outlet toward the upper body, and the ventilation volume of the ventilation device is changed based on the determination result of the determination means. A control means capable of causing the air conditioner and the ventilation device to perform an efficiency improving operation.
Environmental control system equipped with. The environmental control system according to claim 1, wherein the control means executes the efficiency improving operation until the temperature of the head of the human body drops by a predetermined temperature. The environmental control system according to claim 1, wherein the control means executes the efficiency improving operation until the temperature of the head of the human body becomes lower than the temperature of the body of the human body by a specified temperature. The air conditioner has a plurality of the outlets.
At the time of the efficiency improving operation, the control means controls the wind direction changing means so that air is blown from the outlet closest to the upper body of the human body toward the upper body among the plurality of outlets. The environmental control system according to any one of claims 1 to 3. An environmental control system that can control the operation of the ventilation system that ventilates the room.
A surface temperature detecting means capable of detecting the surface temperature of an object in the room,
A determination means for determining the temperature of the human body in the room based on the surface temperature information detected by the surface temperature detecting means, and
A control means capable of causing the ventilation device to perform an efficiency improving operation of changing the ventilation volume of the ventilation device based on the determination result of the determination means.
Environmental control system equipped with. The determination means can determine the number of people in the room based on the surface temperature information detected by the surface temperature detection means.
The environmental control system according to any one of claims 1 to 5, wherein in the efficiency improving operation, the control means increases the ventilation volume of the ventilation device as the number of people in the room increases. .. The environmental control system according to any one of claims 1 to 6, wherein the control means increases the ventilation volume of the ventilation device as the temperature of the human body increases during the efficiency improving operation. The determination means can determine the movement of the position of the human body based on the surface temperature information detected by the surface temperature detection means.
The environmental control system according to any one of claims 1 to 7, wherein in the efficiency improving operation, the control means increases the ventilation volume of the ventilation device as the position of the human body moves more.

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