JP2013160493A - Ventilation control system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a comfortable living environment appropriate to season to a dwelling house of high air tightness, and simultaneously to suppress energy consumption.SOLUTION: A ventilation control system includes an air supply duct 14 and an exhaust duct 16 opened to an exterior wall of a building 12 at one end and opened to a room of the building at the other end, a heat exchanger 26 exchanging heat between the outside air sucked through the air supply duct 14 and the air discharged through the exhaust duct 16, air supply fans 18 taking the outside air indoors through the air supply duct 14, exhaust fans 20 discharging the indoor air to the external through the exhaust duct 16, an operation mode selecting means 48 for storing either a first operation mode for operating both of the air supply fans 18 and the exhaust fans 20 or a second operation mode for operating the air supply fans 18 and stopping the exhaust fans 20, as an operation mode data 66, and a fan control means 50 controlling motion of the air supply and exhaust fans according to contents of the operation mode data 66.

Description

  The present invention relates to a ventilation control system, a ventilation control program, and a recording medium for automatically controlling a ventilation device of a highly airtight house throughout the season.

  In a highly airtight house, it is obliged to operate the ventilator continuously. A heat exchanger ventilation system is employed so that this ventilation device does not interfere with the cooling and heating effect. The heat exchanger ventilation system supplies and exhausts air at the same time, and inserts a sensible heat exchanger or a total heat exchanger into the supply and exhaust pipe. The sensible heat exchanger operates to return heat from the exhausted air to the supplied air. The total heat exchanger operates to return heat and moisture from the exhausted air to the supplied air.

JP 2010-223486 A

In a heat exchanger ventilation system in which a fan for supplying and exhausting air is continuously operated at all times, power consumption for driving the fan becomes a problem. In addition, when a total heat exchanger is used in summer, air with relatively high humidity outdoors may be circulated. Therefore, Patent Document 1 discloses a technique for controlling the air supply fan to stop at a corresponding time. However, if the air supply fan is stopped for a long period of time, there is a problem that dust and dust collect in the air supply duct, and dust and dust flow into the room when the air supply fan is started. When the air supply port is closed in order to keep the air supply duct clean, the exhaust fan is operated to cause negative pressure in the room, and outside air flows from various parts in the room. Air also flows into the room from the bathroom or toilet. Therefore, an unexpected odor or the like may flow into the room.
In order to solve the above-described problems, the present invention provides a ventilation control system, a ventilation control program, and a recording medium for providing a comfortable living environment according to the seasons for a highly airtight house and at the same time suppressing energy consumption. For the purpose.

The following configurations are means for solving the above-described problems.
<Configuration 1>
An air supply duct 14 and an exhaust duct 16 having one end opened in the outer wall of the building 12 and the other end opened into the room of the building, outside air sucked through the air supply duct 14 and air discharged through the exhaust duct 16 A heat exchanger 26 that exchanges heat between the air, an air supply fan 18 that takes outside air into the room through the air supply duct 14, an exhaust fan 20 that exhausts the indoor air to the outside through the exhaust duct 16, In response to the input of the control signal 45, in accordance with the content of the control signal 45, the first operation mode in which both the air supply fan 18 and the exhaust fan 20 are operated, the air supply fan 18 is operated, and the exhaust air is operated. The operation mode selection means 48 for storing any one of the second operation modes in which the fan 20 is stopped as the operation mode data 66 in the storage device 38, and the storage In accordance with the contents of the operation mode data 66 stored in the location, the ventilation control system comprising the fan control means 50 for controlling the operation of the exhaust fan 20 and the air supply fan 18.

<Configuration 2>
An air supply duct 14 and an exhaust duct 16 having one end opened in the outer wall of the building 12 and the other end opened into the room of the building, outside air sucked through the air supply duct 14 and air discharged through the exhaust duct 16 A heat exchanger 26 that exchanges heat between the air, an air supply fan 18 that takes outside air into the room through the air supply duct 14, an exhaust fan 20 that exhausts the indoor air to the outside through the exhaust duct 16, The outdoor temperature sensor 32 that measures the temperature outside the building, the temperature measuring means 42 that receives the output of the outdoor temperature sensor 32 and measures the outside air temperature, and the outside air temperature measured by the temperature measuring means 42 is the seasonal determination threshold value. If it is less than 54, the first operation mode for operating both the air supply fan 18 and the exhaust fan 20 is stored as operation mode data 66. 38, the air supply fan 18 is operated and the exhaust fan 20 is stopped when the outside air temperature measured by the temperature measuring means 42 is equal to or higher than the season determination threshold value 54. A ventilation control system comprising an operation mode selection means 48 for storing the mode data 66 in the storage device 38.

<Configuration 3>
In the ventilation control system according to Configuration 1, the operation mode selection means 48 determines whether the present is winter or other than winter based on calendar information or weather information, selects the first operation mode in winter, and other than winter Generates the operation mode data 66 having contents for selecting the second operation mode.

<Configuration 4>
In the ventilation control system according to Configuration 2, an indoor temperature sensor 30 that measures the temperature inside the building, an outdoor temperature sensor 32 that measures the temperature outside the building, and an output of the indoor temperature sensor 30 that receives the output of the room temperature sensor 30 Temperature measuring means 42 that receives the output of the outdoor temperature sensor 32 and measures the outside air temperature, and the operation mode selecting means 48 has an outdoor temperature measured by the temperature measuring means 42 that is greater than or equal to the seasonal determination threshold value 54. When the outside air temperature exceeds the room temperature, the ventilation control system is characterized in that the first operation mode is stored in the storage device 38 as operation mode data 66.

<Configuration 5>
In the ventilation control system according to Configuration 1, the operation mode selection unit 48 receives a control signal for determining whether or not the air conditioner is in operation, and is in the winter season and is not operating the air conditioner. The second operation mode is stored in the storage device 38 as operation mode data 66, and the first operation mode is stored in the storage device 38 as operation mode data 66 when the air conditioner is in operation other than in winter. A ventilation control system characterized by memorizing.

<Configuration 6>
5. The ventilation control system according to Configuration 2 or 4, wherein an indoor temperature sensor 30 that measures a temperature inside the building, an outdoor temperature sensor 32 that measures a temperature outside the building, and an output of the indoor temperature sensor 30 are received. Temperature measuring means 42 for measuring the room temperature, receiving the output of the outdoor temperature sensor 32 and measuring the outside air temperature, and the operation mode selecting means 48 is configured to determine whether the outside temperature measured by the temperature measuring means 42 is a seasonal determination threshold value. If the outside air temperature exceeds the room temperature, the second operation mode is stored in the storage device 38 as the operation mode data 66 when the outside air temperature exceeds the room temperature.

<Configuration 7>
In the ventilation control system according to Configuration 2, an indoor temperature sensor 30 that measures a temperature inside the building, an outdoor temperature sensor 32 that measures a temperature outside the building, and a room humidity that measures the humidity inside the building. The sensor 34 and the outdoor humidity sensor 36 for measuring the humidity outside the building, the outputs of the indoor temperature sensor 30 and the indoor humidity sensor 34 are received, the enthalpy inside the building is calculated, and the outdoor temperature sensor 32 outdoor humidity sensor. 36, and an enthalpy calculating means 46 for calculating the enthalpy outside the building, and the operation mode selecting means 48 is a case where the outside air temperature measured by the temperature measuring means 42 is a season determination threshold value 54 or more, If the enthalpy outside the building exceeds the enthalpy inside the building, the first operation mode is changed to operation mode data. Ventilation control system, characterized in that stored in the storage device 38 as 66.

<Configuration 8>
The ventilation control system according to Configuration 2 or 7, wherein an indoor temperature sensor 30 that measures a temperature inside the building, an outdoor temperature sensor 32 that measures a temperature outside the building, and a humidity inside the building are measured. The indoor humidity sensor 34 and the outdoor humidity sensor 36 for measuring the humidity outside the building, the outputs of the indoor temperature sensor 30 and the indoor humidity sensor 34 are received, the enthalpy inside the building is calculated, and the outdoor temperature sensor 32 And an enthalpy calculating means 46 for receiving the humidity sensor 36 and calculating the enthalpy outside the building. The operation mode selecting means 48 is a case where the outside temperature measured by the temperature measuring means 42 is less than the seasonal determination threshold value 54. When the enthalpy outside the building exceeds the enthalpy inside the building, the second operation mode is operated. Ventilation control system and to store the mode data 66 in the storage device 38.

<Configuration 9>
In the ventilation control system according to any one of Configurations 1 to 8, the fan control means 50 is configured so that the amount of air discharged by the exhaust duct 16 is smaller than the amount of outside air sucked by the air supply duct 14. A ventilation control system, wherein operating speeds of the air supply fan 18 and the exhaust fan 20 are selected.

<Configuration 10>
The ventilation control system according to any one of configurations 1 to 9, wherein the fan control means 50 is a state in which an individual ventilation fan provided in any room in the building is continuously operated together with the air supply fan 18. Ventilation control system characterized by being held in.

<Configuration 11>
The ventilation control system according to Configuration 2 or 4 to 8, wherein the outdoor temperature sensor 30 is arranged in the vicinity of an outside air inlet of the air supply duct.

<Configuration 12>
A ventilation control program that causes a computer to function as a control device including any means of configurations 1 to 8.

<Configuration 13>
A computer-readable recording medium on which the ventilation control program according to Configuration 12 is recorded.

<Effect of Configuration 1>
The operation mode is selected by the control signal 45. In winter, it is the first mode of operation and ventilates without lowering the room temperature with a heat exchanger. During the summer and intermediate periods (spring and autumn) other than the winter season, the exhaust fan is stopped in the second operation mode, so power can be saved. Since the air supply fan 18 is always operated, the interior of the room is kept at a higher pressure than the outside, and there is no possibility that odors or the like will flow from the gaps between the various parts of the building. Further, it is possible to prevent dust from accumulating inside the air supply duct 14.
<Effect of Configuration 2>
Since the outdoor temperature sensor 32 determines the season, an operation mode corresponding to the place where the building is constructed can be selected.
<Effect of Configuration 3>
If the season is determined from the calendar information and weather information and the result is used as the operation mode data 66, the operation mode can be automatically selected.
<Effect of Configuration 4>
Since the indoor temperature sensor 30 and the outdoor temperature sensor 32 select the operation mode while actually measuring the temperature difference between the indoor and the outdoor, it is possible to select an optimal mode according to the environment of each building. Here, in the summer season, when the room is cool, it is possible to operate without increasing the room temperature using the heat exchanger.
<Effect of Configuration 5>
When the air conditioner is not in operation in winter, warmer outside air is taken in. Further, during the operation of the air conditioner in the summer, it is possible to perform an operation in which cool air is not released using a heat exchanger.
<Effect of Configuration 6>
When the outside air temperature exceeds room temperature in winter, the outside air can be actively taken in to prevent heat exchange.
<Effect of Configuration 7>
By comparing indoor and outdoor enthalpies, energy loss due to ventilation during cooling operation in summer can be prevented.
<Effect of Configuration 8>
By comparing indoor and outdoor enthalpies, it is possible to actively incorporate the energy of the outside air in the winter.
<Effect of Configuration 9>
The interior of the room can always be maintained in a pressurized state.
<Effect of Configuration 10>
Inflow of air from the room in which the individual ventilation fan is provided to the room in which the air supply duct 14 is opened can be prevented.
<Effect of Configuration 11>
The temperature of the outside air that affects ventilation can be measured directly. In addition, since the air supply fan is always operated, the outside air temperature can be measured stably and reliably.

It is a longitudinal cross-sectional view of the building which uses the ventilation control system 10 of this invention. It is a block diagram of the control apparatus which controls the ventilation control system of this invention. An example of control for each season is shown, (a) is the basic control of the first embodiment, (b) is the air conditioner operation in winter, (c) is the air conditioner operation in summer, and (d) is the second, third embodiment. (E) is the control of the second and fourth embodiments, and (f) and (g) are explanatory diagrams showing the control of the fifth embodiment. It is explanatory drawing of the experimental data explaining the effect of this invention. It is explanatory drawing which shows an example of the power saving effect by this invention. 3 is an operation flowchart of the control device according to the first embodiment. It is a control flowchart of Example 1 when the air conditioner is operating. 6 is an operation flowchart of the control device according to the second embodiment. 10 is an operation flowchart of the control device according to the third embodiment. 10 is an operation flowchart of the control device according to the fourth embodiment. 10 is an operation flowchart of the control device in the summer of Example 5. 10 is an operation flowchart of a control device in winter of Example 5.

  In the present invention, the air supply fan is continuously operated for continuous ventilation. Exhaust fans stop operating in seasons other than winter to save power. If control is performed so that the interior of the building does not become negative pressure by the operation of the air supply fan, it is possible to suppress the entry of odors and the like from the gaps in each part of the building. Hereinafter, embodiments of the present invention will be described in detail for each example.

FIG. 1 is a longitudinal sectional view of a building using a ventilation control system 10 of the present invention.
The building 12 in the figure has a two-story structure, and an air conditioner 56 for air conditioning is attached in the living room. Moreover, the individual ventilation fan 28 is attached to the surroundings of water, such as a toilet and a bathroom. An air supply fan 18 and an exhaust fan 20 are attached to the ceilings of the first and second floors. In the example shown in the figure, the first floor and the second floor have the same cross-sectional structure and the same equipment arrangement, so the same reference numerals are used for each equipment. In this example, it is assumed that devices with the same code perform the same operation at the same timing.

  Furthermore, the air supply duct 14 and the exhaust duct 16 are piped in each room of the building for ventilation control. A heat exchanger 26 is stored behind the ceiling of the first floor. The air supply duct 14 is open to one end of the outer wall of the building 12 at the air supply port 22. The exhaust duct 16 opens at one end to the outer wall of the building 12 at the exhaust port 24. The other ends of the air supply duct 14 and the exhaust duct 16 are opened to respective parts in the room of the building. The heat exchanger 26 has a function of performing heat exchange between outside air sucked through the air supply duct 14 and air discharged through the exhaust duct 16. A known sensible heat exchanger or a total heat exchanger is used.

  The air supply fan 18 has a function of taking outside air into the room through the air supply duct 14. The exhaust fan 20 has a function of exhausting indoor air to the outside through the exhaust duct 16. The air supply fan 18 and the exhaust fan 20 are controlled by a control device 37. In the example shown in the figure, the air supply fan 18 and the exhaust fan 20 are arranged directly above the ceiling plate of the room. A heat exchanger 26 was installed in the vicinity of the air supply port 22 and the exhaust port 24. However, for example, the air supply fan 18 and the exhaust fan 20 may be integrated with the heat exchanger 26. Alternatively, the air supply fan 18 may be fixed to the air supply port 22, and the exhaust fan 20 may be fixed to the exhaust port 24.

  The control device 37 receives an input of a control signal 45 described later and stores it in the storage device 38. According to the content of the control signal 45, one of two operation modes is selected to control the operation of the air supply fan 18 and the exhaust fan 20 described above. One of the two operation modes is called a first operation mode, and the other is called a second operation mode. In the first operation mode, as shown in FIG. 1B, both the air supply fan 18 and the exhaust fan 20 are operated. In the second operation mode, as shown in FIG. 1C, the air supply fan 18 is operated and the exhaust fan 20 is stopped.

FIG. 2 is a block diagram of a control device that controls the ventilation control system of the present invention.
The illustrated control device 37 is, for example, a computer that controls various devices in a building. The control device 37 includes an arithmetic processing device 39 and a storage device 38. The control device 37 operates as each means displayed on the arithmetic processing device 39 at a predetermined timing. The temperature measuring means 42 measures the room temperature and the outside air temperature by using the indoor temperature sensor 30 attached to the inner wall of the building 12 and the outdoor temperature sensor 32 attached to the outer wall of the building 12 as shown in FIG. The outdoor temperature data 60 is acquired and stored in the storage device 38.

  The humidity measuring means 44 measures the indoor humidity and the outdoor humidity by the indoor humidity sensor 34 attached to the inner wall of the building 12 and the outdoor humidity sensor 36 attached to the outer wall of the building 12 shown in FIG. 62 and outdoor humidity data 64 are acquired and stored in the storage device 38. The enthalpy calculating means 46 reads the indoor temperature data 58 and the indoor humidity data 62 stored in the storage device 38, calculates the indoor enthalpy, reads the outdoor temperature data 60 and the outdoor humidity data 64, and calculates the outdoor enthalpy. It has a function of calculating and storing the enthalpy data 68 obtained as a result of the calculation in the storage device 38.

  In the first embodiment, the indoor temperature sensor 30, the outdoor temperature sensor 32, the indoor humidity sensor 34, the outdoor humidity sensor 36, the temperature measuring means 42, and the humidity measuring means 44 are not used. These are used for determining the season. In the first embodiment, the season is determined using the control signal 45 input to the control device 37.

  The operation mode selection means 48 receives the input of the control signal 45 and determines whether the current time is in winter or other than winter. The control signal 45 is, for example, calendar data (calendar information) built in the control device 37 or weather information data that informs the outside air temperature. The control signal 45 is input by an arbitrary method. The operation mode selection means 48 automatically determines from the data whether it is winter or other than winter, and selects the first operation mode in winter and selects the second operation mode in other than winter. The operation mode data 66 is generated.

  The operation mode selection means 48 stores the generated operation mode data 66 in the storage device 38. The fan control means 50 has a function of controlling the operations of the air supply fan 18 and the exhaust fan 20 according to the contents of the operation mode data 66 stored in the storage device 38.

  In winter, in the first operation mode, both the air supply fan 18 and the exhaust fan 20 are operated, and the air supplied to the room is warmed using the heat exchanger 26. Therefore, ventilation can be performed without lowering the room temperature. On the other hand, since the exhaust fan 20 is stopped in the second operation mode in summer and intermediate periods (spring and autumn) other than winter, power can be saved significantly.

  When the air supply fan 18 is always operated, dust can be prevented from accumulating inside the air supply duct 14. When the air supply fan 18 is in operation, the indoor air is naturally exhausted through the exhaust duct 16 even if the exhaust fan 20 is not in operation. Also, indoor air is exhausted from the gaps between the various parts of the building. Therefore, odor does not flow from the gaps between the various parts of the building.

  For example, in winter, the fan control means 50 selects the operating speeds of the air supply fan 18 and the exhaust fan 20 so that the amount of air discharged by the exhaust duct 16 is smaller than the amount of outside air sucked by the air supply duct 14. To do. As a result, the interior of the room is kept at a higher pressure than the outside, and there is no risk of odors or the like flowing in from the gaps between the various parts of the building even in winter.

  Further, for example, if the fan control means 50 keeps the individual ventilation fan 28 provided in any room in the building in a state of continuous operation with the air supply fan 18, the water provided with the individual ventilation fan 28 is used. It is possible to prevent the inflow of air from surrounding rooms to the living room.

FIG. 3 shows a control example for each season, (a) is the basic control of the first embodiment, (b) is the air conditioner operation in winter, (c) is the air conditioner operation in summer, and (d) is the embodiment. 2 and 3, (e) is an explanatory diagram illustrating the control of the second and fourth embodiments, and (f) and (g) are diagrams illustrating the control of the fifth embodiment.
The control of the first embodiment is as shown in FIG. 3A, in which the first operation mode is in winter and the second operation mode is in other than winter. Next, the operation mode selection means 48 receives a control signal 45 for determining whether or not the air conditioner 56 is in operation.

  Then, the operation mode selection means 48 stores the second operation mode in the storage device 38 as the operation mode data 66 when the air conditioner is not operated in the winter season (FIG. 3B). This is because heat exchange is suppressed and warmer outside air is taken in. Further, when the air conditioner is in operation other than in the winter season, the first operation mode is stored in the storage device 38 as the operation mode data 66 (FIG. 3C). This is because during the operation of the air conditioner in the summer, a heat exchanger is used to prevent the cold air from escaping.

  This embodiment is the basic operation of FIGS. 3 (d) and 3 (e). In the first embodiment, the season is determined by the control signal 45 such as a calendar. In the second and subsequent embodiments, the season determination is performed using the indoor temperature sensor 30, the outdoor temperature sensor 32, the indoor humidity sensor 34, the outdoor humidity sensor 36, the temperature measuring means 42, and the humidity measuring means 44 shown in FIG. In the second embodiment, only the outdoor temperature data 60 acquired by the outdoor temperature sensor 32 is used.

  The operation mode selection means 48 reads the outdoor temperature data 60 and the season determination threshold value 54 from the storage device 38 and compares them. The season determination threshold value 54 is a constant value set in advance as a temperature suitable for switching the operation mode, and is set to, for example, 15 degrees Celsius. When the outdoor temperature data 60 is less than the seasonal determination threshold value 54, the operation mode selection unit 48 stores the first operation mode for operating both the air supply fan 18 and the exhaust fan 20 as operation mode data 66. 38.

  When the outdoor temperature data 60 is equal to or higher than the season determination threshold value 54, the operation mode selection means 48 sets the second operation mode in which the exhaust fan 20 is stopped by operating the air supply fan 18 as the operation mode data 66. Is stored in the storage device 38. The subsequent operation of the fan control means 50 is the same as that of the first embodiment.

  In the illustrated example, the outdoor temperature sensor 30 and the outdoor humidity sensor 36 are attached to the outer wall of the building 12. However, if the indoor temperature sensor 30 is arranged in the vicinity of the air inlet 22 of the air supply duct 14 where the outside air always flows, the temperature of the outside air that affects the ventilation can be directly measured.

  This embodiment is an exceptional operation of FIG. In the third embodiment, both an indoor temperature sensor 30 that measures the temperature inside the building and an outdoor temperature sensor 32 that measures the temperature outside the building are used. The operation mode selection means 48 is the first when the outside air temperature measured by the temperature measuring means 42 is greater than or equal to the season determination threshold value 54, that is, in the intermediate period or summer season and the outside air temperature exceeds room temperature. Are stored in the storage device 38 as operation mode data 66.

  That is, as shown in FIG. 3D, in addition to the season determination, the operation mode is switched by comparing the room temperature with the outside air temperature. In the summer, when the room is cooler than the outside, the outside air is cooled by the indoor air using a heat exchanger and then taken into the room. When the exhaust fan is in operation, heat can be exchanged positively, so operation without raising the room temperature is possible.

  This embodiment is an exceptional operation of FIG. Example 3 was summer operation control. In the fourth embodiment, winter operation control will be described. The operation mode selection means 48 selects the second operation mode as operation mode data when the outside air temperature measured by the temperature measurement means 42 is less than the seasonal determination threshold value 54, that is, when the outside air temperature exceeds room temperature in winter. 66 is stored in the storage device 38.

  Even if the sun is good and the outside temperature rises, the cold room temperature may not rise at night. As described above, when the outside air temperature exceeds the room temperature in the winter, the control as shown in FIG. 3 (e) can be performed so that the outside air is positively taken in and the heat exchange is not performed.

  The fifth embodiment is control for selecting an operation mode by comparing the enthalpy derived from temperature and humidity between the outdoor and indoor environments. The control illustrated in FIGS. 3F and 3G is performed. Also in this case, the control is divided between the winter and the winter. As described above, the storage device 38 stores the indoor temperature data 58, the outdoor temperature data 60, the indoor humidity data 62, and the outdoor humidity data 64. The enthalpy calculating means 46 reads the indoor temperature data 58 and the indoor humidity data 62 from the storage device 38 and calculates the enthalpy inside the building. Further, the outdoor temperature data 60 and the outdoor humidity data 64 are read to calculate the enthalpy outside the building.

  When the outside air temperature measured by the temperature measuring means 42 is equal to or higher than the seasonal determination threshold value 54, that is, when the enthalpy outside the building exceeds the enthalpy inside the building, the operation mode selecting means 48 The first operation mode is stored in the storage device 38 as operation mode data 66. That is, when the enthalpy in the room is low, heat exchange can be performed effectively to prevent energy loss due to ventilation during the cooling operation in summer.

  On the other hand, when the outside air temperature measured by the temperature measuring unit 42 is less than the seasonal determination threshold value 54, that is, in the winter, the enthalpy outside the building exceeds the enthalpy inside the building. The second operation mode is stored in the storage device 38 as operation mode data 66. That is, when the room is not sufficiently warm in the winter, it is possible to actively take in the energy of the outside air.

FIG. 4 is an explanatory diagram of experimental data for explaining the effect of the present invention.
From August 19th to August 24th, the outside temperature changed as shown in FIG. In contrast, in the room where both the air supply fan and the exhaust fan were operated as usual, the room temperature changed as shown in A of the figure. At this time, in the room adopting the second operation mode in which the exhaust fan is stopped and only the air supply fan is operated, the room temperature has changed as shown in FIG. Neither room uses an air conditioner (air conditioner).

  The reason why the temperature of the room adopting the second operation mode as a whole was kept lower was that when the room temperature was lowered by ventilation, the outside air was warmed by the heat exchanger and taken into the room. In a highly airtight house, when the air conditioner is not used, the room temperature is often higher than the outside temperature due to various heat sources in the room. It is more efficient to use an air conditioner after lowering the room temperature by ventilation. According to the present invention, this ventilation effect can be enhanced.

FIG. 5 is an explanatory diagram showing an example of the power saving effect according to the present invention.
In this example, calendar information is used to determine May to November as a period other than winter. During this period M, when the exhaust fan was stopped and only the air supply fan was operated, the power consumption for ventilation could be halved. It was proved that the power saving effect was remarkable because the period was longer than in winter.

FIG. 6 is an operation flowchart of the control device according to the first embodiment.
Hereinafter, an embodiment of a computer program for operating the above control device will be described. FIG. 7 is a flowchart of the basic operation of the first embodiment. First, in step S11, an input of a control signal 45 for determining the season is received. In step S12, the control signal 45 is stored in the storage device 38. In step S13, the operation mode selection means 48 reads the control signal 45. In step S14, the operation mode data 66 is generated in the manner already described.

  The operation mode data 66 is stored in the storage device 38. In step S15, the fan control means 50 reads the operation mode data 66. In step S16, the fan control means 50 controls each fan in the corresponding operation mode. The operation mode may be switched twice, for example, before the start of the winter period and twice a year when the winter period ends. It can be daily, weekly or monthly. The operation shown in FIG. 6 may be started at a preset time interval.

FIG. 7 is a control flowchart of the first embodiment when the air conditioner is operating.
As shown in FIGS. 3B and 3C, the operation mode selection means 48 performs the exception processing of the control in FIG. 6 in the periods other than winter and winter. In step S21, the season is determined. In the winter season, steps S22 to S24 are executed. In cases other than the winter season, the processes of steps S25 to S27 are executed.

  In the winter season, it is determined in step S22 whether the air conditioner is in operation. If the result of this determination is yes, the process proceeds to step S23. If no, the process ends. In step S23, it is determined whether or not the current operation mode is the first operation mode. If the result of this determination is yes, the process proceeds to step S24, and if no, the process ends. In step S24, the current operation mode is changed to the first operation mode, and the process ends.

  On the other hand, in cases other than the winter season, it is determined in step S25 whether or not the air conditioner is in operation. If the result of this determination is yes, the process proceeds to step S26. If no, the process ends. In step S26, it is determined whether the current operation mode is the second operation mode. If the result of this determination is yes, the process proceeds to step S27, and if no, the process ends. In step S27, the current operation mode is changed to the second operation mode, and the process ends.

FIG. 8 is an operation flowchart of the control device according to the second embodiment.
The following is also the control operation of the operation mode selection means 48. In step S31, outdoor temperature data 60 is read. In step S32, the season determination threshold value 54 is read. In step S33, the outdoor temperature data 60 and the season determination threshold value 54 are compared. In step S34, it is determined whether or not it is winter season from the comparison result. When the result of this determination is yes, the process proceeds to step S35, and when no, the process proceeds to step S36. In step S35, the mode is set to the first operation mode. In step S36, the mode is set to the second operation mode. In this control, the operation mode is selected unconditionally depending on the outdoor temperature.

FIG. 9 is an operation flowchart of the control device according to the third embodiment.
In step S 41, the operation mode selection unit 48 reads the room temperature data 58 from the storage device 38. In step S42, outdoor temperature data 60 is read. In step S43, it is determined whether or not the outside air temperature is equal to or higher than the season determination threshold value 54. If the result of this determination is yes, it is outside the winter season, so the process proceeds to step S44, and if no, the process ends. In step S44, it is determined whether or not the outside air temperature exceeds the room temperature. If the result of this determination is yes, the process proceeds to step S45, and if no, the process ends. In step S45, the first operation mode is set. Exception handling in summer.

FIG. 10 is an operation flowchart of the control device according to the fourth embodiment.
In step S51, the operation mode selection means 48 reads the room temperature data 58 from the storage device 38. In step S52, the outdoor temperature data 60 is read. In step S53, it is determined whether or not the outside air temperature is less than the season determination threshold value 54. If the result of this determination is yes, it is winter, so the process proceeds to step S54, and if no, the process ends. In step S54, it is determined whether or not the outside air temperature exceeds the room temperature. If the result of this determination is yes, the process proceeds to step S55, and if no, the process ends. In step S55, the second operation mode is set. Exception handling in winter.

FIG. 11 is an operation flowchart of the control device in the summer of the fifth embodiment.
In FIGS. 11 and 12, “E” is displayed for enthalpy. In step S61, the room temperature data 58 is read. In step S62, outdoor temperature data 60 is read. In step S63, it is determined whether or not the outside air temperature is equal to or higher than a threshold value. If the result of this determination is yes, it is outside the winter season, so the process proceeds to step S64, and if no, the process ends.

  In step S64, the enthalpy data 68 is read to determine whether the external enthalpy is equal to or greater than the indoor enthalpy. If the result of this determination is yes, the process proceeds to step S65, and if no, the process ends. In step S65, the first operation mode is set.

FIG. 12 is an operation flowchart of the control device in the winter of the fifth embodiment.
In step S71, room temperature data is read. In step S72, outdoor temperature data is read. In step S73, it is determined whether or not the outside air temperature is less than the threshold value. If the result of this determination is yes, it is winter, so the process proceeds to step S74, and if no, the process ends.

In step S74, it is determined whether the external enthalpy is equal to or greater than the indoor enthalpy. If the result of this determination is yes, the process proceeds to step S75, and if no, the process ends. In step S75, the second operation mode is set. As described above, the control of the fifth embodiment is realized.

  Note that the computer program executed by the arithmetic processing unit may be modularized in units illustrated in functional blocks, or may be integrated by combining a plurality of functional blocks. Further, the above computer program may be used by being incorporated into an existing application program. The computer program for realizing the present invention can be recorded on a computer-readable recording medium such as a CD-ROM and installed in any information processing apparatus for use.

DESCRIPTION OF SYMBOLS 10 Ventilation control system 12 Building 14 Supply duct 16 Exhaust duct 18 Supply fan 20 Exhaust fan 22 Supply port 24 Exhaust port 26 Heat exchanger 28 Individual ventilation fan 30 Indoor temperature sensor 32 Outdoor temperature sensor 34 Indoor humidity sensor 36 Outdoor humidity sensor 37 Control device 38 Storage device 39 Processing unit 42 Temperature measurement means 44 Humidity measurement means 45 Control signal 46 Enthalpy calculation means 48 Operation mode selection means 50 Fan control means 54 Season determination threshold 56 Air conditioner 58 Indoor temperature data 60 Outdoor temperature data 62 Indoor Humidity data 64 Outdoor humidity data 66 Operation mode data 68 Enthalpy data

Claims (13)

An air supply duct 14 and an exhaust duct 16 having one end opened in the outer wall of the building 12 and the other end opened into the room of the building;
A heat exchanger 26 that exchanges heat between outside air sucked through the air supply duct 14 and air discharged through the exhaust duct 16;
An air supply fan 18 for taking outside air into the room through the air supply duct 14;
An exhaust fan 20 for discharging the indoor air to the outside through the exhaust duct 16;
In response to the input of the control signal 45, in accordance with the content of the control signal 45, the first operation mode in which both the air supply fan 18 and the exhaust fan 20 are operated, the air supply fan 18 is operated, and the exhaust air is operated. An operation mode selection means 48 for storing any one of the second operation modes in which the fan 20 is stopped as the operation mode data 66 in the storage device 38;
A ventilation control system comprising fan control means (50) for controlling operations of the air supply fan (18) and the exhaust fan (20) according to the contents of the operation mode data (66) stored in the storage device. An air supply duct 14 and an exhaust duct 16 having one end opened in the outer wall of the building 12 and the other end opened into the room of the building;
A heat exchanger 26 that exchanges heat between outside air sucked through the air supply duct 14 and air discharged through the exhaust duct 16;
An air supply fan 18 for taking outside air into the room through the air supply duct 14;
An exhaust fan 20 for discharging the indoor air to the outside through the exhaust duct 16;
An outdoor temperature sensor 32 for measuring the temperature outside the building;
Temperature measuring means 42 for receiving the output of the outdoor temperature sensor 32 and measuring the outside air temperature;
When the outside temperature measured by the temperature measuring means 42 is less than the seasonal determination threshold value 54, the first operation mode for operating both the air supply fan 18 and the exhaust fan 20 is stored as operation mode data 66. 38, the air supply fan 18 is operated and the exhaust fan 20 is stopped when the outside air temperature measured by the temperature measuring means 42 is equal to or higher than the season determination threshold value 54. A ventilation control system comprising an operation mode selection means 48 for storing the mode data 66 in the storage device 38. The ventilation control system according to claim 1,
The operation mode selection means 48 includes:
Based on the calendar information or weather information, it is determined whether the present time is winter or other than winter, and the operation mode data 66 is generated so that the first operation mode is selected during the winter and the second operation mode is selected outside the winter. Ventilation control system characterized by that. The ventilation control system according to claim 2,
An indoor temperature sensor 30 for measuring the temperature inside the building, and an outdoor temperature sensor 32 for measuring the temperature outside the building,
Temperature measuring means 42 for receiving the output of the indoor temperature sensor 30 and measuring the room temperature, and receiving the output of the outdoor temperature sensor 32 and measuring the outdoor temperature;
The operation mode selection means 48 includes:
When the outside air temperature measured by the temperature measuring means 42 is equal to or greater than the season determination threshold value 54 and the outside air temperature exceeds the room temperature, the first operation mode is stored in the storage device 38 as operation mode data 66. Ventilation control system characterized by The ventilation control system according to claim 1,
The operation mode selection means 48 includes:
When a control signal for determining whether or not the air conditioner is in operation is received and the air conditioner is not operating in the winter, the second operation mode is stored in the storage device 38 as the operation mode data 66. The ventilation control system is characterized in that the first operation mode is stored in the storage device 38 as operation mode data 66 when the air conditioner is operating except in the winter season. The ventilation control system according to claim 2 or 4,
An indoor temperature sensor 30 for measuring the temperature inside the building, and an outdoor temperature sensor 32 for measuring the temperature outside the building,
Temperature measuring means 42 for receiving the output of the indoor temperature sensor 30 and measuring the room temperature, and receiving the output of the outdoor temperature sensor 32 and measuring the outdoor temperature;
The operation mode selection means 48 includes:
When the outside air temperature measured by the temperature measuring means 42 is less than the season determination threshold value 54 and the outside air temperature exceeds the room temperature, the second operation mode is stored in the storage device 38 as operation mode data 66. A ventilation control system characterized by memorizing. The ventilation control system according to claim 2,
An indoor temperature sensor 30 for measuring the temperature inside the building, and an outdoor temperature sensor 32 for measuring the temperature outside the building,
An indoor humidity sensor 34 for measuring the humidity inside the building, and an outdoor humidity sensor 36 for measuring the humidity outside the building;
Enthalpy calculating means 46 for receiving the outputs of the indoor temperature sensor 30 and the indoor humidity sensor 34, calculating the enthalpy inside the building, receiving the outdoor temperature sensor 32, the outdoor humidity sensor 36, and calculating the enthalpy outside the building; Prepared,
The operation mode selection means 48 includes:
When the outside temperature measured by the temperature measuring means 42 is equal to or greater than the seasonal determination threshold value 54 and the enthalpy outside the building exceeds the enthalpy inside the building, the first operation mode is set as operation mode data 66. A ventilation control system which is stored in the storage device. The ventilation control system according to claim 2 or 7,
An indoor temperature sensor 30 for measuring the temperature inside the building, and an outdoor temperature sensor 32 for measuring the temperature outside the building,
An indoor humidity sensor 34 for measuring the humidity inside the building, and an outdoor humidity sensor 36 for measuring the humidity outside the building;
Enthalpy calculating means 46 for receiving the outputs of the indoor temperature sensor 30 and the indoor humidity sensor 34, calculating the enthalpy inside the building, receiving the outdoor temperature sensor 32, the outdoor humidity sensor 36, and calculating the enthalpy outside the building; Prepared,
The operation mode selection means 48 includes:
When the outside air temperature measured by the temperature measuring means 42 is less than the seasonal determination threshold value 54 and the enthalpy outside the building exceeds the enthalpy inside the building, the second operation mode is changed to the operation mode data 66. Is stored in the storage device 38 as a ventilation control system. The ventilation control system according to any one of claims 1 to 8,
The fan control means 50
Ventilation control, wherein operating speeds of the air supply fan 18 and the exhaust fan 20 are selected so that the amount of air discharged by the exhaust duct 16 is smaller than the amount of outside air sucked by the air supply duct 14. system. The ventilation control system according to any one of claims 1 to 9,
The fan control means 50
The ventilation control system characterized by maintaining the individual ventilation fan provided in any room in the building in a state of continuous operation with the air supply fan 18 at all times. The ventilation control system according to claim 2 or 4 to 8,
The outdoor temperature sensor 30 is disposed in the vicinity of an outdoor air inlet of the air supply duct.   A ventilation control program for causing a computer to function as a control device including the means according to any one of claims 1 to 8.   The computer-readable recording medium which recorded the ventilation control program of Claim 12.

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