JP2008281224A - Ventilation device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a ventilation device provided with an infrared ray detecting means, operating a fan motor only for a specific time when it receives the stop from an infrared remote controller, and then stopping the fan motor. <P>SOLUTION: A control means 1 is connected with the fan motor 2, a commercial power source 3, and the infrared ray detecting means 4 detecting the infrared ray transmitted from the infrared remote controller. In the constitution, the control means 1 controls the operation or stop of the fan motor on the basis of an operation signal or a stop signal transmitted from the infrared remote controller, and the control means 1 continues the operation for 10 minutes when it receives the stop signal, and then stops the operation. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a ventilation fan that ventilates a room.

  Conventionally, this type of ventilation device has been operated and stopped in conjunction with an operation by an infrared remote controller (see, for example, Patent Document 1). The configuration will be described below with reference to FIG.

As shown in FIG. 17, the infrared remote controller 101 is provided with a switch operation unit 102 and an infrared transmitter 103, and the ventilation device 104 is provided with an infrared detector 105, which is operated or stopped in conjunction with a signal from the infrared remote controller 101. Constructed a ventilator to do.
JP-A-5-322172

  However, in such a ventilator, there is a problem that when stopping, when the infrared remote control signal is received, the ventilator stops immediately in conjunction with the inability to sufficiently ventilate the room. .

  The present invention solves the above-mentioned problem, and even if a switch operation for stopping the infrared remote control is performed, the ventilation device does not work immediately, but a comfortable environment can be created by stopping after a certain time has elapsed. It aims to provide a ventilation device.

  In addition, the signal form transmitted from the infrared remote controller is only to transmit infrared rays or stop infrared rays, and it is not necessary to use a microcomputer to make a complicated signal form, with switches, batteries, infrared LEDs, and resistors. An object of the present invention is to provide a ventilator having a simple transmission circuit and a low-cost infrared remote controller.

  Another object of the present invention is to provide an infrared remote controller that has a simple communication circuit configuration, is small in size and is light in weight, and only transmits infrared rays from the infrared remote controller or stops infrared rays.

  In addition, infrared remote controls are generally dedicated to ventilation fans, and do not operate with remote controls from other manufacturers or remote controls from other products. The number of remote controls at home increases and the distinction between remote controls for products can be understood. There was a problem that it was difficult.

  The present invention solves the above-mentioned problem, and any infrared remote controller having an artificial pulse interval starts or stops when receiving an infrared signal to the ventilator, and when it stops further, a certain time elapses. The aim is to provide a ventilator that will stop after.

  In addition, infrared remote controls are generally dedicated to ventilation fans, and do not operate with remote controls from other manufacturers or remote controls from other products, increasing the number of remote controls at home and making it difficult to distinguish remote controls from products. There was a problem to say.

  The present invention solves the above-mentioned problem, reads an infrared signal from another manufacturer, stores the signal, and starts or stops only when the stored signal is received. The aim is to provide a ventilator that will stop after.

  Further, ventilation is required depending on the indoor air condition.

  An object of the present invention is to provide a ventilator that includes a sensor in an infrared remote controller and transmits an infrared signal to the ventilator by a detection signal of the sensor.

  Moreover, in the conventional ventilation apparatus, it is requested | required that the indoor air should be ventilated by a person in the room.

  The present invention solves such a conventional problem. A human sensor is provided in an infrared remote controller, and the human sensor detects that a person has entered or exited the room, and an infrared is provided in the ventilator. It aims to provide a ventilator that transmits a signal.

  Further, in the conventional ventilator, it is required to ventilate to lower the indoor temperature when the indoor temperature rises.

  The present invention solves such a conventional problem, and a temperature sensor is provided in the infrared remote controller, and when the indoor temperature is detected by the temperature sensor and the temperature exceeds a specified temperature, an infrared signal is sent to the ventilator. It aims to provide a ventilator that transmits.

  Moreover, in the conventional ventilator, when the indoor ammonia concentration rises, ventilation is required to lower the indoor ammonia concentration.

  The present invention solves such a conventional problem. An ammonia sensor is provided in an infrared remote controller, and when the ammonia is detected indoors by the ammonia sensor and exceeds a predetermined concentration, an infrared signal is transmitted to the ventilator. The purpose is to provide a ventilation device.

  In addition, in the conventional ventilation device, it is required to ventilate in order to exhaust smoke or odor to the outdoors when smoking indoors.

  The present invention solves such a conventional problem, and provides a ventilator that provides an infrared signal to the ventilator when a smoke sensor is provided in the infrared remote controller and indoor smoke is detected by the smoke sensor. The purpose is that.

  Moreover, in the conventional ventilator, when the indoor carbon dioxide concentration rises, ventilation is required to reduce the indoor carbon dioxide concentration.

The present invention solves such a conventional problem, and a CO ₂ sensor is provided in the infrared remote controller, and when the carbon dioxide in the room is detected by the CO ₂ sensor and becomes a predetermined concentration or more, the red air is supplied to the ventilator. It aims at providing the ventilator which transmits an outside signal.

  Moreover, in the conventional ventilator, when the carbon monoxide concentration in the room rises, ventilation is required to reduce the carbon monoxide concentration in the room.

  The present invention solves such a conventional problem. A CO sensor is provided in an infrared remote controller. When carbon monoxide is detected by the CO sensor and exceeds a predetermined concentration, an infrared is provided to the ventilator. It aims to provide a ventilator that transmits a signal.

  Moreover, in the conventional ventilator, when the indoor formaldehyde concentration rises, ventilation is required to reduce the indoor formaldehyde concentration.

  The present invention solves such a conventional problem. A VOC sensor is provided in the infrared remote controller, and when the indoor VOC is detected by the VOC sensor and exceeds a predetermined concentration, an infrared signal is sent to the ventilator. The purpose is to provide a ventilator to transmit.

  Further, in the conventional ventilator, if the indoor dust becomes more than specified, ventilation is required to reduce the indoor dust.

  The present invention solves such a conventional problem, and a dust sensor is provided in the infrared remote controller, and when the amount of dust in the room is detected by the dust sensor and becomes more than the designated dust, the infrared is provided to the ventilator. It aims to provide a ventilator that transmits a signal.

  Further, in the conventional ventilator, if the indoor humidity exceeds the specified humidity, it is required to ventilate to reduce the indoor humidity.

  The present invention solves such a conventional problem, and a humidity sensor is provided in the infrared remote controller, and when the humidity inside the room is detected by the humidity sensor, the infrared signal is sent to the ventilator. It aims to provide a ventilator that transmits.

  Moreover, in the conventional ventilator, it is requested | required that it will ventilate when indoor illumination lights.

  The present invention solves such a conventional problem. An optical sensor is provided in an infrared remote controller, and an infrared signal is transmitted to a ventilation device in accordance with ON / OFF of indoor lighting by the optical sensor. The object is to provide a device.

  Moreover, in the conventional ventilator, it is requested | required to ventilate when indoor gas is generated.

  The present invention solves such a conventional problem, and provides a ventilator that provides an infrared signal to a ventilator when a gas sensor is provided in an infrared remote controller and gas is detected indoors by the gas sensor. The purpose is to do.

  In order to achieve the above object, the ventilator according to the present invention operates the fan motor for a predetermined time when it receives a stop signal from the infrared remote controller, and then stops.

  With this method, the room can be ventilated to create a comfortable environment.

  Further, the present invention makes the infrared transmission circuit of the infrared remote controller a simple circuit such as a switch, a battery, an infrared LED, or a resistor.

  By this means, a ventilator equipped with a low-cost infrared remote control can be obtained.

  The present invention also makes the infrared transmission circuit of the infrared remote controller a simple circuit.

  By this means, an infrared remote controller capable of reducing the size and weight of the infrared remote controller can be obtained.

  In addition, the present invention uses not only a dedicated infrared remote controller but also an infrared remote controller of another manufacturer or another product.

  By this means, the number of infrared remote controllers at home can be reduced.

  In addition, the present invention stores not only a dedicated infrared remote controller for a ventilator but also an infrared remote controller of another manufacturer or another product, and reacts only to the stored infrared signal of the infrared remote controller. is there.

  By this means, it is possible to control a ventilator that reacts only to the infrared data of a specific infrared remote control.

  The infrared remote controller is provided with a sensor.

  By this means, a ventilation device that can create a comfortable environment around the infrared remote controller can be obtained.

  In the present invention, a human sensor is provided in an infrared remote controller.

  By this means, a ventilator capable of detecting the presence of a person in the room and ventilating the room air can be obtained.

  In the present invention, the infrared remote controller is provided with a temperature sensor.

  By this means, a ventilator capable of detecting the room temperature and ventilating the room air at the specified temperature is obtained.

  In the present invention, an ammonia sensor is provided in the infrared remote controller.

  By this means, the amount of ammonia in the room can be detected, and a ventilator that can ventilate the air in the room by a specified amount of ammonia or more can be obtained.

  In the present invention, the infrared remote controller is provided with a smoke sensor.

  When indoor smoke is detected by this means, a ventilator capable of ventilating indoor air is obtained.

In the present invention, the infrared remote controller is provided with a CO ₂ sensor.

  By this means, it is possible to obtain a ventilator capable of detecting indoor carbon dioxide and ventilating indoor air by a specified amount of carbon dioxide or more.

  In the present invention, a CO sensor is provided in the infrared remote controller.

  By this means, the amount of carbon monoxide in the room can be detected, and a ventilator that can ventilate the room air with a specified amount of carbon monoxide or more is obtained.

  In the present invention, a VOC sensor is provided in an infrared remote controller.

  By this means, the amount of formaldehyde in the room can be detected, and a ventilator that can ventilate the room air with a specified amount of formaldehyde or more can be obtained.

  Moreover, this invention provides a dust sensor in an infrared remote control.

  By this means, a ventilation device capable of detecting indoor dust and ventilating indoor air by the amount of dust can be obtained.

  In the present invention, the infrared remote controller is provided with a humidity sensor.

  By this means, the indoor humidity is detected, and a ventilator capable of ventilating the indoor air at a specified humidity or higher is obtained.

  In the present invention, the infrared remote controller is provided with an optical sensor.

  By this means, it is possible to obtain a ventilator capable of detecting ON / OFF of indoor lighting and ventilating indoor air.

  Moreover, this invention provides a gas sensor in an infrared remote control.

  By this means, a ventilation device capable of detecting indoor lighting gas and ventilating indoor air can be obtained.

  According to the present invention, a comfortable indoor environment can be created by operating the fan motor for a certain period of time after receiving the stop signal and then stopping the fan motor.

  Moreover, according to this invention, the ventilation apparatus provided with the low-cost infrared remote control can be provided by transmitting infrared rays with a simple circuit.

  In addition, according to the present invention, it is possible to provide an infrared remote controller that can reduce the size and weight of the infrared remote controller by transmitting infrared light with a simple circuit.

  Further, according to the present invention, not only a dedicated infrared remote controller but also an infrared remote controller of another manufacturer or another product is used, and a ventilator that can reduce the number of infrared remote controllers at home can be provided.

  Further, according to the present invention, not only the infrared remote controller dedicated to the ventilator but also the infrared signal of the infrared remote controller of another manufacturer or other product is stored, and only the stored infrared signal of the infrared remote controller is reacted. Can provide ventilation equipment.

  In addition, the infrared remote controller is provided with a sensor, and a ventilation device that can create a comfortable environment around the infrared remote controller can be provided.

  Moreover, according to this invention, the ventilation apparatus which can detect the person who exists indoors and can ventilate indoor air can be provided.

  In addition, according to the present invention, it is possible to provide a ventilator that can detect indoor temperature and ventilate indoor air when the temperature is higher than a specified temperature.

  In addition, according to the present invention, it is possible to provide a ventilator capable of detecting indoor ammonia and ventilating indoor air when ammonia exceeding a specified amount is detected.

  Further, according to the present invention, it is possible to provide a ventilator that can detect indoor smoke and ventilate indoor air when smoke is detected.

  In addition, according to the present invention, it is possible to provide a ventilator that can detect indoor carbon dioxide and ventilate indoor air when the amount of carbon dioxide exceeds a specified amount.

  Further, according to the present invention, it is possible to provide a ventilator capable of detecting indoor carbon monoxide and ventilating indoor air when the amount of carbon monoxide exceeds a specified amount.

  Further, according to the present invention, it is possible to provide a ventilator capable of detecting indoor formaldehyde and ventilating indoor air when formaldehyde exceeding a specified amount is detected.

  Moreover, according to this invention, the ventilation apparatus which can detect indoor dust and can ventilate indoor air when it becomes more than the designated dust amount can be provided.

  Further, according to the present invention, it is possible to provide a ventilator capable of detecting indoor humidity and ventilating indoor air when the humidity exceeds a specified humidity.

  Further, according to the present invention, it is possible to provide a ventilator capable of detecting indoor lighting ON / OFF and ventilating indoor air depending on the ON / OFF state.

  In addition, according to the present invention, it is possible to provide a ventilator that can detect harmful gas in the room and ventilate the air in the room.

  The invention according to claim 1 of the present invention includes a fan motor that exhausts indoor air, an infrared remote controller that transmits infrared rays, an infrared detector that detects infrared rays from the infrared remote controller, and the infrared detectors The ventilator has a control means for receiving a signal from the fan and controlling the energization of the fan motor, and when the stop signal is transmitted from the infrared remote controller, the infrared detecting means of the ventilator receives the signal for a certain period of time. Only by operating the fan motor and then stopping it, the room is sufficiently ventilated and has a function of creating a comfortable environment.

  Further, the infrared remote control has a switch for turning on / off the infrared transmission of the infrared remote control and a configuration function for only sending the infrared while the switch is turned on. Only a simple circuit that can be configured with an infrared LED and a resistor is required, and an infrared remote controller having a low cost, a small number of parts, and a high reliability can be obtained.

  Further, the infrared remote controller only needs to transmit infrared rays while the switch is ON, and has a function of obtaining a small and light infrared remote controller with a simple circuit configuration.

  In addition, the infrared remote controller is not only a dedicated infrared remote controller such as the infrared remote controller, but also an infrared remote controller having a general artificial pulse interval, when the infrared detection means receives a signal, the fan motor is turned on for a specific time. It is characterized in that it is operated and then stopped. Not only a dedicated infrared remote control but also a general infrared remote control such as a TV or an air conditioner receives a signal for a certain period of time. By only operating the fan motor and then stopping it, it has the effect of creating a comfortable environment.

  Also, an infrared signal reading switch for reading an infrared signal is provided in the control means, and when reading a specific infrared signal, the infrared detection means receives the signal while the reading switch is turned on. The infrared signal is stored in the storage means, and when the stored infrared signal is received, the fan motor is operated for a specific time, thereby reading the infrared signal of a general infrared remote control of a device such as a TV or an air conditioner. When storing and receiving a specific signal of the stored device, the fan motor is operated for a certain period of time and then stopped, thereby creating a comfortable environment.

  In addition, the infrared remote controller is provided with a sensor for detecting the environment, and the fan motor is operated or stopped by a signal detected by the sensor to create a comfortable environment around the infrared remote controller.

  Further, the infrared remote controller is provided with a human sensor for detecting a person, transmits an infrared signal upon detection of the person, and has an effect of creating a comfortable environment by driving or stopping.

  In addition, a sensor for detecting temperature is provided in the infrared remote controller, and an infrared signal is transmitted when the temperature is equal to or higher than the predetermined temperature. Has the effect of creating a comfortable environment.

  In addition, a sensor for detecting ammonia is provided in the infrared remote controller, and an infrared signal is transmitted when the ammonia concentration is higher than a predetermined ammonia concentration, and the fan motor is operated by stopping the infrared signal transmission when the ammonia concentration is lower than the predetermined ammonia concentration. Or it has the effect | action which creates a comfortable environment by stopping.

  In addition, a sensor for detecting smoke is provided in the infrared remote controller, and an infrared signal is transmitted when a predetermined smoke concentration is exceeded, and a fan motor is stopped by stopping the infrared signal transmission when the smoke concentration is less than a predetermined smoke concentration. By driving or stopping, it has the effect of creating a comfortable environment.

  Also, a sensor for detecting carbon dioxide is provided in the infrared remote controller, and an infrared signal is transmitted when the concentration exceeds a predetermined carbon dioxide concentration, and the infrared signal is stopped when the concentration falls below the predetermined carbon dioxide concentration. It has the effect of creating a comfortable environment by driving or stopping the motor.

  In addition, a sensor for detecting carbon monoxide is provided in the infrared remote controller, and an infrared signal is transmitted when the concentration exceeds a predetermined carbon monoxide concentration, and an infrared signal is transmitted when the concentration falls below the predetermined carbon monoxide concentration. By stopping or operating the fan motor, it has an effect of creating a comfortable environment.

  In addition, a sensor for detecting formaldehyde is provided in the infrared remote controller, and an infrared signal is transmitted when the concentration is higher than a predetermined formaldehyde concentration. It has the effect of creating a comfortable environment by driving or stopping the motor.

  In addition, a sensor for detecting dust is provided in the infrared remote controller, and an infrared signal is transmitted when the amount of dust exceeds a predetermined amount, and transmission of the infrared signal is stopped when the amount is less than a predetermined amount of dust. It has the effect of creating a comfortable environment by driving or stopping.

  In addition, a sensor for detecting humidity is provided in the infrared remote controller, and an infrared signal is transmitted at a value equal to or higher than a predetermined humidity. By driving or stopping, it has the effect of creating a comfortable environment.

  In addition, an infrared sensor is provided in the infrared remote controller to transmit an infrared signal by detecting the illumination ON, and when the illumination OFF is detected, the transmission of the infrared signal is stopped to stop or operate the fan motor. This has the effect of creating a comfortable environment.

  In addition, a gas sensor is provided in the infrared remote controller, and when a gas is detected, an infrared signal is transmitted, and when a gas is not detected, the infrared signal is stopped, so that the fan motor is operated or stopped, thereby improving a comfortable environment. Has the effect of creating.

(Embodiment 1)
As shown in FIG. 1, the control means 1 is connected to an infrared detection means 4 that detects infrared rays transmitted from a fan motor 2, a commercial power supply 3, and an infrared remote controller 101. As the infrared detecting means 4, it is sufficient that infrared rays can be detected, and examples thereof include an infrared light receiving element.

  In the above configuration, the control means 1 controls the operation or stop of the fan motor 2 according to the operation signal or the stop signal transmitted from the infrared remote controller 101, and the control means 1 operates for 10 minutes when receiving the stop signal. Continue and then stop. As the control means 1, there is a microcomputer programmed with the above control contents.

  In addition, although driving | running | working continuation time was defined as 10 minutes, a further effect is acquired by changing with the magnitude | size of a room | chamber interior, and the condition of indoor dirt.

  The control means 1 is a board on which a relay or triac for supplying power to the fan motor 2 and a microcomputer that receives a signal from the infrared detection means 4 and controls the continuation of the operation time is mounted. .

(Embodiment 2)
The same parts as those in the first embodiment are denoted by the same reference numerals, and detailed description thereof is omitted. FIG. 2 shows a circuit of the infrared remote controller 101, in which the anode of the infrared LED 6 is connected to the positive side of the battery 5, the cathode side of the LED 6 is connected to the resistor 7, the resistor 7 is connected to the switch 8, and the dry battery 5 is connected to the negative side.

  In the above configuration, when the switch 8 is pressed, the infrared LED 6 is turned on and the infrared ray 9 is transmitted, and the ventilation device 104 repeats the operation and the stop operation every time the infrared ray 9 is detected.

(Embodiment 3)
The same parts as those in the first and second embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 2, since the circuit of the infrared remote controller 101 is simple, it can be reduced in size and weight. For example, a circuit is formed in a penlight and used as an infrared remote controller.

(Embodiment 4)
The same parts as those in the first to third embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 3, the control means 1 detects infrared rays transmitted from another product infrared remote controller 10 with different infrared signal data such as the fan motor 2, the commercial power source 3, and the remote control of a television or air conditioner. Connected to infrared detecting means 4.

  In the above configuration, the infrared detection means 4 detects the infrared signal of the infrared unspecified data of various bit configurations transmitted from the infrared remote controller 10 of other products, that is, the infrared signal of the bit configuration that is clearly not in the natural world. When the control means 1 receives the infrared signal, the fan motor 2 is controlled to operate or stop. When the control means 1 receives the stop signal, the control means 1 continues to operate for 10 minutes, and then stops. When the infrared detection means 4 detects an infrared signal of unspecified data from the infrared remote controller 10 and the control means 1 receives the signal, the operation is started. When an infrared signal of unspecified data is received next, a stop operation is performed. Become. That is, the ventilation device 104 repeats the operation and the stop operation every time an infrared signal is received.

(Embodiment 5)
The same parts as those in the first to fourth embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 4, the control unit 1 includes an infrared detection unit 4 that detects infrared rays transmitted from the fan motor 2, the commercial power source 3, the read switch 11, the storage device 12, and the other product infrared remote controller 10. It is connected.

  In the above configuration, when a specific switch of another product infrared remote controller 10 having a different infrared signal such as a remote control of a television or an air conditioner is pressed while pressing a read switch 11 for reading infrared data using a push switch or the like. The other product infrared remote controller 10 transmits unique data possessed by a specific switch as an infrared signal, and the infrared detection means 4 detects the infrared signal of the unique data possessed by the switch and controls the infrared signal. 1 receives the unique infrared signal of the switch in the storage device 12 such as a memory, and when the release switch 11 is released, the infrared receiving means 4 starts red. When an external signal is received, an infrared signal other than the same infrared signal is received in comparison with the infrared signal stored in the storage device 12 such as a memory. Ignoring repeats the operation of stopping the operation each time it receives the stored infrared signal.

  The storage device 12 is a substrate on which ROM, RAM, or EEPROM is mounted for storing infrared signal data.

(Embodiment 6)
The same parts as those in the first to fifth embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 5, a sensor 14, an infrared transmission means 15 for transmitting an infrared signal, and an ON / OFF switch 16 are connected to a microcomputer 13 provided in the infrared remote controller 28.

  With the above configuration, the output signal of the sensor 14 is input to the microcomputer 13, and the microcomputer 13 determines from the signal whether the infrared signal 29 is transmitted from the infrared transmission means 15 to the ventilator 104 and is turned on. Even when the / OFF switch 16 is pressed, the infrared signal 29 is transmitted.

  Each time the ON / OFF switch 16 is transmitted by one switch, the ventilation device 104 repeats operation and stop. However, an ON switch and an OFF switch may be provided separately to clearly separate the operation signal and the stop signal. Similar effects can be obtained.

(Embodiment 7)
The same parts as those in the first to sixth embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 6, a human sensor 17 for detecting a person such as a pyroelectric sensor, an infrared transmission means 15 for transmitting an infrared signal, and an ON / OFF switch are provided to a microcomputer 13 provided in the infrared remote controller 28. 16 is connected.

  With the above configuration, when the microcomputer 13 confirms that there is a person in the vicinity of the infrared remote controller 28, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the infrared transmission means 15 transmits an infrared signal 29 to the ventilator 104. Further, when the human sensor 17 detects that there is no person in the room, the microcomputer 13 transmits a signal to the infrared transmitter 15, and the infrared transmitter 15 transmits an infrared signal 29 to the ventilator 104. The ventilation device 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

  Note that the infrared transmission unit 15 transmits the infrared signal 29 only when there is no person, for example, for 10 minutes after the human sensor 17 detects that there is no person in the room. That is, when the even number of infrared signals 29 are transmitted, the infrared signal 29 is transmitted after confirming that there is no person.

  The infrared transmission means 15 only needs to transmit infrared rays, and is a substrate on which infrared LEDs, resistors, and transistors are mounted.

(Embodiment 8)
The same parts as those in the first to seventh embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 7, the temperature sensor 18 and a red signal for transmitting an infrared signal to the microcomputer 13 provided in the infrared remote controller 28 are provided. The external transmission means 15 and the ON / OFF switch 16 are connected.

  With the above configuration, the microcomputer 13 detects the indoor temperature of the signal from the temperature sensor 18, and when the detected temperature reaches 28 ° C. or higher, the microcomputer 13 transmits a signal to the infrared transmission means 15, When the transmission means 15 transmits an infrared signal 29 to the ventilation device 104, the ventilation device 104 operates. When the detected temperature falls below 26 ° C., the microcomputer 13 transmits a signal to the infrared transmission means 15, When the transmission means 15 transmits the infrared signal 29 to the ventilator 104, the ventilator 104 stops. The ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

  The temperature sensor 18 only needs to be able to detect the temperature. For example, the temperature sensor 18 detects the temperature using a thermistor.

  Note that the detected temperatures of 28 ° C. and 26 ° C. are examples, and differ depending on the size of the room and the air volume of the fan.

(Embodiment 9)
The same parts as those in the first to eighth embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 8, the ammonia sensor 19 and the red signal for sending the infrared signal to the microcomputer 13 provided in the infrared remote controller 28 are shown. The external transmission means 15 and the ON / OFF switch 16 are connected.

  With the above configuration, when the microcomputer 13 detects the amount of ammonia in the room from the signal of the ammonia sensor 19 and the detected concentration reaches 1 ppm or more, the microcomputer 13 transmits a signal to the infrared transmitter 15, and the infrared transmitter When the infrared signal 29 is transmitted to the ventilator 104, the ventilator 104 is operated. When the detected concentration becomes 1 ppm or less, the microcomputer 13 transmits a signal to the infrared transmitter 15, and the infrared transmitter 15 When the infrared signal 29 is transmitted to the ventilator 104, the ventilator 104 stops, and the ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

  The ammonia sensor 19 only needs to be able to measure the amount of ammonia in the room, and may be a coulometric titration type ammonia sensor as an example.

  As an example, the ammonia detection concentration is 1 ppm in the building management method, but the ammonia detection concentration is different depending on various environments.

(Embodiment 10)
The same parts as those in the first to ninth embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 9, the smoke sensor 20 and the red signal for transmitting the infrared signal to the microcomputer 13 provided in the infrared remote controller 28 are provided. The external transmission means 15 and the ON / OFF switch 16 are connected.

  With the above configuration, when the microcomputer 13 detects indoor smoke from the signal of the smoke sensor 20, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the infrared transmission means 15 On the other hand, when the infrared signal 29 is transmitted, the ventilator 104 operates, and when no smoke is detected, the microcomputer 13 transmits a signal to the infrared transmitter 15, and the infrared transmitter 15 transmits red to the ventilator 104. When the external signal 29 is transmitted, the ventilator 104 is stopped, and the ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

  Note that the smoke sensor 20 only needs to be able to detect indoor smoke, and examples thereof include infrared rays and metal oxide semiconductors.

(Embodiment 11)
The same parts as those in the first to tenth embodiments are denoted by the same reference numerals and detailed description is omitted. As shown in FIG. 10, the CO ₂ sensor 21 and the infrared signal are sent to the microcomputer 13 provided in the infrared remote controller 28. An infrared transmitter 15 and an ON / OFF switch 16 are connected.

With the above configuration, when the microcomputer 13 detects the carbon dioxide in the room from the signal of the CO ₂ sensor 21 and the detected concentration reaches 1000 ppm or more, the microcomputer 13 transmits a signal to the infrared transmission means 15, and When the transmission means 15 transmits the infrared signal 29 to the ventilation device 104, the ventilation device 104 operates. When the detected concentration becomes 1000 ppm or less, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the infrared transmission means 15 When the infrared signal 29 is transmitted to the ventilator 104, the ventilator 104 is stopped. The ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

The CO ₂ sensor 21 only needs to be able to measure the amount of carbon dioxide in the room, and may be a solid electrolyte type CO ₂ sensor as an example.

  In addition, although the carbon dioxide detection density | concentration was 1000 ppm of the building management method as an example, it is set as a different value by various environments.

(Embodiment 12)
The same parts as those in the first to eleventh embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 11, the CO sensor 22 and the red signal for transmitting the infrared signal to the microcomputer 13 provided in the infrared remote controller 28 are provided. The external transmission means 15 and the ON / OFF switch 16 are connected.

  With the above configuration, when the microcomputer 13 detects the carbon monoxide in the room from the signal of the CO sensor 22 and the detected concentration reaches 10 ppm or more, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the infrared When the transmission means 15 transmits an infrared signal 29 to the ventilation device 104, the ventilation device 104 operates. When the detected concentration becomes 10 ppm or less, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the infrared transmission. When the infrared signal 29 is transmitted to the ventilator 104, the means 15 stops the ventilator 104, and the ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

  The CO sensor 22 only needs to be able to measure the amount of carbon monoxide in the room. For example, the CO sensor 22 may be a semiconductor CO sensor.

  In addition, although the carbon monoxide detection density | concentration was 10 ppm of the building management method as an example, it is set as a different value by various environments.

(Embodiment 13)
The same parts as those in the first to twelfth embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 12, the VOC sensor 23 and a red signal for transmitting an infrared signal to the microcomputer 13 provided in the infrared remote controller 28 are provided. The external transmission means 15 and the ON / OFF switch 16 are connected.

  With the above configuration, when the microcomputer 13 detects the VOC in the room from the signal of the VOC sensor 23 and the detected concentration reaches 0.08 ppm or more, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the red When the external transmission means 15 transmits the infrared signal 29 to the ventilation device 104, the ventilation device 104 operates. When the detected concentration becomes 0.08 ppm or less, the microcomputer 13 transmits a signal to the infrared transmission means 15, When the infrared transmission means 15 transmits the infrared signal 29 to the ventilator 104, the ventilator 104 stops, and the ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

  The VOC sensor 23 only needs to be able to measure the amount of VOC in the room, and may be a rain molecular thin film type or resistance change type VOC sensor as an example.

  In addition, although the VOC detection density | concentration was 0.08 ppm of the building management method as an example, it is set as a different value by various environments.

(Embodiment 14)
The same parts as those in the first to thirteenth embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 13, the red color is transmitted to the dust sensor 24 and the infrared signal to the microcomputer 13 provided in the infrared remote controller 28. The external transmission means 15 and the ON / OFF switch 16 are connected.

  With the above configuration, when the microcomputer 13 detects indoor dust from the signal of the optical dust sensor 24, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the infrared transmission means 15 provides ventilation. When the infrared signal 29 is transmitted to the device 104, the ventilator 104 operates, and when no smoke is detected, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the infrared transmission means 15 transmits to the ventilation device 104. When the infrared signal 29 is transmitted, the ventilator 104 is stopped, and the ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

(Embodiment 15)
The same parts as those in the first to fourteenth embodiment are given the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 14, a red color is transmitted to the microcomputer 13 provided in the infrared remote controller 28 and the infrared signal. The external transmission means 15 and the ON / OFF switch 16 are connected.

  With the above configuration, when the microcomputer 13 detects the humidity of the room from the humidity sensor 25 and the detected concentration reaches 55% or more, the microcomputer 13 transmits a signal to the infrared transmission means 15 and transmits the infrared signal. When the means 15 transmits the infrared signal 29 to the ventilator 104, the ventilator 104 operates. When the detected concentration becomes 55% or less, the microcomputer 13 transmits a signal to the infrared transmitting means 15, and the infrared transmission. When the infrared signal 29 is transmitted to the ventilator 104, the means 15 stops the ventilator 104, and the ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

  The humidity sensor 25 only needs to be able to detect indoor humidity. As an example, the humidity sensor 25 detects indoor humidity using a capacitance humidity sensor.

  Note that 55% of the detected humidity is an example, and varies depending on the size of the room and the local environment.

(Embodiment 16)
The same parts as those in the first to fifteenth embodiments are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 15, the red light that transmits the optical sensor 26 and the infrared signal to the microcomputer 13 provided in the infrared remote controller 28. The external transmission means 15 and the ON / OFF switch 16 are connected.

  With the above configuration, when the microcomputer 13 detects that the indoor lighting is on the signal of the optical sensor 26, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the infrared transmission means When the infrared signal 29 is transmitted to the ventilator 104, the ventilator 104 is operated. When the microcomputer 13 detects that the illumination is turned off, the microcomputer 13 transmits a signal to the infrared transmitting means 15, and the infrared signal is transmitted. When the transmission means 15 transmits the infrared signal 29 to the ventilator 104, the ventilator 104 stops. The ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

  In addition, the optical sensor 26 is used as what detects light using CDS as an example.

(Embodiment 17)
The same parts as those in Embodiments 1 to 16 are denoted by the same reference numerals, and detailed description thereof is omitted. As shown in FIG. 16, a red gas is transmitted to the microcomputer 13 provided in the infrared remote controller 28 and an infrared signal. The external transmission means 15 and the ON / OFF switch 16 are connected.

  With the above configuration, when the microcomputer 13 detects the amount of gas in the room from the signal of the gas sensor 27, the microcomputer 13 transmits a signal to the infrared transmission means 15, and the infrared transmission means 15 When the infrared signal 29 is transmitted, the ventilator 104 operates. When no gas is detected, the microcomputer 13 transmits a signal to the infrared transmitter 15, and the infrared transmitter 15 transmits the infrared signal to the ventilator 104. When the signal 29 is transmitted, the ventilator 104 is stopped, and the ventilator 104 repeats the operation and the stop operation every time the infrared signal 29 is received.

  The gas sensor 27 only needs to be able to detect indoor gas, and examples thereof include a ceramic type or a semiconductor sensor.

  When the ventilation fan receives the infrared signal, the operation of the operation and the stop is repeated, and the stop can be applied to a ventilation device that can provide a derating time and create a comfortable environment.

Configuration diagram of Embodiment 1 of the present invention Configuration diagram of Embodiments 2 and 3 of the present invention Configuration diagram of Embodiment 4 of the present invention Circuit diagram of Embodiment 5 of the present invention Circuit diagram of Embodiment 6 of the present invention Circuit diagram of Embodiment 7 of the present invention Configuration diagram of Embodiment 8 of the present invention Configuration diagram of Embodiment 9 of the present invention Configuration diagram of Embodiment 10 of the present invention Configuration diagram of Embodiment 11 of the present invention Configuration diagram of Embodiment 12 of the present invention Configuration diagram of Embodiment 13 of the present invention Configuration diagram of Embodiment 14 of the present invention Configuration diagram of Embodiment 15 of the present invention Configuration diagram of Embodiment 16 of the present invention Configuration diagram of Embodiment 17 of the present invention Configuration diagram of conventional ventilation fan

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Control means 2 Fan motor 3 Commercial power supply 4 Infrared detection means 5 Dry cell 6 Infrared LED
7 Resistance 8 Switch 9 Infrared 10 Other product infrared remote control 11 Reading switch 12 Storage device 13 Microcomputer 14 Sensor 15 Infrared transmission means 16 ON / OFF switch 17 Human sensor 18 Temperature sensor 19 Ammonia sensor 20 Smoke sensor 21 CO ₂ sensor 22 CO sensor 23 VOC sensor 24 Dust sensor 25 Humidity sensor 26 Optical sensor 27 Gas sensor 28 Infrared remote control 29 Infrared signal 101 Infrared remote control 102 Switch operation unit 103 Infrared transmission unit 104 Ventilation device 105 Infrared detection means

Claims (17)

A fan motor that exhausts indoor air, an infrared remote controller that sends out infrared rays, an infrared detector that detects infrared rays from the infrared remote controller, and a signal received from the infrared detectors that energizes the fan motor A ventilator having control means for controlling, when a stop signal is transmitted from the infrared remote controller, the infrared detector means of the ventilator receives it, operates the fan motor for a certain time, and then stops Ventilation device characterized by that. The ventilator according to claim 1, wherein the infrared remote controller includes a switch for turning on / off infrared transmission of the infrared remote controller, and a configuration function for only transmitting infrared while the switch is ON. 3. The remote controller according to claim 2, wherein the infrared remote controller has a shape that is small and lightweight by a simple circuit configuration that only needs to transmit infrared rays while the switch is turned on. The infrared remote controller is not only a dedicated infrared remote controller such as the above-mentioned infrared remote controller, but even an infrared remote controller with a general artificial pulse interval operates the fan motor for a specific time when the infrared detection means receives a signal. The ventilation device according to claim 1, wherein the ventilation device is stopped thereafter. An infrared signal reading switch for reading an infrared signal is provided in the control means, and when reading a specific infrared signal, the infrared detecting means receives the infrared detection means while the reading switch is turned on. The ventilator according to claim 1 or 4, wherein the fan motor is operated for a specific time when the signal is stored in the storage means and the stored infrared signal is received. The ventilation device according to claim 1, wherein a sensor for detecting an environment is provided in the infrared remote controller, and the fan motor is operated or stopped by a signal detected by the sensor. 2. The ventilation device according to claim 1, wherein a human sensor for detecting a person is provided in the infrared remote controller, and an infrared signal is transmitted upon detection of the person, and is operated or stopped. A sensor for detecting temperature is provided in the infrared remote controller, and an infrared signal is transmitted when the temperature exceeds a predetermined temperature, and the fan motor is operated or stopped by stopping the transmission of the infrared signal when the temperature is lower than the predetermined temperature. The ventilation apparatus according to claim 1. The infrared remote controller is equipped with a sensor that detects ammonia, and when the concentration exceeds a predetermined ammonia concentration, an infrared signal is transmitted. When the concentration falls below the predetermined ammonia concentration, the fan motor is operated or stopped by stopping the transmission of the infrared signal. The ventilator according to claim 1 characterized by these. The infrared remote controller is equipped with a sensor that detects smoke, and when the concentration exceeds the predetermined smoke concentration, an infrared signal is transmitted, and when the concentration falls below the predetermined smoke concentration, the fan motor is operated or stopped by stopping the transmission of the infrared signal. The ventilation apparatus according to claim 1, wherein The infrared remote controller is equipped with a sensor that detects carbon dioxide, and when the concentration exceeds the specified carbon dioxide concentration, an infrared signal is transmitted. The ventilator according to claim 1, wherein By providing a sensor for detecting carbon monoxide in the infrared remote controller, an infrared signal is transmitted when the concentration exceeds a predetermined carbon monoxide concentration, and transmission of the infrared signal is stopped when the concentration falls below a predetermined carbon monoxide concentration. The ventilation device according to claim 1, wherein the fan motor is operated or stopped. The infrared remote control is equipped with a sensor that detects formaldehyde, and when the concentration exceeds the prescribed formaldehyde concentration, an infrared signal is transmitted, and when the concentration falls below the prescribed formaldehyde concentration, the fan motor is stopped or operated by stopping the transmission of the infrared signal. The ventilator according to claim 1, wherein Infrared remote control is equipped with a sensor to detect dust, and when the amount of dust exceeds the specified amount, an infrared signal is transmitted. The ventilator according to claim 1 characterized by these. The infrared remote control is equipped with a sensor that detects humidity, and transmits an infrared signal with a value above a predetermined humidity. When the value falls below a predetermined humidity, the fan motor is operated or stopped by stopping the transmission of the infrared signal. The ventilation apparatus according to claim 1, wherein An infrared remote controller is provided with an optical sensor to transmit an infrared signal by detecting illumination ON, and when the illumination OFF is detected, the fan motor is operated or stopped by stopping transmission of the infrared signal. The ventilator according to claim 1. 2. The infrared remote controller is provided with a gas sensor, and when the gas is detected, an infrared signal is transmitted, and when the gas is not detected, the infrared signal is stopped to operate or stop the fan motor. Ventilation equipment.

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