Abstract: A method for providing air quality information is disclosed. The method includes steps of collecting single-point air quality data from a plurality of mobile devices in a predetermined period of time, wherein the single-point air quality data is sensed by an actuating and sensing module of the mobile device and transmitted to a cloud data processing device through communication transmission. The single-point air quality data is combined with geographic information and processed to generate a real-time air quality map by the cloud data processing device. After the cloud data processing device receives a current location from a client device through communication transmission, information including a motion direction, a designated route, air quality information related to the current location, abnormal-air-quality notification or an evacuated route is transmitted to the client device.

Abstract: A micro-electromechanical fluid control device includes at least one flow guiding unit. The at least one flow guiding unit includes an inlet plate, a substrate, a resonance membrane, an actuating membrane and an outlet plate sequentially stacked. A first chamber is defined between the resonance membrane and the actuating membrane and a second chamber is defined between the actuating membrane and the outlet plate. While the piezoelectric membrane of the flow guiding unit drives the actuating membrane, a fluid is inhaled into the convergence chamber via the inlet of the inlet plate, transported into the first chamber via the central aperture of the resonance membrane, transported into the second chamber via a vacant space of the actuating membrane, and discharged out from the outlet of the outlet plate, so as to control the fluid to flow.

Abstract: An actuating breathable material structure is disclosed and includes a supporting main body, a plurality of actuating breathable units and a plurality of micro processing chips. The supporting main body is made of a supporting matrix. The plurality of actuating breathable units and the plurality of micro processing chips are compounded and are integrally formed with the supporting matrix into one piece. By controlling the actuation of the plurality of actuating breathable units through the plurality of micro processing chips, a breathing effect resulting from gas transportation in a specific direction is performed.

Abstract: An intelligent bra includes a main body and a gas-collecting actuating device. The main body comprising a supporting base, a cup set and two fixing elements. The cup set includes an outer layer, an inner layer and an air bag layer. The air bag layer includes an airflow channel, wherein a connection end of the airflow channel protrudes out from the cup set. The gas-collecting actuating device connects to the connection end and comprises a gas conveyor, a control module and a pressure sensor. The gas conveyor transports gas to the air bag layer to adjust the inner pressure. The control module controls the operation of the gas conveyor and a threshold setting mode of the pressure sensor. The pressure sensor detects the inner pressure of the air bag layer, so as to monitor and notify the control module to control the operation of the gas conveyor.

Abstract: A miniature pneumatic device includes a miniature fluid control device and a miniature valve device. The miniature fluid control device includes a gas inlet plate, a resonance plate, a piezoelectric actuator and a gas collecting plate. A first chamber is formed between the resonance plate and the piezoelectric actuator. After a gas is fed into the gas inlet plate, the gas is transferred to the first chamber through the resonance plate and then transferred. Consequently, a pressure gradient is generated to continuously push the gas. The miniature valve device includes a valve film and a gas outlet plate. After the gas is transferred from the miniature fluid control device to the miniature valve device, the valve opening of the valve film is correspondingly opened or closed and the gas is transferred in one direction. Consequently, a pressure-collecting operation or a pressure-releasing operation is selectively performed.

Abstract: An electronic device includes a casing, a speaker enclosure and an actuating and sensing module. The casing has an opening. The speaker enclosure is disposed within the casing to enclose a speaker. The speaker enclosure is in communication with the opening of the casing. The actuating and sensing module is disposed within the speaker enclosure. The actuating and sensing module comprises a fluid transportation device and a sensor. The fluid transportation device is driven to transport a fluid from outside the casing into the speaker enclosure through the opening of the casing to make the fluid sensed by the sensor.

Abstract: A pair of glasses with a wearing cushion device includes a main body, at least one inflatable cushion, an air pump, a switch element, a control unit and an air channel. The at least one inflatable cushion is disposed on a surface of at least one temple of the main body. The air pump is in communication with the at least one inflatable cushion. The control unit is electrically connected with the switch element and the air pump. The air channel is embedded within the main body and in communication with the at least one inflatable cushion and the air pump. When the switch element is turned on, the control unit enables the air pump to make ambient gas transferred to the at least one inflatable cushion through the air channel. Consequently, the at least one inflatable cushion is inflated with the gas and expanded to fit user's ears.

Abstract: The actuator includes a suspension plate, an outer frame, at least one bracket and a piezoelectric plate. The suspension plate includes a first surface and a second surface and is capable of bending and vibrating. The outer frame surrounds a periphery of the suspension plate. The at least one bracket is connected between the suspension plate and the outer frame for supporting the suspension plate. The piezoelectric plate includes a first electrode and a second electrode made of silver palladium alloy doped with graphene. The first electrode is coated with a conducting layer made of graphene-doped paint, and the second electrode is coated with an adhesive layer made of graphene-doped epoxy glue. The adhesive layer is configured to attach and in adhesion with the first surface of the suspension plate. A voltage is applied to the first electrode and the second electrode to make the suspension plate bend and vibrate.

Abstract: A pair of glasses with a wearing cushion device comprises a main body, an inflatable cushion system, an air pump, a switch element, a control unit and an air channel. The inflatable cushion system comprises two supporting cushions and two buffer cushions. When the switch element is turned on, the switch element issues an enabling signal to the control unit and the control unit enables the air pump in response to the enabling signal. When the air pump is enabled, an ambient gas is transferred to the two supporting cushions and the two buffer cushions through the air channel. The two supporting cushions and the two buffer cushions are inflated with the gas and expanded, so as to fit closely on the ears of the user by the two buffer cushions, and fit closely on the bridge of the nose of the user by the supporting cushions.

Abstract: An eyeglass buffer protection device for using in a pair of glasses comprises a min body, which has a penetrating channel and comprises an inflatable cushion, an air pump, a switch element and a control unit. When the switch element is turned on, the switch element issues an enabling signal to the control unit and the control unit enables the air pump in response to the enabling signal. When the air pump is enabled, an ambient gas is transferred to the inflatable cushion, so that the inflatable cushion is inflated with the gas and the main body is expanded. By penetrating the at least one leg of the glasses into the penetrating channel of the main body, the at least one leg is protected, and the main body fits closely with the ear of the user.

Abstract: A driving and information transmitting system for a sensing module includes a sensing device, a power supply device and a connection device. The sensing device includes a sensor, a microprocessor, a power controller and a data transceiver. The power supply device transfers an energy to the power controller, thereby enabling the sensor. After a monitored data sensed by the at least one sensor is transmitted to the microprocessor, the monitored data is processed into an output data by the microprocessor. After the output data is received by the data transceiver, the output data is transmitted from the data transceiver to the connection device. After a control command from the connection device is received by the data transceiver, the control command is transmitted to the microprocessor to control the sensor.

Abstract: A VOC detecting and warning method is provided. Firstly, an actuating-and-sensing module having a gas transportation actuator and a gas sensor is provided. Then, the gas transportation actuator guides a specified amount of gas to the gas sensor for obtaining plural monitored values, each of which is generated according to a result of detecting volatile organic compounds of the gas in each monitoring time interval by the gas sensor. All the monitored values obtained in a unit time period are added together, so that an accumulated comparison value is obtained. If the accumulated comparison value is determined greater than an injury threshold defined according to the VOC inhalation amount affecting the health of a human body, the actuating-and-sensing module issues a warning notification to notify the user to take protective measures.

Abstract: A VOC detecting and warning method is provided. Firstly, an actuating-and-sensing module having a gas transportation actuator and a gas sensor is provided. Then, the gas transportation actuator is enabled to guide a specific amount of gas to the gas sensor in each monitoring time interval, so that each monitored value of a VOC in the specific amount of the gas corresponding to each monitoring time interval is acquired. A plurality of the monitoring time intervals define a time unit. Then, the monitored values during the time unit are added up to obtain a metabolism comparison value. If the metabolism comparison value is larger than a warning threshold value that is defined according to an upper limit of the VOC that a human subject inhales per time unit, the actuating-and-sensing module issues an emergency call, thereby providing a user with a protective measure.

Abstract: A VOC detecting and warning method is provided. Firstly, an actuating-and-sensing module having a gas transportation actuator and a gas sensor is provided. Then, the gas transportation actuator guides a specified amount of gas to the gas sensor for obtaining plural monitored values, each of which is generated according to a result of detecting volatile organic compounds of the gas in each monitoring time interval by the gas sensor. All the monitored values obtained in a unit time period are added together and calculated, so that an average comparison value is obtained. If the average comparison value is determined greater than an injury threshold defined according to the VOC inhalation amount affecting the health of a human body, the actuating-and-sensing module issues a warning notification to notify the user to take protective measures.

Abstract: A gas detecting device includes an actuating-and-sensing module, a driving controller, a data storage device and a data processor. The actuating-and-sensing module includes a first gas sensor, a second gas sensor and a gas transportation actuator. The driving controller controls the actuations and non-actuations of the first gas sensor, the second gas sensor and the gas transportation actuator. The first gas sensor measures the target gas and transmits first gas measured information to the data storage device. The second gas sensor measures the target gas and transmits second gas measured information to the data storage device. The data processor calculates concentrations of the gases in the target gas by comparing the information stored in a gas database, the first gas measured information and the second gas measured information.

Abstract: A wearable blood pressure measuring device includes a strap structure, a micro gas pump and a pressure sensor. The strap structure is adapted to be worn by a user and has an outer surface and an inner surface. The micro gas pump is disposed on the strap structure. The pressure sensor is combined with the micro gas pump through an elastic medium, disposed on the inner surface of the strap structure and in contact with skin of the user for monitoring blood pressure. The micro gas pump is operated to drive gas, wherein the gas is transported into the elastic medium to inflate the elastic medium with the gas. The expanded elastic medium pushes the pressure sensor to press against the skin of the user for facilitating measurement of a blood pressure of a target artery by a flattening and scanning operation.

Abstract: A three-dimensional cooking machine includes a control computer and a food ingredient laminating device. The control computer is used for previously storing an image file of a desired food model and outputting a control command corresponding to the image file of the food model. The food ingredient laminating device includes an ink-jet printer. The ink-jet printer is controlled to perform a three-dimensional food laminating operation according to the control command from the control computer.

Abstract: An actuating and sensing module is provided. The actuating and sensing module includes at least one sensor, at least one actuating device and a power storage member. The sensor is disposed for measuring fluid. The actuating device is disposed proximate to the sensor and is disposed for transporting the fluid. The power storage member is configured as a graphene battery and is disposed for providing power to the at least one sensor and the at least one actuating device for driving the at least one sensor and the at least one actuating device. The actuating device is driven to transport the fluid toward the sensor so as to make the fluid measured by the sensor.

Abstract: A micro-electromechanical fluid control device includes at least one flow guiding unit. The at least one flow guiding unit includes an inlet plate, a substrate, a resonance membrane, an actuating membrane and an outlet plate sequentially stacked. A first chamber is defined between the resonance membrane and the actuating membrane and a second chamber is defined between the actuating membrane and the outlet plate. While the piezoelectric membrane of the flow guiding unit drives the actuating membrane, a fluid is inhaled into the convergence chamber via the inlet of the inlet plate, transported into the first chamber via the central aperture of the resonance membrane, transported into the second chamber via a vacant space of the actuating membrane, and discharged out from the outlet of the outlet plate, so as to control the fluid to flow.

Abstract: The actuator includes a suspension plate, an outer frame, at least one bracket and a piezoelectric plate. The suspension plate includes a first surface and a second surface and is capable of bending and vibrating. The outer frame surrounds a periphery of the suspension plate. The at least one bracket is connected between the suspension plate and the outer frame for supporting the suspension plate. The piezoelectric plate includes a first electrode and a second electrode made of silver palladium alloy doped with graphene. The first electrode is coated with a conducting layer made of graphene-doped paint, and the second electrode is coated with an adhesive layer made of graphene-doped epoxy glue. The adhesive layer is configured to attach and in adhesion with the first surface of the suspension plate. A voltage is applied to the first electrode and the second electrode to make the suspension plate bend and vibrate.