Described are a two-dimensional wind-speed and wind-direction sensor and a system thereof, relating to the field of sensing devices. The two-dimensional wind-speed and wind-direction sensor includes: an X-direction wind speed probe assembly and a Y-direction wind speed probe assembly, the X-direction wind speed probe assembly and the Y-direction wind speed probe assembly are perpendicular to each other, and the X-direction wind speed probe assembly is configured to measure a X-direction wind speed including a wind speed in the reverse direction of an X-axis, Vx−, and a wind speed in the forward direction of the X-axis Vx+; and the Y-direction wind speed probe assembly is configured to measure a Y-direction wind speed including a wind speed in reverse direction of an Y-axis, Vy−, and a wind speed in the forward direction of the Y-axis, Vy+.

A quantitative essential oil dripping device which includes: N sealed essential oil containers for containing essential oil, wherein N is a positive integer greater than or equal to 1; N gas inlet tubes and N oil outlet tubes, which are all inserted into the N essential oil containers respectively, wherein in each of the essential oil containers, a gas outlet of the gas inlet tube is located above an inlet of the oil outlet tube; a gas pump arranged at gas inlets of the N gas inlet tubes; a throttle valve communicating the gas pump with the essential oil container; and a drip number detection module configured to detect the drip number of the essential oil dripped from an oil outlet of the oil outlet tube. During use, the gas pump is started, pressure is applied to the essential oil container through the gas pump, and the essential oil is driven to be dripped from the oil outlet tube under the combined action of the gas pump and the throttle valve, thereby achieving the dripping of the essential oil. The drip number of the essential oil dripped from the oil outlet of the oil outlet tube is detected through the drip number detection module, and the amount of the dripped essential oil is measured by recording the drip number, thereby accurately controlling the dripping of the essential oil. After the dripping of the essential oil is completed, the gas pump is stopped.

A two-dimensional wind-speed and wind-direction sensor and a system thereof are provided, relating to the field of sensing devices, in order to alleviate the problem that the prior art fails to meet the user's demand for measuring two-dimensional wind speed and wind direction, and thus results in poor user experience, and to improve the user experience. The two-dimensional wind-speed and wind-direction sensor includes: an X-direction wind speed probe assembly and a Y-direction wind speed probe assembly, the X-direction wind speed probe assembly and the Y-direction wind speed probe assembly are perpendicular to each other, and the X-direction wind speed probe assembly is configured to measure a X-direction wind speed including a wind speed in the reverse direction of an X-axis, Vx−, and a wind speed in the forward direction of the X-axis Vx+; and the Y-direction wind speed probe assembly is configured to measure a Y-direction wind speed including a wind speed in reverse direction of an Y-axis, Vy−, and a wind speed in the forward direction of the Y-axis, Vy+. In addition, the sensor has a simple structure and a small volume, and is convenient to be installed; and has a high sensitivity, enabling a high-precision measurement of a low wind speed, thereby ensuring accuracy of the measurement of two-dimensional wind speed and wind direction; and also has the advantages of safety and reliability.

A quantitative essential oil dripping device which includes: N sealed essential oil containers for containing essential oil, wherein N is a positive integer greater than or equal to 1; N gas inlet tubes and N oil outlet tubes, which are all inserted into the N essential oil containers respectively, wherein in each of the essential oil containers, a gas outlet of the gas inlet tube is located above an inlet of the oil outlet tube; a gas pump arranged at gas inlets of the N gas inlet tubes; a throttle valve communicating the gas pump with the essential oil container; and a drip number detection module configured to detect the drip number of the essential oil dripped from an oil outlet of the oil outlet tube. During use, the gas pump is started, pressure is applied to the essential oil container through the gas pump, and the essential oil is driven to be dripped from the oil outlet tube under the combined action of the gas pump and the throttle valve, thereby achieving the dripping of the essential oil. The drip number of the essential oil dripped from the oil outlet of the oil outlet tube is detected through the drip number detection module, and the amount of the dripped essential oil is measured by recording the drip number, thereby accurately controlling the dripping of the essential oil. After the dripping of the essential oil is completed, the gas pump is stopped.

The present disclosure provides a microfluidic chip and a microfluidic system. The microfluidic chip includes: a droplet flow passage; at least two grating regions that are disposed along a length direction of the droplet flow channel and have different grating constants; a light source disposed at a first end of the droplet flow channel along the length direction of the droplet flow channel and configured to provide incident light rays of different wavelengths; and a wavelength detector used to detect reflected light rays or transmitted light rays of the incident light rays passing through the at least two grating regions.

A monitoring device of an oil flow mixed with air, including a tubular element coupled with at least one first and one second photoelectric sensor that emit a radiation along a first and a second optical line respectively, the tubular element being at least partially transparent to the radiation, the first and the second photoelectric sensor being mounted on the tubular element so that the first and the second optical line are mutually angled.

An automatic detection system is provided for detecting disruptions in the flow of liquid from a liquid container or containers to a dispensing apparatus. Two embodiments of the system are disclosed. In the first embodiment, a single liquid container is utilized. In the second embodiment, two liquid containers are utilized. In both embodiments, an optical sensor is employed to detect a disruption in the flow of liquid from the liquid containers to the dispensing apparatus.

An automatic detection system is provided for detecting disruptions in the flow of liquid from a liquid container or containers to a dispensing apparatus. Two embodiments of the system are disclosed. In the first embodiment, a single liquid container is utilized. In the second embodiment, two liquid containers are utilized. In both embodiments, an optical sensor is employed to detect a disruption in the flow of liquid from the liquid containers to the dispensing apparatus.

The present invention relates to an apparatus for sensing and controlling an amount of gas supply and a method for sensing and controlling an amount of gas supply thereby, which can sense a supply amount of the corresponding gas from an optical sensor in real time on the basis of the number of bubbles generated by any set time difference at the time when a target gas flows in a tube in order to differentiate the supply amount more accurately and whether or not the gas supply state is bad, and which can control pressure of the tube in real time by a series of automated devices in order to precisely realize the target supply amount according to gas supply information obtained from the optical sensor, thereby positively preventing malfunction and continuously maintaining the initial set amount of gas supply.

A monitoring device of an oil flow mixed with air, including a tubular element coupled with at least one first and one second photoelectric sensor that emit a radiation along a first and a second optical line respectively, the tubular element being at least partially transparent to the radiation, the first and the second photoelectric sensor being mounted on the tubular element so that the first and the second optical line are mutually angled.