Water quality analysis PH sensor is an important device used to measure the acidity and alkalinity of water. It usually uses an electrochemical system composed of a glass electrode and a reference electrode to measure the concentration of hydrogen ions in water and then determine the PH value. When the sensor is immersed in water, the special membrane on the surface of the glass electrode responds to the hydrogen ions in the water. By measuring the potential difference between the electrodes, and then through specific conversion and calculation, the accurate PH value is obtained.
Water quality analysis PH sensor is an important device used to measure the acidity and alkalinity of water. It usually uses an electrochemical system composed of a glass electrode and a reference electrode to measure the concentration of hydrogen ions in water and then determine the PH value. When the sensor is immersed in water, the special membrane on the surface of the glass electrode responds to the hydrogen ions in the water. By measuring the potential difference between the electrodes, and then through specific conversion and calculation, the accurate PH value is obtained.
Water quality analysis ORP (oxidation reduction potential) sensors are important devices used to measure the redox capacity of water. ORP sensors determine the redox potential of water by measuring the potential difference between an electrode and a reference electrode. This potential difference reflects the relative strength of oxidants and reductants in water, thus allowing the redox state of the water to be assessed.
Water quality analysis conductivity sensor is an important device used to measure the conductivity of water. The conductivity sensor uses two electrodes inserted into the water and calculates the conductivity of the water by measuring the resistance between the electrodes. The higher the ion concentration in the water, the stronger the conductivity and the greater the conductivity.
Water quality analysis conductivity sensor is an important device used to measure the conductivity of water. The conductivity sensor uses two electrodes inserted into the water and calculates the conductivity of the water by measuring the resistance between the electrodes. The higher the ion concentration in the water, the stronger the conductivity and the greater the conductivity.
The PH controller is used to measure PH. The PH measurement value can be used to control the dosing. This controller/transmitter can be used as a monitor in water treatment, electrolysis water purification, chemical process, food process, water purification or sewage control.
Conductivity is a parameter used to describe the ease with which electric charge flows in a substance. In the formula, conductivity is represented by the Greek letter σ. The standard unit of conductivity σ is Siemens/meter (abbreviated as S/m), which is the reciprocal of resistivity ρ, that is, σ=1/ρ.
When 1 ampere (1 A) current passes through the cross-section of an object and there is a voltage of 1 volt (1 V), the conductivity of the object is 1 S. Siemens is actually equivalent to 1 ampere/volt. If G is the conductivity (unit Siemens), I is the current (unit ampere), and U is the voltage (unit volt), then: G = I/U
The conductivity σ can be calculated by the conductivity G, the cross-sectional area of the conductor A, and the length of the conductor l: σ = Gl/A
Thermal flow switches use precision electronic components widely used in aviation and automobiles, and reliable and stable circuit design, making the flow signal more accurate and stable. They are currently widely used in the steel, metallurgy, pharmaceutical, chemical and other industries.
Thermal flow switches use precision electronic components widely used in aviation and automobiles, and reliable and stable circuit design, making the flow signal more accurate and stable. They are currently widely used in the steel, metallurgy, pharmaceutical, chemical and other industries.
XDB501 series liquid tank level indicator utilize piezoresistive isolated diaphragm silicon oil filled sensing elements. As the signal measuring element, it accomplishes the liquid level pressure measurement proportional to the depth of the liquid level. Then, XDB501 liquid tank level indicator can transform into standard signal output though the signal processing circuit according to the mathematical model of three relations of the measured liquid pressure, density and liquid level.
XDB502 series high-temperature resistant submersible liquid level transmitter is a practical liquid level instrument with a unique structure. Unlike traditional submersible liquid level transmitters, it employs a sensor that is not directly in contact with the measured medium. Instead, it transmits the pressure changes through the air level. The inclusion of a pressure guide tube prevents sensor clogging and corrosion, extending the sensor’s lifespan. This design makes it particularly suitable for measuring high temperatures and sewage applications.
The XDB503 series float water level sensor features an advanced diffusion silicon pressure sensor and high-precision electronic measuring components, ensuring exceptional performance. It is designed to be anti-clogging, overload-resistant, impact- resistant, and corrosion-resistant, providing reliable and accurate measurements. This transmitter is well-suited for a wide range of industrial measurement applications and can handle various media. It utilizes a PTFE pressure-guided design, making it an ideal upgrade option for traditional liquid level instruments and bit transmitters.
XDB504 series submersible anti-corrosion liquid level pressure transmitters feature PVDF material resistant to the acid liquid. They are designed to be overload-resistant, impact-resistant, and strong corrosion-resistant while providing high stability and accuracy in measurement. These transmitters are suitable for various corrosive industrial applications and media.
The 76-81GHz series products refer to frequency modulated continuous wave (FMCW) radar products that work at 76-81GHz and support four-wire and two-wire applications. The products have multiple models, with a range of up to 120m and a blind area of 8 cm. Because of its higher operating frequency and shorter wavelength, it is particularly suitable for solid applications. The working mode of transmitting and receiving electromagnetic waves through lenses has unique advantages in high dust and harsh temperature environments (+200℃). The instrument provides flange or threaded connection methods, making installation convenient and easy.
Ultrasonic level meter is a non-contact, highly reliable, cost-effective, easy to install and maintain liquid/material level measuring instrument, which can be widely used to measure the height of various liquids and solid materials. Common application conditions include liquid level measurement of rivers, pools, storage tanks, etc. in industrial environments such as municipal, chemical, storage and transportation.
