Abstract
A control chip with a multistage flow-rate regulation function based on the correlation between the flow resistance and flow rate has been developed in this article. Compared with the traditional proportional solenoid valve, this kind of flow valve based on microfluidic technology has the characteristics of being light-weight and having no electric drive. It solves such technical problems as how the current digital microfluidic chip can only adjust the flow switch, and the adjustment of the flow rate is difficult. To linearize the output signal, we propose a design method of weighted resistance. The output flow is controlled by a 4-bit binary pressure signal. According to the binary value of the 4-bit pressure signal at the input, the output can achieve 16-stage flow adjustment. Furthermore, we integrate the three-dimensional flow resistance network, multilayer structure microvalve, and parallel fluid network into a single chip by using 3D printing to obtain a modular flow control unit. This structure enables the microflow control signal to be converted from a digital signal to an analogue signal (DA conversion), and is suitable for microflow driving components, such as in microfluidic chip sampling systems and proportional mixing systems. In the future, we expect this device to even be used in the automatic control system of a miniature pneumatic soft actuator.
Highlights
The fluid signal processing function has been one of the most popular research directions for microfluidic devices in recent years
Based on summarizing the microfluidic logic control methods in recent years, Sochol et al reported a microfluidic device with a digital processing function fabricated through a 3D printing method [2] that can process fluid signals itself
We report a microfluidic system based on a weighted flow resistance network that converts multichannel pressure digital signals to an adjustable flow rate
Summary
The fluid signal processing function has been one of the most popular research directions for microfluidic devices in recent years. It is a significant branch of digital microfluidic technology. Compared to being used as an experimental container for biochemical reactions, a microfluidic device with this function can expand the application of microfluidic technology to mechanical and electronic fields. Reported the prototype of a microfluidic device with automated control functions [1]. Based on summarizing the microfluidic logic control methods in recent years, Sochol et al reported a microfluidic device with a digital processing function fabricated through a 3D printing method [2] that can process fluid signals itself.
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