Constant wall temperature /homogeneity in wall temperature is the need of various lab-on-chip devices employed in biological and chemical investigations. However method to maintain this condition does not seem to be available. In this work, a novel and simple way of maintaining constant wall temperature is proposed. A diverging microchannel along with conjugate effects is utilized towards this end. Both measurements and three dimensional numerical simulations are undertaken to prove the design. The investigation has been carried out over a large parameter range (divergence angle: 1–8°; length: 10–30 mm; depth: 86–200 μm; solid-to-fluid thickness ratio: 1.5–4.0, and solid-to-fluid thermal conductivity ratio: 27–646) and input conditions (mass flow rate: 4.17 × 10−5 −9.17 × 10−5 kg/s, heat flux: 2.4–9.6 W/cm2) which helped in establishing the finding. It is observed that a nearly constant wall temperature condition can be achieved over a large parameter range investigated. A model to arrive at the design parameter values is also proposed. The method is further demonstrated for series of microchannels where we successfully maintain each station at different temperature within ±1 °C. The finding is therefore significant and can be employed in both single and multi-stage processes such as PCR requiring different constant wall temperature with a fine resolution.
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机译:恒定的壁温/壁温的均匀性是在生物和化学研究中使用的各种芯片实验室设备的需要。但是,保持这种状况的方法似乎不可用。在这项工作中,提出了一种新颖且简单的保持壁温恒定的方法。为此目的,利用了发散的微通道以及共轭效应。进行了测量和三维数值模拟,以证明该设计。研究已经在较大的参数范围内进行(发散角:1–8°;长度:10–30 mm;深度:86–200μm;固液比:1.5–4.0;固液比-流体的热导率:27–646)和输入条件(质量流量:4.17××10−5 -9.17××10−5 kg / s,热通量:2.4–9.6 W / cm2)有助于建立发现。可以看出,在所研究的较大参数范围内,可以实现接近恒定的壁温条件。还提出了一个用于得出设计参数值的模型。该方法在一系列微通道上得到了进一步证明,其中我们成功地将每个工作站保持在±1°C的不同温度下。因此,这一发现意义重大,可用于单步和多步过程中,例如需要不同恒定壁温和高分辨率的PCR。
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