C004-2 tetrafluoro traditional five-port electrolytic cell
Introduction: The working principle of the five-port electrolytic cell is that when the external power supply is working, electrons flow out from the negative electrode, and on the electrode connected to it, a reduction reaction with electrons is triggered, which we call the cathode; if the electrons flow into the positive electrode of the power supply, it is bound to be On the electrode connected to the positive electrode, an oxidation reaction that loses electrons is initiated, which we call the anode. When the electrolyte solution (or molten electrolyte) is energized, electrons flow from the negative electrode of the power source to the cathode of the electrolytic cell along the wire, and the cations of the electrolyte move to the cathode to obtain electrons for a reduction reaction; the anions of the electrolyte move to the anode to lose electrons (some of which form the anode). The metal atom loses electrons) an oxidation reaction occurs, and the electrons flow out of the anode of the electrolytic cell and flow back to the anode of the power supply along the wire. In this way, the current depends on the directional movement of anions and cations in the electrolyte solution (or molten electrolyte) to pass through the solution (or molten electrolyte), so the conduction process of the electrolyte solution (or molten electrolyte) is the electrolysis of the five-hole electrolytic cell. process. Technical features: 1. The C004-2 tetrafluoro traditional five-port electrolytic cell is upgraded from the glass traditional five-port electrolytic cell, 2. Resistant to strong alkaline solution, 3. All tetrafluoro system. 4. Can be matched with a rotating disc instrument 5. Volume 100/150ml
Introduction: The working principle of the five-port electrolytic cell is that when the external power supply is working, electrons flow out from the negative electrode, and on the electrode connected to it, a reduction reaction with electrons is triggered, which we call the cathode; if the electrons flow into the positive electrode of the power supply, it is bound to be On the electrode connected to the positive electrode, an oxidation reaction that loses electrons is initiated, which we call the anode. When the electrolyte solution (or molten electrolyte) is energized, electrons flow from the negative electrode of the power source to the cathode of the electrolytic cell along the wire, and the cations of the electrolyte move to the cathode to obtain electrons for a reduction reaction; the anions of the electrolyte move to the anode to lose electrons (some of which form the anode). The metal atom loses electrons) an oxidation reaction occurs, and the electrons flow out of the anode of the electrolytic cell and flow back to the anode of the power supply along the wire. In this way, the current depends on the directional movement of anions and cations in the electrolyte solution (or molten electrolyte) to pass through the solution (or molten electrolyte), so the conduction process of the electrolyte solution (or molten electrolyte) is the electrolysis of the five-hole electrolytic cell. process.
