Plate And Frame Heat Exchanger
Removable Plate Heat Exchanger (RPHE) is a type of heat exchanger composed of a series of plates which are held together with gaskets. The plates are connected in a plate pack that forms a sealed Pressure Vessel. The plate pack is assembled between a fixed frame plate and a movable pressure plate and is compressed by tightening bolts.
RPHEs are quite efficient as they have a large surface area compared to other heat exchangers. Heat transfer within the heat exchanger occurs between the plates and the fluids that flow through them. One fluid flows through the plate openings in each of them, and the heat transferred is determined by the size and number of plates in the exchanger. The heat -exchanging process is repeated in each of the plates and the collected heat is transferred to the other fluid.
Plate and Frame Heat Exchangers have proved beneficial in the food and beverage industries where they are used to maintain a safe temperature during the processing and storage of foods. In addition, they are used in chemical manufacturing to cool the various chemicals that are used in this industry.
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In chemical batteries, the direct conversion of chemical energy into electrical energy is the result of spontaneous chemical reactions such as oxidation and reduction inside the battery. This reaction is carried out on two electrodes. The negative electrode active material is composed of a reducing agent having a relatively low potential and being stable in the electrolyte, such as an active metal such as zinc, cadmium or lead, and hydrogen or a hydrocarbon. The positive active material is composed of an oxidizing agent having a positive potential and being stable in the electrolyte, such as metal oxides such as manganese dioxide, lead dioxide, and nickel oxide, oxygen or air, halogens and salts thereof, oxyacids and salts thereof, and the like. . The electrolyte is a material having good ionic conductivity, such as an aqueous solution of an acid, a base, a salt, an organic or inorganic nonaqueous solution, a molten salt or a solid electrolyte. When the external circuit is disconnected, there is a potential difference (open circuit voltage) between the two poles, but there is no current, and the chemical energy stored in the battery is not converted into electric energy. When the external circuit is closed, a current flows through the external circuit under the action of the potential difference between the two electrodes. At the same time, inside the battery, due to the absence of free electrons in the electrolyte, the transfer of charge is inevitably accompanied by oxidation or reduction of the interface between the bipolar active material and the electrolyte, and migration of the reactants and reaction products. The transfer of charge in the electrolyte is also accomplished by the migration of ions. Therefore, the normal charge transfer and mass transfer process inside the battery is a necessary condition for ensuring normal output of electric energy. When charging, the direction of the internal power transmission and mass transfer process of the battery is exactly opposite to the discharge; the electrode reaction must be reversible to ensure the normal mass transfer and transmission process in the opposite direction. Therefore, the reversible electrode reaction is a necessary condition for constituting a battery . For Gibbs reaction free energy increment (focal); F is Faraday constant = 96500 library = 26.8 ampere-hour; n is the equivalent number of battery reactions. This is the basic thermodynamic relationship between the battery electromotive force and the battery reaction, and is the basic thermodynamic equation for calculating the energy conversion efficiency of the battery. In fact, when current flows through the electrode, the electrode potential deviates from the thermodynamically balanced electrode potential, a phenomenon known as polarization. The greater the current density (the current passing through the unit electrode area), the more severe the polarization. Polarization is one of the important causes of battery energy loss. There are three reasons for polarization: 1 the polarization caused by the resistance of each part of the battery is called ohmic polarization; 2 the polarization caused by the blockage of the charge transfer process in the electrode-electrolyte interface layer is called activation polarization; - The polarization caused by the slow mass transfer process in the electrolyte interface layer is called concentration polarization. The method of reducing the polarization is to increase the electrode reaction area, reduce the current density, increase the reaction temperature, and improve the catalytic activity of the electrode surface.