To design the heat exchanger, we first need to determine the heat duty Q required to cool the chemical from 350C to 50C. We will assume that the specific heat capacity Cp of the chemical and water are constant. Let's denote the specific heat capacity of the chemical as Cp_chem and the specific heat capacity of water as Cp_water.1. Calculate the heat duty Q :Q = m_chem * Cp_chem * T_chem_initial - T_chem_final where m_chem is the mass flow rate of the chemical 1000 kg/hr , T_chem_initial is the initial temperature of the chemical 350C , and T_chem_final is the final temperature of the chemical 50C .2. Calculate the heat capacity rates for the chemical and water:C_chem = m_chem * Cp_chemC_water = m_water * Cp_waterwhere m_water is the mass flow rate of the cooling water 5000 kg/hr .3. Calculate the temperature change of the cooling water:T_water = Q / C_water4. Calculate the logarithmic mean temperature difference LMTD :T1 = T_chem_initial - T_water_inletT2 = T_chem_final - T_water_inlet + T_water LMTD = T1 - T2 / ln T1/T2 5. Calculate the required heat transfer area A :A = Q / U * LMTD where U is the overall heat transfer coefficient 500 W/m2K .Now, let's assume the specific heat capacity of the chemical Cp_chem is 2 kJ/kgK and the specific heat capacity of water Cp_water is 4.18 kJ/kgK. We can now calculate the required heat transfer area A .1. Q = 1000 kg/hr * 2 kJ/kgK * 350C - 50C = 600,000 kJ/hr = 166.67 kW2. C_chem = 1000 kg/hr * 2 kJ/kgK = 2000 kJ/hrK C_water = 5000 kg/hr * 4.18 kJ/kgK = 20,900 kJ/hrK3. T_water = 166.67 kW / 20.9 kW/K = 7.98C4. T1 = 350C - 25C = 325C T2 = 50C - 25C + 7.98C = 17.02C LMTD = 325C - 17.02C / ln 325/17.02 = 54.24C5. A = 166.67 kW / 0.5 kW/m2K * 54.24K = 6.14 m2Therefore, the required surface area of the heat exchanger is approximately 6.14 m2.