Concept explainers
(a)
Interpretation:
If a low or high value of specific growth rate is desired when bacteria are used in the production of a commodity chemical should be explained.
Concept introduction:
When an initial growth of bacteria cell is introduced to a nutritional medium. The cells exhibit balanced growth. This means that for a given period the population of cells double. The time required to double the population is called the doubling time. However, the doubling time depends on the factors like type of bacteria, temperature, nutritional medium etc.
Following equation is the modelled equation for this growth,
(b)
Interpretation:
Using the given expression, a graph should be plotted with a straight line and value of growth rate and initial concentration should be determined.
Concept introduction:
When an initial growth of bacteria cell is introduced to a nutritional medium. The cells exhibit balanced growth. This means that for a given period of time the population of cells double. The time required to double the population is called the doubling time. However, the doubling time depends on the factors like type of bacteria, temperature, nutritional medium etc.
Following equation is the modelled equation for this growth,
(c)
Interpretation:
The specific growth rate using given data should be calculated.
Concept introduction:
When an initial growth of bacteria cell is introduced to a nutritional medium. The cells exhibit balanced growth. This means that for a given period of time the population of cells double. The time required to double the population is called the doubling time. However, the doubling time depends on the factors like type of bacteria, temperature, nutritional medium etc.
Following equation is the modelled equation for this growth,
(d)
Interpretation:
An expression for the doubling time of a bacterial growth should be derived and the doubling time should be calculated.
Concept introduction:
When an initial growth of bacteria cell is introduced to a nutritional medium. The cells exhibit balanced growth. This means that for a given period of time the population of cells double. The time required to double the population is called the doubling time. However, the doubling time depends on the factors like type of bacteria, temperature, nutritional medium etc.
Following equation is the modelled equation for this growth,
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Chapter 2 Solutions
ELEM.PRIN.OF CHEMICAL PROC.-W/ACCESS
- The power out of an adiabatic steam turbine is 5 MW and the steam enters turbine at 2 MPa and velocity of 50 m/s, specific enthalpy (h) of 3248 kJ/kg. The elevation of the inlet is 10 m higher than at the datum. The vapor mixture exits at 15 kPa and a velocity of 180 m/s, specific enthalpy (h) of 2361.01 kJ/kg. The elevation of the exit is 6 m higher than at the datum. Let g = 9.81 m/s². Assuming the ideal gas model and R = 0.462 KJ/(kg.K). The steam specific heat ratio is 1.283. Calculate:arrow_forwardstep by step pleasearrow_forwardstep by step pleasearrow_forward
- step by steparrow_forwardThe power out of an adiabatic steam turbine is 5 MW and the steam enters turbine at 2 MPa and velocity of 50 m/s, specific enthalpy (h) of 3248 kJ/kg. The elevation of the inlet is 10 m higher than at the datum. The vapor mixture exits at 15 kPa and a velocity of 180 m/s, specific enthalpy (h) of 2361.01 kJ/kg. The elevation of the exit is 6 m higher than at the datum. Let g = 9.81 m/s². Assuming the ideal gas model and R = 0.462 KJ/(kg.K). The steam specific heat ratio is 1.283. Calculate:arrow_forwardThe power out of an adiabatic steam turbine is 5 MW and the steam enters turbine at 2 MPa and velocity of 50 m/s, specific enthalpy (h) of 3248 kJ/kg. The elevation of the inlet is 10 m higher than at the datum. The vapor mixture exits at 15 kPa and a velocity of 180 m/s, specific enthalpy (h) of 2361.01 kJ/kg. The elevation of the exit is 6 m higher than at the datum. Let g = 9.81 m/s². Assuming the ideal gas model and R = 0.462 KJ/(kg.K). The steam specific heat ratio is 1.283. Calculate:arrow_forward
- O Consider a 0.8 m high and 0.5 m wide window with thickness of 8 mm and thermal conductivity of k = 0.78 W/m °C. For dry day, the temperature of outdoor is -10 °C and the inner room temperature is 20°C. Take the heat transfer coefficient on the inner and outer surface of the window to be h₁ = 10 W/m² °C and h₂ = 40 W/m² °C which includes the effects of insulation. Determine:arrow_forwardCalculate the mass flow rate of the steam. Determine Cp and C₁ of steam.arrow_forwardstep by step pleasearrow_forward
- step by steparrow_forward4. Show that the fraction, F, of the energy released from a supercritical chain reaction that originates in the final m generations of the chain is given approximately by F= 1 km provided the total number of generations is large.arrow_forwardPLEASE SOLVE STEP BY STEP WITHOUT ARTIFICIAL INTELLIGENCE OR CHATGPT I don't understand why you use chatgpt, if I wanted to I would do it myself, I need to learn from you, not from being a d amn robot. SOLVE BY HAND STEP BY STEP A solution containing 7.5% sulfuric acid by weight at 70 °F is concentrated to 45% by weight by evaporating water. The concentrated solution and the water vapor exit the evaporator at 170 °F and 1 atm. Calculate the rate at which heat must be transferred to the evaporator to process 1500 lbm/hr of the feed solution to the evaporator. It is recommended to use the enthalpy-concentration diagram for sulfuric acid from Chapter 8 of Felder's book or an enthalpy-concentration diagram for sulfuric acid found in another unit operations book or chemical engineering manual such as Perry's.arrow_forward
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