The slit viscometer (parallel pressure flow) can be used as an alternative to the capillary viscometer...

A capillary-tube viscometer is being selected to measure viscosity of a liquid food. The maximum viscosity...

A capillary-tube viscometer is being selected to measure viscosity of a liquid food. The maximum viscosity to be measured will be 230 cP, and the maximum flow rate that can be measured accurately is 0.015 kg/min. If the tube length is 10 cm and a maximum pressure of 25 Pa can be measured, determine the tube diameter to be used. The density of the product is 1000 kg/m3.

Explain one mechanism that can lead to increased capillary hydrostatic pressure and subsequently edema. Lab values:...

Explain one mechanism that can lead to increased capillary hydrostatic pressure and subsequently edema. Lab values: Na 138, K 5.5, Cl 105, Glucose 575 pH 7.25, CO2 30, HCO3 8.0 2. List 3 differential diagnoses and include your reasoning behind each. 3. What is the best diagnosis? Explain how you came to this conclusion. 4. What other findings may be present with this patient?

A venturimeter is used to measure water flow rate of 7.5m^3/min. If pressure difference between the...

A venturimeter is used to measure water flow rate of 7.5m^3/min. If pressure difference between the wide and throat sections of the venturi is 12.50 kPa, and the pipe diameter at the wide section is 20 cm, calculate the throat diameter. (Use density=1000 kg/m^3 and coefficient of discharge Cd=0.96).

When you urinate, you increase pressure in your bladder to produce the flow. For an elephant,...

When you urinate, you increase pressure in your bladder to produce the flow. For an elephant, gravity does the work. An elephant urinates at a remarkable rate of 0.0060 m3 (a bit over a gallon and a half) per second. Assume that the urine exits 1.0 m below the bladder and passes through the urethra, which we can model as a tube of diameter 8.0 cm and length 1.2 m. Assume that urine has the same density as water, and...

1. How did Young do his famous double-slit experiment? A. He used a laser to ensure...

1. How did Young do his famous double-slit experiment? A. He used a laser to ensure coherence between the two slits. B. He used a third slit to produce light that was coherent at the two slits. C. He later used a gas and did not worry about coherence between the slits. D. He did not do the experiment at all. 2. In slit problems, when do you make the approximation that the rays come out from the slits parallel...

When a pipeline branches into two parallel pipes, we have seen how the flow can divide...

When a pipeline branches into two parallel pipes, we have seen how the flow can divide unevenly, depending upon the lengths and diameters of the two branches. Consider a parallel pipe system made up of two branches. For simplicity, assume that the friction factors are the same in the two branches. Pipe A has a diameter of 1.5 inches. Pipe B has a diameter of 1 inch and a length of 10 feet. So, if the pipes were the same...

A parallel-plate capacitor has circular plates and no dielectric between the plates. Each plate has a...

A parallel-plate capacitor has circular plates and no dielectric between the plates. Each plate has a radius equal to 2.2 cm and the plates are separated by 1.1 mm. Charge is flowing onto the upper plate (and off the lower plate) at a rate of 2.9 A. (a) Find the rate of change of the electric field strength in the region between the plates. V/m·s (b) Compute the displacement current between the plates and show that it equals 2.9 A....

The best football club in the world (Juventus F. C.) have hired you to develop a...

The best football club in the world (Juventus F. C.) have hired you to develop a turf heat exchanger system for their practice ground in Vinovo (outside Turin, Italy). The premise of this new turf is that you can control the surface properties (firm or soft) by controlling its temperature and will enable their team to practice in the most diverse conditions. You design a heat exchanger system that uses coolant pipes below the turf, through which you will circulate...

QUESTION 14 Given: Net Filtration Pressure = (PC – PIF) – (πC – πIF) IF: capillary...

QUESTION 14 Given: Net Filtration Pressure = (PC – PIF) – (πC – πIF) IF: capillary colloid osmotic pressure = +22 mmHg : interstitial fluid colloid osmotic pressure = +4 mmHg : capillary hydrostatic pressure = +30 mmHg : interstitial fluid hydrostatic pressure = -2 mmHg THEN, the Net Filtration Pressure is _____________ and there is _______________ across the capillary wall. a. -14 mmHg, Net Reabsorption b. 10 mmHg, Net Filtration c. None of the answers given here are correct...

Quantitative Problem Suppose the demand function for a new smartphone can be expressed as QD =...

Quantitative Problem Suppose the demand function for a new smartphone can be expressed as QD = 1000 – 1.5P with QD being quantity demanded and P being price. The supply function can be expressed as QS = 50 + 2P Fill out the following table using the above equations: Price Quantity Quantity   Surplus Demanded Supplied Amount     or Shortage Amount 200 220 240 260 280 300 320 340 Now answer the following questions: What is the equilibrium price? You can...