H2O/ (±0.05°C) 18‚0 18‚5 19‚0 Temperature of H2O/ (±0.05K) 291‚2 291‚7 292‚2 101‚40 101‚40 101‚40 Higher Water Level (±0.05cm) 21‚5 24‚5 28‚5 Lower Water Level (±0.05cm) 12‚5 11‚0 13‚5 Pressure of Atmosphere/ (±0.005kPa) * The temperature is converted to Kelvin from Celsius for the significance of this lab. ! Qualitative Observation ! I. Bubbles that vary in sizes form from the copper (Cu) coiled magnesium (Mg) travel upwards
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design‚ properties and functioning. Effect of various factors like seal balance‚ face pressure‚ temperature and lubrication on performance of seal and probable causes of seal leakage with their corrective action has also been described. Mechanical seals arrest the leak from shaft where it comes out of the casing. They work satisfactorily to seals almost any liquids‚ operate under full vacuum to 80 Bar pressure and temperature from 100 to 840oC. It can handle shaft speeds up to 3600 RPM and special
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)k-1k Where‚ P1 and T1 is initial absolute Temperature and absolute Pressure P2 and T2 is Temperature and Pressure after the expansion. Materials and Apparatus: Perfect gas expansion unit Procedure 1. General start up procedure is performed as stated in appendix A. All valve are fully closed 2. The hose is connected from compressive pump to pressurized chamber 3. The compressive pump is switched on and the pressure inside chamber is allowed to increase up to 160kPa.The pump is switched
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Marcet Boiler 1. Abstract This experiment was carried out to determine the relationship between the pressure andthe temperature of saturated steam in equilibrium. Besides that this experiment was alsodone to demonstrate the vapor pressure curve. The market Boiler was used for thisexperiment. When the pressure increases‚ the temperature also increases. Therefore‚ therelationship of pressure and temperature is directly proportional. The derived formulaeand the data were used to calculate the slope
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Boyle’s law‚ Pascal’s law‚ and Archimedes’ law. Boyle’s Law states that under conditions of constant temperature and quantity‚ there is an inverse relationship between the volume and pressure for an ideal gas. Pascal’s Law states that if pressure is applied to a non-flowing fluid in a container‚ then that pressure is transmitted equally in all directions within the container. Archimedes’ principles is an upward force on an object immersed in a fluid (a liquid or a gas)‚ enabling it to float or
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under variety of different conditions‚ such as‚ different amount of drops of enzymes and different temperature of water. The class measured the pressure in the test tube during the reaction of the substance with‚ 1.5 ml of H2O2‚ 1.5ml of H2O and different amounts of enzyme drops‚ to determine how much oxygen gas is produced during the reaction since the pressure of the test tube will get higher as more oxygen gas is accumulated during the reaction. 2) If more drops of the enzyme are added to the
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message: (561-542-5608) Calculations: 1. Write the balanced equation for the reaction conducted in this lab‚ including appropriate phase symbols. Mg(s) + 2HCl(aq) --> H2(g) + MgCl2(aq) 2. Determine the partial pressure of the hydrogen gas collected in the gas collection tube. The partial pressure of the hydrogen gas is 1.07 atm 3. Calculate the moles of hydrogen gas collected. pv=mrt ; n= .0013mol of hydrogen gas 4. If magnesium was the limiting reactant in this lab‚ calculate the theoretical yield
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temperature of a sample of gas. According to Charles’s law‚ the volume should double. Now‚ how much Force per unit area; in gases arising from the effect of collisions by the molecules of the gas with the wall of the container. ’‚ CAPTION‚ ’pressure’‚BELOW‚LEFT‚ WIDTH‚ 200‚ FGCOLOR‚ ’#D9D9D9’‚ BGCOLOR‚ ’#90A0B6’‚ TEXTCOLOR‚ ’#000000’‚ CAPCOLOR‚ ’#000066’‚ OFFSETX‚ +100‚ OFFSETY‚ -110);" onmouseout="return nd();" onclick="return overlib(’ Force per unit area; in gases arising from the effect
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Relationship Between Pressure‚ Temperature‚ and Volume The relationships between temperature and volume is directly proportional. This means that volume expands as temperature rises. A drop in temperature can also mean a drop in volume. In the 18th century‚ scientists discovered that relationships between pressure‚ volume‚ and temperature were constant across types of gas. These early laws gave rise to the combined gas laws and the ideal gas laws. Charles’s Law Charles’ Law shows a direct relationship
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Results Table showing strains form grids 1 – 3 at different pressures Pressure Ɛ1‚Grid #1(μƐ) Ɛ2‚ Grid #2 (μƐ) Ɛ3‚ Grid #3 (μƐ) (Bar) Up Down Avg Up Down Avg Up Down Avg 0 0 0 0 0 29 14.5 0 -12 -6 68.95 31.5 32.5 32 79.5 95 87.25 38.5 46 42.25 137.89 65 65.5 65.25 154 166 160 97.5 103.5 100.5 206.84 98.5 97.5 98 224 231.5 227.75 154.5 161.5 158 275.79 133.5 131.5 132.5 297.5 299.5 298.5 219.5 220 219.75 344.74 166.5 166.5 166
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