Engineering

Identify 3 Australian Standards relating to working at heights.Detail 6 safe work practices to follow when conducting work from a ladde

Lab Project No. 4 – Hydrograph Analysisimage1.png1. (90pts) The following storm occurs over the watershed:Time (hr) 0.5 1.0 1.5 2.0 2.Accumulative rainfall depth (inch) 0.5 1.2 2.0 3.0 3.2The following unit hydrographs are given for subareas A and B.Time(hr)Subarea A, 2-hr unit hydrograph, (cfs/in)Subarea B, 0.5-hr unit hydrograph, (cfs/in)Time(hr)Subarea A, 2-hr unit hydrograph(cfs/in)SubareaB,0.5hrunithydrograph(cfs/in)0004.52203100.53205.01702501.0160705.51201601.53101906.080902.04403106.560502.55304007.04023.04704507.53003.53804208.02004.03003608.500(a.) Using the (–index values, determine the excess rainfall over each subarea for the storm for each half-hour period (10).(b.) Compute the half–hour unit hydrograph for subarea A from the 2-hr unit hydrograph by using the S-hydrograph method (20). On the same graph, show the S-hydrograph, and the half- hour and 2-hr unit hydrographs (5). A table in your discussion should summarize the peak flow rate, time to peak, and time base of both the half- hour and 2-hr unit hydrographs for subarea A (5).(c.) For the storm above, calculate the direct runoff hydrographs and the streamflow hydrographs for both subareas (30). On the same graph, show both hydrographs for both subareas (5). A table in your discussion should summarize the peak flow rate, time to peak, and time base for the direct runoff and streamflow hydrographs (5).(d) Calculate the drainage area (in both acres and mi2) for each of the subarea (10).2. (10pts) Format and quality of your report.

Believe it or not, but there are Bitcoin ATMs if You want to insert cash, and bitcoins are transferred to your secure, digital wallet. There are also peer-to-peer (PTP) exchanges. Users post what they are hoping to buy or sell and then choose their trading partner(s). like if you ever heard about Cryptoexchange software-USA , they are giving the best and excellent services to the Cryptocurrency and Bitcoins user all over the world.Are There Ways To Purchase Outside An Exchange?

Step 1. Read the following:Chapter 3: Tort LawReview IRAC Methodology in Text Chapter 2: Law, Critical Thinking, and Good CommunicationFree question:What are the fundamental purposes of tort law? Who is it meant to protect?Short Answer Question:What is a trespass?What is an assault?How is self-defense a defense to certain torts?Hypothetical:Ruth carelessly parks her car on a steep hill, leaving her car in neutral and failing to engage the parking brake. The car rolls down the hill, knocking down an electric power pole. The sparks from the live electric power line ignite a grass fire. The fire spreads until it reaches a barn about a mile away. The barn has dynamite stored inside. The dynamite explodes, causing part of burning roof to strike and injure Jim a passing motorist in a convertible. While rushing Jim to the hospital, Jack, an intoxicated ambulance driver, collides with a car driven by thieves fleeing the scene of the robbery.Discuss whether Jim can recover from Ruth for his injuries under a claim of negligence. Be sure to discuss each element of the cause of action of negligence and any affirmative defenses Ruth might raise.

During the modules of this course, you have built your Methodology section piece by piece. In the methodology you have reflected on the means by which you will research your selected organization. In the SLPs, you have covered various methods to analyze data, and you have produced analysis of your Background data for your selected firm. In this section you will reflect on your progress toward completing the Methodology Section and Background section of your Dissertation. Discuss how you will continue to improve these sections in the Dissertation road ahead.

What are the positive and negative impacts of renewable energy resource you chose? Hydropower plants typically use the mechanical energy of water from rivers, streams, or reservoirs to rotate generator blades and produce energy. This allows zero-emission power from a potentially unending  “fuel” source. Additionally, pumped storage plants can take water from lower to higher elevations when the excess flow is available and release it to generate electricity during times of higher electricity demand (M3  33).  However, this comes at a cost, causing local environmental problems since the 1960s, according to the Norwegian Environment  Agency, (2015).  The dams and plants required for hydropower can cause changes in the environment, specifically fish and wildlife, vegetation, and erosion (M3 61). A lack of indigenous support in the Philippines has not only lead to 30 people being killed defending their land and environment in 2018, (as well as 48 murders in 2017) but also disrupt the way of life of these same indigenous people who utilize the waterways for their basic living needs (Delina, 2020). Can or cannot renewable energy replace fossil fuels? I believe that it is possible to eventually replace fossil fuels with renewable energy sources (and have written a few different papers on it over my degree), although admittedly some large barriers still remain.   Norway currently boasts 97% carbon neutral power generation and are still pushing to achieve its remaining 3% (Carroll 2019).  This transition involves overcoming technological, regulatory, and political issues.  Norway’s Energy Act of 1990 deregulated its electricity sector and developed the Nord Pool, which is the world’s largest market for electricity (Hansen 2013).  Within the US, only almost 20% of the power generated is renewable energy (with 7% hydropower, 7% wind energy, 2%  biomass, 2% solar energy and less than 1% geothermal), but separating electrical generation from political gain, putting funding into renewables for advances in energy storage and transitioning fossil fuel jobs into comparable renewable jobs make this a possibility (IEA, 2019). How does renewable energy affect the current power industry infrastructure? Ideally, as new renewable energy gets adapted, the demand on the grid will decrease as efficiencies increase and some buildings will become self-sustaining. In the interim, however, the creation and maintenance of an updated distribution network to provides the safe and reliable delivery of power will require substantial infrastructure investment (M5  33). The costs of new construction and upgrades to the system  (including but not limited to smart meters distribution networks that detect and prevent overloads) will continue to increase along with consumer demand (M5 34). What help, if any, should governments give to help the establishment of renewable energy production? Beginning a focus on a renewable power transition is beneficial to the establishment in both economic and ecological ways.  The application of carbon avoidance costs has already shown large upgrades and additions to current fossil fuel flue gas lines or pulled more money in from these establishments.  Renewables would not only decrease the consumer cost per energy when compared to carbon avoidance costs but also plays a direct role in minimizing the amount of carbon released into the atmosphere.  Funding for renewable research and training for renewable job transitions would feed into electrical corporations’ financial balancing act of building new renewable power plants versus the expenses of fossil fuels and the subsequent carbon emission costs. Will the Clean Power Plan Survive? Why or why not? It is hard to believe that the Clean Power Plan will survive,  although much of my work in furthering my education comes in the hope that I can be part of it succeeding. The Clean Power Plan (Links to an external site.)  of 2015 set limits on carbon pollution from U.S. power plants,  attempting to curb the impacts of climate change around the world (NRDC 2017).   It says that limiting carbon pollution from power plants is “the single biggest step we can take to fight” climate change (NRDC, 2017).   However, the Intergovernmental Panel on Climate Change (IPCC) says that, with current operations, even expecting perfect execution going forward, the goal of limiting temperature rise to 2 degrees Celsius is out of reach, and the 1.5-degree target that scientists say must be achieved to save the earth’s coral reefs is farther still (Poneman,  2019).  I personally have seen the effects of the U.S. “clean coal”  technologies, removing mercury and acid gasses from the flue gas with activated carbon and hydrated lime or pretreating the coal to decrease the chance of those same toxins escaping (M3 55).  However, unless the  aforementioned political and training changes are fulfilled, it seems  unlikely that the IPCC prediction will change

What are the positive and negative impacts of renewable energy resource you chose? The advantages of wind power include Cost-effective: Initial start-up costs are mitigated over a period of time. costing  1–2 cents per kilowatt-hour after the production tax credit. Because the electricity from wind farms is sold at a fixed price over a long period of time (e.g. 20+ years) and its fuel is free, wind energy mitigates the price uncertainty that fuel costs add to traditional sources of energy. Enables industry growth: Wind energy projects account for over 10 billion in annual revenue. Job creation: over 100,000 workers currently in this field and it’s projected to be near 600,000 by 2050. Clean energy source: Wind energy doesn’t pollute the air like power plants that rely on the combustion of fossil fuels, such as coal or natural gas, which emit particulate matter, nitrogen oxides, and sulfur dioxide—causing human health problems and economic damages. It also, in itself does not produce greenhouse gases. Domestic source of energy:  Wind is abundant and inexhaustible. Over the past 10 years, U.S. wind power capacity has grown 15% per year, and the wind is now the largest source of renewable power in the United States. Disadvantages of wind power: Cost:  Wind projects need to be able to compete with the lowest cost electricity projects which currently can be a large challenge even with a  dramatic improvement in cost. Location/Infrastructure: Most windmill sites are remote which means the generated power must be stored and transmitted greater distances which can be another challenge and a  costly one. Furthermore, the locations may be better suited for other options than simply electricity generation. Aesthetics and Wildlife:  Some believe that the windmills themselves do not look attractive and decrease overall land value. There have been reports of many bird strikes and some disruption to habitats. Can or cannot renewable energy replace fossil fuels? The short answer is not yet at least. Wind generation on its own cannot replace fossil fuels but it is suggested that over time several renewable platforms can do the job collectively. In 2007, fossil fuels accounted for nearly 72 percent of the United States’ electric power production, while hydroelectric power supplied only 5.8 percent and other renewables supplied a mere 2.5 percent.  Those are daunting numbers, especially when you factor in Energy  Information Administration estimations that fossil fuels and uranium will still provide 85 percent of the nation’s electricity in 2030. But just as it would be unreasonable to think renewable sources could take the reins now, it’s equally unreasonable to think they can’t eventually facilitate an end to fossil fuel dependency. There’s only so much oil and coal in the Earth, after all, and global warming concerns only punctuate the need for a new direction. How does renewable energy affect the current power industry infrastructure? At the end of 2011, worldwide nameplate capacity of wind-powered generators was 238 gigawatts (GW), growing by 41 GW over the preceding year. Data from the World Wind Energy Association, an industry organization, states that wind power now has the capacity to generate  430 TWh annually, which is about 2.5% of worldwide electricity usage.  There is always wind being generated from a location even if its not windy in one region it will be in another making it reliable in a sense.  To this point, its better suited to bring stability as a hybrid option to aid the power industry’s stability. What help, if any, should governments give to help the establishment of renewable energy production? In some cases there are government incentives to build renewable sources including wind energy options. If this was done federally across the board it would be a giant step. Will the Clean Power Plan Survive? Why or why not? I guess I would say as of today, there inst a chance of survival because our current president doesn’t put as much emphasis on renewable energy or the dangers of global warming. 

 We discussed how Social Media can be implemented into IG. What policy would you implement at your company to utilize Social Media in your IG or IT departments?  What policy would you write to archive Social media data and what legal guidelines would you include as well? How do you think this policy will benefit the organization? 

medical science or Biomedical engineering I’d like to get an inventional type of research paper as they are way easier to be published. I would be interested in a review paper also not just inventional. And are you capable of running simulations and mathematical software? I am not exactly sure maybe COMSOL. but it depends on the topic.

PANPACIFIC UNIVERSITYSchool Of EngineeringProblem set1. What is the value of surface tension of a small drop of water 0.3mm in diameter which is in contact with air if the pressure within the droplet is 561Pa?2. A Hg barometer at the base of Mt. Pek reads 600mm and at the same time another barometer at the top reads 450mm. What is the approximate height of Mt. Pek?3. A building in Panpacific University is 30m high above the street level. The required static pressure of water line at the top of the building is 20kg per square meter. What must be the pressure in kPa in themain water line located 4m below the street level?4. The viscosity of water at 20?C is 1.008 centipoise. Compute for the following: a. Absolute viscosity in Pa-s b. Kinematic viscosity in m²/s and stokes5. Estimate the height to which water at 70?F will rise in a tube of diameter 0.120in. Surface tension is 0.00497lb/ft. Express your answer in inches.6. In the figure shown what is the static pressure in kPa in the air chamber?2mOil 4m2m sg=0.803mH207. For the manometer shown, determine the difference in pressure between A and BOil, sg=0.85800mmB2000mmA Water8. Air is kept at a pressure of 200kPa absolute and at a temperature of 30?C in a 500-liter container. What is the mass of the air?9. A liquid compressed in a container has a volume of 2liter at a pressure of 1MPa and a volume of 1 liter at a pressure of 2MPa. What is the bulk modulus of elasticity of the liquid?10. Determine the pressure difference between pipes A and B.WaterA 1.50mB1.0m0.50m 1.30mMercury11. A vertical rectangular gate 2m wide and 4m high is submerged in water with its top edge 2m below the water surface. Find the total pressure acting on one side of the gate and itslocation from the bottom.12. A vertical triangular surface of height 3m and horizontal base width of 1.5 m is submerged in a liquid with its vertex at the liquid surface. Determine the total force F acting on oneside and its location from the liquid surface.13. A 20m long Dam retains 8m of water. Find the total resultant force acting on the dam and the location of the center of pressure from the bottom.14. A dam is triangular in cross section with the upstream face vertical. Water is flushed withthe top. The dam is 8m high and 6m wide at the base. The coefficient of friction between thebase and foundation is 0.8. Determine the factors of safety against a) overturning ; b)sliding.15. The section of a concrete gravity dam shown in the figure. The depth of water at the upstream side is 6m. Neglect hydrostatic uplift and use unit weight of concrete equal to23.5 kN/m³. Coefficient of friction between the base of the dam and the foundation is 0.60.Determine the following; a) factor of safety against sliding; b) the factor of safety againstoverturning; c) the overturning moment acting against the dam in kN-m.