Archive for November, 2009
Just like solar energy, wind energy is another environment-friendly and economical energy source. With almost 40% of wind energy sources of Europe in the United Kingdom, there is immense potential to use wind energy as a source of energy.
Generating power through wind is not only efficient but also renewable like solar energy. The only downside is that a tall, moderately sized generator can be a sore eye and spoil the visual landscape, leading to murmurs of disapproval among neighbours. Think about this before you go ahead and think about how to generate wind energy in your area. However, if you do not live in a very populated area and your neighbors consent to your wind energy project, there could be nothing more beneficial to harness the potential of such a natural and renewable resource called wind.
Getting Help in the Start
If you are wondering how to generate wind energy, the British Wind Energy Association or BWEA is a good professional source of services and information for initiating projects related to wind energy. This professional body continuously organizes and manages several initiatives to propagate the use of wind as a source of energy across the country and its residences. It has information on local suppliers of wind systems and information on grants and permissions.
The ‘Energy Saving Trust’ which is backed by the government also provides provide advice on several issues for both companies and individuals and companies desiring to install wind generators on a small scale.
Other Practicalities like Cost and Savings
The cost of wind generators should fall in the range of 3000 pounds -15000 pounds for each kilowatt. This is as competitive as solar and actually slightly cheap when compared to the high output it generates. It is also expected to generate higher output in a year compared to its output in the previous year. Your wind generator should break even in about five years and the way the prices of normal energy sources are increasing, the returns of a wind generator will surely increase over a period of time.
How to Position Your Turbine
It is best to place the turbine high if you want to get the most of the wind strength without any obstructions. Also make sure to measure the wind strength in your locality so that you can place the turbine facing the direction where the wind is prevailing. To measure the wind strength, you can either buy or hire an anemometer. You can also get the person installing your wind generator to do that.
Battery or Grid?
A battery can be connected to wind generators of small scale to provide electricity to your house. The other option is to connect the wind generator to the National Grid. The decision to do the former or the latter depends totally on the circumstance. As such there is no major difference except that it will affect the direction of your energy. If you happen to stay in an area that is remote with no access to the National Grid, energy should then be directed to the battery which in turn will be connected to your residence’s mains. If you can easily access the National Grid, get the generator connected to the grid. By connecting to the grid not only will you be benefited from power savings by not using the supply of electricity from the grid, you will also be able to sell surplus electricity to the grid.
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ABSTRACT
Utility bill tracking is at the heart of an effective energy management program. Merely comparing utility bills can yield inaccurate indications of the amount of savings from energy management programs due to the unaccounted influence of weather or other factors. Correcting utility bills for weather data will give more accurate representations of savings that were accrued. This paper presents the how and why of weather correction for those who want to become more familiar with the concepts and methodology.
WHAT UTILITY BILL TRACKING CAN DO FOR YOU
Jim Faes from Jefferson County School District wrote to me “energy accounting is the backbone of our school district’s energy management program.” Why would he write that?
An energy accounting system is much like an airplane’s control panel. In order to correctly navigate your airplane, you need to understand where it is, where it was and where it is going. If you fly the plane without the control panel, you have a good chance of crashing the plane. It is the same with energy management. You need to know where you are, where you were, where you are going, and how where you are now fits with expectations of your progress.
With utility bill tracking systems, Energy managers can:
- Enter target usage and costs and track their actual performance against their targets
- Discover large increases in energy usage and take corrective actions
- Identify the buildings that are using more $/SQFT than the others, and concentrate energy management activities on those buildings.
- Determine whether your meters are on the best rates
- Check to see if you are being billed correctly by the utility
- Create bills for your tenants (if you have any)
- Determine whether you have saved any energy from your energy conservation measures
- Aggregate your usage and costs and pass this aggregated data to potential energy suppliers
- Create utility budgets
More generally, if you keep aware of the state of your utility accounting, you will know where your facility is and how it is faring towards your goals.
UTILITY BILL TRACKING: THE REPORT CARD FOR FACILITIES AND FACILITY MANAGERS
Energy Managers and some Facility Managers all to often have to justify their existence to management. How much did we save last year? Is that more than what we pay our energy manager? Did your recommendations give reasonable paybacks? Why do we even have an energy manager?
There are several methods to determine whether you have saved energy from your energy conservation efforts, as described in the literature. You can wave your hands in the air, and decide upon a number; calculate your savings based upon data logger and control points; compare utility bills to determine savings; and finally, employ a building model. (These are referred to as Option A, B, C and D in the IPMVP, FEMP Guidelines and other literature.)
Most likely, the simplest and most palatable method for the facility manager to determine whether you are saving energy is Option C, comparing utility bills. Why? Well, although some utility managers do present calculations given to them by the friendly sales rep, this method is hardly reliable, as they may produce inflated numbers. Placing dataloggers and using existing control points seems easy enough, but converting these inputs into savings numbers can sometimes prove to be outside of the scope of the facility manager’s skillset. Building modeling, while it can be useful, requires hours of time to construct the model, and may represent how much the building should be using, and may not really represent what the building truly is using. If those objections hold, that leaves utility bills as the last remaining method to quantify your performance as an energy manager. Plus, in the end, it is all about the utility bills, as the bills reflect how much you are paying.
Since most facility managers are already tracking their utility bills, it is only one additional small step to see whether you have saved any energy and costs from your energy management program. Just compare prior year bills to current year’s bills, and you will see if you have saved.
Well, it isn’t that easy. Let’s find out why.
WHY BILL COMPARISON DOESN’T WORK, OR, WHY USE WEATHER CORRECTION
Suppose you want to see savings from the new efficient chilled water system you installed this January. A simple comparison of prior and post bills should show the savings right? Well, not exactly. Suppose last year had a relatively cool summer, and this summer was devilishly hot. Would you see the savings? Maybe not.
There are a couple of ways we can plot the usage from year to year. Suppose we just looked at the usage vs. time, like most people do.
We have marked two regions in Figure 1. The bottom (darker) region, we call non-weather sensitive usage. This usage can be attributed to computers, lights, constant volume pumps and other loads that are on regardless of what the weather is. For an all year operation, this amount is steady. (In this case, the non-weather sensitive usage is very low, since this meter serves a mechanical plant. Typically, the non-weather sensitive usage would be higher.)
We call the top (lighter) region weather sensitive usage. This is usage directly related to, in this case, air conditioning the facility. Usage in this region could be attributed to chillers, cycling chilled water pumps, cooling towers, condenser water pumps, condenser fans, and possibly fans and pumps that cycle or are on a variable frequency drive.
If last summer was cool, and this summer was hot, then the non-weather sensitive usage would likely not change from year to year, but the weather sensitive usage would change. Figure 2 is the same as Figure 1, except that it presents 2 years of data. Notice how in the second year, the weather sensitive portion is much greater due to the hot summer’s increased cooling load.
Now suppose that the new chilled water system reduced weather sensitive consumption by 20%. With the weather variation shown in Figure 2, an annual comparison of the usage may not show any energy savings at all, as we can see in Figure 3. (In Figure 3, we removed 20% of the weather sensitive usage from 2002 data, which is what we might see with a chilled water system retrofit.)
Imagine showing management these results after you invested a half million dollars. It is hard to inspire confidence in management with graphs like Figure 3. So much for utility bill comparison.
To explain these results, you might provide them with a graph of CDDs (as in Figure 4), and then they could see that, the post-retrofit year (2002) was indeed much hotter, and required more cooling and therefore led to increased usage. This might let you off the hook, but you still need to quantify how much you saved, don’t you? Management will only accept arm waving for so long.
You can quantify your savings by correcting your utility bill savings equation for weather. Had you done so you could have presented Figure 5, rather than Figure 3.
HOW WEATHER CORRECTION WORKS
Rather than compare last year’s usage to this year’s usage, when we use weather correction, we compare how much energy we would have used this year to how much energy we did use this year. Many in our industry do not call the result of this comparison, Savings, but rather Usage Avoidance or Cost Avoidance. But, since we are trying to keep this paper at an introductory level, we will use the word Savings.
When we tried to compare last year’s usage to this year’s usage, we saw Figure 3, and a disastrous project. We used the equation:
Savings = last year’s usage – this year’s usage
When we use weather correction, we end up with Figure 5, and use the equation:
Savings = How much energy we would have used this year – how much energy we did use this year**
**where this year’s usage from the 1st equation is the same as how much energy we did use this year from the 2nd equation
The next question is, how do we figure out how much energy we would have used this year. This is done using weather correction as shown below.
First, we select a year of utility bills we want to compare future usage to. This would typically be the year before you started your energy efficiency program, or the year before you, the new facility manager, were hired, or some chosen year. In this example, we would select the year of utility data before the installation of the chilled water system. We will call this year the Base Year.
As shown in Figure 6, we graph Base Year usage versus weather (in the form of Cooling Degree Days or Heating Degree Days). The blue dots represent the utility bills.
Then we find the Best Fit Line between usage and weather. The Best Fit Line is the line that comes closest to all the utility bills as shown in Figure 6. We can tell it is the Best Fit Line by looking at some statistical indicators (such as R2 value, Net Mean Bias Error and CVRMSE, which are not covered in this introductory paper) .
This Best Fit Line has an equation, which we call the Fit Line Equation, or in this case the Baseline Equation. Once we have this equation, we are done with this regression process.
Let’s recap what we have done:
- We graphed a Base Year of utility data versus weather data
- We found a Best Fit Line through the data. The Best Fit Line then represents the utility bills.
- The Best Fit Line Equation, which represents the Best Fit Line, which in turn represents the Base Year of utility data. The Fit Line Equation represents how your facility used energy during the Base Year, and would continue to use energy in the future (varying with changing weather conditions) assuming there were no significant changes occurred in building consumption patterns, such as new equipment, area or operating hours.
Base Year bills – Best Fit Line = Fit Line Equation
In our example:
Baseline Equation = Fit Line Equation
Once you have the Baseline Equation, you can determine if you saved any energy.
How? You take a bill from some billing period after the Base Year. You (or your software) plug in the number of days and the number of degree days from the bill into your Baseline Equation. Remember, the Baseline Equation represents how your building used to use energy in the Base Year. So, with the new inputs of number of days and number of degree days, the Baseline Equation will tell you how much energy the building would have used this year based upon Base Year usage patterns and this years conditions (weather and number of days). We call this usage that is determined by the Baseline Equation, Baseline Usage.
Now, to get a fair comparison of this year versus last year, we compare:
Savings = How much energy we would have used this year – How much energy we did use this year
or if we change the terminology a bit:
Savings = Baseline Energy Usage – Actual Energy Usage
where Baseline Energy Usage is calculated using the Baseline Equation and current month’s weather and number of days, and Actual Energy Usage is the current month’s bill. Both equations are one and the same, Baseline = How much energy we would have used this year, and Actual represents how much energy we did use this year.
CORRECTING FOR OTHER VARIABLES
Facility Managers in the industrial sector may want to correct for production rather than (or in addition to) weather data. This works if you have a simple variable that quantifies your production. For example, an automobile manufacturing plant can track number of automobiles produced. If your factory makes several different things, for example, disk drives, desktop computers, printers and main frame computers, it is difficult to come up with a single variable that could be used to represent production for the entire plant. However, if your printer manufacturing unit was served by a different meter or submeter than the other units, then you could use the number of printers produced as a variable for the meter (or submeter) that serves the printing unit.
WEATHER CORRECTION IN EXCEL VS. CANNED SOFTWARE
Weather correction can be done in Excel, however it can be laborious, and oftentimes may not be as rigorous as when done using specialized software. Excel will give regressions, fit line equations, and statistical indicators which show how well your usage is represented by the fit line. However, it is difficult to find the best balance point in Excel, as you can in specialized software. Excel may force you have to choose just one balance point, and possibly then you would iterate with different balance points, whereas canned software will allow you to easily find the best fit line using different balance points. In addition, if you enter your weather data in high low temperatures or average temperatures, it can be difficult to apply the correct weather data to the correct billing periods. Try it, and you will see.
AVAILABLE WEATHER CORRECTION DESKTOP SOFTWARE
All of the major desktop utility bill tracking software packages will now correct for weather data. Nearly all of them will correct for your own variables as well. The major desktop programs are Energy CAP, Metrix, Stark Essentials, and Utility Manager Pro. You can find information on all of them online.
CONCLUSION
Weather changes from year to year. If wish to use utility bills to show energy savings from energy management programs with any degree of accuracy, it is important to correct your utility bills for fluctuations in weather.
As consumers and providers alike are all to well aware, broadband speeds experienced within metropolitan areas far exceed that of speeds experienced within rural parts of the country.
With super-fast broadband, or ADSL+2 scheduled for roll out next year, some predict the divide is only going to widen.
Predictions show that people living in rural areas could even be waiting decades before they experience speeds close to that of their metropolitan counterparts.
As mentioned, next year, BT plans to implement its ‘next generation’ ADSL (ADSL+2) which promises speeds of up to 24Mbps.
As with the current broadband situation though, your average speed will depend greatly on how far you are from your nearest BT exchange. And for some rural residence, this can be hundreds of miles.
Rural consumer concerns not only lie with the speed that they receive though, but also the extra cost they have to pay.
“There is a growing digital divide as people in built-up urban areas are able to take advantage of cheaper broadband and ‘free’ line rental, while those in the country are left languishing on more expensive packages” said Michael Phillips from Broadbandchoices.co.uk.
“Unbundled services” is the term given to when a provider (ie. Tiscali, TalkTalk, Pipex, etc) installs their own equipment within one of BTs exchanges. This allows providers to offer consumers far more competitive broadband deals than they would prior to unbundling.
As this can cost providers anything in the region of £30,000 though, they tend to reserve such services to urban areas, where development tends to be more cost effective.