Wednesday, 20 May 2015

Weather Report and Forecast For: Kakinada Dated :May 20, 2015


MAY MAX TEMP WILL BE
21 43
22 43
23 47
24 46
25 46
26 45
27 43
28 43
29 41
30 40


ENERGY EFFICIENCIES
WHAT DO I NEED TO KNOW ABOUT ENERGY EFFICIENCY IN MY WINERY?

CHECKLIST OF QUESTIONS TO ANSWER
 
 

AUDITING ENERGY USE AND DETERMINING CONSUMPTION INFORMATION
·          What sources of energy does my winery use?
1.      electrical power grid HOVER LINK TO POP-UP BALLON WITH MORE INFO
2.      onsite nonrenewable fuels: natural gas, fuel oil, petroleum, distilled alcohol, etc. LINK 2
3.      renewable: hydroelectric, solar, wind, biofuel, geothermal, etc. LINK 3
·          What is the quality of the electrical power we use, its impact on voltage tolerances of equipment?
·          What percentage of energy sources used is carbon neutral with lower environmental impact?
·          Is the current utility fee schedule optimized for my current usage profile?
·          How much of each energy source does my winery use?
·          How much of each energy source does my winery use for each operation?
·          How does my winery’s energy needs vary over time?
·          How much energy is used for each gallon of wine produced?
·          How does my winery’s energy use compare to industry standards? LINK 4
ENERGY EFFICIENCY AND CONSERVATION PROGRAMS
·          Are we utilizing programs to optimize energy efficiency and control consumption?
1.      assign an in house energy manager
2.      develop an in house energy management program
3.      establish baselines using appropriate measures of performance for each system and quantify current energy uses and losses LINK 5
4.      set annual energy reduction goals
5.      utilize local utilities to assist in energy audits and obtain tax incentive credits and rebates
·          What are we doing to reduce and offset GHG emissions associated with the package we use?
1.      reduced weight glass
2.      reduced other packaging weight - cardboard, labels, capsules, print
3.      utilizing alternative containers
4.      CO2 equivalents offset practices
·          Do we plan strategically to reduce fuels used for transportation?
1.      optimize process flow to reduce unnecessary or redundant steps
2.      schedule shipping to optimize efficient use of transport vessels
3.      schedule purchasing to optimize transportation energy
4.      use alternative to traditional fossil fuel road transport; i.e. rail, electric, hybrids
5.      encourage company and employee ride share and carpools
6.      utilize truly carbon neutral bio-fuels
·          What have we done to optimize our refrigeration efficiencies?
1.      replace Shaded Pole and Permanent Split-Capacitor (PSC) motors with Electronically Commutated (EC) motors LINK 6
2.      optimize suction pressure to reduce compressor power and save energy LINK 7
3.      variably adjust condenser set-point temperatures to optimize compressor pressure difference for varying ambient temperatures LINK 8
4.      install a thermosyphon oil cooler to replace liquid injection oil cooling LINK 9
5.      increase System Piping Diameter LINK 10
6.      purge non-condensable gases LINK 11
7.      reduced excess heat gain from: interior lights (replace with LED), inadequate defrosting, inadequate insulation, excessive air exchange, worn weather stripping, etc.
8.      clean coils at recommended levels
9.      perform cooling tower water treatment at regular intervals
10.  shift electric consumption into less expensive Off-Peak times
11.  replace air cooled condensers with evaporative condensers
12.  oversize condensers where possible
13.  utilize heat recovery from refrigeration processes when possible
14.  insulate refrigeration lines
15.  install a thermal ice storage systems
16.  insulate jacketed and non-jacketed tanks
17.  optimize tank volumes
18.  utilize electro dialysis for tartrate removal
19.  use R-404 or 507 ammonia refrigerants
20.  utilize high efficiency heat exchangers
21.  install variable speed control on condenser and evaporator fans
22.  cycle evaporator and condenser fans
23.  install computer controls for optimal compressor efficiency
24.  optimize defrost control LINK 12
25.  utilize absorption refrigerator systems which use a heat source to achieve cooling LINK 13
·          Are we using the most efficient lighting sources and controls available?
1.      replace HID fixtures with T5 or T8 fluorescent high bay fixtures
2.      install T5 or T8 fluorescent fixtures with electronic ballasts in office, lab, and common areas
3.      install compact fluorescent fixtures in bathroom and common areas
4.      install LED exit signs
5.      replace Compact fluorescent fixtures with LED white light fixtures or convert fluorescence fixtures to LED LINK 14
6.      utilize lighting controls such as time clocks, by-pass/delay timers, photocells, and motion detectors
7.      clean lighting fixtures once a year
8.      eliminate unused ballasts and remove burned out lamps to avoid ballast damage
9.      reduce lighting levels where appropriate
10.  natural lighting ( i.e Daylighting - use of windows and skylights)
·          Are we utilizing programs to maintain and operate all motors, belts, drives, fans, pumps and compressors for optimum energy efficiency?
1.      install properly sized premium efficiency motors
2.      utilize directly coupled drive systems rather than mechanical drive LINK 15
3.      utilize high torque or synchronous drive V-belts or cogged belts
4.      install timers and sensor controls to turn off during idle time
5.      use an A System Approach for most efficient pump energy reduction LINK 16
6.      install properly sized energy efficient pumps and fans LINK 17
7.      install solid state variable speed drives on pumps and fans LINK 18
8.      replace tower fill material with cellular film
9.      install energy efficient spray nozzles, airfoil fans, and motors on tower fans and pumps
10.  install 2 speed energy efficient motors on condenser fans
11.  utilize floating head pressure control
12.  utilize floating suction pressure control
13.  replace reciprocating compressors with properly sized screw compressors LINK 19
14.  PLC controlled equipment using external control of compressor cylinder loading and unloading
15.  install automatic compressor sequencing controls and shut off timers
16.  perform regular preventative maintenance
·          Do we manage our water practices to reduce associated energy needs?
1.      utilize high efficiency boilers
2.      install stack thermometer and boiler make up water meter
3.      install time clocks on boilers and aerators
4.      perform recommended maintenance on boilers and aerators
5.      employ time-of-use rates when possible
6.      perform regular combustion analysis on boilers (air/fuel mixture)
7.      water test and treatment at recommended intervals
8.      insulate hot water and steam lines
9.      heat recovery off of stacks to preheat in-take water
10.  full modulating burners (varies burner based on demand)
11.  base boiler blow down on the amount of total dissolved solids
12.  install proper steam traps, condensate storage tanks and pressurized return systems
13.  match steam load to boiler output
14.  automatic pump shutoff on low/no demand
15.  affective pre-screening of fluids into ponds
16.  install premium efficiency motors
17.  install variable speed motors to vary speed based on demand
18.  install dissolved oxygen sensors in ponds
19.  install fine bubble diffusion aerators
·          What have we done to optimize our building envelope?
1.      optimize insulation on building and tanks
2.      utilize night air cooling
3.      utilize solar screens to reduce heat gain
4.      install strip curtains on conditioned buildings with high traffic
5.      energy efficient timers and sensors for HVAC
·          What have we done to optimize our process flow and building efficiency design?
1.      gravity feed instead of pump
2.      efficient equipment layout
·          Are we using any forms of alternative and/or renewable energy?
1.      solar
2.      wind
3.      bio-fuels
4.      other
CARBON FOOTPRINTING AND CARBON OFFSETS
·          What is my winery’s carbon footprint?
1.      Quantify carbon footprint of all production components
2.      WRI based green house gas protocol – International Wine Carbon Calculator
3.      LIVE closure CO2 calculator and energy use summary
·          Do we utilize any carbon sequestering practices?
1.      grape marc composting
2.      vineyards
·          Do we employ any carbon offsets or credits?
1.      bio-mass conversion to heat or fuels
ENERGY EFFICIENT PRACTICES AND EMPLOYEE TRAINING
·          Does my winery educate and train employees in the use of energy efficient practices?
1.      employees receive training in energy and water conservation
2.      assigned an energy manager and team
·          Do we notify employees of company energy programs and accomplishments?
      1.   inform employees and costumers about efforts to improve efficiencies
·          Does my winery have an employee incentive program?
      1.   incentive and recognition programs for achievement of energy efficiency goals
ESTABLISHING AN INHERENT SYSTEM TO CONTINUOUSLY IMPROVE ENERGY EFFICIENCY
·          Do we have commitment from executive through all levels to improve energy efficiency?
·          Is a continuous improvement system imbedded in your energy management program?
RESOUCES:
Washington State Department of Ecology http://www.ecy.wa.gov/tree/index.html

Bonneville Power Administration  http://www.bpa.gov/corporate/
Consortium for Energy Efficiency, Inc.  http://www.cee1.org/
Department of Energy http://www.eere.energy.gov/
The World Resources Institute GHG protocol http://www.wri.org/project/ghg-protocol
The Wine Institute wine green house gas protocol http://www.wineinstitute.org/ghgprotocol
Winemakers Federation of Australia http://www.wfa.org.au/environment.htm
Environmental Protection Agency http://www.epa.gov/smartway/
The Wine Institute winery water guide http://www.wineinstitute.org/winerywaterguide
American Association of Wine Economists http://www.wine-economics.org/workingpapers/AAWE_WP09.pdf
Integrated Production of Wines in South Africa http://www.ipw.co.za/
Integrated Renewable energy http://intergratedrenewableenergy.com
BioEnergy Washington http://www.bioenergy.wa.gov/
Central Washington Biodiesel http://www.cwbiodiesel.com/
Special Thanks To The Following For Their Contributions:
Tom Osborn, Mechanical Engineer, Bonneville Power Administration
Bradley D. Miller, Agriculture Sector Lead, Bonneville Power Administration
Bill Clemens, Regional Community Manager, Pacific Power
Bruce Etzel, Community Development & Member Relations Manager, Benton REA
Kevin Fischer, Key Accounts Representative, Benton PUD
Washington Department of Ecology TREE team
Meryl Rickey, Enologist, Snoqualmie, Ste. Michelle Wine Estates
Warren Kenney, Maintenance Supervisor Snoqualmie, Ste. Michelle Wine Estates
Jeff Paeschke, Technical Specialist Projects, Ste. Michelle Wine Estates
LINK 1
Electrical power provided over the grid is comprised of a majority of non-renewable and some renewable generation.  Unless they specifically purchase renewable, it should be counted as nonrenewable.  This is distinct from carbon neutral, since nuclear energy can be considered carbon neutral.
LINK 2
As distinct from power sourced from the grid.  Alcohol conventionally distilled from corn is a net energy user and should not be considered renewable.
LINK 3
This can be generated on-site or purchased through the utility. It should be noted that each of these has various carbon footprints and environmental consequences that may need a prioritization scheme of its ownHydroelectric can refer to hydroelectric dams, run-of-the-river low head turbines, wave, or tidal generation.
LINK 4
The Code of Sustainable Winegrowing Practices Self-Assessment Workbook suggests an industry standard of 2.9 gallons of water to every gallon of wine produced.
LINK 5
A thermodynamic energy balance is really the only way to get a handle on energy efficiency.  This might be accomplished through heat signature measurement.  Quantification of losses as thermodynamic energy balance is the best means of identifying unnecessary energy use.  
LINK 6
There are two primary reasons you should consider using EC motors: Regulatory Compliance and Energy Efficiency. First, effective January 1, 2008, California Energy Commission (CEC) Title 20 will require all new unit coolers used in walk-in coolers and freezers to be equipped with EC motors. Other states are also considering this legislation and will likely adopt similar language within the next few years. Secondly, EC motors are much more efficient than PSC or Shaded Pole motor offerings.  EC motors by InterLink are up to 75% efficient—that’s a 51-59% increase over shaded-pole motors and a 30-35% increase over permanent split-capacitor (PSC) motors. Additionally, these motors run cooler than PSC or shaded pole motors, introducing less heat into the refrigerated space and further increasing energy savings.
LINK 7
Raise suction temperature to the highest possible for particular loads at any time. Drop suction (low-side) pressure/temperature to maintain colder loads. Raising suction pressure decreases compressor work.
LINK 8
A useful guideline says you can expect the efficiency of your system’s compressors to improve by 1.3% for each degree F in lower saturated condensing temperature.
LINK 9
Oil seals, cools, and lubricates screw compressors, liquid-refrigerant injection cooling uses 5-15% of compressor power to recompress refrigerant.
LINK 10
Small piping diameter requires higher pressure to overcome friction losses.
LINK 11
Non-condensable gases, such as air or CO2, reduce the effective surface area of the condenser that could condense refrigerant vapor, thereby decreasing heat exchanger efficiency.
LINK 12
Evaporator coils must be free of ice to maximize heat transfer. Use hot gas or water defrost instead of electric defrost. High-pressure refrigerant uses less energy than electric heaters. Reduce defrost time by using airflow sensors and thermocouples can stop the defrost system as soon as the ice has melted.
LINK 13
These use a heat source to achieve cooling and can reduce the electricity requirement by 80 to 90%.  This technology has found good acceptance in locations having waste heat or access to cheaper alternative fuels.
LINK 14
Some facts about converting to LED lighting:
  • Save money – low temp and low voltage
  • Ultra strong and robust – no glass or filaments to break
  • Zero maintenance – lifetime = 75,000 hours
  • Environmentally friendly – no mercury
  • Superior light quality – mimics sunlight, no flickering/buzzing
  • COST COMPARISON CHART
  • (BASED ON 100 FIXTURES)
Existing Watts
Hours per day
Cost per KWH
ANNUAL ENERGY COST
Hourly Rate
Replacement Time
Yearly Replacements
ANNUAL LABOR COST
# of Lamps
# Times Replaced
ANNUAL LAMP COST
TOT. ANNUAL COST
SAVINGS:
Incandescent
40
24
$0.10
$3,504.00
$25.00
30min.
2.9
$3,625.00
2@$3.25 ea
2.9
$1,885.00
$9,014.00
$8,804.00
Fluorescent
17
24
$0.10
$1,489.00
$25.00
30min.
0.9
$1,125.00
2@$4.86 ea
0.9
$875.00
$3,488.00
$3,278.00
LED
2.4
24
$0.10
$210.00
$25.00
30min.
0
$0.00
0
0
$0.00
$210.00
LINK 15
Directly coupled drive systems are more efficient than mechanical drives and take up less space.  New permanent-magnet synchronous motors can generate sufficient speed and torque without necessitating an intervening gearbox.
LINK 16
To design an energy efficient pump system all of the following criteria should be taken into account:
a.                 Basic plant layout
b.                Pipe work configuration and restrictions
c.                 Liquid velocity in pipe work
d.                System characteristics and pump selection
e.                 Pump/System control
LINK 17
Look for symptoms associated with inefficient energy consumption:
• Throttle-valve control for the system  
• Cavitation noise or damage in the system
• Continuous pump operation to support a batch process
• Constant number of parallel pumps supporting a process with changing demands
• Bypass or recirculation line normally open
• High system maintenance
• Systems that have undergone change in function.
Pumping System Assessment Tool (PSAT) Saves Energy
The Pumping System Assessment Tool (PSAT) software uses data that is typically available or easily obtained in the field (e.g., pump head, flow rate, and motor power) to estimate potential energy and dollar savings in industrial pump systems. The software, developed by the U.S. Department of Energy (DOE) Industrial Technologies Program (ITP) is available at no cost for evaluating industrial pump systems.
Smoothing the outer front and back shroud of the impeller can be a cost-efficient procedure to improve pump efficiency and reduce the clearance of the sealing gaps to the smallest possible value in order to increase the volumetric efficiency.  From investigations based on statistically evaluated data it is known, that the largest potential regarding an improvement of efficiency exists at low specific speeds.
Various conditions that decrease the efficiency of your pump should be checked for and corrected.  These include:
  1. Packing generates approximately six times as much heat as a balanced mechanical seal.  Carbon film, polymeric composite, or Ultrananocrystalline-Diamond (UNCD) mechanical seals demonstrate generally higher efficiencies.
  2. Wear rings and impeller clearances are critical. Anything that causes these tolerances to open will cause internal recirculation that is wasting power as the fluid is returned to the suction of the pump. If the wear ring is rubbing, the generated heat is consuming power.
  3. A bypass line installed from the discharge side of the pump to the suction piping. The heat generated from this recirculation can, in some cases, cause pump cavitation as it heats the incoming liquid.
  4. A double volute design pump restricts the discharge passage lowering the overall efficiency.
  5. Running the pump with a throttled discharge valve.
  6. Eroded or corroded internal pump passages will cause fluid turbulence.
  7. Any restrictions in the pump or piping passages such as product build up, a foreign object, or a stuck check valve.
  8. Over lubricated or over loaded bearings.
  9. Rubbing is a major cause of energy loss. It can be caused by:
·         Misalignment between the pump and driver.
·         Pipe strain.
·         Impeller imbalance.
·         A bent shaft.
·         A close fitting bushing.
·         Loose hardware.
·         A protruding gasket rubbing against the mechanical seal.
·         Cavitation. (5 kinds)
·         Harmonic vibration.
·         Improper assembly of the bearings, seal, wear rings, packing, lip seals etc..
·         Thermal expansion of various components in high temperature applications. The impeller can hit the volute, the wear rings can come into physical contact etc.
·         Solids rubbing against the rotating components, especially the seal.
·         Operating too far off of the best efficiency point of the pump.
·         Water hammer and pressure surges.
·         Operating at a critical speed.
·         Dynamic, non o-ring elastomers that cannot flex and roll, but must slide, eventually fretting the shaft or sleeve.
·         A build up of product on the inside of the stuffing box rubbing against the mechanical seal.
·         Grease or lip seals rubbing the shaft next to the bearings.
·         Over tightening packing or improper seal installation.
LINK 18
Comparison of energy losses for throttling/on-off/VSD drive control
Fitting VSDs will enable you to control the motor speed in order to match the speed need
from the equipment it is driving.
• A 20% speed reduction can result in a power reduction of close to 50%.
• VSDs are relatively simple to install or retrofit.
Utilizing an Electrical variable speed drive is the simplest and most economical way of
controlling the pump and matching it to the pump system, providing it is mainly frictional.
LINK 19
Advantages
1.Excellent individual full-load and part-load efficiency.
2.Chillers operating with multiple compressors on common refrigeration circuits provide better partload efficiency (IPLV) than chillers with a single large screw compressor and capacity controls.
3.Very few moving parts (three).
4.Proven reliability.
5.A single compressor failure in a chiller with multiple refrigeration circuits results in loss of capacity, but the chiller can remain in service.
6.Very quiet operation.
7.Very low vibration.
8.Continuous compression process with almost no pulsation or vibration.
9.Precise machining permits sealing vane flanks with a thin film of oil.
10.Non-compliant designs (where there is no contact between the scrolls) have very low friction, which improves efficiency.
Disadvantages
1.Compressor cannot be disassembled in field for maintenance.
2.Incremental capacity control on systems with multiple compressors.

Local Weather Report and Forecast For: Kakinada    Dated :May 20, 2015
Kakinada
Past 24 Hours Weather Data
Maximum Temp(oC) 41.6
Departure from Normal(oC) 3
Minimum Temp (oC) 29.9
Departure from Normal(oC) 1
24 Hours Rainfall (mm) NIL
Todays Sunset (IST) 18;27
Tommorows Sunrise (IST) 05;28
Moonset (IST) 20;35
Moonrise (IST) 07;20
Today's Forecast:Sky condition would be Partly cloudy. Maximum & Minimum temperatures would be around 42 and 30 degrees Celsius respectively.
Date Temperature ( o C ) Weather Forecast
Minimum Maximum
21-May 30.0 42.0 Partly cloudy sky
22-May 30.0 43.0 Partly cloudy sky
23-May 30.0 43.0 Partly cloudy sky
24-May 29.0 43.0 Partly cloudy sky
25-May 29.0 42.0 Partly cloudy sky
26-May 28.0 42.0 Partly cloudy sky








Actual
Average
Record
Temperature

Mean Temperature
35 °C
-

Max Temperature
42 °C
-
- ()
Min Temperature
29 °C
-
- ()
Cooling Degree Days
30


Growing Degree Days
46 (Base 50)


Moisture

Dew Point
27 °C


Average Humidity
62


Maximum Humidity
79


Minimum Humidity
33


Precipitation

Precipitation
0.0 mm
-
- ()
Sea Level Pressure

Sea Level Pressure
1002.88 hPa


Wind

Wind Speed
2 km/h ()


Max Wind Speed
7 km/h


Max Gust Speed
-


Visibility
7.0 kilometers


Events
 



T = Trace of Precipitation, MM = Missing Value
Source: Averaged Metar Reports
Daily Weather History Graph


Daily Weather History Graph


TODAY PREDICTION




Max Avg Min Sum
Temperature
Max Temperature 42 °C 37 °C 30 °C
Mean Temperature 35 °C 32 °C 28 °C
Min Temperature 30 °C 27 °C 24 °C
Degree Days
Heating Degree Days (base 65) 0 0 0 0
Cooling Degree Days (base 65) 30 25 19 524
Growing Degree Days (base 50) 46 40 34 838
Dew Point
Dew Point 28 °C 26 °C 22 °C
Precipitation
Precipitation 14.0 mm 0.7 mm 0.0 mm 14.20 mm
Snowdepth - - - -
Wind
Wind 11 km/h 1 km/h 0 km/h
Gust Wind - - -
Sea Level Pressure
Sea Level Pressure 1011 hPa 1007 hPa 1001 hPa

Monthly Weather History Graph

Monthly Weather History Graph







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