COLD WEATHER TECHNOLOGIES : REVOLUTIONARY GREEN HEAT
Who is Cold Weather Technologies (CWT)? CWT is the division of Grit responsible for the Heat Driven Loop technology
What is the Heat Driven Loop? The Heat Driven Loop A new adaptation of existing thermosyphon heat pump technology Uses latent heat of evaporation from an evacuated, closed system to transfer heat Consists of an evaporator section and a condenser/heat exchanger section.
Natural gas line heaters Used in upstream, transportation, and distribution systems Used to stop internal and external freezing on lines and/or equipment
Joule-Thomson Effect Why does ice form on the lines downstream of the regulator? Because of the Joule-Thomson Effect: A gas will lower its temperature as the pressure is decreased. This effect is also called the Joule-Kelvin Effect and is the basis of how modern refrigeration techniques work.
What are the advantages of CWT? Increased heat transfer efficiency so reduced fuel requirements Lower fuel pressure at burner Eliminates direct firing of firetubes – no scale – no hot spots Reduced hazards Reduced environmental risk and emissions Lower heat losses to ambient Increased thermal efficiencies – in the order of 80% Reduced fuel requirements – annual reductions in excess of 50% Ease of operation and dependability Reduced maintenance Safe to light and silent Reduced glycol requirements
Energy required for phase change chart
Lower boiling point Mount Everest 29,000 ft Water boils at 68°C Sea Level 0 ft Water boils at 100°C CWT Line Heater Water boils at 43°C Deep Space Water boils at 39°C
Operating Parameters Pressure Operates on a vacuum As low as -26” Hg when cold Maximum operating pressure is 14.7 psig Temperature Operates below 121°C
Other good things about the vacuum… Minimal air in system reduces corrosion Lower operating temperature reduces heat loss to ambient
Alignment and support guides High Pressure – 6 pass Process Coil Alignment / Support Guides
Inside the steam condenser chamber Inside the Steam Condenser Chamber Alignment and Support Ports Steam Inlet Condensate Outlet
The new heat exchanger
Testing new exchanger INLET OUTLET The new style heat exchanger in a 2.3 million BTU heater is much smaller than the old style.
Some history Process was first developed when trying to find a better way to heat oilfield tanks with low pressure gas SaskEnergy suggested looking at developing a line heater Initial bench testing done in Lloydminster under the direction of the SRC in 2003
Bench test results “The HDL Dry Unit technology shows significant advantage over conventional line heaters including: improved overall efficiency improved combustion efficiency Reduced emissions Improved response time with a lower thermal capacitance” Saskatchewan Research Council
Line heater field trials Sask Energy field tested 2 units Maidstone – 250,000 BTU/hr Melville – 500,000 BTU/hr Installed in fall of 2003 Trouble free operation Inspected after 6 and 15 months - no corrosion or erosion - no breakdown in glycol quality Dissected Maidstone in May 07 - no concerns
CWT SaskEnergy performance Melville TBS 315,000 btu/hr In service: 4 years Annual Savings: 42% ( $3,000/yr )
CWT SaskEnergy performance Yorkton TBS 770,000 btu/hr In service: 1 year Annual Savings: 31% ( $5,000/yr )
CWT SaskEnergy performance Battleford TBS 770,000 btu/hr In service: 2 years Annual Savings: 60% ( $16,000/yr )
Melville station usage ratio
Conventional Heater Cold Weather Technologies Heater Melville station consumption per day
Melville station consumption per month
Numbers… The CWT line heater has a thermal efficiency of between 75 and 80%. A conventional line heater has a thermal efficiency of 35 to 45%. In most applications the CWT will use less than half the fuel for the same load as a conventional heater. A 500,000 btu/hr CWT heater will do the work of 1.0 mmbtu/hr conventional heater – a lower capital cost. If we assume that both are running 50% of the time, the conventional heater would consume 2,190 mmbtu/year more than the CWT. Using a gas price of $7.00 per mmbtu, the extra fuel cost is in the order of $15,330 annually.
Glycol CWT Dryline Heaters are shipped with all the required fluid – there in no glycol to buy The CWT is a sealed unit – no need to “top up” A small amount of glycol so no containment is required A 1.0 mmbtu/hr conventional heater requires about 25 bbls of glycol $700/bbl = $17,500) Glycol is propylene based – minimal or no containment required
GHG emissions A single conventional bath-type line heater burning 500,000 btu/hr NG emits over 520 t of CO 2 e in one year Using the 53% reduction in consumption determined by SaskEnergy that same line heater consumes 235,000 btu/hr and emits 244 t of CO 2 e in one year This results in a GHG reduction of 276 t of CO 2 annually on the basis of reduced fuel consumption
Melville emissions
Some of our clients Aliant Energy ATCO Pipeline ATCO Gas Barchard Engineering Campbell Ryder Engineering Ltd. Enbridge ENGAS Heritage Gas Keyspan National Fuel Gas Supply Corp. National Grid Nicor Pacific Northern Gas Puget Sound Energy Sask Energy SNC Lavalin Terasen Gas Union Gas Numerous Canadian gas co-ops
The Cold Weather models images The Cold Weather models
Model 140 Evaporator
Model 315 Model 315 Evaporator
Model 385 Evaporator
Model 630 Model 630 Evaporator
Model 630E Model 630E Evaporator
Model 770 Evaporator (2x385’s)
Modular design for large heaters Multiple Evaporators on Single Condenser Staged Firing Uses Internal or Utility Power Model 770 Evaporator
Model 770 Model 770 Evaporator
Process Gas Temp Sensors
Alliant, Iowa
Keyspan, Canarsie
CWT 770 Modular 2.3 MM btu/hr at Saskatoon TBS #2 CWT 770 Modular Evaporator
2.3 MMBTU for Enbridge 2.3 Million BTU Evaporator
3 Million BTU in shop 3 Million BTU Evaporator
Operating the Line Heater “The Basics”
Pressure when the heater is cold When the heater is cold the pressure should be in the order of -24” Hg.
Fluid level The line heater contains a mixture of glycol and water. The volume is dependent on the style of evaporator but is generally around 20 gallons. When cold the site glass should be near full. When operating the level varies dramatically but should stay in or near the middle of the site glass
Installing the unit A solid foundation is required (cannot slope away from condensate return), Conduit to the gas process line downstream of the station is required.
Poor footing image
Thermopile power system
Pressure gauges Evaporator Boiling at 77°C and -19” Hg (-9.6 psig) When operating normally in Natural Gas Line Heating applications the device will generally run at some level of negative pressure.
Discharge temperature switch This switch controls the vapor temperature and is generally set between 79 and 93°C. This acts as a thermostat and will open and close the main gas valve as required
High pressure switch This pressure switch will shutdown the main burner when the pressure reaches a preset limit (usually set to shut down at about 3-5 psig). This may be manual or automatic reset
High temperature ESD switch This temperature control is located in the control box. This is the high temperature ESD which will trigger if the glycol mixture reaches 115° F in the liquid phase. This ESD has a manual reset.
Rupture disk This is a rupture disk which will fail at 15 psig. If for some reason the heater pressure exceeds 15 psig the disk will burst and the water/glycol mixture would be vented and collected in the containment
Containment vessel image Evaporator model containment shown. Boiler model containment is slightly different.
Process Temperature or line temperature is controlled by this thermostat. This is generally installed at the outlet from the station, downstream of the regulation. This controls the temperature of the gas after the regulating station. This is set by the operator (usually around 3°C) Line temperature thermostat
Why a CWT Dry Line Heater? On new systems or replacements the reasons are the same… Low capital cost Fuel economy Less glycol Less maintenance Simple Safe Silent