Condensate Management 2005 Armstrong International Inc Condensate Return

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Condensate Management © 2005 Armstrong International, Inc.

Condensate Management © 2005 Armstrong International, Inc.

Condensate Return • Hotter boiler feed water temperatures • Minimizes the amount of chemicals

Condensate Return • Hotter boiler feed water temperatures • Minimizes the amount of chemicals required to treat boiler feed water • Eliminates environmental concerns • Minimizes water usage which is critical in some areas • Condensate is a tangible item which can be measured in the form of a savings analysis • Effective return can lower overall costs which can impact profitability Let’s take a look at a savings analysis. . . 2 2

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Methods of condensate return Electric Centrifugal Pumps Duplex 4300 series installed at a brewery

Methods of condensate return Electric Centrifugal Pumps Duplex 4300 series installed at a brewery 4 4

Electric Condensate Pumps Condensate Inlet (Centrifugal) Control Panel w/starters Overflow to drain Pump and

Electric Condensate Pumps Condensate Inlet (Centrifugal) Control Panel w/starters Overflow to drain Pump and motor assembly Float switch or alternator Receiver: Non-pressurized Suction isolation valve 5 5

Nema 1 Float Switch for simplex (one pump) packages 6 6

Nema 1 Float Switch for simplex (one pump) packages 6 6

Nema 1 Mechanical Alternator for duplex (two pumps) packages 7 7

Nema 1 Mechanical Alternator for duplex (two pumps) packages 7 7

Nema 12 Control Panel 8 8

Nema 12 Control Panel 8 8

Installation Accessories 9 9

Installation Accessories 9 9

Advantages • Excellent for returning cooler condensate • Standard models 200°F or less •

Advantages • Excellent for returning cooler condensate • Standard models 200°F or less • 210° floor mounted units available • 212° elevated units available • Inexpensive for initial purchase • Low inlet height applications • Can operate against high back pressures without dramatically increasing foot print of package • Most understood method of condensate return 10 10

Disadvantages • • 11 Long term repetitive maintenance costs – Leaking seals • High

Disadvantages • • 11 Long term repetitive maintenance costs – Leaking seals • High temp condensate from blow through traps or leaks in system – Impeller wear – Cavitation • Condensate temperature exceeds NPSH design of pump – Corrosion on electrical components Requires two trades for installation and repair Safety for pit areas (flooding) Must be vented to atmosphere – Units sized 3: 1 to allow condensate to cool

Disadvantages 12 12

Disadvantages 12 12

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Mechanical Pumps 14 14

Mechanical Pumps 14 14

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Pump Trap Operation: Filling Step 1. During filling, the steam or air inlet and

Pump Trap Operation: Filling Step 1. During filling, the steam or air inlet and check valve on pumping trap outlet are closed. The vent and check valve on the inlet are open. Steam/Air In Closed Steam/Air Out - Open Check Valve Closed Check Valve 16

Pump Trap Operation: Begin Pumping Steam/Air In - Open Steam/Air Out - Closed Check

Pump Trap Operation: Begin Pumping Steam/Air In - Open Steam/Air Out - Closed Check Valve Closed Open Check Valve Step 2. Float Rises with level of condensate until it passes trip 17 point, and then snap action reverses the positions shown in step one.

Pump Trap Operation: End Pumping Step 3. Float is lowered as level of condensate

Pump Trap Operation: End Pumping Step 3. Float is lowered as level of condensate falls until snap action again reverses positions. Steam/Air - In Vent Closed Check Valve Open Check Valve 18

Pump Trap Operation: Repeat Filling Step 4. Steam or air inlet and trap outlet

Pump Trap Operation: Repeat Filling Step 4. Steam or air inlet and trap outlet are again closed while vent and condensate inlet are open. Cycle begins anew. Steam/Air In - Closed Steam/Air Out - Open Check Valve Closed Check Valve 19

Mechanical vs. Electrical • No seals, motors or impellers – Eliminates repetitive maintenance Low

Mechanical vs. Electrical • No seals, motors or impellers – Eliminates repetitive maintenance Low maintenance – Few moving parts – advanced mechanism design Sized for actual condensate load: No need to apply 3: 1 safety factor • • – Hot condensate is no problem • Can be used in closed loop applications – Conserve flash steam (BTU’S) 20 20

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Heat Exchanger Stall • Stall – The point at which there is no differential

Heat Exchanger Stall • Stall – The point at which there is no differential across the trap orifice and condensate starts to back up in to the system 22

Big Problem 23 23

Big Problem 23 23

“Stalled” Heat Exchanger Steam Condensate 24 24

“Stalled” Heat Exchanger Steam Condensate 24 24

Effects of “Stall” • • 25 Inadequate condensate drainage Water hammer Frozen coils or

Effects of “Stall” • • 25 Inadequate condensate drainage Water hammer Frozen coils or coil leaks Corrosion due to Carbonic Acid formation Poor temperature control of product (water, air etc) Control valve hunting (system cycling) Reduction of heat transfer capacity 25

Factors Contributing to Stall • Oversized equipment • Conservative fouling factors • Excessive safety

Factors Contributing to Stall • Oversized equipment • Conservative fouling factors • Excessive safety factors • Large operating ranges • Back pressure at steam trap discharge • Changes in system parameters 26 26

Finding “Stall” Where does Stall occur? • Air heating coils • Shell & tube

Finding “Stall” Where does Stall occur? • Air heating coils • Shell & tube heat exchangers • Plate & frame heat exchangers • Reboilers • Kettles • Any type of heat transfer equipment that has Modulating Steam Control 27 27

Mechanical Pump Applications © 2005 Armstrong International, Inc.

Mechanical Pump Applications © 2005 Armstrong International, Inc.

Closed-Loop Systems 29 29

Closed-Loop Systems 29 29

Big Problem 30 30

Big Problem 30 30

Closed-loop Solution 31 31

Closed-loop Solution 31 31

Solution: Closed Loop 32 CO 2 evaporator 32 32

Solution: Closed Loop 32 CO 2 evaporator 32 32

Closed-loop Solution 33 33

Closed-loop Solution 33 33

Considerations for closed-loop systems • • 34 Receiver sizing – Typically smaller receiver to

Considerations for closed-loop systems • • 34 Receiver sizing – Typically smaller receiver to handle condensate load only Vent sizing on receiver – Vent line is equalized to receiver and capped with thermostatic air vent or A/VB combination (TAVB) Location of Receiver – Fill head is important May or may not require trap down stream of pump – Depends upon max system pressure downstream of the control valve 34

Closed Loop Receiver Sizing 35 35

Closed Loop Receiver Sizing 35 35

Double Duty® Steam Trap/Pump Combination Double Duty -4 Double Duty- 6 Double Duty-12 36

Double Duty® Steam Trap/Pump Combination Double Duty -4 Double Duty- 6 Double Duty-12 36 36

Double Duty® - 4 • Double Duty 4 – 1” x 1” Ductile Iron

Double Duty® - 4 • Double Duty 4 – 1” x 1” Ductile Iron Pump – Up to 350 lb/hr pumping capacity – Up to 4, 000 lb/hr trapping capacity – Integral trap/pump mechanism – single float – Max pressure is 72 psi 37 37

Double Duty® - 6 • Double Duty 6 – – – – 38 1

Double Duty® - 6 • Double Duty 6 – – – – 38 1 -1/2” x 1” 150# flanged Carbon Steel Pump 200 psig rated body • 200 psig max operating pressure Separate pump and trap mechanisms Up to 4, 800 lb/hr pumping capacity Up to 22, 000 lb/hr trapping capacity External motive/vent seats Inconel X-750 Springs 38

Double Duty® 12… 39 39

Double Duty® 12… 39 39

Double Duty Closed Loop Application Double Duty® Steam trap/pump combination 40 40

Double Duty Closed Loop Application Double Duty® Steam trap/pump combination 40 40

Double Duty® 12 100% turndown application… 41 41

Double Duty® 12 100% turndown application… 41 41

Closed System Advantages: • No flash steam loss • No need to run long

Closed System Advantages: • No flash steam loss • No need to run long expensive vent lines • No electric pump problems (seals, motors, etc. ) • Return condensate hotter Precautions: • Dedicated pump for a single piece of equipment • Can not use air as motive force 42 42

Open (vented) System 43 43

Open (vented) System 43 43

Double Duty Vented System – No Internal Trap Mechanism Double Duty™ 6 Steam trap/pump

Double Duty Vented System – No Internal Trap Mechanism Double Duty™ 6 Steam trap/pump combination 44 44

Open System Advantages: • Drain Multiple pieces of equipment • Can use Air or

Open System Advantages: • Drain Multiple pieces of equipment • Can use Air or Steam for pump trap operation • Easiest to understand Important notes: • Modulating steam sources must drain by gravity to receiver inlet (no lifting of condensate) • If installing a Pressure Reducing Valve (PRV), outlet of PRV must be a minimum of 10 feet from pump inlet. If room doesn’t permit, add an accumulator pipe. • Add a vacuum breaker on discharge side of heat exchanger and a thermostatic air vent at high side of exchanger (if not designed to run in vacuum) • Add necessary auxiliary equipment…water level gauges, pressure gauges, receiver overflow, discharge gate valves, drains for receiver/pumps etc 45 45

Considerations for open systems • • 46 Receiver sizing – Receiver must be sized

Considerations for open systems • • 46 Receiver sizing – Receiver must be sized to provide adequate separation of flash steam and condensate Vent sizing on receiver – Vent line velocity of 3, 000 – 4, 000 FPM Location of Receiver – Fill head is important Prevent flashing in the pump trap – Vent connection on pump too small to vent atmospheric flash steam of any quantity – Could build pressure inside pump body affecting flow into the pump 46

Vented Receiver Sizing (assumes straight up vertical piping) 47 47

Vented Receiver Sizing (assumes straight up vertical piping) 47 47

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Flash Recovery • Not just a lot of hot air 49 49

Flash Recovery • Not just a lot of hot air 49 49

Uses of flash steam… • Atmospheric vent condenser – Preheat water/glycol or other media

Uses of flash steam… • Atmospheric vent condenser – Preheat water/glycol or other media • Preheat coils • Supplement existing lower pressure steam lines • Recover flash to Deaerator Flash vent condenser on a DPT-3512 LBRPI-24 -12 50 50

Flash Steam Calculation 50 psig pressure 267. 5 Btu/lb 180. 07 Btu/lb % of

Flash Steam Calculation 50 psig pressure 267. 5 Btu/lb 180. 07 Btu/lb % of flash steam = 267. 5 – 180. 07 x 100 970. 3 % of flash steam = 9. 01% If our condensate load is 2000 lb/hr, the flash steam produced would be: Flash steam produced =. 0901 x 2000 or 180 lb/hr of flash steam 51 51

Flash Steam Graph 52 52

Flash Steam Graph 52 52

Flash Steam Savings Calculator • Armstrong Steam-A-ware CD 53 53

Flash Steam Savings Calculator • Armstrong Steam-A-ware CD 53 53

Armstrong VAFT Vertical Flash Vessels • • • Excellent for providing low velocity flash

Armstrong VAFT Vertical Flash Vessels • • • Excellent for providing low velocity flash steam with no water carryover ASME Sec. VIII U stamped to 150 PSI (other pressures upon request) Models include: – – 54 VAFT-6 VAFT-8 VAFT-12 VAFT-16 54

Armstrong HAFT Horizontal Flash Vessels • • 55 Excellent for providing low velocity flash

Armstrong HAFT Horizontal Flash Vessels • • 55 Excellent for providing low velocity flash steam with no water carryover – HAFT-4 – HAFT-6 – HAFT-8 – HAFT-10 – HAFT-12 – HAFT-16 – HAFT-2448 – HAFT-2472 – HAFT-30 ASME Sec. VIII U stamped to 150 PSI (other pressures upon request) – No internal baffling 55

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Engineered Solution 58 58

Engineered Solution 58 58