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Heatless Desiccant Air Dryers - NEXTGen TW Series
*PRODUCT IMAGE IS REPRESENTATIVE PROVIDED BY THE MANUFACTURER. DO NOT MAKE BUYING DECISIONS SOLEY BASED ON THE IMAGE. PLEASE VERIFY SPECIFICATIONS MEET YOUR REQUIREMENTS.
Parker NEXTGen TW Series Heatless Desiccant Air Dryers remove water vapor from compressed air through a process known as Pressure Swing Adsorption. A standard pressure dewpoint of -40°F (-40°C) is attained by directing the flow of saturated compressed air over a bed of desiccant.
The most commonly used desiccant is activated alumina, a spherical shaped, hygroscopic material, selected for its consistent size, shape and extreme surface to mass ratio. This physically tough and chemically inert material is contained in two separate but identical pressure vessels commonly referred to as "dual" or "twin" towers.
As the saturated compressed air flows up through the "on line" tower, its moisture content adheres to the surface of the desiccant. The dry compressed air is then discharged from the chamber into the distribution system.
A solid state controller automatically cycles the flow of compressed air between the towers, while the "on line" is drying, the "off line" tower is regenerating. Regeneration, sometimes referred to as purging, is the process by which moisture accumulated during the "on line" cycle is stripped away during the "off line" cycle. As dry low pressure purge air flows gently through the regenerating bed, it attracts the moisture that had accumulated on the surface of the desiccant during the dryer cycle and exhausts it to the atmosphere.
To protect the desiccant bed from excess liquid, all Parker NEXTGen TW Series Heatless Air Dryers are designed to work with the natural pull of gravity. By directing the saturated air into the bottom of the "on line" tower and flowing up through the bed, liquid condensate caused by system upset, is kept away from the desiccant and remains at the bottom of the tower where it can be easily exhausted during the regeneration cycle. Counter flow purging ensures optimum performance by keeping the driest desiccant at the discharge end of the dryer.
Heatless dryers in general are the most reliable and least expensive of all desiccant type dryers. Parker NEXTGen TW Series Heatless Desiccant Air Dryers are the most energy efficient thanks to standard features like, "Variable Cycle Control", "CycleLoc" and regulating of the purge flow.
Features / Benefits
Basic & Basic Plus Controller
Allen-Bradley® PLC
NEMA 12, 4X SS, or 7 Enclosures
LCD User Interface
4 Line Digital Display
-Tower Regeneration Status
-Time remaining in Cycle
-Dewpoint (Basic Plus Only)
Powerloc Energy Management (Basic Plus Only)
Adjustable Timing Cycles
Filter Maintenance Timer
Manual Stepping
Compressor Lock
Cycle Lock
Alarms (Basic Plus Only)
-High Dewpoint
-Bad Blowdown
-Bad Repressurization
Advanced Controller
Allen-Bradley® PLC
NEMA 12, 4X SS, or 7 Enclosures
LCD Touch Panel Display
-Dewpoint
-Inlet Temperature
-Inlet & Outlet Pressures
-Left & Right Tank Pressures
- Pre & After Filter Differential Pressure
Powerloc Energy Management
Adjustable Timing Cycles
Filter Maintenance Timer
Manual Stepping
PLC Controlled Timed Solenoid Drain
Modbus TCP / Ethernet Standard
Modbus RTU RS485 - Optional
Iot Gateway Included - Voice of the Machine Enabled
Alarms
-Failure to switch
-High Inlet Temp
-High Dewpoint
-Low Inlet Pressure
-Bad Blowdown
-Bad Repressurization
-Drain Fault
Read More...The most commonly used desiccant is activated alumina, a spherical shaped, hygroscopic material, selected for its consistent size, shape and extreme surface to mass ratio. This physically tough and chemically inert material is contained in two separate but identical pressure vessels commonly referred to as "dual" or "twin" towers.
As the saturated compressed air flows up through the "on line" tower, its moisture content adheres to the surface of the desiccant. The dry compressed air is then discharged from the chamber into the distribution system.
A solid state controller automatically cycles the flow of compressed air between the towers, while the "on line" is drying, the "off line" tower is regenerating. Regeneration, sometimes referred to as purging, is the process by which moisture accumulated during the "on line" cycle is stripped away during the "off line" cycle. As dry low pressure purge air flows gently through the regenerating bed, it attracts the moisture that had accumulated on the surface of the desiccant during the dryer cycle and exhausts it to the atmosphere.
To protect the desiccant bed from excess liquid, all Parker NEXTGen TW Series Heatless Air Dryers are designed to work with the natural pull of gravity. By directing the saturated air into the bottom of the "on line" tower and flowing up through the bed, liquid condensate caused by system upset, is kept away from the desiccant and remains at the bottom of the tower where it can be easily exhausted during the regeneration cycle. Counter flow purging ensures optimum performance by keeping the driest desiccant at the discharge end of the dryer.
Heatless dryers in general are the most reliable and least expensive of all desiccant type dryers. Parker NEXTGen TW Series Heatless Desiccant Air Dryers are the most energy efficient thanks to standard features like, "Variable Cycle Control", "CycleLoc" and regulating of the purge flow.
Features / Benefits
Basic & Basic Plus Controller
Allen-Bradley® PLC
NEMA 12, 4X SS, or 7 Enclosures
LCD User Interface
4 Line Digital Display
-Tower Regeneration Status
-Time remaining in Cycle
-Dewpoint (Basic Plus Only)
Powerloc Energy Management (Basic Plus Only)
Adjustable Timing Cycles
Filter Maintenance Timer
Manual Stepping
Compressor Lock
Cycle Lock
Alarms (Basic Plus Only)
-High Dewpoint
-Bad Blowdown
-Bad Repressurization
Advanced Controller
Allen-Bradley® PLC
NEMA 12, 4X SS, or 7 Enclosures
LCD Touch Panel Display
-Dewpoint
-Inlet Temperature
-Inlet & Outlet Pressures
-Left & Right Tank Pressures
- Pre & After Filter Differential Pressure
Powerloc Energy Management
Adjustable Timing Cycles
Filter Maintenance Timer
Manual Stepping
PLC Controlled Timed Solenoid Drain
Modbus TCP / Ethernet Standard
Modbus RTU RS485 - Optional
Iot Gateway Included - Voice of the Machine Enabled
Alarms
-Failure to switch
-High Inlet Temp
-High Dewpoint
-Low Inlet Pressure
-Bad Blowdown
-Bad Repressurization
-Drain Fault
| Action | Part No. | Availability | Partner Available | Price | Compatible After Filter | Weight | Maximum Inlet Pressure Rating | Compatible After Filter Element | Division | Height | Pressure Dew Point | Minimum Operating Pressure | Maximum Operating Temperature | Compatible Prefilter Element | Current | Depth | Connection Type | Minimum Operating Temperature | Maximum Ambient Temperature | Maximum Operating Pressure | Purge Air Equivalent | Minimum Ambient Temperature | Installed Condensate Drain Type | Compatible Prefilter | Width | Electrical Requirements | Maximum Flow Rate |
|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|---|
| TW0055-FB11NNF | Quote Required | TBD | AOPX020DNFX | 400 lbs | 100 PSI | P020AO | Industrial Gas Filtration and Generation Division | 79 in | -40°F | 80 PSIG | 120°F | P020AA | 2.0 A | 27 in | 3/4'' NPT | 50°F | 100°F | 150 psig | 9 | 40°F | Float Drain | AAPX020DNFX | 24 in | 120V/1Ph/60Hz | 55 SCFM | ||
| TW0100-FB11NNF | Quote Required | TBD | AOPX025ENMX | 468 lbs | 100 PSI | P025AO | Industrial Gas Filtration and Generation Division | 86 in | -40°F | 80 PSIG | 120°F | P025AA | 2.0 A | 36 in | 1'' NPT | 50°F | 100°F | 150 psig | 15 | 40°F | Float Drain | AAPX025ENFX | 52 in | 120V/1Ph/60Hz | 100 SCFM | ||
| TW0130-FB11NNF | Quote Required | TBD | AOPX025ENMX | 496 lbs | 100 PSI | P025AO | Industrial Gas Filtration and Generation Division | 86 in | -40°F | 80 PSIG | 120°F | P025AA | 2.0 A | 36 in | 1'' NPT | 50°F | 100°F | 150 psig | 20 | 40°F | Float Drain | AAPX025ENFX | 52 in | 120V/1Ph/60Hz | 130 SCFM | ||
| TW0200-FB11NNF | Quote Required | TBD | AOPX030GNMX | 692 lbs | 100 PSI | P030AO | Industrial Gas Filtration and Generation Division | 86 in | -40°F | 80 PSIG | 120°F | P030AA | 2.0 A | 36 in | 1 1/2" NPT | 50°F | 100°F | 150 psig | 30 | 40°F | Float Drain | AAPX030GNFX | 52 in | 120V/1Ph/60Hz | 200 SCFM | ||
| TW0250-FB11NNF | Quote Required | TBD | AOPX035GNMX | 776 lbs | 100 PSI | P035AO | Industrial Gas Filtration and Generation Division | 85 in | -40°F | 80 PSIG | 120°F | P035AA | 2.0 A | 36 in | 1 1/2" NPT | 50°F | 100°F | 150 psig | 38 | 40°F | Float Drain | AAPX035GNFX | 52 in | 120V/1Ph/60Hz | 250 SCFM | ||
| TW0300-FB11NNF | Quote Required | TBD | AOPX035GNMX | 796 lbs | 100 PSI | P035AO | Industrial Gas Filtration and Generation Division | 85 in | -40°F | 80 PSIG | 120°F | P035AA | 2.0 A | 36 in | 1 1/2" NPT | 50°F | 100°F | 150 psig | 45 | 40°F | Float Drain | AAPX035GNFX | 52 in | 120V/1Ph/60Hz | 300 SCFM | ||
| TW0400-FB11NNF | Quote Required | TBD | AOPX040HNMX | 1626 lbs | 100 PSI | P040AO | Industrial Gas Filtration and Generation Division | 88 in | -40°F | 80 PSIG | 120°F | P040AA | 2.0 A | 36 in | 2" NPT | 50°F | 100°F | 150 psig | 60 | 40°F | Float Drain | AAPX040HNFX | 52 in | 120V/1Ph/60Hz | 400 SCFM | ||
| TW0500-FB11NNF | Quote Required | TBD | AOPX045HNMX | 1735 lbs | 100 PSI | P045AO | Industrial Gas Filtration and Generation Division | 88 in | -40°F | 80 PSIG | 120°F | P045AA | 2.0 A | 36 in | 2" NPT | 50°F | 100°F | 150 psig | 75 | 40°F | Float Drain | AAPX045HNFX | 52 in | 120V/1Ph/60Hz | 500 SCFM | ||
| TW0600-FB11NNF | Quote Required | TBD | AOPX050INMX | 1740 lbs | 100 PSI | P050AO | Industrial Gas Filtration and Generation Division | 89 in | -40°F | 80 PSIG | 120°F | P050AA | 2.0 A | 60 in | 2" NPT | 50°F | 100°F | 150 psig | 90 | 40°F | Float Drain | AAPX050INFX | 56 in | 120V/1Ph/60Hz | 600 SCFM | ||
| TW0800-FB11NNF | Quote Required | TBD | AOPX050INMX | 2120 lbs | 100 PSI | P050AO | Industrial Gas Filtration and Generation Division | 89 in | -40°F | 80 PSIG | 120°F | P050AA | 2.0 A | 60 in | 2" NPT | 50°F | 100°F | 150 psig | 120 | 40°F | Float Drain | AAPX050INFX | 56 in | 120V/1Ph/60Hz | 800 SCFM | ||
| TW1000-FB11NNF | Quote Required | TBD | AOPX055JNMX | 3676 lbs | 100 PSI | P055AO | Industrial Gas Filtration and Generation Division | 98 in | -40°F | 80 PSIG | 120°F | P055AA | 2.0 A | 61 in | 3" NPT | 50°F | 100°F | 150 psig | 150 | 40°F | Float Drain | AAPX055JNFX | 65 in | 120V/1Ph/60Hz | 1000 SCFM | ||
| TW1200-FB11NNF | Quote Required | TBD | AOPX055JNMX | 4605 lbs | 100 PSI | P055AO | Industrial Gas Filtration and Generation Division | 110 in | -40°F | 80 PSIG | 120°F | P055AA | 2.0 A | 61 in | 3" NPT | 50°F | 100°F | 150 psig | 180 | 40°F | Float Drain | AAPX055JNFX | 65 in | 120V/1Ph/60Hz | 1200 SCFM | ||
| TW1500-FB11NNT | Quote Required | TBD | JC1010-FH | 4985 lbs | 100 PSI | JE-FC1660-HT | Industrial Gas Filtration and Generation Division | 117 in | -40°F | 80 PSIG | 120°F | P055AA | 2.0 A | 77 in | 3" Flg | 50°F | 100°F | 150 psig | 225 | 40°F | Timed Solenoid Drain | AAPX055JNFX | 72 in | 120V/1Ph/60Hz | 1500 SCFM | ||
| TW2000-FB11NNT | Quote Required | TBD | AOPX055JNFX | 5206 lbs | 100 PSI | P055AO | Industrial Gas Filtration and Generation Division | 113 in | -40°F | 80 PSIG | 120°F | P055AA | 2.0 A | 59 in | 4" Flg | 50°F | 100°F | 135 PSIG | 300 | 40°F | Timed Solenoid Drain | AAPX055JNFX | 118 in | 120V/1Ph/60Hz | 2000 SCFM | ||
| TW2600-FB11NNT | Quote Required | TBD | JZ-F03320OXX | 7600 lbs | 100 PSI | JE-FC3320-HT | Industrial Gas Filtration and Generation Division | 111 in | -40°F | 80 PSIG | 120°F | JE-C3001 | 2.0 A | 67 in | 4" Flg | 50°F | 100°F | 135 PSIG | 390 | 40°F | Timed Solenoid Drain | JZ-C03001OXX | 138 in | 120V/1Ph/60Hz | 2600 SCFM | ||
| TW3000-FB11NNT | Quote Required | TBD | JZ-F03320PXX | 8300 lbs | 100 PSI | JE-FC3320-HT | Industrial Gas Filtration and Generation Division | 111 in | -40°F | 80 PSIG | 120°F | JE-C3001 | 2.0 A | 67 in | 4" Flg | 50°F | 100°F | 135 PSIG | 450 | 40°F | Timed Solenoid Drain | JZ-C03001PXX | 138 in | 120V/1Ph/60Hz | 3000 SCFM |