Armstrong Design Envelope Integrated Pumping System (IPS 4000)
- Applications-Multi-pump control for heated – or chilled – water system optimization in buildings.
- Description-The Design Envelope Integrated Pumping System (IPS 4000) is an advanced multi-zone control that directly integrates with pumping units to optimize energy performance, system handling, and installation.
- Materials (MOC)-Enclosure, circuitry, software
- Configuration-Integrates seamlessly with Armstrong Design Envelope pumps in a headered configuration.
- Performance range-Up to 8 pumps, 16 zones (variable primary, secondary or tertiary) and 8 flow sensitive equipment (variable primary)
IPS 4001w / IPS 4501w for up to 3 pumps, 3 zones and 3 flow sensitive equipment
IPS 4002w / IPS 4502w for up to 4 pumps, 6 zones and 4 flow sensitive equipment
IPS 4003w / IPS 4503w for up to 6 pumps, 12 zones and 6 flow sensitive equipment
IPS 4004w / IPS 4504w for up to 8 pumps, 16 zones and 8 flow sensitive equipment - Power Range-No limitations in system size and capacity.
- Size-No limitations in system size.
Description
Benefits & Features
Design Envelope Integrated Pumping System (IPS 4000)
- The Integrated Pumping System (IPS 4000) offers low risk, fast and simple setup for the most cost effective and efficient results:
- Compatible with existing building automation system
- Pre-programmed for easy installation and set-up
- Controls up to 8 pumps and 16 zones
- Sensorless technology reduces building operating and maintenance costs
Lowest installed cost
- Onboard Sensorless technology for eliminating the need of external sensors and related installation costs.
- Compatibility with existing building automation systems for easy installing and setup.
- Intuitive software-based setup for easy commissioning.
Lowest operating cost
- Advanced control sequences and zone control for harnessing energy and cost performance benefits inherent in variable speed pumping systems.
- High-quality dependable logic components for carefree long-term performance.
Lowest energy consumption and carbon emissions
- Advanced control sequences and zone control for harnessing energy performance benefits inherent in variable speed pumping systems. Exceeds energy savings requirements prescribed in ASHRAE 90.1
Lowest project and operating risk
- Compatibility with existing building automation systems for easy installing and setup.
- High-quality dependable logic components for carefree long-term performance.
Related products
Armstrong Design Envelope 4302 Dualarm Pumps
- Applications-HVAC system pumping; general purpose pumping; industrial/process pumping (water or glycol based) Armstrong Design Envelope Pumps with integrated controllers are OSHPD pre-approved!
- Description-Pipe-mounted 2-pump unit with integrated intelligent controls for space-saving installation, superior energy performance, and full redundancy or parallel-pumping operation. Saves up to 75% in energy over comparable traditional constant speed or variable frequency operated pump installations.
- Materials (MOC)-Cast iron or ductile iron casing, Cast iron or bronze impeller, Sintered silicon carbide mechanical seal
- Configuration-On-board Intelligent Variable Speed controls with Sensorless or Parallel Sensorless control. Controls enclosure UL type 12 or UL type 4X (outdoor applications). Available with NEMA premium motors. Outside balanced or inside single spring mechanical seal
- Performance range-Up to 1250 USgpm flow and 250 ft head (80 L/s, 76 m)
- Temperature-250°F (121°C)
- Power Range-0.33 hp to 75 hp (0.25 kW to 55 kW)
- Size –1″ to 8” (25 mm to 200 mm)
Armstrong Design Envelope 9521 Integrated Plant Control System (IPC 9521)
- Applications-Automated chiller plant control for optimizing variable primary flow water-cooled chiller plants. The 9521 IPC works in a variable primary configuration and keeps the entire plant including water-cooled chillers, cooling towers, chilled water and condenser pumps running smoothly.
- Description-The Armstrong Integrated Water-Cooled Chiller Plant Control System (IPC) boosts energy efficiencies of new and existing chiller plant installations to leading class levels. The IPC 9521 works with all variable primary configurations, keeping the entire plant – including water-cooled chillers, cooling towers, chilled water and condenser pumps – running at optimum performance and occupant comfort.
- Configuration-Integrates with all brands of chillers, pumps, and automation systems. Installs directly with chiller plant equipment. If preferred, the IPC connects seamlessly with any central building automation system (BAS) maintaining full control of the chilled water plant through the BAS
- Performance range-Controls up to five chillers, five cooling towers and five pumps. No limitations in plant size and cooling capacity.
- Power Range-No limitations in plant cooling capacity
Armstrong Design Envelope Compass h Circulators
- Applications-Residential heating and cooling; potable water supply.
- Description-The Armstrong Compass H is an energy-efficient variable speed wet-rotor circulator. Designed to replace existing fixed speed circulators, with popular flange-to-flange dimensions, Compass H can be considered a universal replacement for all circulators in its capacity range.
- Materials (MOC)-Cast iron and stainless steel volutes.
- Configuration-Eight operation modes with patented “Auto” algorithm, four Sensorless modes and three fixed speed modes. 50 Hz and 60 Hz designs
- Performance range-Up to 20 USgpm (1.26 L/s) flow; up to 20 ft (6.1 m) head
- Temperature-Max ambient temp. 40°C; max water temp. 110°C
- Power Range-5 W to 45 W
- Size-1″
Armstrong Design Envelope Intelligent Fluid Management System
- Applications-Commercial or industrial closed-loop systems, including HVAC chilled-water systems, boiler systems, cooling tower systems, or process water loops.
- Description-The Armstrong Intelligent Fluid Management System (iFMS) integrates superior pump- and control technology into a single pumping solution yielding both compact and carefree installation as well as superior energy performance. iFMS is ideally suited for partial or all variable speed chilled-water plant applications (variable primary flow, variable secondary flow, variable condenser water flow). In combination with Parallel Sensorless control iFMS saves 30% or more in energy over any other parallel pumping configuration available today.
- Configuration-Up to 4 pumps in one unit. Catalogue-based pre-engineered solutions or designed to customer specification. Integrated control system (IPS 4000, IPC 11550) or connecting to chiller plant/BMS control. Optional single point power panel
Armstrong Vortex Air Separators
- Applications-Air removal from hydronic and HVAC systems – air can get trapped during initial fill, during routine equipment maintenance (including pressure upkeep), and due to the use of cooling towers.
- Description-The Armstrong vortex air separators create a vortex or whirlpool action, sending the heavier air-free water to the outer portion of the tank, and allowing the lighter air-entrained water mixture to move into the lower-velocity center. At the center of the vortex the air is released from the water, forms bubbles and exits through an air vent or compression tank installed above it.
- Materials (MOC)-Cast iron or fabricated steel (shell), stainless steel mesh (strainer)
Full View Sight Glass (PN10)
Applications:
Industrial facilities, oil refineries, bath soap manufacturing plane, gas industries, petrochemical complex, high viscous process media, building construction, environmental water treatments, synthetics, plastic and resin industries, polymer manufacturing plant, food industries (chocolate, sauce etc.), fertilizer industries etc.Technical Data :
| Design Std. | As per BS 5352 |
| Testing Std. | As per API 598 |
| End Connection | As per ANSI B16.5 |
| Size | ½” to 4” (15 mm to100 mm) |
| Pressure rating | PN10 |
| Maximum working pressure | 10 Kg/cm2 |
| Test pressure | 15 Kg/cm2 |
Dimensions
| Size | A | B | C |
| 15 | 153 | 51 | 137 |
| 20 | 153 | 51 | 137 |
| 25 | 153 | 51 | 137 |
| 40 | 178 | 64 | 146 |
| 50 | 190 | 76 | 190 |
| 75 | 229 | 102 | 132 |
| 100 | 299 | 127 | 283 |
All dimensions are in mm.
POT-BASKET TYPE STRAINER (ANSI 150#, 300#)
Applications:
Strainer can be used in liquid as well as gas line, Regulator and valve protection, steam traps protections, flow meter and pump protections, heat exchanger and refrigeration set protection, Suitable for Hazardous environments. Y-Strainers and pot basket type strainers is a device for mechanically removing unwanted solids from liquid, gas or steam lines by means of a perforated or wire mesh straining element. Where the amount of material to be removed from the flow is relatively small, resulting in long intervals between screen cleanings, the strainer screen is manually cleaned by shutting down the line and removing the strainer cap.Technical Data :
| Design Std. | As per ASME B16.34 |
| Testing Std. | As per API 598 |
| End Connection | Flanged Drill as per ANSI B16.5 |
| Material | Body : IS 2062, Seal : NBR / PTFE / Graphite + SS, Mesh : SS |
| Shell Wall Thickness | As per ANSI B16.34 |
| Size | 2" to 18", Class 150, 300 |
Dimensions 150#
| Size | F/F | A | B |
| 50 | 320 | 190 | 285 |
| 80 | 360 | 200 | 320 |
| 100 | 400 | 210 | 360 |
| 125 | 460 | 230 | 430 |
| 150 | 510 | 240 | 430 |
| 200 | 560 | 280 | 530 |
| 250 | 810 | 420 | 635 |
| 300 | 890 | 430 | 715 |
Dimensions 300#
| Size | F/F | A | B |
| 50 | 380 | 200 | 305 |
| 80 | 420 | 235 | 400 |
| 100 | 475 | 260 | 405 |
| 125 | 510 | 275 | 435 |
| 150 | 620 | 295 | 490 |
| 200 | 630 | 345 | 560 |
| 250 | 900 | 390 | 690 |
| 300 | 1000 | 440 | 770 |
All dimensions are in mm.
Y-Type Strainers (ANSI 150#, 300#)
Applications:
Strainer can be used in liquid as well as gas line, Regulator and valve protection, steam traps protections, flow meter and pump protections, heat exchanger and refrigeration set protection, Suitable for Hazardous environments. Y-Strainers and pot basket type strainers is a device for mechanically removing unwanted solids from liquid, gas or steam lines by means of a perforated or wire mesh straining element. Where the amount of material to be removed from the flow is relatively small, resulting in long intervals between screen cleanings, the strainer screen is manually cleaned by shutting down the line and removing the strainer capTechnical Data :
| Design Std. | As per ASME B16.34 |
| Testing Std. | As per API 598 |
| End Connection | Flanged End as per ANSI B16.5, F to F as per ANSI B16.10 |
| Shell Wall Thickness | As per ANSI B16.34 |
| Size 150# & 300# | 50 mm to 300 mm (2” to 12”) |
| Standard Trims | WCB / CF8M, Mesh : SS |
Dimensions 150#
| Size | ~L | ~H |
| 50 | 225 | 190 |
| 80 | 315 | 270 |
| 100 | 370 | 305 |
| 150 | 470 | 400 |
| 200 | 600 | 490 |
| 250 | 695 | 670 |
| 300 | 810 | 800 |
Dimensions 300#
| Size | ~L | ~H |
| 50 | 270 | 190 |
| 80 | 320 | 270 |
| 100 | 355 | 305 |
| 150 | 450 | 400 |
| 200 | 560 | 490 |
| 250 | 730 | 670 |
| 300 | 850 | 800 |
All dimensions are in mm.
