• 
  
  Communication
  • Orinoco Outdoor Wireless LAN
  • Mobile Inspection Assistance
  • Global Mobile Communications System
• 
  
  Engineering Software
  • A Decision Support System for the Selection of Imaging Technologies to Detect Underground Utilities: IMAGTECH
  • PRRTTM Project Rework Reduction Tool
  • Augmented Reality Computer-Aided Drawing (AR CAD)
  • Decision Aid for Electronic Simulation in Construction
  • REALabor - Labor Management Software
  • Dynamic Construction Visualizer
  • Lean Project Delivery System
  • Stroboscope
  • Palm Estimating
  • Updater: Mobile Schedule Tracking Software
  • Prosidyc: Simulation Program for Construction
  • VirtualSTEP: 4D Simulation
• 
  
  Equipment Automation
  • Pneumatic Capsule Pipeline
  • 3D GPS Based Earthmoving
  • Trevi Park - Automatic Parking System
  • Non-Intrusive Site Scanning with LIDAR (Light Radar) System
  • Real-time Construction-component Tracking System
  • 4D Modeling
  • Hybrid Computerized Decision Support System for Infrastructure Assessment
  • Device for Improving Crane Productivity & Safety
  • Automated Composite Column Wrapping
  • Radio Frequency Identification Tag
• 
  
  Non-Destructive Evaluation
  • Sensors for SCAPS
  • Site Characterization and Analysis Penetrometer System (SCAPS): Assessing Site Contamination
  • Real-time 3D GPS Monitoring System
  • 3D Ground Penetrating Imaging Radar
  • Fiber Optic Sensor - Monitoring Precast Beams
  • ARCAgent - Weld Process Quality Monitoring System
  • Leak Detection System for Underground Storage Tank
  • Smart Structures for Bridges
• 
  
  Recycling
  • RP-1 Polymer Identification System: Recycler or Plastic
  • Production of Construction Materials Using Advanced Recycling Technologies
  • Infrared Gas Sensor
• 
  
  Remediation
  • Encapco Emulsified Treated Base Product
  • T.O.C.S. : Hydrogen Sulfide Remission System
  • Fiber-Optic Laser Technology for Decontaminating Metals
  • DMA^TM: Digestion Material for Asbestos
  • Asbestos Removal System using High-Pressure Water
• 
  
  Robotics
  • Robotized Spraying of Glass Reinforced Concrete (GRC) Panels
  • Reinforced Cage Robot for Concrete Beams and Columns
  • Mobile Bricklaying Robot
  • Automated Tank Surface Finishing System
• 
  
  Security
  • Acoustic Wave Sensor
  • Air Ventilation Protection System for Building Security
  • Pattern Recognized Surveillance System
  • Emerging Video Surveillance and Monitoring System
  • New Access Control Technologies: Biometric Identification Recognition
• 
  
  Site Positioning and Metrology
  • 3D Laser scanning and modeling system
  • Real-Time Positioning
• 
  
  Soil Remediation
  • Funnel and Gate System
  • In Situ Enhanced Soil Mixing
  • In Situ Remediation using Horizontal Wells
  • Jet-Grouting Constructed Laminar Diaphragms
  • Glass Diaphragm Walls
  • Extraction of Contaminated Soils using High Pressure Jet Grouting Techniques
  • Hydraulic and Pneumatic Fracturing for In Situ Remediation
  • In Situ Vitrification (ISV)
  • Plasma Torch - Soil and Waste
• 
  
  Water/Waste Systems
  • Storm Chamber
  • Chemical Cleaning Process for Potable Water Pipes
• 
  
  Water Dectection/Resistance
  • ElectroOsmotic Pulse Technology for Prevention of Water Intrusion in the Concrete Structure
  • Cable-based Water Leak Detection System

Home > Other Tech. > Air Ventilation Protection System for Building Security

Air Ventilation Protection System for Building Security

The Need

In general and nationwide, indoor environmental quality (IEQ) is an important public health issue. Its absence - often through benign neglect- can lead to widely publicized problems such as sick building syndrome, building-related illness, multiple chemical sensitivity and building security issue as well. IEQ problems are estimated to effect more than 10 million workers in up to 30 percent of buildings in the United States alone, resulting in billions of dollars of decreased productivity, litigation, and adverse publicity. Thus, the air ventilation protection system demand is increasing across a broader spectrum of applications in response to the widening recognition of the vulnerability faced by occupants in less secure governmental, military, and commercial buildings, transportation facilities and, major event venues.

The Technology

Collective protection equipment (CPE) has traditionally been reserved for protection of military facilities and sensitive government structures, such as the White House. Commercially, CPE has been used for security purposes in high value manufacturing processes, like semiconductor fabrication, and in hospital operating rooms, where mitigation costs are much lower than potential costs associated with infection. CPE systems typically provide protection through overpressurization of the structure itself with the makeup air supply and simultaneous filtration of either the makeup air or the recycle air. Makeup air filtration protects occupants against a chemical or biological agent release occurring outside the structure (external release) while recycle air filtration provides protection against an internal release. In either case, airborne contaminants are removed through some filtration process before any humans or critical operations are exposed to the suspect air stream. Conventional CPE systems generally accomplish chemical and biological agent mitigation through two separate purification steps, particulate and biological warfare agent (BWA) removal with non-woven HEPA (High Efficiency Particulate Air) filters, and adsorption or reaction of chemical warfare agents (CWA) in packed beds of sorbent and/or catalyst pellets. The new technology to solve the limitation of conventional CPE system has been developed as "Combined ESP/ESF/PCO and microfibrous media CPE application". This concept of this new technology is the combination of the both systems; 1) Microfibrous Material Technology, and 2) Photocataytic Oxidation Technology.

1. Microfibrous Material Technology (MMT) The basic MMT element is a thin sheet of media consisting of a sinter-locked network of micron diameter metal fibers entrapping sorbent and catalyst powders at void volumes between 50% and 95%.The use of sorbent and catalyst powders (ca. 100 μm diameter) virtually eliminates rate-limiting phenomena, namely intraparticle heat and mass transfer, commonly found in packed-bed systems while simultaneously improving contacting efficiency between the sorbent material and contaminants in the air stream.
2. Photocatalytic Oxidation Technology Electrostatic precipitation (ESP) is a well-known technology in which particles in an airstream are ionized in an electric field and collected on a series of parallel plate electrodes in a flow-past arrangement. Electrostatic filtration (ESF) is an extension of ESP, except that ionized particles are captured by flowing through a relatively open, non-woven filter element/electrode. Photocatalytic oxidation (PCO) involves illuminating TiO2 surfaces with ultraviolet radiation (less than 385 nm) to produce hydroxyl radicals and O2- ions, which are both powerful oxidation agents. Researchers at the University of Missouri have developed and demonstrated TiO2 spray coating methods (Figure 2) that enable PCO and ESP/ESF to be combined in a single filtration element. By illuminating TiO2-coated ESP and ESF electrodes with ultraviolet radiation, collected particulate biomass, including spores, molds, and biological agents, is continuously oxidized and removed from the system. Units operated in this manner are therefore self-sterilizing and not subject to fouling.

The Benefits

The several and obvious benefits compared to the typical HEPA filter/packed bed approach are primarily related to operational, maintenance and life-cycle cost savings achieved by reducing the logistical tail associated with constant replacement of disposable filter media and lowering HVAC fan/blower power requirements by removing a substantial amount of pressure drop from the filter system.

Microfibrous media is far superior in stopping hazardous air quality contaminants compared to Commercial Off-The-Shelf (COTS) carbon HEPA filters currently used in HVAC systems.

Characteristic	COTS Carbon	IntraMicron (holds patents for technology)
Active material	Carbon only	Very flexible - variety of sorptive and neutralizing media
Pressure drop across the filter	Very high	Far more “breathable” - 1/2 to 1/8th of current filters
Utilization of adsorptive media at breakthrough	Approximately 25%	Far more efficient - greater than 95%
Regeneration/reuse	Not possible	Can be regenerated / reused by heating the media
Capable of new formulations to meet new threats	No	Yes, protective sorptive media can be added to meet new threats or specific threat
Ease of manufacturing	Labor intensive	Automated: high speed, "roll-to-roll" on paper machine

Status

The mitigation technology consists of front-end TiO²-coated ESP and ESF units illuminated with UV bulbs to provide PCO at the collection electrodes (viz., an ultra low pressure drop HEPA filtration capability for biological agents) followed by high efficiency, low pressure drop microfibrous sorbent media to remove CWAs, volatile organic compounds (VOCs), toxic industrial chemicals (TICs) and toxic industrial materials (TIMs). Individual modular components of the ESP/PCO/ESF and microfibrous media technologies were fabricated and tested. Specifically, a 500 cfm(cubic meters / hour) capacity ESP/PCO/ESF unit and a 1000 cfm capacity chemical sorbent canister containing pleated microfibrous media were constructed and tested, both separately and as a complete system. These units are shown in Figure 1 assembled as a complete system for testing

The 3000 cfm unit shown as Figured 3 and 4 is currently being testing in Anniston, AL by the Defense Advanced Research Projects Agancy (DARPA) as part of their immune building program. Another unit will be manufactured and tested by the General Services Administration in a courthouse in Key west. FL as soon as they receive budget approval. The capability to manufacture media in commercial production capabilities with the necessary quality control is in place. IntraMicron is currently seeking commercial clients willing to conduct prototype tests for their own facilities.

Barriers

The major hurdles to commercializing this and many other emerging technologies are:

• Risk mitigation/indemnification insurance-as yet there is no "good Samaritan" type legislation.
• An efficient way to show that product meets/exceeds the proliferation of building code requirements.
• Lack of rapid contracting mechanisms to fast track prototype projects.
• Willingness/ability of decision-makers to prioritize threats to enable customized solutions.

Points of Contact

• C. H. "Stretch" Dunn, CHD Consulting. Stretch will coordinate any introductions needed with the appropriate individuals at IntraMicron, Auburn University or BE&K -the 3 entities allied to provide one-stop solutions to a clients requirement. Phone: 205-337-0820 Email: dunnst@bek.com

Refrences

1. BE&K Website: http://www.bek.com
2. Papers "Intramicron Regenerable Collective Protection System" and "Innovative Description-Microfibrous Material Ventilation System Filter (MMVSF)"

Disclaimer Statement

Neither the Construction Industry Institute nor Purdue University in any way endorses this technology or represents that the information presented can be relied upon without further investigation.

Comments

Add Comment