Compressed Natural Gas Stations: Fueling the American Dream

  • July 5, 2013

CNG Stations are popping up all over the country. View an interactive map showing where these Compressed Natural Gas Stations – which use ChemTec EFVs – are being built!

Related ChemTec Product: HPEFV

Shown below, ChemTec’s HP-EFV-750-S in a CNG filling station; installed on the line between the supply line and vehicle.

Chemtec HP-EFV-750-S High Pressure Excess Flow Valve in a CNG Filling Station

Visit Our Catalog to learn more about excess flow valves, or discuss alternative fuel applications in our Distributor Zone.

Efficient AODD Pump Operation

  • July 2, 2013

Eliminating dry running can save money and protect equipment

Every year, air operated double diaphragm (AODD) pump users spend thousands on electricity, replacement parts and labor because they dry run their pumps. Unlike many other types of pumps, AODD pumps can run dry (run without being fully primed) without immediate damage. Therefore, they are useful in applications such as sumps and tank transfers in which the liquid may unexpectedly run out.

Routinely relying on an AODD pump’s ability to run dry, however, can incur substantial costs—including energy loss, increased maintenance and lost compressor capacity. This article details these costs, the prevalence of dry-running pumps and solutions for running a greener and more cost-effective operation.

The Cost of Dry Running an AODD Pump
When a pump runs dry, 100 percent of the consumed air is wasted. Although lost energy from wasted air is the most obvious cost, additional maintenance, downtime and lost compressor capacity are also significant.

A simple method to estimate the cost of a dry-running pump is to multiply the percentage of time that the pump runs dry by the total operating cost.

As seen in Table 1, the yearly dry-running costs can exceed the cost of the original pump. Furthermore, the air and maintenance costs are often much higher, as a dry-running pump can operate two to three times faster than it does when under load. This means more air usage and faster wear and tear on the pump.

The cost of dry running an AODD pump

Table 1. The cost of dry running an AODD pump

While the direct pump and compressed air costs are substantial, the associated costs can be just as high. A few 70 standard cubic feet per minute (scfm) “leaks” in an air system represent a significant drain on a compressor, requiring plant engineers to consider increasing the overall system pressure, or increasing the size and number of compressors. Frequent and unexpected pump failures can also lead to product loss and production downtime, both of which can match the air and maintenance costs.

The Prevalence of Dry-Running AODD Pumps
Despite the high cost of dry-running pumps, the practice is a common occurrence in many factories. Some typical causes and observations seen at several factories are described in this section.

Operators Leave Pumps Running
A chemical factory needed to rebuild one to two pumps every month. Given the number of pumps that the factory had and the amount of time the pumps needed to be in use, only one to two rebuilds per year should have been required. The parts cost per rebuild was $300 to $500 plus labor, and the maintenance bills were adding up quickly.

Operators unintentionally left the pumps running throughout the weekend. Because the plant’s energy or maintenance bill was not included on performance reviews, the operators had little incentive to remember to turn off the pumps.

The same pattern is repeated in other factories. Another example is a large paint factory at which workers use pumps to empty large tanks. Again, operators would turn the pump on, get distracted by other tasks and forget to turn them off.

Failed or Missing Level Sensors
Because AODD pumps are often used in “dirty” situations—outside or in waste sumps in factory floors—debris or corrosion frequently cause level sensors to fail. Non-contact types are susceptible to debris or being dislodged as well.

In many of the observed factories, sumps had level sensors that were bypassed because they were not reliable enough. In these cases, the sump pumps operated 24 hours per day, despite the sump filling only occasionally. By equipping two of their pumps with monitoring equipment, the operators discovered that a 2-inch pump was only pumping liquid 32.8 percent of the time, and a 1-inch pump only 7.3 percent of the time. More than half of their energy and maintenance bill was being used to needlessly pump air.

Whether the cause is operator error, a failed level sensor or simply installing a pump to run non-stop when unnecessarily, dry-running AODD pumps appear to be a common occurrence.

Although dry-running pumps can be costly, several solutions, ranging from inexpensive procedure changes to sensor-based control solutions, can reduce costs substantially. Most of these solutions will show a return on investment within six months to one year, depending on the frequency of dry running.

Solutions can be divided into three categories: procedural changes, level sensing sensors and switches, and air monitoring controllers.

Procedural Changes
If personnel are informed of the true cost of dry-running pumps, including the resulting increase in maintenance, they can work individually to avoid leaving pumps running unnecessarily. Adding dry-running observations to maintenance records can help diagnose the root cause of pumps that require frequent rebuilding. Routinely checking sump level sensors for correct operation can also help to avoid long stretches of dry-running operation.

The main issue with this solution is that it relies on human intervention to ensure proper pump operation.

Level Sensors and Switches
A myriad of level sensors and controllers can be used to turn pumps off when they are not needed. Inexpensive, simple float-trigger switches indicate when a tank or sump level is too high or low, turning the pump on or off as required. Because floats can easily become obstructed by debris, many float-less types—such as capacitive (both contact and non-contact), radar and ultrasonic—are other options.

When considering level sensors, end users should evaluate the whole system cost because many sensors require an additional solenoid and, in some cases, a separate programmable logic controller (PLC). Installation requirements for all the separate components should also be taken into account. Unfortunately, since many level sensing solutions are in contact with the pumping liquid, they suffer from corrosion or clogging. Even non-contact sensors can be blocked by debris or dislodged.

Air monitoring controllers monitor the pump through the air line without contacting the pumped fluid.

Figure 1. Air monitoring controllers monitor the pump through the air line without contacting the pumped fluid.

Air Monitoring Controllers
Another category of controllers that avoids the problems of level detection devices is air monitoring controllers. Air monitoring controllers work similarly to load-monitoring controllers on electric motors, turning the pump off when the air input indicates that the pump is running dry.

Some controllers in this category rely only on mechanical switches, while others use electronic controls. The mechanical controllers typically detect a change in pressure or flow to determine when a pump is running dry. Because a dry-running pump faces little to no resistance, it operates faster and uses more air than when transferring liquid.

While mechanical controllers have the benefit of operating without power, they can be unreliable when plant conditions change, such as the input or pump discharge pressure.

Air monitoring controllers with electronics can employ more sophisticated logic to compensate for changing environments, and also better detect when a pump is truly running dry.

Some of these solutions use pressure sensors to listen to the pump like a stethoscope to detect the individual stroke rate, which typically changes much more than the air input rate.

Ignoring short-term changes (false positives), restarting on timers and interfacing with PLCs are other benefits.

AODD pump in a factory transfer application with an air monitoring controller.

Image 1. AODD pump in a factory transfer application with an air monitoring controller.

Dry-running AODD pumps are a costly problem that can easily go unnoticed, wasting significant energy, money and maintenance resources. Since many people are unaware of the high cost, dry-running pumps are a common occurrence in many factories. Fortunately, many solutions are available that provide a fast return on investment, ranging from simple maintenance procedural changes to controllers that automatically turn off pumps when they are not needed.

Written by: Scott Driscoll
Originally Published May 1, 2013 on

Related ChemTec Product

ChemTec’s LCA Series is an in line, field adjustable flow monitor for liquid flow to detects loss of flow or signal no-flow conditions.
Chemtec LCA Series Adjustable Flow Monitor

Click Here to download the product Spec Sheet.

Industry Spotlight: Cooling Towers & Chillers

  • February 1, 2013

Chillers and cooling towers are implemented in various processing systems across many industries and are put into place for several reasons, including extending the life of the equipment and improving the quality of equipment performance.  Outside of equipment, chillers & cooling towers help maintain a constant temperature of liquid or air.

Flow monitors and flow meters are both suitable for cooling towers and chillers. Flow monitors are installed in-line to indicate loss of flow of cooling water in a chiller or cooling tower which is crucial to the cooling process. Flow meters are installed in-line to provide an accurate indication of flow. Detecting an increase or decrease in flow can help prevent quality problems and damage to expensive equipment.

ChemTec’s line of flow monitors and flow meters offer the accuracy, dependability and durability required by cooling towers and chillers. Designed to sense high & low flow conditions, ChemTec’s monitors & meters can be used in both manual and programmable linear controllers.  The LPH flow monitor is economical, compact and customizable to meet application demands. ChemTec’s MAO flow meter offers superior performance output.

To learn more about ChemTec’s LPH & MAO Series visit our catalog.

Chemtec's LPH-125-A Non-Adjustable Flow Monitor



Chemtec's MAO-125-T Non-Adjustable Flow Monitor



Chemtec's MAO-500-T Non-Adjustable Flow Monitor



Where to Find Cooling Towers & Chillers:

Air Conditioning/ HVACR (refrigeration)
Oil Refineries
Petrochemical/Chemical Plants
Thermal Power Stations
Water Treatment Plants
Medical Equipment Chillers (MRI’s, Lasers, CAT scans)
Process Equipment Chillers
Food Processing & Potable Water Chillers
Dry Cleaning Machine Chillers
Indoor/Outdoor Industrial Process Chillers
Cold Plunge Pools /Sports Therapy Pools
Plastics & Injection Molding

Types of Low Flow Coolers & Chillers:

Closed loop
Open loop

Chemtec's Flow Monitor Application

View our Flow Monitor Application Case Study

Lasers for Science, Medical & Industrial Applications

  • January 11, 2013

Types of Lasers: Scientific

There are many different types of lasers. The laser medium can be a solid, gas, liquid or semiconductor. Lasers are commonly designated by the type of lasing material employed:

  • Solid-state lasers have lasing material distributed in a solid matrix (such as the ruby or neodymium:yttrium-aluminum garnet “Yag” lasers). The neodymium-Yag laser emits infrared light at 1,064 nanometers (nm). A nanometer is 1×10-9 meters.
  • Gas lasers (helium and helium-neon, HeNe, are the most common gas lasers) have a primary output of visible red light. CO2 lasers emit energy in the far-infrared, and are used for cutting hard materials.
  • Excimer lasers (the name is derived from the terms excited and dimers) use reactive gases, such as chlorine and fluorine, mixed with inert gases such as argon, krypton or xenon. When electrically stimulated, a pseudo molecule (dimer) is produced. When lased, the dimer produces light in the ultraviolet range.
  • Dye lasers use complex organic dyes, such as rhodamine 6G, in liquid solution or suspension as lasing media. They are tunable over a broad range of wavelengths.
  • Semiconductor lasers, sometimes called diode lasers, are not solid-state lasers. These electronic devices are generally very small and use low power. They may be built into larger arrays, such as the writing source in some laser printers or CD players.

Types of Lasers:  Medical
Commonly used lasers in health care

Medical Laser Use Chart

Types of Lasers: Industrial

There are two main types of industrial laser of interest to structural fabrication; CO2 and Nd:YAG lasers.

Applications for Lasers:

  • Laser micro-machining
  • Laser cooling systems
  • Laser cutting
  • Laser engraving
  • Arc Welding
  • Steel –foraging
  • HVAC Equipment
  • Hydro-cutting systems
  • Laser show systems
  • Medical devices, surgical lasers, laser therapy for tissue
  • Particle image velocimetry systems
  • Photonics
  • Semiconductor
  • Photovoltaics

Sales Opportunity:

ChemTec’s flow monitors are currently employed in the cooling systems of industrial, scientific & medical lasers.

Chemtec LCA-500-B Adjustable Flow Monitor

LCA-500-B (custom B-783 unit shown here)


Chemtec FS Series Non-Adjustable Flow Monitor

FS Series (custom unit in PVC shown here)


Chemtec LPH-375-A Non-Adjustable Acrylic Flow Monitor

LPH-375-A (standard options shown here)


Related Articles:

Industry Spotlight: Food & Beverage

  • November 1, 2012

Applications are abundant in food and beverage processing, packaging, dispensing and storage.  Here are some opportunities we think you will find useful.