Tag Archives: industrial

New XHB Basic Millivolt Series Pressure Sensor

Welcome to All Sensors “Put the Pressure on Us” blog. This blog brings out pressure sensor aspects in a variety of applications inspired by headlines, consumer and industry requirements, market research, government activities and you. In this blog we’ll discuss our new XHB Series.

New XHB Basic Millivolt Series Pressure Sensor

All Sensors has announced a new line of basic millivolt pressure sensors, ranging from 1 to 70 PSI. The XHB Series Pressure Sensor provides an uncalibrated and uncompensated analog millivolt output signal and is intended to be used with dry air and non-corrosive gases. Miniature DIP housing allows for through-hole PCB-mounting and maximum OEM design flexibility. This series provides an operating temperature range of -40°C to 85°C, and pressure ranges include 1, 5, 15, 30, and 70 PSI.

The XHB Series features:

  • 1 to 70 PSI
  • Miniature DIP packages
  • Maximum OEM design flexibility
  • RoHS compliant

Ideal applications for this device include:

  • Industrial and Pneumatic Controls
  • Instrumentation
  • Medical Devices

Datasheet download here. Samples are available for product testing.

What do you think/Comments?
Do you have a pressure sensing question? Let me know and I’ll address it in an upcoming blog.
-Dan DeFalco, Marketing Manager, All Sensors Corporation (ddefalco@allsensors.com)

Pressure Sensing and Improved HVAC Efficiency

Welcome to All Sensors “Put the Pressure on Us” blog. This blog brings out pressure sensor aspects in a variety of applications inspired by headlines, consumer and industry requirements, market research, government activities and you. In this blog we’ll look at pressure sensing and how it improves HVAC efficiency.

Pressure Sensing and Improved HVAC Efficiency

Clean air in heating, ventilating and air conditioning (HVAC) systems requires filtering to eliminate dust, pollen and other airborne contaminants in residential, commercial and industrial buildings for the health of occupants and equipment. Some locations such as clean rooms in semiconductor and other manufacturing operations as well as hospital operating rooms and research laboratories have very special requirements. Clean air depends on the filter’s initial efficiency and the pressure drop across it, which increases with usage. The pressure drop is also called the air filter resistance.

The National Air Filtration Association (NAFA) says, “Most large HVAC commercial grade systems are designed to handle pressure drops of one inch, possibly more, for the air filter resistance. Matching filter initial, final and average resistance to the system is critical for proper air filtration and air exchange rates. Also, providing pressure drop reading devices such as manometers or electronic pressure sensors is an absolute requirement.”

According to the Lawrence Berkeley National Laboratory (Berkeley Lab or LBL) Design Guide for Energy-Efficient Research Laboratories – Version 4.0, for HEPA filters, the “pressure drops can be as low as 0.1 inches water gage (w.g.) (24.9 Pa) and as high as 1.0 inches w.g. (249 Pa), with significant energy use impacts resulting from the nonlinear power use requirements of higher pressure drop filters.”

Filters are rated in static pressure at a specified cubic feet per minute (CFM) air flow. In 103 – Filtration Fundamentals, one company states that most heating /cooling systems in the residential and light commercial markets are designed to move 900 CFM to 2000 CFM at a total system static pressure of approximately 0.5″ to 0.7″ total pressure drop including the resistance through the ductwork and the filter.

With usage, the total pressure drop increases causing the filter to draw more power and increase the stress on the air handling equipment. The point where the pressure drop increases the electrical power consumption and overtakes the initial cost of the filter indicating that a filter change is required is called the optimal change-out point and is shown in Figure 1.

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Figure 1. The optimum final pressure drop across an air filter.

The equation used to determine the energy cost based on the final pressure drop is:

Energy Consumption (in kWh)= Q ∆P t / η 1000

Where:

Q = airflow (m3/sec)

ΔP = avg. pressure loss (Pa)

t = time in operation (hours)

η = fan efficiency

In the summary for pressure drop considerations for air filters, NAFA concludes, “Pressure drop reading devices are essential to determine optimum performance results and filter change-out frequency.”

Achieving the optimum performance leads to efficient filter operation and safe, clean air.

What do you think/Comments?
Do you have a pressure sensing question? Let me know and I’ll address it in an upcoming blog.
-Dan DeFalco, Marketing Manager, All Sensors Corporation (ddefalco@allsensors.com)

New DLV Series Low Voltage Digital Pressure Sensor

Welcome to All Sensors “Put the Pressure on Us” blog. This blog brings out pressure sensor aspects in a variety of applications inspired by headlines, consumer and industry requirements, market research, government activities and you. In this blog we’ll look at All Sensors’ new DLV pressure sensor.

New DLV Series Low Voltage Digital Pressure Sensor

All Sensors has announced a new DLV Series Low Voltage Digital Pressure Sensor. The DLV Series is based on the already popular DLVR Series Pressure Sensors. This new device series offers design engineers excellent performance over middle pressure ranges of 5 to 60 psi compared to the DLVR low pressure ranges of 0.5 to 60 inH2O.

Product highlights include supply voltage options to ease application integration into a wide range of process control and measurement systems and multiple power consumption modes for battery-powered or remote systems. The DLV Series provides a calibrated and compensated output over a wide temperature range of -20°C to 85°C.

The DLV Series embodies innovative features:

  • 3.3V or 5V supply voltage
  • I2C or SPI interface
  • Better than 0.5% accuracy over temperature (typical)
  • Sil-Gel die coating is added for enhanced media protection
  • Miniature packaging with SIP and DIP lead configurations

Ideal applications for this device include:

  • Medical breathing
  • Environmental Controls
  • HVAC
  • Industrial controls
  • Portable devices/hand-held equipment
  • Other applications measuring clean, dry air and gases

Datasheet download here. Samples are available for product testing.

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What do you think/Comments?
Do you have a pressure sensing question? Let me know and I’ll address it in an upcoming blog.
-Dan DeFalco, Marketing Manager, All Sensors Corporation (ddefalco@allsensors.com)