Wednesday, January 8, 2020

Friday, November 22, 2019

Heated Cube for Next Generation Mass Spectrometry

BCE Heated Cube
BCE Heated Cube

An analytical company approached BCE for their small space and high temperature heated gas requirement.  They needed to reduce the length and diameter of the current heat source to be able to fit into a more compact design for their next generation mass spectrometry tool.

  • The Heated Cube needed to satisfy the following:
  • Temperature up to 500°C   
  • Small, compact footprint 
  • Insulate heat source to retain heat and reduce outer temperature 
  • Reduce size from a 36” long cylinder to a 2” square cube 
  • 120-Volt 200-Watt 
  • Must pass all electrical safety and Meg-Ohm requirements 
  • Air path must be clean and free from ni-chrome wire exposure (chromium flaking) 

BCE produced a highly effective high temperature clean gas electric air heater with a major reduction in size.  A stainless steel gas heating package with a footprint of 2” x 1 ½”x 1” was the result.  This heater is compact and has an inlet of 1/8” BSPP and a 1/16” NPT outlet with a 36” long heated path that maximizes heat transfer to the fullest.

There are two zones of heat each at 100 watt with two sensors, one to control and one to monitor the temperature.  The outlet temperature can reach up to 500°C.

The Heated Cube comes complete with insulation and a SST jacket.  It can be mounted in an extremely tight space for most OEM tools that put a premium on space and performance.  Liquid and gas medium can be processed with this design.

Call BCE today at 510-274-1990 for more information, or visit their web site at

Monday, November 11, 2019

BCE Thanks Our Veterans

Veterans Day is a day of observance and celebration for those who have served in the United States military. Veterans Day was originally called Armistice Day because of the November 11 Armistice that ended World War I. In 1954 it was officially changed to Veterans Day to include Veterans of all wars. This holiday honors those who took an oath to defend the United States and our Constitution, from all enemies, foreign and domestic. Through the observance of Veterans Day, we remind ourselves of our Veterans patriotism, love of country and willingness to serve and sacrifice for the common good.

BCE thanks our Veterans, past and present, for serving our country and protecting our freedom.

Wednesday, September 18, 2019

Resistive Heating Elements for Gas Chromatography

Gas Chromatography Heater
Custom gas chromatograph heater by BCE.

What is Gas Chromatography?

The most basic understanding of gas chromatography (GC) is that of a separation technique. It is used in analytical chemistry for the prompt separation, identification and quantification of compounds that can be vaporized without decomposition. Common uses of GC include testing the purity of a substance or separating and identifying the different components of a mixture.

The basic components of the GC system are:
  1. A long thin tube, referred to as a "column", and an oven or direct heating element that provides accurate temperature control and profiling. 
  2. The injector, which provides the means for the sample to enter the column.
  3. The detector, which provides the means for the sample to exit the column.
  4. The temperature control system.

Basic Understanding of Gas Chromatography

The sample (analyte) is transported through the column by the flow of an inert, gaseous mobile phase (typically nitrogen, helium, argon, or carbon dioxide). The GC column contains a liquid referred to as the "stationary phase" which, as it traverses the column, is repeatedly adsorbed onto the surface of an inert solid and desorbed back into the carrier gas stream. Based on an adsorbent's composition, it can have varying affinities to "hold". Because some constituent components are likely to spend more time in the stationary phase, while others are likely to spend less time, the separation process occurs.

Constant demand for optimized analytical throughput, GC portability, and less costly analysis propels the development of new gas chromatography designs and technologies. In recent decades, resistive heating technologies designed for the sample column heating have become commercially available and have grown in popularity. Resistive heaters have clear advantages over traditional air bath ovens, most notably direct, low-mass heating through conduction. The growth of portable GC systems has also benefitted from small, compact, low power resistive heaters.

The temperature control system is at the heart of gas chromatography accuracy, sensitivity and speed. This system is comprised of the electric heating elements, temperature controllers, and temperature sensors. All are critical in sample and column temperature regulation.

Gas Chromatography Heaters

This specialized category of electric heating element is designed to provide extremely uniform temperature profiles across the length of the GC column. This uniformity accommodates a stable temperature environment for the capture of repeatable and consistent data between runs. Gas chromatograph heaters allow for very precise temperature ramping and set point control to very tight tolerances. This is critical because the slightest fluctuation in column temperature during analysis will have significant effect on analysis outcomes.

Controlling the Temperature of the GC Column

Once the temperature profile of the column is established, a precision thermal control system is required to provide precision temperature control during the operation of the profile. The control system must be highly accurate and responsive, and must include advance control algorithms to handle a wide variety of column profiles.

Temperature Programmed Elution

In most cases, a ramping temperature profile is required when the analyte enters the column. The ramping temperature profile starts at a lower temperature and increases over time in a precise and linear fashion. At different points along the temperature profile, compound movement changes according to temperature exposure. This precise exposure to changing temperature enhances analyte separation and reduces cycle time.  Considering this, the heating element must be sized properly and have sufficient wattage to sustain the power requirements of the ramping temperature profile at all points along the ramp.

For more information about the application of resistive heaters for gas chromatography, contact a BCE applications engineer.

Thursday, September 12, 2019

High Temperature 16 Pair Type J Thermocouple Feedthrough

Type J Thermocouple Feedthrough
16 Pair, High Temp Type J Thermocouple Feedthrough

A 3D Printer company specializing in Aerospace parts provided BCE a challenge in creating a High Temperature Feedthrough for their new composite 3D printer.  The 3-D composite company needed a high enough temperature in the sealed area with a vacuum chamber being essential in printing aircraft components.  They had difficulties integrating their existing thermocouple design into their expanded chamber with an off the shelf feedthrough.


The 16 (32-wire) Pair Thermocouple feedthrough needed to satisfy the following:
  • Operating temperatures between -25 C to 300 C
  • Low vacuum leak rate of 10^-9 ATM-CC/S or better
  • Able to withstand a 450 C Bake-out temperature
  • Type J thermocouples (customer preference) with ring terminations 
  • Fiberglass lead wires to withstand the high temperature

BCE successfully designed a Thermocouple Feedthrough with a type J T/C extension wire so that the customer could integrate the component with ease into their 3D Printer. The High Temperature Feedthrough went through extensive pressure and temperature cycling before being shipped.  One final helium leak check was made and a polarity verification for all connectors was done too.

For more information, contact BCE by calling 510-274-1990 or by visiting

Monday, September 2, 2019

Copper Flange Heater for Gas Chromatograph

Copper Flange Heater
A gas chromatography application was brought to BCE involving a custom heater to ramp a cell end plate to 105°C. The customer had issues finding a solution due to the small surface area that needed to be heated (~ 0.75” diameter).  The requirement was a 25-Watt 120-Volt source, which resulted in a high resistance value (576 ohms) eliminating many heater options for this size and surface area.

  • Heater plate to be 105°C 
  • Good temperature uniformity (+/- 1.5%C)
  • 25 W 120 V
  • 1/8” Plate thickness max
  • Geometry to allow for three tubes to exit
  • 0.75” Diameter

Since etched foil polyimide heaters were not an option for this application, BCE engineers designed a 110 copper plate with a rod heater welded within the groove.  The rod style heater allowed for a higher resistance value and was more robust compared to other types of heaters.  Additionally, the cold section and lead orientation can be easily modified by the customer to accommodate their assembly.  BCE’s Copper Flange Heater was able to efficiently heat the small surface and save the customer from an expensive assembly redesign.

For more information, contact BCE by calling 510-274-1990 or by visiting

Friday, August 23, 2019

High Temp Heater Chuck – 200mm

High Temp Heater ChuckA semiconductor equipment company in the Atomic Layer Deposition (ALD) market approached BCE in need of a custom high temperature heater solution.  Their application involved a thin-film deposition using a sequence of various chemical processes.  Repeating these processes results in a thin film being slowly deposited. 


High Temperature Heater Chuck needed to satisfy the following:

  • Temperature <700°C   
  • Internal element must be able to withstand higher than 700°C
  • Thermal break between flange and base reducing heat transfer to flange area 
  • 316 Stainless steel base, sleeve, and flange must pass all required vacuum specifications
  • 240Volt 1450Watt
  • Built-in thermocouple type “K” inside internal element grounded with RF screening 

High Temp Heater Chuck
Click for larger view.

BCE produced a highly effective high temperature heater with exceptional uniformity.  The design was able to compress the internal element enough to allow for optimal temperature transfer.  The weld around the outside periphery of the base plate and the (3) lift–pin-hole-standoffs were essential in the design for vacuum integrity, ramp rate, and temperature stability. 

For more information, contact BCE. Call them at 510-274-1990 or visit their web site at