ruggedized radiation detectors for oil and gas exploration

Extreme Environment

Ruggedized Detectors

All-welded package ensures hermiticity in harsh environments
Unique glass-to-metal sealing technology for high-temperature reliability
Photomultiplier tube integration options

The primary use of our ruggedized detectors is for oil and gas exploration. Our reputation for designing and manufacturing detectors capable of surviving use in the harsh environmental conditions of oil exploration has gained us wide recognition and acceptance in this industry.

Reasons for high performance of our product:

Patented Polyscin® NaI(Tl) provides enhanced resistance to thermal/mechanical shock
All-welded package ensures hermiticity in harsh environments
Unique glass-to-metal sealing technology for high-temperature reliability
Photomultiplier tube integration options for turnkey detection solutions

Our detectors, as integral components of gamma-ray logging tools, provide superior performance and survivability under the most extreme environmental conditions. The newer generation of exploration and production logging tools place incredible performance demands on scintillation-based sub-assemblies. Several patented features in our crystal packages and our series of integrated detector designs provide gamma logging professionals significant advantages.

Design Considerations

Complex sets of dynamic engineering principles are used in the design of our geophysical detectors to assure that they meet both mechanical survivability and performance specifications demanded by the Logging Service Industry. Each gamma-ray tool requires a custom detector design. The fundamental elements of a downhole device must take into account the following considerations:

Space Constraints
Environmental Considerations (Temperature, Shock, Vibration)
Nuclear Performance Demands
Energy of Interest (Gross Counting vs. Spectral)
Photomultiplier Tube Performance

Design Options

Detectors can be customized for very specific applications
All-welded hermetic package and glass-to-metal seal options to withstand the rugged Wireline & MWD operating environments
Choice of scintillators:
- LaBr₃(Ce): Highest light output at temperature, fast counting for pulse neutron activated measurement, more accurate energy level determination
- NaI(Tl): Versatile, industry standard for wireline and MWD applications
- CsI(Tl): One of the brightest scintillators with very good stopping power
- BGO: High gamma stopping power for wireline logging, without intrinsic radioactivity
Integration with photomultiplier tubes available, thus allowing for unmatched survivability and performance of a fully functioning gamma-ray detector system

Detectors are designed with the strongest, most reliable hermetic seals possible. The glass-to-metal or soldered eyelet seal, combined with the all-welded package construction, constitutes the basis for our detector survivability.

Our seals withstand temperature extremes and cycling stresses that eventually cause both epoxy and other seals to fail. Sodium iodide (the principal scintillator in Wireline and MWD applications) is a brittle, reactive material sensitive to thermal shock. By placing the crystal in the Geophysical package under substantial compression, we assure the survival of the sodium iodide crystal at the limits of Wireline and MWD shock and vibration.

Our MWD detector technology incorporates all the dynamic design considerations of our ruggedized detectors with the advantages of an integrated photomultiplier tube and engineered design, thus allowing for unmatched survivability and performance of a fully functioning gamma-ray detector system.

Unique glass to metal sealing technology and all-welded construction eliminates epoxy seals for high-temperature reliability
Operating Temperature +25°C to +175°C (Gradient 3°C per minute maximum)
Mechanical Survival Shock 100g @ 11ms – 3 shocks per axis; 2 axis total. (X & Z)
Vibration Random 5G_RMS 50-500Hz 15 minute duration per axis; 2 axis total

Unique glass to metal sealing technology and all-welded construction eliminates epoxy seals for high-temperature reliability
Operating Temperature +25°C to +175°C (Gradient 3°C per minute maximum)
Mechanical Survival Shock 1000g @ 1ms – 3 shocks per axis; 2 axis total. (X & Z)
Vibration Random 20G_RMS 30-1000Hz 30 minute duration per axis; 2 axis total

Maximized crystal volume - Larger crystals provide increased count rates
Thinner wall allows for larger crystal, more counts, and greater low energy sensitivity
Stronger sapphire window is much thinner for increased light transmittance
High strength sapphire-to-metal seals

Example with open window

Scintillation Radiation Detectors for Oil & Gas Exploration

Custom Temperature, Shock, and Vibration Specifications available upon request.

G – Style Crystal Package - Standard with glass to metal seals

Operating Temperature	+25°C to +175°C
Survival Temperature	-20°C to +200°C
Gradient	3°C per minute maximum
Mechanical Survival Shock	100g @ 11ms – 3 shocks per axis; 2 axis total. (X & Z)
Vibration	Random 5g_RMS 50-500Hz 15-minute duration per axis; 2 axis total

SG & SG-XR Styles Crystal Package - Standard with glass to metal seals

Operating Temperature	+25°C to +175°C
Survival Temperature	-20°C to +200°C
Gradient	3°C per minute maximum
Mechanical Survival Shock	1000g @ 1ms – 3 shocks per axis; 2 axis total. (X & Z)
Vibration	Random 20g_RMS 30-1000Hz 30-minute duration per axis; 2 axis total
Mechanical Performance	* (-XR Type Only)
Vibration	Random 20g_RMS 30-1000Hz 2.5 minute duration per axis; 2 axis total per the following power spectral density profile: 30-80Hz. @ 6db/octav 80-1000Hz .43g2/Hz
Acceptance Criteria	Vibration induced counts per second not to exceed base + 2 X SQRT(BASE)

MG Style - Integrated Detector Assemblies for Wireline Applications

Operating Temperature	+25°C to +150°C
Survival Temperature	-20°C to +175°C
Gradient	3°C per minute maximum
Mechanical Survival Shock	100g @ 11ms – 3 shocks per axis; 2 axis total. (X & Z)
Vibration	Random 5gRMS 50-500Hz; 2 axis total

MWD and MWD-XR Styles - Integrated Detector Assemblies for MWD Applications

Operating Temperature	+25°C to +150°C
Survival Temperature	-20°C to +200°C
Gradient	3°C per minute maximum
Mechanical Survival Shock	1000g @ 1ms – 3 shocks per axis; 2 axis total. (X & Z)
Vibration	Random 20g_RMS 30-1000Hz 30-minute duration per axis; 2 axis total
Mechanical Performance	* (-XR Type Only)
Vibration	Random 20g_RMS 30-1000Hz 2.5-minute duration per axis; 2 axis total per the following power spectral density profile: 30-80Hz. @ 6db/octave 80-1000Hz .43g2/Hz
Acceptance Criteria	Vibration induced counts per second not to exceed base + 2 X SQRT(BASE)

The combination of titanium and sapphire packaging technology provides increased scintillation performance with the same rugged specifications Luxium Solutions has provided for years in its geophysical designs.

These new features are available for wireline, MWD and multi-phase flow applications and can be provided with integrated phototubes and electronics, if desired. Custom designs and specifications are available upon request.

Stronger titanium housing material yields thinner walls for higher crystal volume
- Larger crystals provide increased count rates
  - Increased Efficiency
  - Greater Sensitivity
High strength sapphire-to-metal seals for ruggedness
- Stronger sapphire window is much thinner for increased light transmittance
  - 15-30% increase in light output when compared to standard designs
Integration with photomultiplier tubes available.
Fully qualified for wireline and MWD operation
Guaranteed for performance and hermetic seal integrity.

Specifications

Pulse Height Resolution (FWHM) at 662keV	Typical NaI(Tl) crystal as measured on a standard laboratory 2” phototube 8.5% at 25°C and 12.5% at 150°C
Temperature (Survival)	-20°C to +175°C 3°C per minute gradient
Maximum Vibration (MWD applications)	Random 20grms, 30-1000Hz per the following power spectral density profile: 30-80Hz @6db/octave 80-1000Hz @0db/octave Acceptance Criteria: Counts per second not to exceed BASE+ 2σ during specified vibration. (σ =SQRT(Bkg.))
Maximum Shock (MWD applications)	1000g @ 1ms – half sine
Available crystal sizes	Diameter: ½” through 3” Length: sizes up to 18”

All standard geophysical LaBr crystals are packaged in titanium housings with our proprietary sapphire window assemblies to get the absolute best performance.

Features	Benefits
Sharper PHR	Less Pulse Pile-up
Faster Counting	More Accurate Isotope Identification
Higher Light Output	More Accurate Energy Level Determination
Greater Linearity	Better Fidelity at High Temperatures

These allow the greatest possible light transmission from the LaBr crystals. The design allows more crystal volume than in standard designs and offers an increase of up to 30% in light output versus the standard designs with stainless steel housings and conventional welded or soldered glass-to-metal seals or windows. The LaBr line of scintillation detectors has been fully qualified in MWD environments, including testing at temperatures from -55ºC to +175ºC survival. For operations, we recommend and rate detectors from -20ºC to +150ºC.

Compared to NaI(Tl), LaBr has a higher density, has nearly half the FWHM (full width at half maximum) photopeak resolution and twice the light output at high temperature. Also, the degradation of the light yield as a function of temperature for LaBr is less than 5% in the range of -65ºC to +140ºC.

Material	Density	Light Yield photons/kev	Decay Time tau (ns)	Timing FOM* ________________ tau/(photons/keV)	Peak Emission Wavelength (nm)
LaBr₃(Ce)	5.1	63	16	0.5	380
NaI(Tl)	3.7	38	250	2.6	415
BGO	7.1	9	300	5.8	480
CsI(Na)	4.5	41	630	3.9	420