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Smart and simple, this multi-gas detector kit monitors (O2), combustibles (LEL), carbon monoxide (CO), as well as hydrogen sulfide (H2S). Field-tough, this kit comes with an IR connectivity kit, hydrophobic and particulate pump filters, a sampling probe, calibration gas, and a 0.5 LPM regulator.
Smart and simple, this multi-gas detector kit monitors (O2), combustibles (LEL), carbon monoxide (CO), as well as hydrogen sulfide (H2S). Field-tough, this kit comes with an IR connectivity kit, hydrophobic and particulate pump filters, a sampling probe, calibration gas, and a 0.5 LPM regulator.
An $85 hazmat/handling fee will automatically apply to all orders with this product.
The GasAlertMax XT II Confined Space Entry Kit is easy to use, easy to carry. It offers all the essential tools required for confined space entry, including a 4-gas detector, calibration and sampling equipment, IR connectivity kit and more.
Gas Alert Max XT II
The GasAlert Max XT II portable and multi-gas detector simultaneously monitors and displays up to four gases including hydrogen sulfide (H2S) carbon monoxide (CO), new 4-series oxygen (O2) sensor - SR-X10-C1 and combustibles (%LEL). The compact and field tough GasAlertMax XT II features a non-intrusive integrated sampling pump designed for performance, reliability and ease-of-use. SmartSample pump technology improves remote sampling result accuracy and ensures a consistent, uniform flow.
One-button operation guarantees ease of use even while wearing gloves. Tamper-proof, user adjustable options enable the instrument to be customized to suit your specific application. Confined space entry and remote sampling have never been so easy with new intelligent pump technology. Minimize pump blockages and improve remote sampling result accuracy. The GasAlertMax XT II is fully compatible with the MicroDock II automated test and calibration system.
Improved Oxygen O2 Sensor
The Max XT II uses an improved oxygen sensor SR-X10-C1 that lasts longer and ultimately helps reduce down time.
The older Max XT uses the SR-X-MC oxygen sensor and will not work with the Max XT II gas detector.
Features
| Detection Range | H2S: 0 to 200 ppm (1 ppm increments) CO: 0 to 1000 ppm (1 ppm increments) O2: 0 to 30.0% vol. (0.1% volume increments) LEL (combustible): 0 to 100% LEL (1% LEL increments) or 0 to 5.0% v/v methane |
| Sensor Rype | H2S, CO, O2: Single plug-in electrochemical cell LEL (combustibles): Plug-in catalytic bead |
| O2 Measuring Principle | Capillary controlled concentration sensor |
| Alarm Conditions | TWA alarm, STEL alarm, low alarm, high alarm, multi-gas alarm, over limit (OL) alarm, low battery alarm, confidence beep, automatic deactivation alarm, pump alarm |
| Audible Alarm | 95 dB+ at 30 cm variable pulsed beeper with full battery charge |
| Visual Alarm | Red light-emitting diodes (LEDs) |
| Alarm Setpoints | May vary by region and are user-defined |
| Display | Alphanumeric liquid crystal display (LCD) |
| Backlight | Activates upon startup and when the pushbutton is pressed; deactivates after 10 seconds. Activates during an alarm condition and remains lit until alarm ceases |
| Self-Test | Initiated during activation, self-test runs continuously while detector is operational |
| Calibration | Automatic zero and automatic span |
| User Field Options | Startup message, lockout on self-test error, safe mode, confidence beep, latching alarm, force calibration, cal IR lock, force bump, location logging, force block test, set datalog interval, set confidence interval, language selection. |
| Sensor Options | Sensor enable/disable, set span concentration values, set calibration interval, set bump interval, set alarm setpoints, set STEL interval, set TWA period, auto zero at startup enable/disable, 5% overspan, low alarm acknowledge, oxygen measurement, and combustible gas measurement |
| Battery Operating Time | One rechargeable lithium polymer battery at 20°C provides 13 hours operating runtime |
| Operating Temperature | -4 to 122°F (-20 to 50°C) |
| Storage Temperature | -40 to 140°F (-40 to 60°C) |
| Operating Humidity | 10 to 100% relative humidity (non-condensing) |
| Dust and Moisture Ingress | IP66/67 |
| Dimensions | 5.1 x 2.8 x 2.0" (13.1 x 7.0 x 5.2 cm) |
| Weight | 10.6 oz (300 g) |
There are many gas detection products on the market that might appear to be the same, but a closer inspection of specification, functionality and features reveals major differences in what products can do and the potential value they can offer. Similarly, individual applications are also unique in their respective designs, needs and processes undertaken.
Before beginning to consider gas detection equipment, a risk assessment needs to be conducted. Any company employing staff has the obligation to conduct risk assessments to identify potential hazards and these can include potential gas, vapor or Oxygen deficiency risks. If gas hazards are identified, gas detection is applicable as a risk reduction method.
Depending on the processes being undertaken and the gases being detected, remote or off-site alarm notification plus event data logging/reporting may also be required for Health and Safety management records. Another factor impacting on the need for enhanced reporting functions might be regulatory compliance or a condition of insurance.
Having identified the primary objective, the suitable equipment is selected by asking a number of key questions. These fall into three broad categories:
The gases to be detected should be identified by the risk assessment, however experienced gas detection equipment manufacturers and their approved distributors are often able to help in this process, based on their experience of similar applications. However, it is important to remember that it is the end-user’s responsibility to identify all potential hazards. It is also essential to identify the potential source of a gas release as this helps determine the number and location of detectors required for a fixed gas detection system.
The performance, accuracy and reliability of any gas detection equipment will be affected by the environmental conditions it is subjected to. Temperature, humidity and pressure levels at the location all have a direct bearing on the type of equipment that should be selected. Additional factors such as potential variations resulting from a production process itself, diurnal/nocturnal fluctuations and seasonal changes may also affect the type of device which is suitable.
The next area of consideration relates to additional product functionality. Aspects like wiring configuration are important, especially when retro-fitting into an existing application. If the apparatus is being integrated into a separate safety system, certain communication protocols may also be required such as HART®, Lonworks or Modbus®. Consideration will also need to be given regarding the requirement for local displays on transmitter units and local configuration of the unit and gas displays may also be a useful addition.
Routine maintenance is another important consideration. Some gases and vapors can be detected with a number of different sensing technologies, e.g. Hydrocarbon gases with catalytic beads or Non-dispersive Infrared NDIR. Catalytic beads do not provide fail-to-safety operation and therefore can require a high frequency of routine maintenance, however NDIR based solutions tend to have a higher initial purchase price, but may require less routine maintenance. In-house resource to undertake such routine maintenance needs to be identified and in the absence of such a resource, budgeting for third party maintenance is an important factor in selecting the right equipment.
If you have questions about any of our gas detection products or services, please don’t hesitate to contact us. Whether you need a hand finding a new product or need help with your current system, just ask our team of Factory Trained Experts.
Click on a category to view a selection of compatible accessories with the Honeywell BW Max XT II Multi-Gas Detector Kit, %LEL/O2/H2S/CO.
| Detection Range | H2S: 0 to 200 ppm (1 ppm increments) CO: 0 to 1000 ppm (1 ppm increments) O2: 0 to 30.0% vol. (0.1% volume increments) LEL (combustible): 0 to 100% LEL (1% LEL increments) or 0 to 5.0% v/v methane |
| Sensor Rype | H2S, CO, O2: Single plug-in electrochemical cell LEL (combustibles): Plug-in catalytic bead |
| O2 Measuring Principle | Capillary controlled concentration sensor |
| Alarm Conditions | TWA alarm, STEL alarm, low alarm, high alarm, multi-gas alarm, over limit (OL) alarm, low battery alarm, confidence beep, automatic deactivation alarm, pump alarm |
| Audible Alarm | 95 dB+ at 30 cm variable pulsed beeper with full battery charge |
| Visual Alarm | Red light-emitting diodes (LEDs) |
| Alarm Setpoints | May vary by region and are user-defined |
| Display | Alphanumeric liquid crystal display (LCD) |
| Backlight | Activates upon startup and when the pushbutton is pressed; deactivates after 10 seconds. Activates during an alarm condition and remains lit until alarm ceases |
| Self-Test | Initiated during activation, self-test runs continuously while detector is operational |
| Calibration | Automatic zero and automatic span |
| User Field Options | Startup message, lockout on self-test error, safe mode, confidence beep, latching alarm, force calibration, cal IR lock, force bump, location logging, force block test, set datalog interval, set confidence interval, language selection. |
| Sensor Options | Sensor enable/disable, set span concentration values, set calibration interval, set bump interval, set alarm setpoints, set STEL interval, set TWA period, auto zero at startup enable/disable, 5% overspan, low alarm acknowledge, oxygen measurement, and combustible gas measurement |
| Battery Operating Time | One rechargeable lithium polymer battery at 20°C provides 13 hours operating runtime |
| Operating Temperature | -4 to 122°F (-20 to 50°C) |
| Storage Temperature | -40 to 140°F (-40 to 60°C) |
| Operating Humidity | 10 to 100% relative humidity (non-condensing) |
| Dust and Moisture Ingress | IP66/67 |
| Dimensions | 5.1 x 2.8 x 2.0" (13.1 x 7.0 x 5.2 cm) |
| Weight | 10.6 oz (300 g) |
There are many gas detection products on the market that might appear to be the same, but a closer inspection of specification, functionality and features reveals major differences in what products can do and the potential value they can offer. Similarly, individual applications are also unique in their respective designs, needs and processes undertaken.
Before beginning to consider gas detection equipment, a risk assessment needs to be conducted. Any company employing staff has the obligation to conduct risk assessments to identify potential hazards and these can include potential gas, vapor or Oxygen deficiency risks. If gas hazards are identified, gas detection is applicable as a risk reduction method.
Depending on the processes being undertaken and the gases being detected, remote or off-site alarm notification plus event data logging/reporting may also be required for Health and Safety management records. Another factor impacting on the need for enhanced reporting functions might be regulatory compliance or a condition of insurance.
Having identified the primary objective, the suitable equipment is selected by asking a number of key questions. These fall into three broad categories:
The gases to be detected should be identified by the risk assessment, however experienced gas detection equipment manufacturers and their approved distributors are often able to help in this process, based on their experience of similar applications. However, it is important to remember that it is the end-user’s responsibility to identify all potential hazards. It is also essential to identify the potential source of a gas release as this helps determine the number and location of detectors required for a fixed gas detection system.
The performance, accuracy and reliability of any gas detection equipment will be affected by the environmental conditions it is subjected to. Temperature, humidity and pressure levels at the location all have a direct bearing on the type of equipment that should be selected. Additional factors such as potential variations resulting from a production process itself, diurnal/nocturnal fluctuations and seasonal changes may also affect the type of device which is suitable.
The next area of consideration relates to additional product functionality. Aspects like wiring configuration are important, especially when retro-fitting into an existing application. If the apparatus is being integrated into a separate safety system, certain communication protocols may also be required such as HART®, Lonworks or Modbus®. Consideration will also need to be given regarding the requirement for local displays on transmitter units and local configuration of the unit and gas displays may also be a useful addition.
Routine maintenance is another important consideration. Some gases and vapors can be detected with a number of different sensing technologies, e.g. Hydrocarbon gases with catalytic beads or Non-dispersive Infrared NDIR. Catalytic beads do not provide fail-to-safety operation and therefore can require a high frequency of routine maintenance, however NDIR based solutions tend to have a higher initial purchase price, but may require less routine maintenance. In-house resource to undertake such routine maintenance needs to be identified and in the absence of such a resource, budgeting for third party maintenance is an important factor in selecting the right equipment.
If you have questions about any of our gas detection products or services, please don’t hesitate to contact us. Whether you need a hand finding a new product or need help with your current system, just ask our team of Factory Trained Experts.
Click on a category to view a selection of compatible accessories with the Honeywell BW Max XT II Multi-Gas Detector Kit, %LEL/O2/H2S/CO.
