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CCHN is a trusted U.S. registered company in industrial automation & controls, CCHN's goal is helping saving your money by bypassing all kinds of local dealers/agents in buying industrial automation products from Chinese manufacturers directly. You will be enjoyed to get free tech support on how to choose, how to wire, how to commissioning with CCHN professional engineers. Shopping for your automation systems on CCHN one-stop online store now. The price on the website only for sample reference. for Mass order,please send the enquiry to us.

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Foam cutting is a device for processing materials in the chemical industry such as foam and sponges. It mainly uses the high

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CCHN Industry
 
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CCHN Industry

CCHN is a trusted U.S. registered company in industrial automation & controls, CCHN's goal is helping saving your money by bypassing all kinds of local dealers/agents in buying industrial automation products from Chinese manufacturers directly. You will be enjoyed to get free tech support on how to choose, how to wire, how to commissioning with CCHN professional engineers. Shopping for your automation systems on CCHN one-stop online store now. The price on the website only for sample reference. for Mass order,please send the enquiry to us.

Blog

Foam cutting is a device for processing materials in the chemical industry such as foam and sponges. It mainly uses the high

...
Three Axis Accelerometer Sensor, Current Output
 
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Three Axis Accelerometer Sensor, Current Output


$1289.60
Current output accelerometer sensor at affordable price, with 4-20mA output current, three measuring axis X, Y, Z,
SKU: CHN-AS-AKF398
Free Shipping Worldwide
Delivery date: 6-12 days

Lower cost 3-axis accelerometer sensor with 21μg/ Hz or 86.6μg/ Hz noise density, MIL-HDBK-217, Grade 2 reliability. It offers low power consumption which has been calibrated, and a solid structure and stable output.

Parameters

ModelAKF398
Measuring Range (g)±2±4±8±10±20±40
Sensitivity (± 10%) (mA/g)4210.80.40.2
Lateral vibration sensitivity ratio (%)125
Nonlinearity (% FS) (highest)<0.5<0.8<1
Deviation Temperature Coefficient (%/ ℃) (Typical value)0.010.05
Cross-axis sensitivity (%)12
Resonance frequency (kHz)2.45.5
Noise Density (μg/ Hz)2186.6
0g Output 12mA<0.005<0.003
Deviation Calibration (mg)<1
Measuring AxisX, Y, Z
Up/ off Power Repeatablity(mg) (highest)<2
Resolution/ Threshold (@ 1Hz) (mg) (highest)<1
Frequency Response (Hz)500
Bandwidth (3Db) (Hz)1000
Output Current4-20mA
ReliabilityMIL-HDBK-217, Grade 2
Shock Resistance100g@11ms, Triaxial And Identical (Half Sine Wave)
Recovery Time<1ms (1000g, 1/2 Sin 1ms, Shock Acting On The i Axis)

Vibration

20g Rms, 20-2000Hz (Random Noise, o, p, i Per Axis For Action 30 Minutes)
Input (Vdd_Vss)9-36 VDC
Running Current Consumption<60mA @ 12 VDC
ConnectorIndustrial standard M12 connector
Weight73.5g
Dimension34.3*34.3*38.5mm
CertificateCE
Warranty12 months

Dimension (unit=mm)

 Dimension of accelerometer sensor

Dimension of Mounting Fittings (unit=mm)

Mounting dimension of accelerometer sensor  

        Magnetic adsorption base plate                                                                                  L-type adapter plate 

Electrical Connection

Electrical connection of acceleromrter sensor

Tips: Selection Guide of Triaxial Accelerometer Sensor.

Sensitivity

Generally speaking, the more sensitive the better. The more sensitive the sensor is more sensitive to changes in acceleration within a certain range, and the greater the change in output voltage, which makes it easier to measure and obtain more accurate measurement values. The minimum acceleration measurement value is also called the minimum resolution. Taking into account the noise problem of the post-amplification circuit, it should be as far away as possible from the minimum available value to ensure the best signal-to-noise ratio. The maximum measurement limit should consider the non-linear influence of the accelerometer itself and the maximum output voltage of the subsequent instrument. The estimation method is: the maximum measured acceleration × the charge/voltage sensitivity of the sensor.

Whether the above value exceeds the maximum input charge/voltage value of the supporting instrument, it is recommended that if the measured acceleration range is known, it can be selected in the "reference range range" in the sensor index (taking into account the frequency response and weight). At the same time, in the frequency response and weight If allowed, the sensitivity can be considered higher to increase the input signal of subsequent instruments and improve the signal-to-noise ratio.