 |
| Place of Origin: | China (Mainland) |
| Brand Name: | Kacise |
| Certification: | certificate of explosion-proof, CE |
| Model Number: | KQRS14 |
| Minimum Order Quantity: | 1pcs |
|---|---|
| Packaging Details: | each unit has individual box and all boxes are packed in standard packages or customers requests available |
| Delivery Time: | 5-8 working days |
| Payment Terms: | T/T, Western Union, MoneyGram |
| Supply Ability: | 1000 Pieces per Week |
| Output Noise (DC To 100 Hz): | ≤0.05°/sec./√Hz | Scale Factor Over Temperature (Dev. From 22°C Typical): | ≤0.06%/°C |
|---|---|---|---|
| Standard Range Full Scale: | ±50,100,200,500°/sec. | Vibration Survival: | 10 Grms 20 Hz To 2 KHz Random 5 Minutes/axis |
| Storage Temperature: | -55°C To +100°C | Weight: | ≤50g |
| Bias Variation Over Temperature (Dev. From 22°C): | <3.0°/sec. | Full Scale Output (Nominal): | ±5 Vdc |
| High Light: | Impact resistant Quartz Rate Sensor,50g Quartz Rate Sensor |
||
The KQRS14 is a highly useful sensor that can be used to measure angular rotation rates in a compact and durable package. Its design features a single-piece quartz sensing element that provides unparalleled accuracy and reliability.
This sensor is built with internal power regulation, ensuring that it performs consistently and reliably in all conditions. It can be powered with either +12Vdc or +15Vdc, making it suitable for use with a variety of battery types and conventional power supplies.
The KQRS14 comes in two versions, each with unique features to accommodate different use cases. For those who require a high-level output, the +12Vdc version provides a +1.0 to +4.0 Vdc output. The +15Vdc version offers a bipolar output of ±5 Vdc and is designed for use with double-sided power supplies.
● Compact,Lightweight Design
● Wide Temperature Range
● DC Input/High-Level DC Output
● lnternal Power Regulation
● High Reliability
● Shock Resistant
| Parameter | KQRS14-0XXXX-102** | KQRS14-0XXXX-103** |
| Power Requirements | ||
| Input Voltage | +9 to +18 Vdc | +9 to +18 Vdc |
| Input Current | <20 mA | <25 mA (each supply) |
| Performance | ||
| Standard Ranges | ±50,100,200,500°/sec. | |
| Full Scale Output (Nominal) | +1.0 Vdc (-FS) to +4.0 Vdc (+FS) | ±5 Vdc |
| Scale Factor Calibration (at 22°C Typical) | ±2% of value | |
| Scale Factor Over Temperature (Dev. from 22°C Typical) | ≤0.06%/°C | |
| Bias Calibration (at 22°C Typical) | +2.5 ±0.045 Vdc | 0.0±0.075 Vdc |
| Bias Variation over Temperature (Dev. from 22°C) | <3.0°/sec. | |
| Short Term Bias Stability (100 sec at const. temp) | <0.05°/sec, typical | |
| Long Term Bias Stability (1 year) | ≤1.0°/sec. | |
| G Sensitivity (Typical) | ≤0.06°/sec/g | |
| Start-Up Time (Typical) | <2.0 sec | |
| Bandwidth (-90° Phase Shift) | >50 Hz | |
| Non-Linearity (Typical) % Full Range | ≤0.05% of F.R. | |
| Threshold/Resolution | ≤0.004°/sec.* | |
| Output Noise (DC to 100 Hz) | ≤0.05°/sec./√Hz* | ≤0.02°/sec./√Hz* |
| Weight | ≤50 grams | |
| Environments | ||
| Operating Temperature | -40°C to +85°C | |
| Storage Temperature | -55°C to +100°C | |
| Vibration Operating*** | 5 grms 20 Hz to 2 kHz random | |
| Vibration Survival*** | 10 grms 20 Hz to 2 kHz random 5 minutes/axis | |
| Shock | 200g,any axis | |
Dimensions:
KQRS14-0XXXX-102 pin assignment
| Num | Explain | Num | Explain |
| 1 | Power and Signal Ground | 5 | Rate Output |
| 2 | +Vdc Input | 6 | No connection, Leave Open |
| 3 | No connection, Leave Open | 7 | Built-in-test |
| 4 | No connection, Leave Open |
KQRS14-0XXXX-103 pin assignment
| Num | Explain | Num | Explain |
| 1 | -Vdc Input | 5 | Rate Output |
| 2 | +Vdc Input | 6 | No connection, Leave Open |
| 3 | Power Ground | 7 | Built-in-test |
| 4 | Signal Ground |
When it comes to improving the stability of platforms, navigation, and instrumentation, many technological advancements have emerged over the years. These improvements can be classified into different categories as outlined below:
With the advancement of technology, various improved stability technologies have been developed to mitigate the challenges of platform stabilization for marine vessels, UAVs, and other mobile platforms. These technologies include improved gyroscopes and accelerometers that help in maintaining stability and reducing jerky movements even in uneven terrains.
Short term navigation refers to the ability of a platform to accurately and quickly navigate from one point to another. Improved stability technologies such as GPS receivers that are capable of tracking multiple satellites and using advanced algorithms to provide highly accurate positioning are being used to ensure short term navigation of platforms.
In addition to the use of GPS technologies for short term navigation, GPS augmentation technologies have been developed to improve the accuracy, availability, and integrity of GPS receivers. These include ground-based augmentation systems (GBAS), satellite-based augmentation systems (SBAS), and regional navigation satellite systems (RNSS).
Camera stabilization technologies are used to ensure that images and videos captured by cameras are clear and free of jerky movements. These technologies include gimbals, stabilizers, and vibration dampeners that can absorb vibrations and maintain stability, even in high-speed environments.
Instrumentation technologies are used to improve the accuracy and reliability of data collected by various sensors onboard a platform. Improved stability technologies such as advanced signal processing techniques and vibration measurement sensors can help minimize errors and improve the accuracy of instrumentation data in harsh environments.
Ride control stabilization is used to improve the stability of vehicles and ensure a smoother ride for passengers. Technologies such as active suspension systems, which use sensors and computer-controlled actuators to adjust the vehicle's suspension settings in real-time, are being used to deliver a comfortable ride even on uneven surfaces.
Wind turbines need to maintain stability and keep the rotors aligned with the wind direction to ensure efficient power generation. Improved stability technologies such as light detection and ranging (LIDAR) systems, which use lasers to detect wind shear and turbulence, are being used to provide critical data that can be used to adjust the turbine control systems and ensure optimal performance.
Our Electronic Gyroscope Sensor is designed to provide accurate and reliable measurements of angular velocity for a variety of applications. We offer comprehensive technical support and services to ensure our customers get the most out of their product.
Our team of experienced engineers is available to provide guidance and assistance with installation, calibration, and troubleshooting. We also offer a range of training options, including on-site training and webinars, to help our customers fully understand and utilize the capabilities of our product.
In addition, we provide ongoing maintenance and repair services to ensure our customers' sensors are functioning properly and delivering accurate data. Our service technicians can perform repairs and calibrations both in-house and on-site, as needed.
At our company, we are committed to providing exceptional support and service to our customers. If you have any questions or concerns about your Electronic Gyroscope Sensor, please do not hesitate to contact us.
Product Packaging:
The electronic gyroscope sensor will be packaged in a sturdy cardboard box with foam padding to protect it from damage during shipping.
Shipping:
The product will be shipped via UPS ground within the continental United States. International shipping options are available at an additional cost. Shipping and handling fees will be added at checkout.
Contact Person: Ms. Evelyn Wang
Tel: +86 17719566736
Fax: 86--17719566736
Address: i City, No11, TangYan South road, Yanta District, Xi'an,Shaanxi,China.
Factory Address:i City, No11, TangYan South road, Yanta District, Xi'an,Shaanxi,China.
