Vernier Go Direct Current ProbeOrder code: GDX-CUR
|Purchase QTY: (Each)||1+|| || || || |
|Scientrific's price|| $152.00|| || || ||
Note: Prices do NOT include GST
VERNIER GO DIRECT CURRENT PROBE
Simplify your experimental setup by using the Vernier Go Direct Current Probe to measure electric currents in circuits. It connects wirelessly via Bluetooth® or wired via USB to your device. The wireless connection eliminates additional cables that can clutter the lab bench.
• Capture small currents like those produced by a magnet falling through a coil.
• Use in combination with the Vernier Go Direct Voltage Probe to investigate Ohm’s law or series and parallel circuits.
• Explore RC and RLC circuits.
Rechargeable Battery — Ready When You Are
The Vernier Go Direct™ robust rechargeable battery offers long battery life and provides always-ready operation. Monitor battery life directly from Vernier's free Graphical Analysis™ 4 app Should the battery run low simply connect the sensor to the charging cable and keep on collecting — no interruptions or inconvenience to you or your students.
Wired or Wireless — The Flexibility to Choose
Vernier's Go Direct™ sensors connect directly to your mobile device, Chromebook or computer using Vernier's free Graphical Analysis™ 4 app. No additional equipment or software purchases are necessary. Go Direct sensors can be used wired via USB or wirelessly via Bluetooth allowing you to choose the solution best for your classroom or laboratory.
View >>>> COMPATIBILITY CHECK and Set Up Guide for your Vernier sensor, interface and software
• Range: +/- 1A and +/- 0.1A
• Maximum non-damaging current: 1.5A and 0.5A
• Typical resolution: 0.031mA and 0.003mA
• Vernier Go Direct Current Probe
• Micro USB Cable
Educational use only:
Vernier and Kidwind products are designed for educational use. They are not appropriate for industrial, medical or commercial applications. Details
WarrantyThis product is used in teaching these Australian Curriculum codes:
ACSPH044 - Thermal nuclear and electrical p - Electrical circuits - Circuit analysis and design involve calculation of the potential difference across, the current in, and the power supplied to, components in series, parallel and series/parallel circuits
ACSPH039 - Thermal nuclear and electrical p - Electrical circuits - Energy is conserved in the energy transfers and transformations that occur in an electrical circuit
ACSPH041 - Thermal nuclear and electrical p - Electrical circuits - Energy is required to separate positive and negative charge carriers; charge separation produces an electrical potential difference that can be used to drive current in circuits
ACSPH042 - Thermal nuclear and electrical p - Electrical circuits - Power is the rate at which energy is transformed by a circuit component; power enables quantitative analysis of energy transformations in the circuit
ACSPH043 - Thermal nuclear and electrical p - Electrical circuits - Resistance for ohmic and nonohmic components is defined as the ratio of potential difference across the component to the current in the component
ACSPH040 - Thermal nuclear and electrical p - Electrical circuits - The energy available to charges moving in an electrical circuit is measured using electric potential difference, which is defined as the change in potential energy per unit charge between two defined points in the circuit
ACSSU155 - Physical Sciences - Energy Forms - Energy appears in different forms, including movement (kinetic energy), heat and potential energy, and energy transformations and transfers cause change within systems
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Purchase GDX-CRG to recharge multiple Go Direct sensors