MOSFET-based low-field nuclear magnetic resonance Q converting circuit

Abstract

The invention provides an MOSFET-based low-field nuclear magnetic resonance Q converting circuit. The converting circuit comprises a resonance circuit, a converting circuit, a duplexer, a first controller and a second controller. The resonance circuit comprises a tuning capacitor and an inductor which is parallel connected with the tuning capacitor. The converting circuit comprises an MOSFET circuit and a power resistor which is serially connected with the MOSFET circuit. The converting circuit is parallel connected with the resonance circuit so that a parallel network is formed. The duplexer is serially connected with the parallel network. The first controller is connected with the duplexer. The second controller is connected with the MOSFET circuit. By controlling on or off of the MOSFET circuit, a single antenna is allowed to work in a high Q-value state when a radio frequency signal is sent and a nuclear magnetic resonance signal is received, and during discharging of energy of the resonance circuit, the signal antenna works in a low Q-value state, so restoration time constant and restoration time of the single antenna are reduced, and detection precision for the nuclear magnetic resonance signal by the low-field nuclear magnetic resonance device and sensitivity of the nuclear magnetic resonance device are improved.

Description

technical field [0001] Embodiments of the present invention relate to the field of oil exploration, and in particular to a MOSFET-based low-field nuclear magnetic resonance Q-switching circuit. Background technique [0002] NMR logging is a new logging technology suitable for open-hole wells. It is currently the only logging method that can directly measure the seepage volume characteristics of free fluid in any lithologic reservoir, and has obvious advantages. The NMR technique utilizes the paramagnetism of atomic nuclei and the external magnetic field that interacts with them. [0003] Existing low-field nuclear magnetic resonance instruments adopt a single-antenna structure, which transmits high-power radio frequency signals through a single antenna to excite the measured sample, and uses a single antenna to receive the nuclear magnetic resonance signal generated by the measured sample at a specific time, that is, the single antenna is both The function of receiving sign...

AI Technical Summary

Problems solved by technology

In order to improve the transmission efficiency of the signal and the signal-to-noise ratio level of the received signal, when designing a single antenna, it is required that the single antenna has a high quality factor Q value and a low antenna resonance frequency ω, but the recovery time constant of the single antenna and The single-antenna recovery time is proportional to the quality factor Q value and inversely proportional to the antenna resonance frequency ω, resulting in a long single-antenna recovery time constant and single-antenna recovery time

[0004] The longer single-antenna recovery time constant and the single-antenna recovery time will easily cause the nuclear magnetic resonance signal received by the single antenna to be covered by the energy discharge signal on the single antenna, resulting in inaccurate detection of the nuclear magnetic resonance signal by the low-field nuclear magnetic resonance instrument, and low Low sensitivity of field NMR instruments

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