Moving Coil Analog Geophone - China Petroleum Chemical Equipment Network

动圈式模拟地震检波器

Core Equipment Moving coil geophone main unit Multiple geophones connected in series (to improve signal clarity) Seismic recording station and main control unit

Key Technologies Electromagnetic induction technology (converts vibration into electrical signals) Inertial structure design (ensures accurate signal reception) Spike coupling (inserts firmly into the ground for reliable detection) Anti-interference, waterproof and dustproof technology

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产品介绍

A geophone is a high-sensitivity seismic sensor widely used in geological exploration and oil & gas surveying. It converts ground vibration signals generated by seismic waves into measurable electrical signals, providing core data for analyzing underground geological structures and resource distribution.

Featuring high sensitivity, low distortion, and strong anti-interference ability, it can effectively capture weak seismic signals even in complex field environments. With stable performance and high reliability, it supports long-term continuous operation under various temperature and terrain conditions.

Geophones are essential components of seismic data acquisition systems, widely applied in land seismic exploration, engineering geological detection, mineral resource exploration, and oil & gas field development.

Types and Characteristics of Equipment

Type

The 10Hz geophone is the most versatile, suitable for both shallow and deep formations, and has the largest usage volume in the Middle East and Africa (Tanzania).

Features

Simple structure, high reliability, drop-resistant, sand-wind resistant and stable under high and low temperatures.Passive operation without power supply, convenient for field construction.Low cost, good consistency, compatible with most seismic instruments worldwide.Analog signal output, directly connectable to the recording station without complicated configuration.Adaptable to harsh environments such as deserts, frozen ground, grasslands and swamps.

动圈式模拟地震检波器

Converts seismic vibrations into electrical signals for exploration.

动圈式模拟地震检波器

High-sensitivity sensor for geological and oil-gas surveying.

动圈式模拟地震检波器

Core component of seismic data acquisition systems.

Basic Principles and System Composition

Basic Working Principle

Moving coil geophone = velocity seismic sensor Inertia principleGround vibration → the geophone case moves along with the ground → the internal mass and coil remain relatively stationary due to inertia. Electromagnetic inductionThe coil moves relative to the magnetic field of the permanent magnet → cuts magnetic lines of force → generates induced electromotive force. Signal relationshipOutput voltage is proportional to ground vibration velocity (not displacement, nor acceleration — it is “velocity-type”). Final functionConverts mechanical energy of seismic waves from underground into analog electrical signals for recording by the seismic acquisition system.

Overall System Composition

Internal Structure of the Geophone Permanent magnet (generates magnetic field) Coil winding (induces voltage) Mass element (provides inertia) Spring elements (support and restoring force) Housing, base, and connection terminals Spike (ensures good coupling with the ground)

Basic Principles and System Composition

Line Layout and Positioning Deploy geophone points and shot points using GPS according to the design. Geophone Installation Bury or directly insert the spike into the ground to ensure tight coupling with the surface. Multiple geophones are connected in series to form a geophone array for improved signal quality. Cabling and System Testing Connect to the acquisition cable → link to the recording station → test continuity and noise level. Source Activation Vibroseis sweeping / explosive detonation to generate seismic waves propagating downward. Signal Reception and Recording Seismic waves reflect back to the surface → geophone vibrates → outputs analog electrical signals → amplified by the recording station → recorded by the host unit. Quality Control (QC) Review single-shot records to verify normal signal-to-noise ratio; repeat the operation if abnormal. Relocation and Recovery After completing one segment, retrieve geophones and cables, move to the next spread and repeat operations. Subsequent Data ProcessingRaw data → Preprocessing → Stacking → Migration imaging → Geological interpretation.