Device and method for early monitoring of gas intrusion based on pressure wave propagation

What is claimed is: 1. A device for early monitoring of gas intrusion based on pressure wave propagation, comprising: a liquid storage tank; a gas storage tank; a simulated wellbore; a computer; a centrifugal pump; a pressure-stabilizing water tank; a mass flowmeter; a screw air compressor; a micro-orifice flowmeter; a gas-liquid mixer; a pressure-disturbing device; a gas-liquid separator; and an oscilloscope; wherein a lower end of the liquid storage tank is connected to an inlet end of the pressure-stabilizing water tank through a first liquid-injection pipeline and the centrifugal pump; an outlet end of the pressure-stabilizing water tank is connected to a liquid inlet of the gas-liquid mixer through a second liquid-injection pipeline and the mass flowmeter; a first end of the gas storage tank is connected to the screw air compressor and a second end of the gas storage tank is connected to a gas inlet of the gas-liquid mixer through a gas-injection pipeline and the micro-orifice flowmeter; the gas-liquid mixer is provided at an upper end of the simulated wellbore; the pressure-disturbing device is connected to a lower side of the gas-liquid mixer; a plurality of pressure sensors are provided at a middle of the simulated wellbore, and connected to the computer through a wire and the oscilloscope; the gas-liquid separator is connected to a lower end of the simulated wellbore, and a liquid outlet of the gas-liquid separator is in pipeline connection with the liquid storage tank for recycling; and the pressure-disturbing device comprises: a pressure wave generator; a pressure wave propagation unit; and a disturbance tube; wherein the pressure wave generator is provided with one or more pistons; a lower outlet of each of the one or more pistons is connected to a collection chamber; an outlet end of the collection chamber communicates with the pressure wave propagation unit; an outer wall of the disturbance tube is provided with a plurality of openings; the plurality of openings are each provided with a rubber membrane; an outer end of the pressure wave propagation unit is connected to the disturbance tube; and the rubber membrane is configured to collect and concentrate pressure waves for propagation. 2. The device of claim 1 , wherein a first side of the pressure wave propagation unit is a cylindrical structure, and a second side of the pressure wave propagation unit is a spherical-like structure; and an outer end of the spherical-like structure is connected to the disturbance tube. 3. The device of claim 2 , wherein a first regulating valve, a first ball valve, a first pressure measurement point and a first temperature measurement point are sequentially provided on the second liquid-injection pipeline; the number of the mass flowmeter is one or more, and one or more mass flowmeters are provided on a first side of the first temperature measurement point; a first end of each of the one or more mass flowmeters is connected to a first micro-regulating valve, and a second end of each of the one or more mass flowmeters is connected to a second micro-regulating valve; and the first regulating valve, the first ball valve, the first micro-regulating valve and the second micro-regulating valve are configured to be adjusted in terms of opening degree to control liquid flow and pressure input into the simulated wellbore. 4. The device of claim 3 , wherein a second regulating valve, a second ball valve, a second pressure measurement point and a second temperature measurement point are sequentially provided on the gas-injection pipeline; the number of the micro-orifice flowmeter is one or more, and one or more micro-orifice flowmeters are provided on a side of the second temperature measurement point away from the gas storage tank; a third pressure measurement point is provided on a first side of each of the one or more micro-orifice flowmeters; and a third micro-regulating valve is provided on a second side of each of the one or more micro-orifice flowmeters; and the second regulating valve, the second ball valve and the third micro-regulating valve are configured to be adjusted in terms of opening degree to adjust a void fraction and a pressure disturbance frequency, so as to simulate effects of different parameters on a propagation pattern of the pressure waves inside a wellbore. 5. The device of claim 4 , wherein the simulated wellbore comprises an outer pipe and an inner pipe; and the outer pipe and the inner pipe are both made of a transparent acrylic glass. 6. The device of claim 5 , wherein the plurality of pressure sensors are arranged at intervals of 0.5 m on an outer side of the simulated wellbore; and the plurality of pressure sensors are connected to the oscilloscope through an optical fiber to transmit a pressure signal to the oscilloscope. 7. The device of claim 6 , wherein an angular frequency of the pressure waves generated by the pressure-disturbing device ranges from 0 to 314 Hz. 8. The device of claim 7 , wherein an expansion tube is provided at the lower end of the simulated wellbore; and the expansion tube is configured to eliminate reflection of the pressure waves. 9. A method for early monitoring of gas intrusion based on the device of claim 8 , comprising: (S1) opening a shut-off valve on the first liquid-injection pipeline, and turning on the centrifugal pump to pressurize water, such that the first liquid-injection pipeline is filled with water; allowing the water to flow sequentially through the first regulating valve, the first ball valve, the first pressure measurement point, the first temperature measurement point, the first micro-regulating valve, the mass flowmeter, the second micro-regulating valve, and a check valve into the liquid inlet of the gas-liquid mixer; and allowing the water to flow through an outlet of the gas-liquid mixer to enter the simulated wellbore to flow downwards along the inner pipe; wherein the plurality of pressure sensors are arranged at intervals of 0.5 m on the outer side of the simulated wellbore, and connected to the oscilloscope through the optical fiber to transmit the pressure signal to the oscilloscope and the computer; (S2) after a flow pattern in the second liquid-injection pipeline and a pressure reading on the computer tends to be stable, turning on the screw air compressor, and opening the gas storage tank connected to the screw air compressor, and the second regulating valve, such that gas flows sequentially through the second regulating valve, the second ball valve, the second pressure measurement point and the second temperature measurement point on the gas-injection pipeline; adjusting, by the one or more micro-orifice flowmeters, a pressure of the gas to be larger than a pressure within the second liquid-injection pipeline; allowing the gas to enter the gas-liquid mixer through the gas inlet and flow into the inner pipe of the simulated wellbore to simulate gas intrusion; and adjusting an opening degree of the second ball valve to change a void fraction of a fluid within the simulated wellbore, so as to simulate the gas intrusion under various formation conditions; (S3) reading pressure changes from the computer and obtaining readings of the mass flowmeter and the one or more micro-orifice flowmeters; reading pressures from the plurality of pressure sensors, the first pressure measurement point and the second pressure measurement point based on the oscilloscope and the computer to analyze a two-phase flow pattern in the simulated wellbore under different void fractions and a pressure propagation pattern when a gas intrusion occurs; allowing the water to flow through the expansion tube to eliminate a re