基于高压脉动水力压裂的脉动波传播机理研究

基于高压脉动水力压裂的脉动波传播机理研
究
1.高压脉动水力压裂是一种有效的裂缝增强技术。

High-pressure pulsating hydraulic fracturing is an effective method of enhancing fractures.
2.在脉动水力压裂中，裂缝内的压力波传播是一个复杂的过程。

In pulsating hydraulic fracturing, the propagation of pressure waves inside the fractures is a complex process.
3.研究脉动波传播机理可以帮助优化水力压裂的效果。

Studying the mechanism of pulsating wave propagation can help optimize the effectiveness of hydraulic fracturing.
4.脉动波在裂缝中的传播受到地下岩石条件的影响。

The propagation of pulsating waves in fractures is influenced by underground rock conditions.
5.理解脉动波的传播机理对于改进水力压裂的设计和实施至关重要。

Understanding the mechanism of pulsating wave propagation is crucial for improving the design and implementation of hydraulic fracturing.
6.高压脉动水力压裂可以提高裂缝的导流性。

High-pressure pulsating hydraulic fracturing can improve the conductivity of fractures.
7.脉动水力压裂过程中的脉动波传播会产生压力的变化。

The propagation of pulsating waves during hydraulic fracturing can lead to fluctuations in pressure.
8.通过研究脉动波传播，可以更好地预测水力压裂中的压力变化。

By studying pulsating wave propagation, pressure changes during hydraulic fracturing can be better predicted.
9.控制脉动波传播可以减少水力压裂中的能量损失。

Controlling pulsating wave propagation can reduce energy loss during hydraulic fracturing.
10.了解脉动波在裂缝中的行为可以提高水力压裂的成功率。

Understanding the behavior of pulsating waves in
fractures can improve the success rate of hydraulic
fracturing.
11.研究表明，脉动波的传播速度受到裂缝尺寸和岩石性质的影响。

Studies have shown that the propagation speed of
pulsating waves is influenced by fracture size and rock properties.
12.通过改变脉动波的频率和振幅，可以调控水力压裂的裂缝扩展。

By altering the frequency and amplitude of pulsating waves, the expansion of fractures during hydraulic fracturing can be controlled.
13.对脉动波传播机理的研究可以为水力压裂的实时监测提供支持。

Research on the mechanism of pulsating wave propagation can support real-time monitoring of hydraulic fracturing.
14.脉动波在水力压裂中的传播速度可能受到岩石孔隙结构的影响。

The propagation speed of pulsating waves in hydraulic fracturing may be influenced by the pore structure of rocks.
15.了解脉动波传播的路径和途径有助于改善水力压裂的设计参数。

Understanding the path and pathways of pulsating wave propagation can help improve the design parameters of
hydraulic fracturing.
16.研究脉动波的传播特性可以为水力压裂的模拟和预测提供基础。

Researching the propagation characteristics of pulsating waves can provide a basis for the simulation and prediction
of hydraulic fracturing.
17.岩石的弹性模量和泊松比可能影响脉动波在裂缝中的传播特性。

The elastic modulus and Poisson's ratio of rocks may affect the propagation characteristics of pulsating waves in fractures.
18.通过数值模拟可以分析脉动波在水力压裂中的传播过程。

Numerical simulation can be used to analyze the propagation process of pulsating waves in hydraulic fracturing.
19.实验研究可以验证脉动波传播机理的模型和假设。

Experimental studies can validate the models and assumptions of the mechanism of pulsating wave propagation.
20.使用声波技术可以监测脉动波在裂缝中的传播情况。

Acoustic wave technology can be used to monitor the propagation of pulsating waves in fractures.
21.脉动波在水力压裂中的传播对于裂缝的尺寸和形态具有重要影响。

The propagation of pulsating waves in hydraulic
fracturing has a significant impact on the size and morphology of fractures.
22.脉动波在水力压裂中的传播速度可能随时间而变化。

The propagation speed of pulsating waves in hydraulic fracturing may vary over time.
23.了解脉动波传播的机理可以优化水力压裂中的流体注入方案。

Understanding the mechanism of pulsating wave propagation can optimize fluid injection schemes in hydraulic fracturing.
24.脉动波在水力压裂中的传播路径可能受到地下裂隙网络的影响。

The propagation path of pulsating waves in hydraulic fracturing may be influenced by underground fracture networks.
25.采用仿真模型可以揭示脉动波在水力压裂中的传播规律。

Using simulation models can reveal the propagation
patterns of pulsating waves in hydraulic fracturing.
26.脉动波在裂缝中的传播受到岩石破碎特性的影响。

The propagation of pulsating waves in fractures is influenced by rock fragmentation characteristics.
27.地震监测技术可以用于评估脉动波在水力压裂中的传播情况。

Seismic monitoring technology can be used to assess the propagation of pulsating waves in hydraulic fracturing.
28.脉动波在水力压裂中的传播会产生岩石位移和变形。

The propagation of pulsating waves in hydraulic
fracturing can lead to rock displacement and deformation.
29.脉动波的传播速度可以受到地下流体压力的影响。

The propagation speed of pulsating waves can be influenced by underground fluid pressure.
30.了解脉动波的传播路径有助于优化水力压裂中的地质调查。

Understanding the propagation path of pulsating waves can help optimize geological surveys in hydraulic fracturing.
31.脉动波的传播路径可能受到地下断裂带和地层压力的影响。

The propagation path of pulsating waves may be influenced by underground fault zones and formation pressure.
32.脉动波在裂缝中的传播会引起应力变化和岩石破裂。

The propagation of pulsating waves in fractures can cause stress changes and rock fracturing.
33.用于监测脉动波传播的地面设备可能需要考虑地下介质的复杂性。

The ground equipment used to monitor the propagation of pulsating waves may need to consider the complexity of underground media.
34.通过分析脉动波的传播路径，可以更好地控制水力压裂中的裂缝扩展方向。

By analyzing the propagation path of pulsating waves, the direction of fracture expansion in hydraulic fracturing can be better controlled.
35.脉动波在水力压裂中的传播速度可能受到地下地质构造的影响。

The propagation speed of pulsating waves in hydraulic fracturing may be influenced by underground geological structures.
36.脉动波的传播路径可以通过地震勘探技术来确定。

The propagation path of pulsating waves can be determined using seismic exploration technology.
37.了解脉动波的传播机理可以为水力压裂中的地震活动风险评估
提供依据。

Understanding the mechanism of pulsating wave propagation can provide a basis for assessing the seismic activity risk
in hydraulic fracturing.
38.脉动波在水力压裂中的传播速度可能受到地下水体压力的影响。

The propagation speed of pulsating waves in hydraulic fracturing may be influenced by underground water pressure.
39.了解脉动波传播路径的变化有助于调整水力压裂中的操作参数。

Understanding the changes in the propagation path of pulsating waves can help adjust operational parameters in hydraulic fracturing.
40.通过数值模拟可以模拟脉动波在水力压裂中的实际传播情况。

Numerical simulation can simulate the actual propagation of pulsating waves in hydraulic fracturing.
41.脉动波的传播速度受地下地层压力的影响。

The propagation speed of pulsating waves is affected by underground formation pressure.
42.了解脉动波的传播机理是优化水力压裂操作的关键。

Understanding the mechanism of pulsating wave propagation is crucial for optimizing hydraulic fracturing operations.
43.地震监测技术可以用于实时监测脉动波在水力压裂中的传播情况。

Seismic monitoring technology can be used for real-time monitoring of the propagation of pulsating waves in hydraulic fracturing.
44.了解脉动波的传播路径有助于调整水力压裂的进度和方向。

Understanding the propagation path of pulsating waves helps adjust the progress and direction of hydraulic fracturing.
45.脉动波在水力压裂中的传播速度可能受到断裂带的影响。

The propagation speed of pulsating waves in hydraulic fracturing may be influenced by fault zones.
46.脉动波在裂缝中的传播会引起岩石的微观破裂。

The propagation of pulsating waves in fractures can cause microscopic fracturing of rocks.
47.了解脉动波传播机理对于减少水力压裂中的不完全裂缝至关重要。

Understanding the mechanism of pulsating wave propagation is crucial for reducing incomplete fractures in hydraulic fracturing.
48.通过地震监测技术可以实时检测脉动波在水力压裂中的传播路径。

Seismic monitoring technology can be used to real-time detect the propagation path of pulsating waves in hydraulic fracturing.
49.了解脉动波的传播路径可帮助优化水力压裂中的地质参数。

Understanding the propagation path of pulsating waves can help optimize geological parameters in hydraulic fracturing.
50.脉动波在水力压裂中的传播速度受地层孔隙结构的影响。

The propagation speed of pulsating waves in hydraulic fracturing is influenced by formation pore structure.
51.通过数值模拟可以预测脉动波在水力压裂中的传播速度和路径。

Numerical simulation can predict the propagation speed
and path of pulsating waves in hydraulic fracturing.
52.了解脉动波的传播机理有助于避免水力压裂中的压裂失效。

Understanding the mechanism of pulsating wave propagation helps avoid fracturing failure in hydraulic fracturing.
53.地面监测设备可以用于实时监测脉动波在水力压裂中的传播情况。

Ground monitoring equipment can be used for real-time monitoring of the propagation of pulsating waves in hydraulic fracturing.
54.了解脉动波传播的机理可以提高水力压裂的效率和安全性。

Understanding the mechanism of pulsating wave propagation can improve the efficiency and safety of hydraulic fracturing.。