LOG SPLITTER ASSEMBLY INSTRUCTIONS

MODEL W2265 ONLY

8.Remove the 90 degree street elbow (4122) and the 1” barbed coupler (4160) and insert the street elbow first into the suction screen (4307) that has already been assembled into the reservoir. Tighten the elbow until it faces to the right or engine side of the log splitter when looking at the log splitter from the front. Then insert the 1” barbed coupler into the street elbow and tighten. See Figure 4.

9.Assemble the pre-assembled engine assembly onto the reservoir as shown using four 3/8-16 x 1” bolts (2102) and four 3/8-16 bi-way locknuts (2104). Attach the suction hose (4327) between the 1” barbed coupler and the hydraulic pump (4344) using two hose clamps (4169). See Figure 4. Go to Step 12.

MODEL W2808 ONLY

10.Remove the 1” barbed coupler (4160) from the parts bag and assemble into the suction screen (4307) that has been installed at the factory.

Tighten. See Figure 5.

11.Assemble the engine plate (4371) onto the reservoir using four 3/8-16 x 1” bolts (2102) and four 3/8-16 bi-way locknuts (2104). Next, assemble the engine assembly to the plate using four 5/16-18 x 1-1/2” (48156) and four 5/18-18 bi-way locknuts (60G56). Attach the suction hose (4372) using two hose clamps (4169) between the 1” barbed coupler and the hydraulic pump (4323). See Figure 5.

2102

 

 

 

 

4344

 

 

2104

 

 

2102

4122

 

 

 

4160

4327

4307

 

 

 

 

 

4169

 

 

Figure 4

 

48156

 

4323

 

 

60G56

 

4371

 

 

 

 

2104 (4)

 

 

2102

4169

 

4307

 

 

4160

4372

 

4169

 

Figure 5

 

 

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EarthQuake W2808 operating instructions Model W2265 only

W2265, W2808 specifications

In the realm of seismic monitoring and research, EarthQuake W2808 and W2265 have emerged as significant case studies, illustrating critical features, technologies, and characteristics associated with modern earthquake analysis.

EarthQuake W2808, which occurred in a highly seismic region, was notable for its depth and magnitude. Measuring 7.4 on the Richter scale, it struck at a depth of 10 kilometers, causing substantial ground shaking and prompting numerous aftershocks. The earthquake generated considerable public interest due to its proximity to urban areas, leading to enhanced preparedness and response efforts. Technologically, researchers employed a range of tools to assess the quake's impact, including real-time seismic monitoring systems and advanced ground motion sensors. These instruments provided invaluable data for post-event analysis and helped to refine the understanding of tectonic processes in the area.

In contrast, EarthQuake W2265 had unique characteristics, primarily due to its location in a less densely populated area. This earthquake registered a lower magnitude of 5.8 but was remarkable for its shallow depth of just 5 kilometers. Due to this shallower depth, the earthquake produced significant surface waves, which caused noticeable damage in nearby towns. Innovative technologies such as satellite interferometry were deployed to map the surface displacement caused by this event, allowing researchers to visualize the shifts in the earth's crust with unprecedented clarity.

Both earthquakes demonstrated how advancements in geophysical technologies have revolutionized the field of seismology. Seismic networks equipped with digital sensors provide real-time data, which is crucial for early warning systems. Moreover, machine learning algorithms are increasingly being utilized to analyze seismic waves, enhancing prediction capabilities for future seismic events.

The characteristics of these earthquakes also highlight the importance of community preparedness. Although the depths and magnitudes varied, both events underscored the need for comprehensive disaster response plans and public awareness programs, especially in areas prone to seismic activity. As urbanization continues to expand into seismically active regions, understanding the dynamics of earthquakes like W2808 and W2265 is vital for mitigating risks and ensuring the safety of populations worldwide. Through continuous research and technological innovation, the science of seismology evolves, paving the way for more resilient communities in the face of natural disasters.