4- Stroke Engine

The Four-Stroke Engine The four-stroke engine is one of the most important innovations in mechanical and marine engineering. Known for its reliability and efficiency, this internal-combustion engine powers ships, vehicles, and generators across the world. Each cycle of this engine goes through four distinct strokes — intake, compression, power, and exhaust — that convert fuel into mechanical energy efficiently and cleanly. A Brief History The concept of the four-stroke cycle was first proposed in 1862 by French engineer Alphonse Beau de Rochas, who described how an engine could work more efficiently by separating the intake, compression, power, and exhaust processes. This theory was brought to life in 1876 by German engineer Nikolaus August Otto, whose engine design became known as the “Otto Cycle.” His invention marked the foundation of modern engines, influencing both automotive and marine propulsion systems.

The Four Pillars of the International Maritime Organization (IMO)

The International Maritime Organization (IMO) establishes global standards to promote safety, protect the marine environment, ensure proper training of seafarers, and safeguard their welfare. These standards are anchored on four key conventions known as the 4 Pillars of IMO: 1. SOLAS – Safety of Life at Sea (1974) SOLAS is considered the most important international treaty concerning maritime safety. It sets the minimum standards for the construction, equipment, and operation of ships to ensure they are safe for both crew and passengers. This includes: • Fire protection systems • Life-saving appliances • Navigation and communication requirements • Emergency preparedness Its ultimate purpose is to prevent loss of lives at sea. 2. MARPOL – Marine Pollution (1973/1978) MARPOL addresses the prevention of pollution from ships. It regulates: • Oil and chemical spills • Sewage and garbage discharge • Air emissions from ships Its goal is to protect the marine and coastal environment by minimizing pollution from ship operations and accidents. 3. STCW – Standards of Training, Certification, and Watchkeeping for Seafarers (1978) STCW sets global training and competency standards for seafarers working on commercial vessels. It ensures: • Seafarers are properly trained, qualified, and certified • Uniform watchkeeping and operational safety practices across the world This helps maintain a high level of professionalism and safety at sea. 4. MLC – Maritime Labour Convention (2006) The MLC is often called the “Seafarers’ Bill of Rights.” It ensures that seafarers have: • Fair wages and employment contracts • Safe working and living conditions • Adequate rest hours • Medical care, social protection, and welfare The convention promotes human rights and dignity for those working at sea.

JET CHISEL

A jet chisel (also called needle scaler) is a pneumatic tool made up of multiple thin steel rods (“needles”) that rapidly move back and forth when connected to compressed air. The vibration of the needles chips away rust, old paint, scale, and marine growth on metal surfaces. Think of it as “pangbaklas ng kalawang, pero industrial version.” Purpose: • Remove rust, corrosion, and scale from steel surfaces • Prepare metal before painting, welding, or coating • Clean areas where grinders and wire brushes can’t reach (corners, tight spots, edges) • Reduce manual scraping time and physical fatigue How to Use: 1. PPE First • Safety goggles / face shield • Ear protection (maingay ’yan) • Gloves • Mask (dust/rust particles) • Proper coverall 2. Check the Tool • Inspect air hose, connectors, and needles • Ensure air compressor pressure is within recommended range (usually 90 psi ± depending on tool) 3. Connect to Compressed Air • Attach hose firmly • Open the air valve gradually 4. Operate • Hold the tool with both hands • Press the needles gently against the surface — do not push too hard • Let the vibration do the work • Work in steady strokes 5. After Use • Shut off air supply • Clean and oil the needles to prevent rust • Store in dry location

EMERGENCY GENERATOR

Ship Emergency Generator: Essential Safety Power at Sea On board a ship, electricity powers almost every operation from navigation and communication systems to lighting, pumps, and emergency alarms. When the main power supply fails, the safety of the vessel, its crew, and cargo relies on a reliable backup source. This is where the ship’s emergency generator becomes indispensable. Mandated by the International Convention for the Safety of Life at Sea (SOLAS), the emergency generator is a critical piece of equipment designed to supply electrical power to essential systems during emergencies. Background and Purpose The emergency generator serves as the ship’s lifeline during power loss or blackout. It automatically starts and transfers load to an emergency switchboard to ensure that key systems remain operational. Its purpose is not to run the entire ship but to sustain safety and emergency functions until the main power supply can be restored or the ship is brought to safety. The generator powers essential equipment such as emergency lighting in accommodation spaces, machinery areas, lifeboat embarkation points, and escape routes. It also supplies energy to fire detection and alarm systems, communication equipment, navigation instruments like radar and GPS, and in some cases, the steering gear. Pumps for fire-fighting and bilge operations, as well as emergency batteries and chargers, also depend on this backup system. Location and Construction To maximize reliability, the emergency generator is installed in a separate compartment from the main engine room—typically on an upper deck with its own ventilation, fire protection, and access. This arrangement prevents the generator from being compromised by incidents in the engine room. Most are diesel-driven alternators chosen for their rapid start-up capability and rugged design. They have independent fuel tanks, cooling systems, and starting mechanisms to ensure operation even if the main systems fail.