MT 212A: Machine Tools Operation Week 7 PDF

Summary

This document covers the principles, parts, and functions of hydraulic systems used in machine tools, with emphasis on the Technological University of the Philippines curriculum and its application across various sectors.

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MT 212A: Machine Tools
Operation
Week 7 – Hydraulic System/Drive

Ceajay O. Flores – Instructor I
Manufacturing Engineering Technology
Objectives:
Identify the principles of hydraulic systems; and
Determine the parts and functions involved in
the hydraulic system.
Introduction
In modern metalworking plants, hydraulic pressure is
widely used to operate various machine tools due to
its simplicity and flexible control. Hydraulics, though
not a new science, is commonly seen in daily
applications such as hydraulic jacks, lifts, chairs, presses,
and elevators. Recently, hydraulic systems have been
integrated into production tools like broaching,
grinding, and milling machines, and are now standard in
general machine shops and toolmaking departments.
Hydraulic Principles
Hydraulics is the study of liquids in motion, and its
widespread use in force multiplication and control
mechanisms is attributed to the unique physical
properties of liquids that enable efficient power
transmission.
Hydraulic Principles
Liquids are largely incompressible, making them
effective shock absorbers that cushion impacts
during starts and stops.
Even under high pressure, liquids experience
minimal volume changes.
Pressure applied to one surface of a confined
liquid is transmitted uniformly to other surfaces.
Hydraulic Principles
Unlike mechanical systems, liquid pressure can be
easily redirected through pipes, eliminating the
need for additional components.
This makes hydraulic systems a more efficient
method for transmitting power.
Hydraulic Principles
The second property that makes confined liquids
ideal for the transmission of power is their ability
to multiply force.This property was discovered on
the seventeenth century by a French scientist
named Pascal and is known as Pascal’s Law.
According to it, “ A pressure exerted on a confined
liquid is exerted undiminished throughout all portions of
the liquid.”
Conditions
1. The force given by fluid is given by the
multiplication of pressure and area of cross
section.
2. As the pressure is same in all direction, the
smaller piston feels a smaller force and a large
piston feels large force.
3. Therefore, a large force can be generated with
a smaller force input by using hydraulic systems.
Principle of Hydraulic System
Principle of Hydraulic System
Essential Parts of a Hydraulic System
Basic Hydraulic System
Two Basic Methods of Controlling the flow of oil in Hydraulic systems

1. Constant-Volume System – characterized by
a fixed volume where pressure and temperature
can change, but the total volume remains
constant throughout the process.
2. Variable-Volume System - allows for
dynamic changes in volume, which facilitates
work production and energy transfer in various
applications.
Elements of Hydraulic Systems
Pumps – the pump, which runs at constant speed, usually
by an electric motor, takes the oil from the supply
reservoir and delivers it at sufficient and pressure to do
the work required.
Gear Pumps
The simplest commercial medium-pressure
constant-delivery pump has been widely used for
raising and circulating liquids. Its popularity in
hydraulic power transmission stems from its ability
to handle
large volumes at medium pressure,
quiet operation at high speeds (ball bearings and
helical gears),
simplicity, low cost, and compact size.
Vane Pumps
This system is called "hydraulically balanced"
because it features two opposing pumping
chambers that cancel out thrust forces,
preventing heavy bearing loads during high
operating pressures.
This design offers advantages in size, weight, quiet
operation, long life, and high efficiency.
Plunger Pump
The piston or plunger draws in oil as it moves
outward and expels it when pushed back.
Pumps typically have five or more radial cylinders,
each with its own plunger.
Well-suited for variable delivery, high pressure,
and smooth flow, making them crucial in various
hydraulic applications, either alone or in
combination with constant-delivery units.
Elements of Hydraulic Systems
Valves - the purpose of the valves is to control the
flow of oil. The flow is through passages called
ports; in through the suction (intake or inlet) port;
out through the pressure (outlet) port. Valves may
be operated mechanically, electrically, or
hydraulically, and for most actions may be
automatic.
Piston–type Valves
Most valves in hydraulically operated machines are
of the plunger or piston type.
These valves close ports using the "land" of the
plunger to shut off oil flow, while "spools" between
the lands create connections between adjacent
ports.
Ports are formed as annular grooves or radial holes
in the valve chamber.
For smooth operation, it is essential that the oil
pressure is balanced, which is characteristic of
plunger-type valves.
Control Valves
Is a power-operated valve used to regulate or
manipulate the flow of fluids, such as gas, oil,
water, and steam.

The pump generates pressure in the oil to
provide power to the machine, while the valves
control the oil flow, directing power to where it
is needed.
Modern Control Valves
A modern plunger-type control valve features
drilled flanges for easy integration into hydraulic
systems, typically alongside the pump.
Installation involves connecting the pipeline to
one or more cylinders and linking the valve stem
to the control mechanism, which can be
operated mechanically (via cam action or ram
arm), electrically (using a solenoid), or
hydraulically (through a pilot valve).
Resistance (foot) Valves
The device is mounted vertically, with a steel ball
that seals the check valve by gravity. Oil entering
from the side can exit through the top connection
by raising the ball. However, oil flowing in from the
top is restricted by spring pressure, requiring the
entire plunger to move against the spring to allow
flow. The spring pressure can be adjusted using a
screw.
Directional Control Valves (DCV)
Used to stop, start, route, and revert fluids
without affecting the pressure level or the flow
rate of the system.
Identified by the number of ways that fluid can
flow and the number of positions the valve can
produce.
Ways = number of ports
Position = number of discrete operating positions
of the internal valve element.
Hydraulic Oil Requirements
A properly selected hydraulic oil must have :
a) Exceptional chemical stability – to resist oxidation
and thus the formation of sludge or grummy deposits
b) Maximum demulsibility – to separate readily from
water, and thus to minimize the formation of emulsions
c) Adequate film strength – to minimize the wear of
pumps, valves, cylinders, pistons, etc., and in some machines,
to prevent chatter of tables and sticking of slides
d) Proper viscosity and minimum change of viscosity
– to minimize leakage, and at the same time assure ready
flow and prompt response to all controls, and to assure
uniformly high production during the warming – up periods.