RESOURCES -- A PATHWAY TO IDEALITY
Although people usually appreciate elegant
(i.e., close to ideal) inventions, they are often somewhat disappointed:
it looks so simple, even obvious – what is so special about this
invention? In such cases people are confusing the simplicity of the solution
with the simplicity of the problem. In contrast, the most
successful American designers know that:
- Parts not present in a machine never
wear.
- It is easy to make something simple; it
is difficult to make simple things.
- Intelligence is not enough to design
simple things.
Similarly, the designer of the famous
Russian tank T-34, Alexander Morosov, noted in his memoirs that the most
successful principle his group of designers applied was the following:
"The most reliable, indestructible, lightest and cheapest part is a
part that is not there."
Designing with the principle of ideality in
mind is quite helpful, but the principle alone is not enough to produce
reliable and repeatable results. For this purpose, TRIZ provides two
general approaches for achieving close-to-ideal solutions:
- Use of resources
- Use of physical,
chemical, geometrical and other effects
A resource in TRIZ is:
- any substance (including waste)
available in the system or its environment
- an energy reserve
- free time
- unoccupied space
- the ability to jointly perform
additional functions
- information
- etc.
Let us analyze some of the inventions
(including some from previous tutorials) that illustrate how ideality can
be increased through the utilization of resources.
Invention 17 . Corrosion testing
Testing a material’s resistance to
aggressive mediums (acids) is usually performed by submerging a
cube-shaped sample of the material in an acid. The acid is held at a fixed
temperature for a predetermined length of time, after which the sample is
rinsed, dried, and weighed to determine its loss in mass. Such tests are
usually conducted in platinum vessels because platinum is very resistant
to acids. Platinum is expensive, however, and thus most testing facilities
have only one test vessel. As a result, testing must be performed
sequentially -- a time-consuming process.
To improve the situation, it was suggested
that the test sample itself should hold the acid, making the chamber unnecessary.
In this case, the sample material served as
a resource for holding the acid; the vessel became unnecessary.
As mentioned above, any kind of substance
(i.e., material) available within a system or its environment can be
regarded as a resources, including waste:
Invention 25. Casting waste products in
useful shapes
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A mold for casting thermoplastic parts
includes runners that convey the plastic into the mold. The runners become
filled with solidified plastic, which must then be removed and recycled.
The runners themselves can be made in the
shapes of useful items -- letters of the alphabet, for example. As a
result, less waste material remains. |
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Raw materials and even products themselves
can be utilized as resources, as in the following illustration:
Invention 26. Filtering with gravel
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When porous clay is produced, it is
washed with water to remove small particles. If the water is reused,
these particles clog the filters in the water system.
The clogging can be eliminated by
filtering the recirculated water through wells filled with porous clay.
The unwanted particles will remain in the wells when the water passes
through. |
The next invention illustrates the
utilization of resources from the environment:
Invention 27. Preventing coal-dust
explosions in pits
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One of the dangers in coal pits is the
possibility of coal-dust explosions.
To prevent explosions in northern coal
pits, snow is blown into the area. The snow accumulates, then slowly
melts and cools the air.
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When you need energy, don’t rush to buy a
power supply. Instead, try using the power you already have:
Invention 28. Jet-powered brush
The hulls of ships at sea slowly become
encrusted with barnacles and other undesirable marine growth, which must
be periodically removed by divers equipped with rotating brushes. It is
difficult, however, for the divers to forcefully press the brushes
against the hulls, since there is no external means of support or
stabilization.
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To provide adequate pressure against the
hull, the shaft of the brush drives a small propeller which creates a
"jet" of water from the back of the brush, forcing the brush
toward the hull.
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Invention 29. Manufacturing lined pipes
of complex cross section
Glass-lined metallic pipes are used
extensively in the chemical industry. Pipes with circular cross section
are lined using a centrifugal method, whereby melted glass in a heated,
rotating pipe is spread evenly along the inside surface of the pipe by
centrifugal forces. How can glass-lined pipes having a square cross
section be manufactured?
To accomplish this, a glass pipe of
desired wall thickness, which is soldered at both sides, is placed
inside the pipe to be lined. This "compound" pipe is then
placed in the furnace. The glass softens as it heats, and the expanded
air inside the pipe presses the melted glass to the steel pipe walls.
After cooling, the result is a square pipe lined with glass.
Needed energy might be borrowed from the
environment, as is the case with gravity in the invention Braking of
an automatic welder drum.
Automatic welding machines use a steel
wire unreeled from a rotating drum as an electrode. A special motor in
the welding head pulls the wire during the welding process. When welding
stops the motor stops, but the drum continues to rotate under its own
momentum and the wire becomes entangled as a result.
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The drum's rotary
shaft can be fixed, with movement only allowed along a groove cut
at an angle of 1 to 3 degrees with the horizontal plane. When the
drum is not subject to the pulling force of the wire, its shaft is
in the lowermost position, and the drum's side surfaces are
pressed to the brake plates under its own weight. When the wire is
under tension, the drum shaft moves along the groove and away from
the brake plates. |
One of the most effective resources is the capability
to perform additional functions:
Invention 30. Accurately applying
insecticide
Plant insecticides can pollute farm
soil and ground water.
To apply the insecticide with greater
accuracy and minimize pollution, the insecticide can be placed on the
deck of a beehive. The bees will deliver it directly to flowers in the
field.
Invention 31. Manufacturing bushes
without micro-cracks
The procedure for manufacturing a steel
bush includes turning the bush from a rod, drilling a hole in it, and
quenching the surface. During quenching, the bush compresses due to
stress. As a result, micro-cracks often form on the internal surface.
| This can be prevented
by changing the order of operations: First, turn the external
surface; next, quench the surface; and last, drill the hole. Since
the stresses are removed together with the drilled material,
cracks will not form. |
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Often when solving problems with TRIZ an
added benefit is obtained from the system in the way of additional useful
functions. This is called a "super effect."
Invention 32. Improving blood flow with
catheters
Catheters (thin polyester tubes) are
inserted into arteries to examine a patient's heart. Statistics show that
catheterization itself improves the condition of many patients. What
accounts for this phenomenon?
The catheter widens the arteries and
improves blood flow.
The most important point being made with
these illustrations is that an elegant (close-to-ideal) solution can be
developed without introducing external materials, energy, etc. into the
system by achieving the necessary effects through the utilization of
resources. Indeed, numerous inventions have resulted when inventors realized
they could make use of unused energy, vacant space, idle time, etc.
The greatest difficulty in utilizing
resources is to reveal useful resources that are hidden in or around the
system. Imagine, for example, that you are in your office and want to punch
a hole in a piece of paper, but there is no hole punch available. You could
use a nail, of course, but what if you can’t find one? There is likely a
nail holding a picture on the wall – such hidden resources are difficult
to "see."
Sometimes creativity is just as necessary to
discover a resource as it is to solve a problem. A systematic approach can
be of great help in such cases. To conduct a thorough search of a crime
scene, the area is divided into small sections and each section is carefully
searched. We do something similar when looking for resources by using a
special set of check lists:
Readily-available resources
Substance resources
- Waste
- Raw materials or unfinished
products
- System elements
- Inexpensive substances
- Substance flows
- Substance properties
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Field (energy) resources
- Fields (energy) in a system
- Fields (energy) in the environment
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Functional resources
Space resources
- Vacant space
- Other dimensions
- Reverse side
- Space inside an object
- Dynamic space in a moving object
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Time resources
- Prior time
- Pauses
- Idle times
- Parallel processing time
- Group processing time
- Staggered processing time
- Post-process time
Informational resources
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ASSIGNMENT 1
Find ways to use resources to solve the
following problems. Consider this three-step process:
- Create an ideal vision of the solution.
- Identify what is required to realize this
vision.
- Using the above checklists, identify a
resource(s) that can provide the necessary results.
Problem 8. Protecting bunker walls
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When storing powdered materials in a bunker, the
sections of the bunker walls that contact the material as it is unloaded
wear quickly, especially near the outlet. How can the walls be protected
from wear?
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Problem 9. Removing piles
Suggest an economical way to clear piles
left from the remains of an old bridge.
Problem 10. Drying motor windings
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To inspect and repair a motor that has been
immersed in water, the windings must be dried. This is normally done with a
jet of hot air. Is there an easier way?
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ASSIGNMENT 2
Look for examples of the utilization of
various resources, in your work and everyday life.
Next:
Tutorial #5
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