Shock indicator
A shock indicator, also known as impact indicator, is a mechanical device that detects and records mechanical shocks experienced by it. It is a common practice to attach shock indicators to expensive goods that are to be shipped. This way, the magnitude and the time of shocks are recorded to ensure that delicate and expensive instruments are not mishandled or exposed to inappropriate environmental conditions during shipping. The shock indicator provides a visual indication whether the shock threshold has been reached or exceeded, e.g. in the form of a broken spring, color change or a digital display.
The shock indicator was invented to ensure safe shipment of expensive goods and to hold the right people liable for damage. As with other inventions, it has undergone various stages of development. The earliest shock indicators were simple mechanical devices with a spring-load assembly. Newer ones come integrated with a complex set of electronic circuits that detect, measure and record shocks. Many companies make these indicators and conduct active research.
Spring-Load Assembly
Spring-load type shock indicators involve a simple extensible spring with a load attached to one end. Small shocks cause only temporary excursions of the load from its resting position following Hooke's law. A shock strong enough to stretch the spring beyond its elastic limit will lead to an irreversible deformation of the spring, thus providing a permanent indication that such a shock was experienced by the system. The critical acceleration at which the elastic limit is reached can be tuned by carefully choosing the material and shape of the spring, as well as the mass of the load.
Viscosity & Surface Tension[1]
Physical type shock indicators involve surface tension and capillary action. This shock indicator made of water, ink and absorbing material. A shock exceeds its surface tension resulting in droplets falling and absorbing by the material.[2] In most applications, the absorbing material is white and the droplet is red. The user will see the color change.
Strong shocks and small shocks involve viscosity. Higher viscosity requires strong shocks to make the droplet falls while lower viscosity requires small shocks. This is the principle to set a specific force.
Modern Indicators
Modern indicators that rely heavily on their supporting electronics are much more complex than their mechanical counterparts. They can not only detect and measure the shock, but also record the entire spectrum of shocks experienced over a period of several months or even years. They sometimes involve piezo-based accelerometers with low consumption of electrical power.
References
- "Shock Indicator Principle & Function". WAN-YO Enterprise Co., Ltd.
- "Physical Shock Indicator color change". YouTube.