The aim of this guide is to provide a comprehensive overview of different types of compression springs and their common applications. We will explore popular styles and sizes available from SpringXpert Ltd and offer insights into which springs to purchase for a variety of everyday uses. Additionally, we will delve into the mechanics of these springs and explain how to accurately measure them, making it easier to select the ideal coil springs for specific tasks.
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Read nowWhile finding the best possible design solution can be challenging, knowing what options are available can make it easier for you.
One option Smalley provides is a wave spring.
A wave spring, a type of compression spring, is a solution that optimizes space concerns while providing form, fit, and function.
Lets start by defining what a spring is. Most people have used or at least have heard of springs. Theyre virtually everywhere, from the bed you wake up on, to the gas pump you use to fuel your car, to as far as the rovers on Mars. If you unscrew your pen, youll find a spring in there to push the plunger and the ink tip up and down as you click.
There are three main types of springs compression, extension, and torsion. The type well focus on today is a compression spring.
Invented by Smalley more than 100 years ago, a wave spring is a type of compression spring made of flat wire with a unique 'multiple waves per turn' design. This innovative design is why a wave spring can offer the same spring force as a traditional round wire coil spring but at 50% of its operating height.
Similar to a traditional coil spring, a wave spring starts at free height. Free height is the natural height of the spring with no load applied, denoted as H in the image below. Work height, denoted as WH, is a height the spring is compressed to at a specified load. As the wave spring is compressed, a load is output until a working height is reached. At the springs work height, the specified load is achieved.
This concept is displayed by the force-deflection curve below. Lets say you have two load requirements for your application, 20 and 28 lb. The first load is output at a work height of 0.08 in., as indicated by the leftmost blue x on the curve. The 28 lb. load requirement is output at a work height of 0.06 in.
Now lets take a part number out of our catalog for a Crest-to-Crest Wave Spring, C100-M1. The spring has a free height of .250 in. and a work height of .087 in. At this designated work height, the Crest-to-Crest Wave Spring outputs a load of 18 lb. Beyond this work height, the spring may take a set, making the spring forces unpredictable.
Read more about wave spring work height and compression.
Now that you have a basic understanding of what a wave spring is and how it works, well go over our manufacturing process. Edgewinding, our No-Tooling-Cost manufacturing process, is the only process we trust to deliver precise yet flexible solutions to meet your wave spring needs.
The process begins by cold working round wire to flat dimensions. Cold rolling causes the metal grains to elongate and lock together, improving the strength and stability of the material.
After cold rolling, the flat wire is then coiled on edge to form the Crest-to-Crest wave structure.
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Since the grain follows the direction of the coil, it provides better spring properties than if the shape were to be stamped and the grain only went in one direction. The circular-grain metallurgy is formed during this process, which gives our parts better spring properties.
Edgewinding is a flexible and economical process, allowing us to customize designs with no tooling dies and nearly no material waste. What this means for you is that we can easily incorporate design changes during any stage of the process. It is both quick and economical for you, whether its a prototype or a production run.
There are 5 main types of wave springs Crest-to-Crest, Overlap- & Gap-Type Single-Turn, Nested Spirawave®, Wavo®, and Linear. While all wave springs are based on a wave type design, they all have distinct features that determine spring performance under load.
The use-case is described in the table below.
Selecting the right material is critical for optimal spring performance. There are several factors to consider during spring material selection, such as operating environment, cycle life, and budget.
Standard Smalley Wave Springs are available in carbon steel and 17-7 stainless steel. Smalley stocks over 40 additional material options, including exotic alloys such as Inconel X-750® and Elgiloy®, to withstand practically any environment.
From small to large diameters, light to heavy-duty loads, carbon steel to exotic materials, wave springs have been the trusted, space-saving solution for tens of thousands of applications. From everyday consumer products such as the smartwatch on your wrist to life-saving medical devices such as robotic surgical instruments to extreme environments like oil wells deep under the Earth's surface, to as high as Mars, there is virtually no limit for wave springs.
One common application that utilizes the benefits of a wave spring is a flow valve. While many spring systems can be designed into valves, engineers often choose wave springs because of their space-saving capability and linear compression behavior through 80% of the compression range. These unique features allow for more precise and repeatable control of both flow and pressure.
As fluid pressure increases a Crest-to-Crest Wave Spring precisely controls the linear displacement of the piston.
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