SERVICES

We receive order according to your specification, don't hesitate to contact us. The descriptions bellow are the common spring applied in industrial components.

A. COIL SPRINGS

We make and produce any kind of precision spring just for a special order. Send us your technical drawing and product specification …!

Material and Diameter :

Carbon steel wire or stainless steel wire with range of steel spring wire from Ø 0.4 mm until Ø 38 mm. Material Standard according to DIN, JIS, SAE. AISI, or equivalent

Compression Spring, Extension Spring or Torsion Spring, Valve Spring (Pump, Gas, Hydraulic, Pneumatic), Conical Spring, etc. We can produce in big shape of spring wire Ø for heavy duty work.

B. PLATE SPRING

We make and produce any kind of precision (sheet) plate springs just for a special order. Send us your technical drawing and your product specification …!

Material and Diameter :

Carbon spring steel plate or stainless steel plate with range of plate thickness from 0.2 mm until Ø 12 mm. Material Standard according to DIN, JIS, SAE. AISI, or equivalent

Any Kinds of Plate Spring :

Disk spring (also known as belleville spring), spring washer or wave spring washer, spiral spring, tension plate spring, rolling helical plate for feeding support, and many other shapes of plate spring according to special order from user. We also receive order to supply (sheet) plate spring material for industrial needs.

C. DISC SPRING

Disc springs, or Belleville washers, are used singly, or in stacks, to achieve desired load and travel.

A. COMPRESSION SPRING

COMPRESSION SPRINGS are open-coil helical springs wound or constructed to oppose compression along the axis of wind. Helical Compression Springs are the most common metal spring configuration. Generally, these coil springs are either placed over a rod or fitted inside a hole. When you put a load on a compression coil spring, making it shorter, it pushes back against the load and tries to get back to its original length. Compression springs offer resistance to linear compressing forces (push), and are in fact one of the most efficient energy storage devices available.

Key Parameters:

Dimensions: Outer Diameter, Inner Diameter, Wire Diameter, Free Length, and Solid Height.
Free Length is the overall length of a spring in the unloaded position.
Solid Height is the length of a compression spring under sufficient load to bring all coils into contact with adjacent coils.
Spring Rate (stiffness, Spring Rate is the change in load per unit deflection in pounds per inch (lb. /in.) or Newtons per millimeter (N/mm), Unit of Measures

C. TORSION SPRING

A torsion spring is a spring that works by torsion or twisting; that is, a flexible elastic object that stores mechanical energywhen it is twisted. When it is twisted, it exerts a force (actually torque) in the opposite direction, proportional to the amount (angle) it is twisted. There are two types. A torsion bar is a straight bar of metal or rubber that is subjected to twisting (shear stress) about its axis by torque applied at its ends. A more delicate form used in sensitive instruments, called a torsion fiberconsists of a fiber of silk, glass, or quartz under tension, that is twisted about its axis. The other type, a helical torsion spring, is a metal rod or wire in the shape of a helix (coil) that is subjected to twisting about the axis of the coil by sideways forces (bending moments) applied to its ends, twisting the coil tighter. This terminology can be confusing because in a helical torsion spring the forces acting on the wire are actually bending stresses, not torsional (shear) stresses.

B. EXTENSION SPRING

Helical extension springs are similar to helical compression springs, but are loaded in tension. Hooks orloops are provided to allow a pull force to be applied. Usually, extension springs are attached at both ends to other components. When these components move apart, the spring tries to bring them together again. Extension springs absorb and store energy as well as create a resistance to a pulling force. It is initial tension that determines how tightly together an extension spring is coiled. This initial tension can be manipulated to achieve the load requirements of a particular application. Extension Springs are wound to oppose extension. They are often tightly wound in the no-load position and have hooks, eyes, or other interface geometry at the ends to attach to the components they connect. They are frequently used to provide return force to components that extend in the actuated position.

D. RING WASHER

A Ring washer is a thin plate (typically disk-shaped) with a hole (typically in the middle) that is normally used to distribute the load of a threaded fastener, such as a screw or nut. Other uses are as a spacer, spring (belleville washer, wave washer), wear pad, preload indicating device, locking device, and to reduce vibration (rubber washer). Washers usually have an outer diameter (OD) about twice the width of their inner diameter (ID).

Washers can be categorised into three types :

Plain washers, which spread a load, and prevent damage to the surface being fixed, or provide some sort of insulation such as electrical
Spring washers, which have axial flexibility and are used to prevent fastening loosening due to vibrations
Locking washers, which prevent fastening loosening by preventing unscrewing rotation of the fastening device; locking washers are usually also spring washers.

E. DISC SPRING (BELLEVILE WASHERS)

Disc springs, or Belleville washers, are used singly, or in stacks, to achieve desired load and travel. A Belleville washer, also known as a coned-disc spring, conical spring washer, disc spring, Belleville spring orcupped spring washer, is a type of spring shaped like a washer. It has a frusto-conical shape which gives the washer a spring characteristic. The Belleville name comes from the inventor Julian F. Belleville. Disc Springs are conically-shaped, washer-type components designed to be axially loaded.

Multiple Belleville washers may be stacked to modify the spring constant or amount of deflection. Stacking in the same direction will add the spring constant in parallel, creating a stiffer joint (with the same deflection). Stacking in an alternating direction is the same as adding springs in series, resulting in a lower spring constant and greater deflection. Mixing and matching directions allow a specific spring constant and deflection capacity to be designed.

Example: 1 Spring is considered to be 1 in Parallel, 1 in Series. (This notation is needed for load calculations)

If n = number of springs in a stack, then: Parallel Stack (n in parallel, 1 in series) - Deflection is equal to that of one spring, Load is equal to that of n x 1 spring. i.e. Stack of 4 in parallel, 1 in series will have the same deflection as that of one spring and the load will be 4 times higher than that of one spring.

Series Stack (1 in parallel, n in series) - Deflection is equal to n x 1 spring, load is equal to that of one spring. i.e. Stack of 1 in parallel, 4 in series will have the same load of one spring and the deflection will be 4 times greater.