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Torsion springs - Information on selecting metal springs

Material

Torsion springs are manufactured from stainless steel spring wire material no. 1.4310 in compliance with EN 10270 part 3 (AISI 302 / BS 301S21). The tolerances for the wire diameters correspond to DIN specification 2076.

Design

Torsion springs are available from stock with either right (clockwise) or left (anti-clockwise) hand coiling. An catalogue number ending with the letter "R" in the tables indicates a right-hand coiled spring, and a number ending with the letter "L" indicates a left-hand coiled spring.


left-hand coiled

right-hand coiled

In principle, the torsion springs should only be loaded in the direction of the coil. The spring bodies are coiled without pitch.

Legs

Standard legs are straight and extend at a tangent from the spring body ("TS1").


TS 1

We can also supply torsion springs with any forms of legs for an extra charge.

Leg position

Torsion springs are available in stock with leg positions 0 degrees, 90 degrees, 180 degrees, and 270 degrees.


0 degree

90 degree

180 degree

270 degree

Mandrel

Torsion springs are usually operated in conjunction with a mandrel which holds the spring in position. We have provided a range of possible mandrel diameters for each respective torsion spring, as the spring body tends to contract when bending if the mandrel is too large, and to tilt if the mandrel is too small. The smallest possible mandrel diameter in the table is represented by "Ddmin", and the largest by "Ddmax".

Loads

We have stated the maxium possible torque in the column "Mn", as the length of leverage is different in every application. The maximum possible spring load can be determined by dividing "Mn" by leverage "RH":

Fn=Mn/RH

To calculate the load at a particular angle "Alphax" the following formular must be used:

Fx= (Fn/Alphan) x Alphax

Here, Alphan is the largest possible rotation angle given in the table.

Surface treatment

The spiral springs are made from material no.1.4310 and will not be re-coated after production, as surface protection is not normally required. The disadvantage of an additional surface coating for the majority of spiral springs is that protecting the spring bodies in between the coils can only be made at extremely high cost. Here the selection of a suitable material should be made for an additional surface coating.

Production compensation

The spring manufacturers require a production compensation, in order to retain the default parameters. Normally our spiral springs are compensated through the spring's unloaded leg position (Alpha0).

Quality control

Torsion springs are tested for compliance to the tolerated loads and measurements before they are approved and reach the production warehouse. The tests take place in our quality control department according to DIN ISO 2859-1 level II. The procedure normally consists of a simple spot check programme, test-level AQL=1.0. Specific tests can also be carried out and documented for each individual spring upon the customer's request. The following charges apply for the quality control certificates issued by us.
In compilance with:
DIN EN 10204-2.1 (DIN 50049-2.1)
DIN EN 10204-2.2 (DIN 50049-2.2)
DIN EN 10204-2.3 (DIN 50049-2.3)
DIN EN 10204-3.1B (DIN 50049-3.1B)
Testing of prototypes

Calculation

The calculation of torsion springs is carried out according to DIN specification 2088. DIN 2194 Grade 2 is taken as the basic standard for the tolerances.

spring materials

Here you can see a selection of our normal spring materials, they we have on stock. In all questions to the right selection of spring material, please contact our Department Engineering:

Gutekunst Federn · Dep. Engineering · Gewerbegebiet · D-02733 Cunewalde
Tel. (+49) 035877/227-11 · Fax (+49) 035877/227-14 · technik@gutekunst-co.com

Designation, Material-description Max. operating temp. DIN EN France
(AFNOR)		 GB
(BS)		 Sweden
(SIS)		 USA
(AISI)
EN 10270-1 type SH and DH
Spring steel wire
For all common springs		80°C17223-1 10270-1NFA 47-301-76BS 5216-75 *AMS 5112
1.4310 / X12CrNi177
Stainless steel V2A
High corrosion resistance		200°C1722410270-3Z12CN17.07301S212330302
EN 10270-2 / VDC (unalloyed)
Valve spring wire
In high dynamical stress		80°C17223-2 10270-2****
EN 10270-2 / VDSiCr (alloyed)
Valve spring wire
In high dynamical stress over		120°C17223-210270-2*2803 685A55HD*6150
EN 10270-2 / VDCrV (alloyed)
Valve spring wire
In high dynamical stress over		120°C17223-2 10270-2****
1.4301 / X5CrNi1810
Spring steel V2A
Corrosion resistance		250°C17440Z6CN18.09304S152332304
1.4401 / X5CrNiMo171-12-2
Spring steel V4A
Corrosion resistance, good relaxation, non-magnetic		300°C17224 10270-3Z6CND17.11316S312347316
1.4436 / X5CrNiMo17133
Spring steel V4A
Good corrosion resistance, slightly magnetic		300°C17440Z6CND17.12316S162343 316
1.4539 / X1NiCrMoCuN25-20-5
Spring steel V4A
For aggressive environments, non-magnetic		300°C1744010088Z1NCDU25.20*2562904 L
1.4568 / X7CrNiAI17-7
Spring steel V4A
Minimal relaxation, high dynamical stress		350°C1722410270-3Z8CNA17.07.01301S812388631
1.4571 / X6CrNiMoTi17-12-2
Spring steel V4A
Corrosion resistant, high strength		300°C1774010270-3Z6CNDT17.12320S312350316Ti
CW507L / CuZn36
Copper wire
Non-magnetic, salt-water proof		60°C1768212166****
CW452K / CuSn6
Bronze alloy
Non-magnetic, solderable, weldable, corrosion resistant		60°C1768212166****
CW101C / CuBe2
Copper beryllium
Corrosion resistant, anti-magnetic, non-sparking		80°C1768212166****
2.4610 / NiMo16Cr16Ti
Hastelloy C4
For very corrosive environments		450°C17744*3076 NA 45*5698 / 5699
2.4669 / NiCr15Fe7TiAI
Inconel X750
High temperature, non-magnetic		600°C17752*HR 505*AMS 5698
2.4632 / NiCr20CO18Ti
Nimonic 90
Resistant to most gas corrosion		500°C17754*BS 3075 (NA19)**
Duratherm / CoNiCrFe
Duratherm
High temperatures		600°C****


surface treatments

Here you can see a selection of our normal surface treatments, they we can produce for you in addition. In all questions to the right surface treatment, please contact our Department Engineering:

Surface treatmentAttributes
GalvanisedAnti-corrosion protection.
Galvanised with
polished finish		Visual surface coating, anti-corrosion protection.
Galvanised with
chromatic coating		Visual surface coating, anti-corrosion protection.
(colour blue, yellow, black, olive)
Nickel-platedVisual surface coating, anti-corrosion protection,
affordable frictionless characteristics.
Chrome-platedVisual surface coating, anti-corrosion protection.
PickledRemoved by chemically encased pollutants.
PassivatedSurface resistance due to oxide film, self repairing,
anti-corrosion protection.
Copper-platedGood conductivity, anti-corrosion protection.
BronzedVisual surface coating, smooth coloured surface,
reduced noncorrosive properties.
Electro-polishedSurface coating for stainless steel, visual finishing.
Mainly used for medical equipment.
Gold-platedVisual surface coating, conductivity, prevents excessive
arcing. Less mechanical and chemical resistance.
Teflon-coatingVery good frictionless characteristics.
Delta MagniVery high anti-corrosion protection, perfect for food.
Shot-peeningIncreased dynamic lifespan.
Plastic-powder-coatingVisual surface coating, the 180 different RAL colours are colour fast, sheen durability/RAL colour no.


Gutekunst Federn · Dep. Engineering · Carl-Zeiss-Strasse 15 · D-72555 Metzingen
Tel. +49 (0)7123 960-193 · Fax +49 (0)7123 960-150 · technik@gutekunst-co.com

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