Starrett Spring Testing Solutions

Spring measurement, testing and analysis is complex. While a spring may appear to be a simple device, its operation and performance can be difficult to determine precisely. Until now.

Precision, Quality, Innovation

SPRING TESTING SOLUTIONS

Material Analysis

Force Analysis

High Volume Testing

Economical Testing

MTH Manual Tester

Digital Force Gages

Digital Force Testers

Accessories

Bulletin 1830

P recision . A ccuracy . R epeatability . F lexibility . Spring measurement, testing and analysis is complex. While a spring may appear to be a simple device, its operation and performance can be difficult to determine precisely. Until now. Starrett, a global leader in measurement technology, has engineered spring analysis, spring testing and spring measurement solutions that precisely characterize a spring’s operation and performance. Our solutions can verify and validate your spring’s performance and characteristics including: working loads, height and solid height variations, spring index, slenderness ratio, initial tension and more. Starrett solutions ensure measurement accuracy and repeatability. And we offer a level of testing and measurement solutions that are sophisticated enough for spring design engineers yet easy enough to use for the novice user. Starrett knows spring measurement, testing and analysis.

L et S tarrett show you how .

E ngineered M easurement S olutions . D esign . P roduction . A pplication . Starrett offers a complete line of measurement, analysis and testing solutions for the design engineer, production manager and quality professional. Spring performance begins with the materials used in its design; next to the manufacturing processes employed; and finally through to the quality evaluation.

M aterial C haracterization A spring’s overall performance begins with choosing the appropriate materials for its application, service and life cycle. Starrett L3 systems are used to characterize materials and to determine their performance capabilities. Material stress and strain measurements, using a Starrett L3 system, ensures that the material selected for your spring meets the design and performance requirements you require. Requirements such as material stiffness, elasticity, strength, and resilience are easily measured using a Starrett L3 system. Confidence in your spring performance begins with the material used in the spring design.

P erformance A nalysis Verifying your spring design can consist of determining spring rate, spring constant, free length and initial tension. Having the ability and methods to precisely determine the spring’s performance and operation can be accomplished using the Starrett L2Plus system. With its graphical measurement capability, you see your spring’s performance--- graphically. With data sampling at up to 2000Hz, you can use a variety of measurement tools to find precise points, slopes for spring rates, hysteresis traits, elasticity, linearity and nonlinearity performance.

Q uality C ontrol & A ssurance

Once in to full production, Starrett S2 and S1 systems can be used to verify spring performance, repeatability and quality. Quality testing can be performed quickly and easily without compromising measurement accuracies or testing methods. Starrett systems can be used to evaluate and determine spring tolerances and basic performance characteristics including free length, spring rate, spring constant and initial tension. Conditioning can be employed including scragging and solid height. Testing may be either a single or two-point method. Certification and compliance reports can be created and issued with your products for your customers.

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M aterial A nalysis with the S tarrett L3 S ystem

Starrett L3 systems are ideal for analyzing, verifying and validating the application suitability and performance of material used in your spring design. The L3 system lets you perform tensile testing of your raw material to determine such performance factors as: • Tensile strength • Maximum shear stress • Elastic modulus • Elastic limit • Endurance limit • Proportional limit and offset yield

• Stress and strain limits • Stiffness and brittleness

With L3 software, you can create tests based on international testing standards from ASTM, ISO, DIN and others. Test creation is graphical and intuitive. Once your test is created, you perform the test and determine material characteristics using powerful, yet easy-to-use measurement tools. Find results with a simple click on the graph.

S tarrett delivers confidence in your materials ’ P erformance .

Create your test graphically in seconds. Your test is a combination of test movements and their required performance and specifications.

Create your test method to internationally-accepted standards, measure results graphically, analyze your data and export to your SPC application. L3 systems are easy-to-use and let you test your materials without compromise up to 50kN. Ideal for all types of wire materials.

Use the Min/Max/Average tool to find the maximum material stress (tensile strength) of your wire material.

Use the slope tool to measure the elastic modulus and to find the elastic limit. Touch the tool. Touch the graph. Its that easy.

The Starrett L3 system for material testing will verify and validate your spring design materials. Perform tensile strength analysis and characterize your materials with our comprehensive testing software that is easy-to-use, intuitive, and precise.

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F orce A nalysis with the S tarrett L2 P lus S ystem Starrett L2 Plus systems are ideal for determining your spring design performance. Create simple or complex testing routines and perform complex measurements with a simple “click on the graph”. With L2 Plus software, you find your results using the graph created from your test method. Measurement tools let you find key spring characteristics including: • Spring rate • Spring constant • Free length

• Initial tension • Solid height • Resilience

With L2 Plus software, you not only find themeasurements for your springs, but you have comprehensive data and information on your sample that shows precisely the “why, where and when” the measurement occurred. Plus, with advanced tolerancing, including the ability to have tolerance banding for your sample, you can view any single point that may be outside your tolerance limits.

Use the slope tool to measure spring rate.

Use the point tool to measure individual values including spring rate and your limits.

Display individual results using the graph while displaying the results in a tabular format for all individual tests for that batch. Krate is measured using the slope tool between the L1 and L2 points. Height information is also displayed, including the free length. Just touch the graph to measure your results.

Out-of-tolerance results are immediately identified using a tendency bargraph.

The L2 Plus software data view displays results in a tabular format. You can view statistics for your batch and compare individual test results quickly and easily. Out-of-tolerance results are displayed in red with a tendency bargraph.

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S tarrett S2 software is ideal for compression and extension. Springs are available withan outside diameter of 8 inches (200 mm), load rates of 1100lbf (5 kN) and travel lengths of 40 inches (1016 mm). The software lets you determine the following: • Load at Height/Length Limits (One or Two Points) • Load at Height/Length Limits (Multiple Points with optional Test Builder) • Height/Length at Load Limits (One or Two Points) • Height/Length at Load Limits (Multiple Points with optional Test Builder) • Free Length/Height • Spring Rate, Spring Constant, Initial Tension H igh - volume P roduction T esting with the S tarrett S2 S ystem

S2 software can operate on any Windows computer, including tablet computers, laptop computers or all-in-one workstations.

F ast . E fficient , P roduction T esting .

S oftware F eatures • Use preconditioning options to exercise your spring prior to testing. You can scrag for a number of cycles or duration. You can also compress to a load set and hold for a duration. • Single or dual limit tests may be used. You may specify a target load or target height/length to determine spring rate, spring constant, load and length at target limits, initial tension and measured free length. • The Data View displays the measured results. The spring constant is displayed for a single point test while the spring rate is displayed when using a dual point test method. • You may graph the test including the ability to witness the load at length/height or load at time profiles. Using the “overlay” function, you can map individual test graphs and overlay them onto one another to get a visual of individual test relationships. • The Summary View lets you compare all tests within a batch. You can establish tolerances for your springs and display “pass/fail” and tolerance relationships. • The Statistics View displays key statistical information for your batch including mean, range, standard deviations and tolerance results. • Perform more sophisticated, multi-stage testing when you use the optional Test Builder software. You can convert from a Spring Test template to the Test Builder quickly and easily.

T est S etup O ptions • Pre-Test Options - Units of Measurement

- User Prompts to assist operator during testing - Spring preconditioning (Scrag & Load Set Hold for duration)

• Test Options

- Measure Free Length - One Point Limit Test (Load or Height)

- Two Point Limit Test (Load and/or Height) - Exceptions (Abort test if an exception is met)

• Data Options

- Spring Constant (One Point) - Spring Rate (Two Point) - Date, User, Limit Setpoints

• Post-Test Options

- Export Raw Data to a file location (up to 1000 pts/second) - Export Results (Overwrite or Append data file)

Your two-point test setups may be based on a load or height target. (Top) Height targets are used as setpoints where the KSR is determined based on the spring length. (Bottom) Load targets are used as setpoints to determine KSR. The “Stop Test If” conditions will stop a test should either the Max Load or Max Height be encountered. SI units of measure are being used.

With the S2 software you can overlay the graphs of multiple test results to verify each spring against a benchmark curve. Imperial units are used.

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E conomical S pring T esting with the S tarrett S1 S ystem Starrett S1 systems represent our most basic digital testing solution for compression and extension springs. S1 systems are ideal for high-volume production testing and individuals looking for more consistent testing results over manual testing methods. Two types of test methods are supplied for compression and extension springs. Easy-to-use test templates let you create your test setup in seconds. The small footprint make S1 systems ideal for lean manufacturing environments or in-situ production locations. With the S1 system, you can measure: • Spring rate • Spring constant

Test templates make test setup simple and fast. One- and two-point methods may be used. Measure free length by selecting the combo button. Test targets may be load- or height-based.

• Free length • Solid Height • Initial tension

Make use of tolerances to determine immediate “Pass/fail” results. View results graphically or in tabular formats. You can also print out custom reports and export data to Microsoft Excel or SPC software such as ProLink’s QC CALC application.

E conomical D igital S pring T esting .

(Top) Display your results with a full graph for your test. You can display three graph types: Load x Height, Load x Time or Distance x Time. You can also overlay graphs to compare the graph profiles. You can also print out a report with your graph and the results for each test with a single key-press. (Bottom) Display your results in a tabular format. Tabular results may be displayed with tolerance limits and “pass/fail” indication. You can also display statistical results for individual tests or for all the tests performed for a batch. Export result or your raw data with a single key-press.

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MTH M anual S pring T ester The MTH Manual Tester is a single column, manually-operated force tester. The MTH has a load measurement capacity of 550lbf (2500N, 250kgf) and can be used for compression or tensile testing. The mechanical advantage afforded by the MTH- 550’s precision, high-resolution worm gear design lets you test effortlessly. One rotation of the hand wheel positions the crosshead 0.03” (0.75mm). Total stroke for the MTH-550 is 4” (102mm). Force measurement is performed using a Starrett digital force gage. The MTH-550 is an ideal, affordable solution for spring testing. Fit the MTH- 550 with a digital force gage and optional digital scale to determine spring rates, initial tension and more. The hand wheel may be positioned anywhere along the 30” (762mm) column, and with a 4” (102mm) throat, large samples can be accurately tested. The base may be permanently affixed to your workbench. Optional gage adapter kits are available for use with non-Starrett force gages. Quick-change clevis adapters let you mount a large selection of Starrett testing fixtures. F eatures • Tension or Compression Testing • Excellent for Cost-Effective Spring Testing • Effortless Crosshead Movement • Precision Worm Gear Design • Excellent Position Resolution: Single Rotation for 0.03” (0.75mm) • 30” (762mm) Column Height, 15” (380mm) Working Area • Adjustable Gage Mounting

D igital F orce G ages

• Use as handheld instrument or mount to Starrett test frames: FMM, MTL and MTH • Excellent display resolutions:

- - DFC 10,000:1 - - DFG 5,000:1 • Precise and accurate load measurements:

- - DFC 0.1% full scale - - DFG 0.2% full scale • Load sensors have safe overload rating of 200% • High-resolution OLED color display with adjustable backlight and Auto Off feature • Supplied with NIST-traceable Certificate of Calibration • 3-year warranty

• A primary and secondary display window shows your results, out-of-tolerance results display in red • Adjustable sampling rates help you capture peak loads, filters can be applied to peak and display values • Multiple display languages • Battery provides more than 30 hours of continuous operation, charge battery using USB cable • Programmable sounds for alarms, such as an out-of-tolerance result

MMS and FMS S eries P recision D igital F orce T esters

S pecifications

MMS & FMS Series - Digital Force Testers

Material Testers Force Measurement Testers MMS-500 MMS-1000 MMS-2500 MMS-5000 FMS-500 FMS-1000 FMS- 2500

Models

FMS- 5000 5000 500 1124

N kgf lbf

500 50 112

1000 100 225

2500 250 652

5000 500 1124

500 50 112

1000 100 225

2500 250 652

Load Capacity

mm/min in/min mm/min in/min

0.001 0.00004

0.02 0.001

Crosshead Speed - MINIMUM

1525 60 0.125 4.9

Crosshead Speed - MAXIMUM

0.250 9.8

µm µin

Position Control Resolution

2.7 15,400

4.3 24,500

8.5 48,500

2.7 15,400

4.3 24,500

8.5 48,500

kN/mm lbf/in

Frame Axial Stiffness

mm in mm in mm in mm in mm in mm in

559 22 381 15 100 4 813 32 381 15

953 37.5 762 30

1257 49.5 1016 40

559 22 381 15

953 37.5 762 30

1257 49.5 1016 40

Vertical Test Space 1

Total Crosshead Travel

Throat

1270 50

1575 62

813 32

1270 50

1575 62

Total Height

Total Width

514 20.25

Total Depth

61 135

77 170

88 195

61 135

77 170

88 195

kg lb

Test Frame Weight

±0.5% of reading down to 1/1000 of load cell capacity. Starrett load cell sensors are supplied with a Certificate of Calibration traceable to NIST. Starrett recommends verification of load cell accuracy during installation per ASTM E4, ISO 7500-1 or EN 10002.

Load Measurement Accuracy

FMS frames cannot use extensometers

±0.010mm or 0.1% displacement (whichever is greater)

Position Measurement Accuracy

±0.005mm or 0.1% displacement (whichever is greater)

±0.5% of reading down to 1/50 of full scale with ASTM E83 class B or ISO 9513 class 0.5 extensometer

Strain Measurement Accuracy

FMS frames cannot use extensometers

Crosshead Velocity Accuracy

±0.1% of set speed at zero or constant load hold

Data Sampling

0.001 to 2000Hz

12 total channels Channel 1 & 2 for Power (5-24V) Channels 3 thru 10 for either digital inputs or outputs Channels 11 & 12 for Ground

Digital I/O

Analog Inputs Analog Outputs

1 channel @ ±10V 2 channels @ 0-10V

Extensometer Ports

2 channels for independent connection to an extensometer(s)

FMS frames cannot use extensometers

USB Interface

1 USB 2.0 connector

Single Phase Voltage (Vac) ±10% 110, 120, 220, 230, 240

Electrical Phase

Frequency

50/60Hz

°C °F °C °F

+10 to +38 °C +50 to +100 °F -40 to +66 °C -40 to +150 °F

Operating Temperature

Storage Temperature

Humidity

10% to 90%, non-condensing

CE Compliance

MMS and FMS Series Systems meet all relevant CE standards

NOTES Total vertical space is the distance from the top surface of the base plate to the bottom surface of the crosshead. MMS and FMS Test Frames use MLC and FLC Series load cell sensors only. MMS and FMS Test Frames may be used with L3, L2Plus and S2 software applications only. Starrett MMD and FMD Test frames (not shown) are available in 10kN, 30kN and 50kN capacities.

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FMM S eries E conomy D igital F orce T esters

S pecifications

FMM Series - Motorized Force Testers Models

Short Travel Extended Travel FMM-110S FMM-330S FMM-550S FMM-110 FMM-330 FMM-550 FMM-110X FMM-330X FMM-550X Standard Travel

Lbf

110 500

330

550

110 500

330

550

110 500

330

550

Load Capacity, Full Scale

1500

2500

1500

2500

1500

2500

Kgf

150

250

150

250

150

250

inch/min 0.002 mm/min 0.05 inch/min 40 mm/min 1000 inch/min 40 mm/min 1000

Crosshead Speed, Minimum

Crosshead Speed, Maximum

Maximum Speed, Full Load

Accuracy- Speed

Better than 0.1% of test speed

+0.001mm (+20 microns) or 0.1% displacement (whichever is greater)

Accuracy- Crosshead Position

inch 0.001 mm 0.025 kN/mm 2.5

Travel Resolution

2.6

2.7

2.5

3.1

2.2

2.5

Axial Frame Stiffness

lbf/in

14,200

14,800

15,400

14,200

17,700

12,500 14,200 14,200

Cycling, Maximum Counts 99,999 Duration 27 hours Constant Hold, Maximum Duration 27 hours Vertical Test Space 1 inch 15.6

mm 400

559

813

inch

Crosshead Travel

mm 305 USB 2.0, RS-232

508

762

Communication

Input/Output Channels

0 - 24Vdc (independent, configurable)

Power

Single Phase Voltage (Vac) +10% 110, 120, 220, 230, 240 50/60 Hz

0.09A Holding

0.11A Holding

0.18A Holding

0.09A Holding

0.11A Holding

0.18A Holding

0.09A Holding

0.11A Holding

0.18A Holding

Amps

Using 117V Mains at Full Scale Load

Watts 10.5 Watts 12.9 Watts 21.1 Watts 10.5 Watts 12.9 Watts 21.1 Watts 10.5 Watts 12.9 Watts 21.1 Watts

°F °C

+40 to +110

Operating Temperature

+5 to +43

Humidity

10 to 90%, non-condensing

inch 3.9 mm 100

Throat

inch

28.9

Height

mm 733 11.5 mm 292 inch inch 16.5 mm 419

940

1194

Width

Depth

inch

#10-32, 5/16-18, 1/4-28, 1/2-20 (optional)

Base Plate Threads

mm M4, M6, M10, M12 (standard)

lbs

95 43

Weight (approx.)

kgs

31.8

36.3

CE Compliance

Meets all relevant CE standards for safety, immunity, noise

NOTES Total vertical space is the distance from the top surface of the base plate to the bottom surface of the crosshead. FMM Test Frames use BLC Series load cell sensors only. FMM Test Frames may be used with S1 or S2 software applications only.

E asy - to - use D eflection C ompensation Spring testing results may be adversely affected when total system deflection is not correctly compensated for. Starrett software includes deflection compensation so that your entire system’s deflection can be compensated for so you achieve more accurate results. When deflection compensation is used, the deflection affects of the test frame, load cell and test fixture are entered into the software’s Correction setting. When the specific load cell, test fixture and test frame are used for compression or extension spring measurement, the associated deflection compensation values are automatically applied. You have more accurate results.

S tarrett T esting F ixtures and A ccessories Starrett offers a variety of testing fixtures and accessories optimized for spring analysis, testing and measurement. We also develop custom solutions for testing to your exact requirements.

S pring R od S ets Spring rod sets help maintain perpendicularity, especially on small dimension springs that may buckle when a load is applied. Starrett offers standard spring rod sets, or we can create spring rods to your spring’s dimensions: inside diameter, wire diameter, outside diameter and free length.

H ook A dapters Starrett can supply a variety of specialized hook adapters ideal for extension spring testing. Swivel- style hooks help ensure correct axial alignment. Fixed, clevis-style hooks are available for testing up to 50kN (11,000lbf).

C ompression P latens A variety of compression platens are available including swivel platens that help counter issues with non- parallelism. Starrett can supply platens made from aluminum, steel, stainless steel or specialized metals to your requirements.

S plinter S hields Splinter shields are available for all Starrett test frames. We can provide simple manual shields made from clear acrylic to shields made of Lexan ® aerospace acrylic with electronic interlocks.

L oad C ell S ensors Starrett has available a complete selection of load cell sensors with capacities from 1N to 50kN (100gf to 11,000lbf). We offer both s-beam style and our superior MLC sensors ideal for applications where axial alignment affects are present. All sensors have a +0.1% measurement accuracy and come with a Certificate of Calibration.

E xtensometers Starrett L3 systems can be supplied with extensometers for precision stress and strain on the material used to construct your springs.

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L oad C ell S ensors Starrett offers a full range of accessories including sensor technologies for precision load and strain measurements. These sensors interface seamlessly with our testing frames and are “self-recognizing”. Starrett sensors are ideal for demanding material testing and force measurement applications. All load cell sensors are compliant with IEEE 1451.4 and meet or exceed ASTM E4, BS 1610, ISO 7500-1 and EN 10002-2. Sensors are supplied with a NIST-traceable Certificate of Calibration. Load accuracy on all sensors is 0.1% full scale.

MLC Series - Material Test Low-profile Sensors Model Number Load Capacity

Safe Overload Full Scale Deflection Height 1

Width

Thread

N KGF LBF % Full Scale in

mm in

mm in mm mm

MLC-125 125 12.5 28

150 150

0.003 0.08 0.003 0.08 0.003 0.08 0.003 0.08 0.001 0.03 0.001 0.03 0.001 0.03 0.001 0.03 0.002 0.05 0.002 0.05

1.5 38.1 2.75 69.8 M6 x 1-6H 1.5 38.1 2.75 69.8 M6 x 1-6H 1.5 38.1 2.75 69.8 M6 x 1-6H 1.5 38.1 2.75 69.8 M6 x 1-6H 2.51 104.8 4.13 104.8 M16 x 2-4H 2.51 104.8 4.13 104.8 M16 x 2-4H 2.51 104.8 4.13 104.8 M16 x 2-4H 2.51 104.8 4.13 104.8 M16 x 2-4H 2.51 104.8 4.13 104.8 M16 x 2-4H 2.51 104.8 4.13 104.8 M16 x 2-4H

MLC-250 250 25 MLC-500 500 50

112 150

MLC-1000 1000 100 225 150 MLC-1500 1500 150 337 150 MLC-2500 2500 250 562 150

MLC-5K

5000 500 1124 150

MLC-10K 10,000 1000 2248 150 MLC-25K 25,000 2500 5620 150 MLC-50K 50,000 5000 11,240 150

NOTES MLC Sensors cannot be used with FMM Test Frames or with S1 systems. Load measurement accuracy is ±0.05% of load cell capacity. Display resolution is 10,000:1. Height includes the base adapter

FLC-P Series - Force Measurement Premium Sensors

Load Capacity

Safe Overload Full Scale Deflection Height

Width

Thread

Model Number

N KGF LBF % Full Scale in

mm in

mm mm

FLC-5P FLC-10P FLC-25P FLC-50P FLC-100P FLC-250P

0.5 1

1000 1000 1000

0.014 0.4 0.012 0.3 0.011 0.3 0.009 0.2 0.007 0.2 0.006 0.2

2.48 63.0 2.33 59.2 M6 x 1-6H 2.48 63.0 2.33 59.2 M6 x 1-6H 2.48 63.0 2.33 59.2 M6 x 1-6H 2.48 63.0 2.33 59.2 M6 x 1-6H 2.48 63.0 2.33 59.2 M6 x 1-6H 2.48 63.0 2.33 59.2 M6 x 1-6H

10 1

25 2.5 5

50 5

11 1000

100 10 22 1000 250 25 56 1000

NOTES FLC-P Sensors cannot be used with FMM Test Frames or with S1 systems. Load measurement accuracy is ±0.1% of load cell capacity. Display resolution is 10,000:1.

FLC-E Series - Force Measurement Economy Sensors

Load Capacity

Safe Overload Full Scale Deflection Height

Width

Thread

Model Number

N KGF LBF % Full Scale in

mm in mm in

mm mm

FLC-50E FLC-100E FLC-200E FLC-500E

50 5

11 150

0.003 0.08 0.003 0.08 0.003 0.08 0.004 0.10 0.006 0.15 0.006 0.15 0.005 0.13 0.005 0.13

2.5 63.5 2.0 50.8 M6 x 1-6H 2.5 63.5 2.0 50.8 M6 x 1-6H 2.5 63.5 2.0 50.8 M6 x 1-6H 2.5 63.5 2.0 50.8 M6 x 1-6H 2.5 63.5 2.0 50.8 M6 x 1-6H 3.0 76.2 2.0 50.8 M6 x 1-6H 3.0 76.2 2.0 50.8 M6 x 1-6H 3.0 76.2 2.0 50.8 M6 x 1-6H

100 10 22 150 200 20 45 150 500 50 112 150

FLC-1000E 1000 100 225 150 FLC-2000E 2000 200 450 150 FLC-2500E 2500 250 562 150 FLC-5000E 5000 500 1124 150

NOTES FLC-E Sensors cannot be used with FMM Test Frames or with S1 systems. Load measurement accuracy is ±0.1% of load cell capacity. Display resolution is 10,000:1.

BLC Series - Basic Force Measurement S-beam Sensors (Use with FMM Test Frames and S1 Software only)

Load Capacity

Safe Overload Full Scale Deflection Height

Width

Thread

Model Number

N KGF LBF % Full Scale in

mm in mm in mm mm

BLC-2 BLC-5

10 1 20 2 50 5

2 5

150 150

0.009 0.22 0.008 0.21 0.007 0.18 0.007 0.18 0.006 0.15 0.003 0.08 0.003 0.08 0.005 0.13

3.0 76.2 3.0 76.2 M6 x 1-6H 3.0 76.2 3.0 76.2 M6 x 1-6H 3.0 76.2 3.0 76.2 M6 x 1-6H 2.0 50.8 2.0 50.8 M6 x 1-6H 2.0 50.8 2.0 50.8 M6 x 1-6H 2.0 50.8 2.0 50.8 M6 x 1-6H 2.0 50.8 2.0 50.8 M6 x 1-6H 2.0 50.8 2.0 50.8 M12 x 1.75-5H

BLC-10 BLC-20 BLC-50 BLC-100 BLC-200 BLC-500

10 150

100 10 20 150 250 25 50 150 500 50 110 150 1000 100 225 150 2500 250 550 150

NOTES BLC Sensors are to be used on FMM test frames and S1 systems. They may not be used with MMS, FMS, MMD or FMD test frames or with S2, L2Plus or L3 software. Load measurement accuracy is ±0.1% of load cell capacity. Display resolution is 10,000:1. Starrett recommends on-site verification of accuracy during installation. Sensor calibration should be performed at least annually.

G lossary of S pring T erms

Terms

Description

Active Coils Allow for Set

The coils that are free to deflect when under load.

Spring is supplied longer than specified to compensate for length loss when fully compressed.

Angular Relationship to Ends

The relative position of the plane of the hooks or loops of extension springs to each other.

Buckling

Bowing or lateral deflection of compression springs when compressed, related to the slenderness ratio (L/D). Ends of compression springs where pitch of the end coils is reduced so that the end coils touch.

Closed Ends

Closed & Ground Ends Same as with closed ends, except that the end is ground to provide a flat plane. Closed Length

Also called Solid Height. Height of a compression spring when under sufficient load to bring all the coils into contact with adjacent coils.

Close-Wound

Coiled with adjacent coils in contact.

Also called Pitch. The distance from center to center of the wire in adjacent active coils (recommended practice is to specify number of active coils rather than pitch).

Coils per Inch

Deflection

Motion of spring ends or arms under the application or removal of an external load. Maximum stress to which a material may be subjected without producing permanent set.

Elastic Limit

Endurance Limit

Maximum stress at which any given material will operate indefinitely without failure for a given minimum stress.

Free Length

The overall length of a spring in the unloaded position.

Gradient

Also called Rate. Change on load per unit deflection, generally given in pounds per inch or Newtons per millimeter.

Helix

The spiral form (open or closed) of compression, extension and torsion springs.

Hooks

Open loops or ends of extension springs.

The mechanical energy loss that always occurs under cyclic loading and unloading of a spring, proportional to the area between the loading and unloading load-deflection curves within the elastic range to a spring.

Hysteresis

Initial Tension

The force that keeps the coils of an extension spring closed and which must be overcome before the coils start to open.

Load

The force applied to a spring that causes a deflection.

Loops

Coil-like wire shapes at the end of extension springs that provide for attachment and force application.

Mean Coil Diameter Modulus in Shear

Outside spring diameter (O.D.) minus one wire diameter.

Coefficient of stiffness for extension and compression springs. Modulus in Tension Coefficient of stiffness used for torsion and flat springs (Young’s Modulus). Moment End of a compression spring with a constant pitch for each coil. Open and Ground End “Open ends, not ground” followed by an end grinding operation. Permanent Set Open Ends. Not Ground

Also called Torque. A twisting action in torsion springs which tends to produce rotation, equal to the load multiplied by the distance (or moment arm) from the load to the axis of the spring body. Usually expressed in inch-oz., inch-pounds or foot-pounds.

A material that is deflected so far that its elastic properties have been exceeded and it does not return to its original condition upon release of load is said to have taken a “permanent set”. The distance from center to center of the wire in adjacent active coils (recommended practice is to specify number of active coils rather than pitch).

Pitch

Preset

Full compression of a spring to solid state by manufacturer when needed to prevent length loss in operation. Change on load per unit deflection, generally given in pounds per inch or Newtons per millimeter. Full compression of a spring to solid state by manufacturer when needed to prevent length loss in operation.

Rate

Remove Set

Stresses induced by set removal, shot peening, cold working, forming and other means. These stresses may or may not be beneficial, depending on the application.

Residual Stress

Set

Length loss in operation due to the high stress condition of the spring.

Slenderness Ratio

Ratio of spring length (L) to mean coil diameter (D).

Solid Height Spring Index Stress Range Stress Relieve Shot Peened

Height of a compression spring when under sufficient load to bring all the coils into contact with adjacent coils.

Ratio of the mean coil diameter (D) to wire diameter (d).

The difference in operating stress at minimum and maximum loads.

To subject springs to low-temperature heat treatment so as to relieve residual stresses.

A cold working process in which the material surface is peened to induce compressive stresses and thereby improve fatigue life.

Squareness of Ends Angular deviation between the axis of a compression spring and a normal to the plane of the ends. Squareness Under Load Same as Squareness of Ends, except with the spring under load. Torque

A twisting action in torsion springs which tends to produce rotation, equal to the load multiplied by the distance (or moment arm) from the load to the axis of the spring body. Usually expressed in inch-oz., inch-pounds or foot-pounds.

Total Coils Wahl Factor

Number of active coils (n) plus the coils forming the ends.

A factor to correct stress in helical springs effects of curvation and direct shear.

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C ommon C ompression S pring T erminology Symbol Units Description Formula D mm, in Mean diameter D = De - d De mm, in External diameter De = D + d Di mm, in Internal diameter Di = D - d d mm, in Wire diameter d = De - D E, Mpa, PSI Modulus of elasticity E = δ/ε L1, L2 N, Lbf Target loads (related to target heights/lengths) Fc Th N, Lbf Theoretical load/force at set solid Fn N, Lbf Load/force related to Ln (smalled length) fe Hz Natural frequency k - Stress correction factor L0, FL mm, in Free length/height D1, D2 mm, in Target Length/distance (related to target loads) Lc mm, in Solid length Lc = d(n+ni+nm) Ld mm, in Length of wire Ld = p D [ 2 + nm + n / Cos(z)] LK mm, in Buckling length Ln mm, in Smallest allowed operating length (geometric) Ln = d (n + ni +nm) + Sa Lr mm, in Smalled allowed operating length (stress) M g, lb Mass M =Ld p π d 2 10 -3 / 4 m mm, in Spring pitch m = [ L0 - d (ni + nm) ]/n N Number of cycles n Number of active coils n = G d 4 / (8 R D 3 ) ni Coils related to the ends nm Number of dead coils nt Total number of coils nt = n + nm + 2 R, KSR N/mm, Lbf/in Spring Rate R = G d 4 / (8 n D 3 ) or (L1-L2) / (D1-D2) Rm Mpa, PSI Ultimate tensile strength Sh mm, in Spring travel Sh = D1 - D2 W Nmm, Joule Stored energy W = 0.5(L1+L2)(D1-D2) w - Spring index w = D / d

Closed and Ground Closed and ground ended com- pression springs are also com- mon but they are more expensive. Closed and ground ends will help your compression spring stand vertically straight on a flat surface when the slenderness ratio is too large.

Closed and Squared Closed and squared end com- pression springs are the most common. This end type allows the spring to stand vertically when placed on a flat surface. The last coil on either end is closed. This end type is suited for compres- sion springs with a low slender- ness ratio.

Open Ended Open ended compression springs are uncommon since the spring will not be able to stand unless supported by a shaft or mandrel. There is a pitch between each coil on an open ended compression spring.

Double Closed Double closed ends are very simi- lar to closed and squared ended compression springs. Instead of the spring having one closed coil at the ends, it has two. They are used to provide stability when your spring has a high slender- ness ratio. This end type helps prevent buckling.

C ommon S pring D esign M aterials

Corrosion Resistance

Material

Stress

Application

Brass

Low

Yes

Water resistant Electrical connectivity Corrosive environments Large diameters

Phosphor Bronze Low

Yes

Stainless Steel (302/304) Oil Tempered

Low

Yes

Medium

No No No

Hard Drawn MB Medium

Low cost

Music Wire

High

High stress

Hooks and Loops Extension springs make use of hooks or loops. Loops are closed while hooks have an open side or section.

C ommon E xtension S pring T erminology Symbol Units Description Formula A L0 mm, in Free length tolerance D mm, in Mean diameter D = De - d De mm, in External diameter De = D + d Di mm, in Internal diameter Di = D - d d mm, in Wire diameter d = De - D E, Mpa, PSI Modulus of elasticity E = δ/ε F0 N, Lbf Initial tension Pi = 2P1 - P2 L1, L2 N, Lbf Target loads (related to target heights/lengths) Fc Th N, Lbf Theoretical load/force at set solid Fn N, Lbf Load/force related to Ln (smalled length) fe Hz Natural frequency k - Stress correction factor L0, FL mm, in Free length/height D1, D2 mm, in Target Length/distance (related to target loads) Lc mm, in Solid length Lc = d(n+ni+nm) Ld mm, in Length of wire

Machine Hook and Loop Machine hooks are a common type of extension spring hook. These hooks are stronger than cross over center hooks because the radius of the bend to make the hook is not as pronounced.

No Hooks These types of ends have o

stress or fatigue on the ends of the extension spring. The amount of pulling force and distance increases and the life cycles re longer. No hooks have the ability to use a bolt to thread into the inner diameter of the extension or tension spring thus securing the ends of the spring

Ld = p D [ 2 + nm + n / Cos(z)]

mm, in Buckling length

mm, in Smallest allowed operating length (gemometric) Ln = d (n + ni +nm) + Sa

mm, in Smalled allowed operating length (stress)

M =Ld p π d 2 10 -3 / 4

M g, lb Mass

m mm, in Spring pitch

m = [ L0 - d (ni + nm) ]/n

N n ni

Number of cycles

n = G d 4 / (8 R D 3 )

Number of active coils Coils related to the ends Number of dead coils Total number of coils

nt = n + nm + 2

Extended Hooks Extended hook extension springs are very useful when you need a long length inside hooks but a short body length to get more force out of the spring through less coils. It is the most expensive hook type.

Crossover Center Hooks Crossover center type extension springs are very common. This type of hooks is made by lifting the last coil and twisting the coil towards the middle therefore crossing the center.

R = G d 4 / (8 n D 3 ) or (L1-L2) / (D1-D2)

R, KSR N/mm, Lbf/in Spring Rate

Rm Mpa, PSI Ultimate tensile strength Sh mm, in Spring travel

Sh = D1 - D2

W Nmm, Joule Stored energy

W = 0.5(L1+L2)(D1-D2)

Spring index

w = D / d

Side Hooks This hook type is used when

the body of the spring must not interfere with the components of a mechanism. This is due to the fact that the hooks are on one side of your spring therefore the other side of the spring is offset. They are made by simply bending the last coil so they are more economical than cross over center hooks

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software capabilities

L x S ystems

Lx System Product Comparisons and Capabilities Target Applications Use for Stress, Strain and Material Testing applications

L3 m m m m

L2 Plus

Use for Advanced Load, Distance and Force Analysis applications Use for Basic Load, Distance and Force Measurement applications Use for Advanced Extension and Compression Spring applications Use for Basic Extension and Compression Spring applications

m m m

User Interface All-In-On Computer Workstation, Windows ® OS

Tablet Computer, Windows ® OS Software Applications Test Builder Force Quick Test Templates Spring Quick Test Templates

m m

m  

Formula Builder

m 

 

Automation Builder

Measurement Methodology Measure results using the graph

m m m

Measure results using a List of Value menu

m m m m m m m

m  m    

Create Test Setups using Graphical Test Methods (No programming)

Create Test Setups using Quick-Test Templates Test Methods Tensile Testing, Load, Distance, Break, Rate Compression Testing, Load, Distance, Break, Rate Hold Testing, Load, Distance for Duration or Event Cyclic Testing for Duration, Count, Loop or Event

m m m m m m m m m m m m m m m m w w w m m m m m m m m m m m m

m m m m m m m m m

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Shear Testing Flexural Testing

Peel Testing

Coefficient of Friction Testing

Spring Testing

Measurement Capabilities Measure Stress, Strain, Elongation, Strengths

Measure Offset Yield

Measure Modulus (Elastic, Chord, Tangent)

Measure Strain and Elongation using Extensometer(s) (requires MMx test frames)

Measure Energy, Work, Resilience

m w w w w w m m m m m m m m m m m m

Create Mathematical Expressions using Algebraic, Trigonometric and Logarithmic functions

Create Basic Expressions using Add, Subtract, Multiple and Divide

w w

Use Digital I/O

Use Analog I/O (requires MMx test frames) Use Command and Conditional Logic

w m m

Measure Load, Distance, Time

m m

Measure Minimum, Maximum and Averages

Measure Slopes and Intersections

Measure Peaks, Valleys, Counts, Averages

Measure Break, Rupture

m m

Measure Delta between results within a test

Measure results within multiple test runs simultaneously (multiview)

Measure Spring Rate, Spring Constant, Free Length

Reporting and Exporting Data Print using standard reports, graph, batch, tolerance, statistics

m m m m

Export results/data in .csv for custom reporting

Export results/data in .csv for integration with SPC software

Include tolerances on any result

Note: L1 and S1 require a FMM frame. L3, L2 Plus, L2 and S2 software require a FMS, MMS, FMD or MMD frame

 = Standard  = Optional  = Requires Test Builder application w = Requires Automation Builder application

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1-Athol, Massachusetts, USA

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Waite Park USA

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Factories and Distribution Centers

Starrett Distribution Centers and Offices

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Suzhou China

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STARRETT PRODUCT LINES Band Saw Blades

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SPRING TESTING SOLUTIONS

Phone: (978) 249-3551 | Fax: (978) 249-8495 121 Crescent Street-Athol, MA 01331-1915-USA

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