Return to site
Return to site

Totalspaces 2 8 6 Mm

broken image


  1. Totalspaces 2 8 6 Mm Equals
  2. Totalspaces 2 8 6 Mm =
  3. Totalspaces 2 8 6 Mm In Inches Chart Conversion
  4. Totalspaces 2 8 6 Mm Inches

6.4mm: 7 mm: 7.6mm: 8 mm: 9.2mm: 10.5 mm: 12.5 mm: 14 mm: 14.8 mm: 16.8 mm: 18.8 mm: Base Diameter. Ifinance 4 3 3 – comprehensively manage your personal finances. Base Diameter; 3/8 ' 1/2 ' 9/16 ' 45/64 ' 23/32 ' 3/4 ' 7/8 ' 29. 6 x 4 mm.5 carat: 6 x 5 mm.7 carat: 4 x 2 mm.10 carat: 7 x 5 mm: 1.0 carat: 7 x 5 mm.75 carat: 5 x 2.5 mm.25 carat: 8 x 6 mm: 1.5 carat: 8 x 5 mm: 1.0 carat: 6 x 3 mm. Choose from our selection of metric spacers, including over 10,000 products in a wide range of styles and sizes. In stock and ready to ship. 3/8 X 1/2 X 3/4 STEEL SPACERS Our Price: $2.56 Quantity Discounts: Quantity Discounts. 25 Price: $1.920 Quantity: Add to cart: 3/8 X 3/4 X 3/4 STEEL SPACERS.

Deutsche Version

Conversion and calculation − cross section < > diameter

Cable diameter to circle cross-sectional areaand vice versa ●

Round electric cable
Totalspaces 2 8 6 mm inches
, conductor, wire, cord, string,wiring, and rope

Cross section is just a two-dimensional view of a slice through an object.
An often asked question: How can you convert the diameter of a round wire d = 2 × r to the
circle cross section surface or the cross-section area A (slice plane) to the cable diameter d?
Why is the diameter value greater than the area value? Because that's not the same.
Resistance varies inversely with the cross-sectional area of a wire.

The required cross-section of an electrical line depends on the following factors:
1) Rated voltage. Net form. (Three-phase (DS) / AC (WS))
2) Fuse - Upstream backup = Maximum permissible current (Amp)
3) On schedule to be transmittedpower (kVA)
4) Cable length in meters (m)
5) Permissible voltage drop (% of the rated voltage)
6) Line material. Copper (Cu) or aluminum (Al)
The used browser does not support JavaScript.
You will see the program but the function will not work.

The 'unit' is usually millimeters but it can also be inches, feet, yards, meters (metres),
or centimeters, when you take for the area the square of that measure.

Litz wire (stranded wire) consisting of many thin wires need a 14 % larger diameter compared to a solid wire.

Cross sectional area is not diameter.



Cross section is an area.
Diameter is a linear measure.
That cannot be the same.

The cable diameter in millimeters
is not the cable cross-section in
square millimeters.

The cross section or the cross sectional area is the area of such a cut.
It need not necessarily have to be a circle.

Commercially available wire (cable) size as cross sectional area:
0.75 mm2, 1.5 mm2, 2.5 mm2, 4 mm2, 6 mm2, 10 mm2, 16 mm2.
Calculation of the cross section A, entering the diameter d = 2 r:
r = radius of the wire or cable
d = 2 r = diameter of the wire or cable
Calculation of the diameter d = 2 r, entering the cross section A:

Totalspaces 2 8 6 Mm Equals

The conductor (electric cable)
There are four factors that affect the resistance of a conductor:
1) the cross sectional area of a conductor A, calculated from the diameter d
2) the length of the conductor
3) the temperature in the conductor
4) the material constituting the conductor

There is no exact formula for the minimum wire size from the maximum amperage.
It depends on many circumstances, such as for example, if the calculation is for DC, AC or
even for three-phase current, whether the cable is released freely, or is placed under the
ground. Also, it depends on the ambient temperature, the allowable current density, and the
allowable voltage drop, and whether solid or litz wire is present. And there is always the
nice but unsatisfactory advice to use for security reasons a thicker and hence more
expensive cable. Common questions are about the voltage drop on wires.

Voltage drop Δ V

Totalspaces 2 8 6 Mm =

The voltage drop formula with the specific resistance (resistivity) ρ (rho) is:


Δ V = I × R = I × (2 × l × ρ/ A)

I = Current in ampere
l = Wire (cable) length in meters (times 2, because there is always a return wire)
ρ = rho, electrical resistivity (also known as specific electrical resistance or volume
resistivity) of copper = 0.01724 ohm×mm2/m (also Ω×m)
(Ohms for l = 1 m length and A = 1 mm2 cross section area of the wire)ρ = 1 / σ
A = Cross section area in mm2
σ = sigma, electrical conductivity (electrical conductance) of copper = 58 S·m/mm2

Quantity of resistance
R = resistance Ω
ρ = specific resistance Ω×m
l = double length of the cable m
A = cross sectionmm2

Free slot games on facebook. The derived SI unit of electrical resistivity ρ is Ω ×m, shortened from the clear Ω ×mm² / m.
The reciprocal of electrical resistivity is electrical conductivity.

Electrical conductivity and electrical resistivity κ or σ = 1/ρ
Electrical conductance and electrical resistance ρ = 1/κ = 1/σ
Electrical
conductor		Electrical conductivity
Electrical conductance		Electrical resistivity
Specific resistance
silverσ = 62 S·m/mm²ρ = 0.0161 Ohmmm²/m
copperσ = 58 S·m/mm²ρ = 0.0172 Ohmmm²/m
goldσ= 41 S·m/mm²ρ = 0.0244 Ohmmm²/m
aluminiumσ = 36 S·m/mm²ρ = 0.0277 Ohmmm²/m
constantanσ= 2.0 S·m/mm²ρ = 0.5000 Ohmmm²/m

Difference between electrical resistivity and electrical conductivity

The conductance in siemens is the reciprocal of the resistance in ohms.

To use the calculator, simply enter a value.
The calculator works in both directions of the sign.

The value of the electrical conductivity (conductance) and the specific electrical resistance
(resistivity) is a temperature dependent material constant. Mostly it is given at 20 or 25°C.

Resistance = resistivity x length / area

The specific resistivity of conductors changes with temperature.
In a limited temperature range it is approximately linear:
where α is the temperature coefficient, T is the temperature and T0 is any temperature,
such as T0 = 293.15 K = 20°C at which the electrical resistivity ρ (T0) is known.

Convert resistance to electrical conductance
Conversion of reciprocal siemens to ohms
1 ohm [Ω] = 1 / siemens [1/S]
1 siemens [S] = 1 / ohm [1/Ω]

To use the calculator, simply enter a value.
The calculator works in both directions of the sign.

Totalspaces 2 8 6 Mm In Inches Chart Conversion

1 millisiemens = 0.001 mho = 1000 ohms

Mathematically, conductance is the reciprocal, or inverse, of resistance:
The symbol for conductance is the capital letter 'G' and the unit is the
mho, which is 'ohm' spelled backwards. Later, the unit mho was
replaced by the unit Siemens − abbreviated with the letter 'S'.

Table of typical loudspeaker cables

Cable diameter d0.798 mm0.977 mm1.128 mm1.382 mm1.784 mm2.257 mm2.764 mm3.568 mm
Cable nominal cross section A0.5 mm20.75 mm21.0 mm21.5 mm22.5 mm24.0 mm26.0 mm210.0 mm2
Maximum electrical current3 A 7.6 A 10.4 A 13.5 A 18.3 A 25 A 32 A -

Always consider, the cross section must be made larger with higher power and higher length of
the cable, but also with lesser impedance. Here is a table to tell the possible power loss.

Cable length
in m		 Section
in mm2		Resistance
in ohm		Power loss at Damping factor at
Impedance
8 ohm		Impedance
4 ohm		Impedance
8 ohm		Impedance
4 ohm
10.750.0420.53%1.05%9849
1.500.0210.31%0.63%12362
2.500.0130.16%0.33%15175
4.000.0080.10%0.20%16783
20.750.0841.06%2.10%6533
1.500.0420.62%1.26%8543
2.500.0260.32%0.66%11356
4.000.0160.20%0.40%13366
50.750.2102.63%5.25%3216
1.500.1251.56%3.13%4824
2.500.0650.81%1.63%7638
4.000.0400.50%1.00%10050
100.750.4205.25%10.50%179
1.500.2503.13%6.25%2814
2.500.1301.63%3.25%4724
4.000.0801.00%2.00%6733
200.750.84010.50%21.00%95
1.500.5006.25%12.50%157
2.500.2603.25%6.50%2713
4.000.1602.00%4.00%4020

The damping factor values show, what remains of an accepted damping factor of 200
depending on the cable length, the cross section, and the impedance of the loudspeaker.
Conversion and calculation of cable diameter to AWG
and AWG to cable diameter in mm - American Wire Gauge

The gauges we most commonly use are even numbers, such as 18, 16, 14, etc.
If you get an answer that is odd, such as 17, 19, etc., use the next lower even number.

AWG stands for American Wire Gauge and refers to the strength of wires.
These AWG numbers show the diameter and accordingly the cross section as a code.
They are only used in the USA. Sometimes you find AWG numbers also in catalogues
and technical data in Europe.

American Wire Gauge - AWG Chart

Totalspaces 2 8 6 Mm Inches

AWG
number		46454443424140393837363534
Diameter
in inch		0.00160.00180.00200.00220.00240.00270.00310.00350.00400.00450.00500.00560.0063
Diameter (Ø)
in mm		0.040.050.050.060.060.070.080.090.100.110.130.140.16
Cross section
in mm2		0.00130.00160.00200.00250.00290.00370.00490.00620.00810.010 0.013 0.016 0.020

AWG
number		33323130292827262524232221
Diameter
in inch		0.00710.00790.00890.01000.01130.01260.01420.01590.01790.02010.02260.02530.0285
Diameter (Ø)
in mm		0.180.200.230.250.290.320.360.400.450.510.570.640.72
Cross section
in mm2		0.0260.0320.0400.0510.0650.0800.100.130.160.200.260.320.41

AWG
number		201918171615141312111098
Diameter
in inch		0.03190.03590.04030.04530.05080.05710.06410.07190.08080.09070.10190.11440.1285
Diameter (Ø)
in mm		0.810.911.021.151.291.451.631.832.052.302.592.913.26
Cross section
in mm2		0.520.650.821.01.31.72.12.63.34.25.36.68.4

AWG
number		76543210
(1/0)
(0)		00
(2/0)
(-1)		000
(3/0)
(-2)		0000
(4/0)
(-3)		00000
(5/0)
(-4)		000000
(6/0)
(-5)
Diameter
in inch		0.14430.16200.18190.20430.22940.25760.28930.32490.36480.40960.46000.51650.5800
Diameter (Ø)
in mm		3.674.114.625.195.836.547.358.259.2710.4011.6813.1314.73
Cross section
in mm2		10.613.316.821.126.733.642.453.567.485.0107.2135.2170.5

back Search Engine home

English • العربية • български • català • čeština • Deutsch • Ελληνικά • español • فارسی • français • hrvatski • magyar • italiano • română • 日本語 • 한국어 • lietuvių • Nederlands • norsk • polski • português • русский • Türkçe • українська • 中文(中国大陆)‎ • 中文(台灣)‎ • עברית • azərbaycanca •

NEMA 17 Stepper motor

Vitamin

A NEMA 17 sized stepper motor.
WikipediaStepper motor


Macfamilytree 9 the best in genealogy v9 0 10.

another NEMA-17 size motor


A NEMA 17 stepper motor Double u casino gratis. is a stepper motor with a 1.7 x 1.7 inch (43.18 x 43.18 mm) faceplate. The NEMA 17 is larger and generally heavier than for example a NEMA 14, but this also means it has more room to put a higher torque. However, its size is not an indication of its power.

Dimensions


Common Stepper Motor Models

The most commonly used stepper motors in Reprap–based 3D printers are the Kysan 1124090/42BYGH4803, Rattm 17HS8401, and Wantai 42BYGHW609.

However, motors close to NEMA 17 size, with approximately the following specifications, can also work:

  • 1.5A to 1.8A current per phase
  • 1-4 volts
  • 3 to 8 mH inductance per phase
  • 44 N·cm (62oz·in, 4.5kg·cm) or more holding torque
  • 1.8 or 0.9 degrees per step (200/400 steps/rev respectively)

You are welcome to add information on any stepper motor you encounter, but please add only steppers (not other motors), which were tested to actually work on some or all printers.

Totalspaces 2 8 6 Mm
, conductor, wire, cord, string,wiring, and rope

Cross section is just a two-dimensional view of a slice through an object.
An often asked question: How can you convert the diameter of a round wire d = 2 × r to the
circle cross section surface or the cross-section area A (slice plane) to the cable diameter d?
Why is the diameter value greater than the area value? Because that's not the same.
Resistance varies inversely with the cross-sectional area of a wire.

The required cross-section of an electrical line depends on the following factors:
1) Rated voltage. Net form. (Three-phase (DS) / AC (WS))
2) Fuse - Upstream backup = Maximum permissible current (Amp)
3) On schedule to be transmittedpower (kVA)
4) Cable length in meters (m)
5) Permissible voltage drop (% of the rated voltage)
6) Line material. Copper (Cu) or aluminum (Al)
The used browser does not support JavaScript.
You will see the program but the function will not work.

The 'unit' is usually millimeters but it can also be inches, feet, yards, meters (metres),
or centimeters, when you take for the area the square of that measure.

Litz wire (stranded wire) consisting of many thin wires need a 14 % larger diameter compared to a solid wire.

Cross sectional area is not diameter.



Cross section is an area.
Diameter is a linear measure.
That cannot be the same.

The cable diameter in millimeters
is not the cable cross-section in
square millimeters.

The cross section or the cross sectional area is the area of such a cut.
It need not necessarily have to be a circle.

Commercially available wire (cable) size as cross sectional area:
0.75 mm2, 1.5 mm2, 2.5 mm2, 4 mm2, 6 mm2, 10 mm2, 16 mm2.
Calculation of the cross section A, entering the diameter d = 2 r:
r = radius of the wire or cable
d = 2 r = diameter of the wire or cable
Calculation of the diameter d = 2 r, entering the cross section A:

Totalspaces 2 8 6 Mm Equals

The conductor (electric cable)
There are four factors that affect the resistance of a conductor:
1) the cross sectional area of a conductor A, calculated from the diameter d
2) the length of the conductor
3) the temperature in the conductor
4) the material constituting the conductor

There is no exact formula for the minimum wire size from the maximum amperage.
It depends on many circumstances, such as for example, if the calculation is for DC, AC or
even for three-phase current, whether the cable is released freely, or is placed under the
ground. Also, it depends on the ambient temperature, the allowable current density, and the
allowable voltage drop, and whether solid or litz wire is present. And there is always the
nice but unsatisfactory advice to use for security reasons a thicker and hence more
expensive cable. Common questions are about the voltage drop on wires.

Voltage drop Δ V

Totalspaces 2 8 6 Mm =

The voltage drop formula with the specific resistance (resistivity) ρ (rho) is:


Δ V = I × R = I × (2 × l × ρ/ A)

I = Current in ampere
l = Wire (cable) length in meters (times 2, because there is always a return wire)
ρ = rho, electrical resistivity (also known as specific electrical resistance or volume
resistivity) of copper = 0.01724 ohm×mm2/m (also Ω×m)
(Ohms for l = 1 m length and A = 1 mm2 cross section area of the wire)ρ = 1 / σ
A = Cross section area in mm2
σ = sigma, electrical conductivity (electrical conductance) of copper = 58 S·m/mm2

Quantity of resistance
R = resistance Ω
ρ = specific resistance Ω×m
l = double length of the cable m
A = cross sectionmm2

Free slot games on facebook. The derived SI unit of electrical resistivity ρ is Ω ×m, shortened from the clear Ω ×mm² / m.
The reciprocal of electrical resistivity is electrical conductivity.

Electrical conductivity and electrical resistivity κ or σ = 1/ρ
Electrical conductance and electrical resistance ρ = 1/κ = 1/σ
Electrical
conductor		Electrical conductivity
Electrical conductance		Electrical resistivity
Specific resistance
silverσ = 62 S·m/mm²ρ = 0.0161 Ohmmm²/m
copperσ = 58 S·m/mm²ρ = 0.0172 Ohmmm²/m
goldσ= 41 S·m/mm²ρ = 0.0244 Ohmmm²/m
aluminiumσ = 36 S·m/mm²ρ = 0.0277 Ohmmm²/m
constantanσ= 2.0 S·m/mm²ρ = 0.5000 Ohmmm²/m

Difference between electrical resistivity and electrical conductivity

The conductance in siemens is the reciprocal of the resistance in ohms.

To use the calculator, simply enter a value.
The calculator works in both directions of the sign.

The value of the electrical conductivity (conductance) and the specific electrical resistance
(resistivity) is a temperature dependent material constant. Mostly it is given at 20 or 25°C.

Resistance = resistivity x length / area

The specific resistivity of conductors changes with temperature.
In a limited temperature range it is approximately linear:
where α is the temperature coefficient, T is the temperature and T0 is any temperature,
such as T0 = 293.15 K = 20°C at which the electrical resistivity ρ (T0) is known.

Convert resistance to electrical conductance
Conversion of reciprocal siemens to ohms
1 ohm [Ω] = 1 / siemens [1/S]
1 siemens [S] = 1 / ohm [1/Ω]

To use the calculator, simply enter a value.
The calculator works in both directions of the sign.

Totalspaces 2 8 6 Mm In Inches Chart Conversion

1 millisiemens = 0.001 mho = 1000 ohms

Mathematically, conductance is the reciprocal, or inverse, of resistance:
The symbol for conductance is the capital letter 'G' and the unit is the
mho, which is 'ohm' spelled backwards. Later, the unit mho was
replaced by the unit Siemens − abbreviated with the letter 'S'.

Table of typical loudspeaker cables

Cable diameter d0.798 mm0.977 mm1.128 mm1.382 mm1.784 mm2.257 mm2.764 mm3.568 mm
Cable nominal cross section A0.5 mm20.75 mm21.0 mm21.5 mm22.5 mm24.0 mm26.0 mm210.0 mm2
Maximum electrical current3 A 7.6 A 10.4 A 13.5 A 18.3 A 25 A 32 A -

Always consider, the cross section must be made larger with higher power and higher length of
the cable, but also with lesser impedance. Here is a table to tell the possible power loss.

Cable length
in m		 Section
in mm2		Resistance
in ohm		Power loss at Damping factor at
Impedance
8 ohm		Impedance
4 ohm		Impedance
8 ohm		Impedance
4 ohm
10.750.0420.53%1.05%9849
1.500.0210.31%0.63%12362
2.500.0130.16%0.33%15175
4.000.0080.10%0.20%16783
20.750.0841.06%2.10%6533
1.500.0420.62%1.26%8543
2.500.0260.32%0.66%11356
4.000.0160.20%0.40%13366
50.750.2102.63%5.25%3216
1.500.1251.56%3.13%4824
2.500.0650.81%1.63%7638
4.000.0400.50%1.00%10050
100.750.4205.25%10.50%179
1.500.2503.13%6.25%2814
2.500.1301.63%3.25%4724
4.000.0801.00%2.00%6733
200.750.84010.50%21.00%95
1.500.5006.25%12.50%157
2.500.2603.25%6.50%2713
4.000.1602.00%4.00%4020

The damping factor values show, what remains of an accepted damping factor of 200
depending on the cable length, the cross section, and the impedance of the loudspeaker.
Conversion and calculation of cable diameter to AWG
and AWG to cable diameter in mm - American Wire Gauge

The gauges we most commonly use are even numbers, such as 18, 16, 14, etc.
If you get an answer that is odd, such as 17, 19, etc., use the next lower even number.

AWG stands for American Wire Gauge and refers to the strength of wires.
These AWG numbers show the diameter and accordingly the cross section as a code.
They are only used in the USA. Sometimes you find AWG numbers also in catalogues
and technical data in Europe.

American Wire Gauge - AWG Chart

Totalspaces 2 8 6 Mm Inches

AWG
number		46454443424140393837363534
Diameter
in inch		0.00160.00180.00200.00220.00240.00270.00310.00350.00400.00450.00500.00560.0063
Diameter (Ø)
in mm		0.040.050.050.060.060.070.080.090.100.110.130.140.16
Cross section
in mm2		0.00130.00160.00200.00250.00290.00370.00490.00620.00810.010 0.013 0.016 0.020

AWG
number		33323130292827262524232221
Diameter
in inch		0.00710.00790.00890.01000.01130.01260.01420.01590.01790.02010.02260.02530.0285
Diameter (Ø)
in mm		0.180.200.230.250.290.320.360.400.450.510.570.640.72
Cross section
in mm2		0.0260.0320.0400.0510.0650.0800.100.130.160.200.260.320.41

AWG
number		201918171615141312111098
Diameter
in inch		0.03190.03590.04030.04530.05080.05710.06410.07190.08080.09070.10190.11440.1285
Diameter (Ø)
in mm		0.810.911.021.151.291.451.631.832.052.302.592.913.26
Cross section
in mm2		0.520.650.821.01.31.72.12.63.34.25.36.68.4

AWG
number		76543210
(1/0)
(0)		00
(2/0)
(-1)		000
(3/0)
(-2)		0000
(4/0)
(-3)		00000
(5/0)
(-4)		000000
(6/0)
(-5)
Diameter
in inch		0.14430.16200.18190.20430.22940.25760.28930.32490.36480.40960.46000.51650.5800
Diameter (Ø)
in mm		3.674.114.625.195.836.547.358.259.2710.4011.6813.1314.73
Cross section
in mm2		10.613.316.821.126.733.642.453.567.485.0107.2135.2170.5

back Search Engine home

English • العربية • български • català • čeština • Deutsch • Ελληνικά • español • فارسی • français • hrvatski • magyar • italiano • română • 日本語 • 한국어 • lietuvių • Nederlands • norsk • polski • português • русский • Türkçe • українська • 中文(中国大陆)‎ • 中文(台灣)‎ • עברית • azərbaycanca •

NEMA 17 Stepper motor

Vitamin

A NEMA 17 sized stepper motor.
WikipediaStepper motor


Macfamilytree 9 the best in genealogy v9 0 10.

another NEMA-17 size motor


A NEMA 17 stepper motor Double u casino gratis. is a stepper motor with a 1.7 x 1.7 inch (43.18 x 43.18 mm) faceplate. The NEMA 17 is larger and generally heavier than for example a NEMA 14, but this also means it has more room to put a higher torque. However, its size is not an indication of its power.

Dimensions


Common Stepper Motor Models

The most commonly used stepper motors in Reprap–based 3D printers are the Kysan 1124090/42BYGH4803, Rattm 17HS8401, and Wantai 42BYGHW609.

However, motors close to NEMA 17 size, with approximately the following specifications, can also work:

  • 1.5A to 1.8A current per phase
  • 1-4 volts
  • 3 to 8 mH inductance per phase
  • 44 N·cm (62oz·in, 4.5kg·cm) or more holding torque
  • 1.8 or 0.9 degrees per step (200/400 steps/rev respectively)

You are welcome to add information on any stepper motor you encounter, but please add only steppers (not other motors), which were tested to actually work on some or all printers.

Model Holding Torque Rated voltage Shaft Step angle Motor length Rated current Inductance
17HS08-1104S 13 N·cm 3.5 V Single 1.8° 20 mm 1.0A 4.5±20% mH
42HS02 22 N·cm 1.8° 40 mm 0,4A 21±20% mH
42HS03 BiPolar Parallel 47 N·cm 1.8° 48 mm 1,4A 4±20% mH
42HS03 BiPolar Series 47 N·cm 1.8° 48 mm 0,7A 16±20% mH
42HS03 UniPolar 34 N·cm 1.8° 48 mm 1.0A 4±20% mH
42HSC8402-25B, 42HSC8402-15B11 60 N·cm 3.0 V Ø 5 mm Single 1.8° 60 mm 1.5A 4.5±20% mH
42HT47 44 N·cm 2.8 V Ø 5 mm Dual 1.8° 47 mm
42SHD0404-22 52 N·cm 3.84 V Ø 5 mm Single 1.8° 48 mm
42SHDC3025-24B 40 N·cm 3.96 V Ø 5 mm Single 1.8° 40 mm 0.9A
42SHDC4047Z-23B 34 N·cm 3.96 V Ø 5 mm Single 1.8° 40 mm 0.9A
42SHD3418-24B15 50 N·cm 3.75 V Ø 5 mm Single 1.8° 40 mm 1.5A 5.0 mH
42BYGH4803(SKU 1124030) 54.0 N·cm 4.2 V Ø 5 mm single 1.8° 48 mm
42BYGH4803-DC (SKU 1124090) 54.0 N·cm 4.2 V Ø 5 mm single 1.8° 48 mm
LDO-42STH47-1684A 50 N·cm 2.8 V Ø 5 mm single or dual 1.8° 47 mm 1.68A 2.8 mH
LDO-42STH47-1684AC 50 N·cm 2.8 V Ø 5 mm single or dual 1.8° 47 mm 1.68A 2.8 mH
4118S-62-07 31 N·cm Ø 5 mm 1.8° 34 mm
17HS4417 40.0 N·cm 2.6 V Ø 5 mm single 1.8° 40 mm 1.7A 2.8 mH
SM-42BYG011-25 23.0 N·cm 12 V Ø 5 mm single 1.8° 34 mm 0.33A 46 mH[1]
17HS1011-20B 28.0 N·cm 4.8 V Ø 5 mm single 1.8° 34 mm
17HS3001-20B 40.0 N·cm 2.0 V Ø 5 mm single 1.8° 40 mm 1.2 A 4.5 mH
17HS5005-S24 44.0 N·cm 3 V Ø 5 mm double 1.8° 48 mm
17HS6002-27B 65.0 N·cm 4.05 V Ø 5 mm single flat 1.8° 60 mm
17HD2038E 45.0 N·cm Ø 5 mm single 1.8°
17HS19-1684S 55 N·cm 2.8 V Ø 5 mm single 1.8° 47 mm 1.68A 2.8mH
KH42JM2B087C 33 N·cm 6.7 V Ø 5 mm single 1.8° 42 mm
SY42STH47-1206A 31.1 N·cm 4.0 V Ø 5 mm single 1.8° 40 mm 1.2A 2.8 mH
SY42STH47-1504A 55.0 N·cm 2.8 V Ø 5 mm 1.8° 47 mm
SY42STH47-1684A 43.1 N·cm 2.8 V Ø 5 mm single 1.8° 48 mm
SY42STH47-1684B 43.1 N·cm 2.8 V Ø 5 mm double 1.8° 48 mm
SL42STH40-1684A 40 N·cm 2.8 V Ø 5 mm single 1.8° 40 mm 1.68A 3.2 mH
TB35HT36-1004A 35.3 N·cm 2.8 V Ø 5 mm single 1.8° 36 mm
TB35HT36-1004B 35.3 N·cm 2.8 V Ø 5 mm double 1.8° 36 mm
QSH4218-51-049 49 N·cm Ø 5 mm 1.8° 47 mm
42BYGH W811 47.0 N·cm 3.1 V Ø 5 mm 1.8° 48 mm 2.5A 1.8 mH
42HB34F103AB 23.5 N·cm Ø 5 mm single 1.8° 34 mm
42SHD0412-175S 44 N·cm 2.8 V Ø 8mm mm dual L175mm 1.8º 44 mm
1704HS168A 54 N·cm 2.8 V Ø 5 mm single flat 1.8° 48 mm 1.68A 2.8mH
1703HS168A 44 N·cm 2.8 V Ø 5 mm single flat 1.8° 40 mm 1.68A 3.6mH
1704HD150AW 55 N·cm 4.2 V Ø 5 mm single flat 1.8° 48 mm
JK42HS34-1334AC 22 N·cm 2.8 V Ø 5 mm single flat 1.8° 34 mm 1.33A 2.5mH
17HS16-2004S1 45 N·cm - Ø 5 mm single flat 1.8° 40 mm 2A 2.6mH
17HS24-1206S 65 N·cm - Ø 5 mm single flat 1.8° 60 mm 1.2A 7mH
17HS6002-N27BA 65 N·cm 4.05 V Ø 5 mm single flat 1.8° 60 mm 1.5A 6.5mH
17HS8401B 52 N·cm - Ø 5 mm double 1.8° 48 mm 1.8A 3.2mH

0.9° Stepper Motor Models

Model Holding Torque Rated voltage Shaft Step angle Motor length Rated current Inductance
42BYGHM809 48 N·cm 3.06 V Ø 5 mm no flat 0.9° 48 mm 1.7A 2.8mH
17HM19-2004S 46 N·cm - Ø 5 mm 0.9° 48 mm 2A 3mH

Geared stepper

Model Holding Torque Rated voltage Shaft Step angle Motor length Rated current Inductance Gear ratio
1040222 220 N·cm 2.6 V Ø 8 mm single flat 1.8° 34+27 mm 1A 3.5 mH 5.2:1
17HS1070-C5X 260 N·cm 2 V Ø 8 mm single flat 1.8° 34+27 mm 1.3A 2.4 mH 5:1
1702HS040-AWP518 260 N·cm 12 V Ø 8 mm single flat 1.8° 34+31 mm 0.4A 37 mH 5.18:1
  1. With such inductance, this stepper is incapable of any speed and is unusable for a printer, as are most very low current steppers.
Retrieved from 'https://reprap.org/mediawiki/index.php?title=NEMA_17_Stepper_motor&oldid=188151'




broken image
PreviousNext
Cookie Use
We use cookies to improve browsing experience, security, and data collection. By accepting, you agree to the use of cookies for advertising and analytics. You can change your cookie settings at any time. Learn More
Accept all
Settings
Decline All
Cookie Settings
Necessary Cookies
These cookies enable core functionality such as security, network management, and accessibility. These cookies can’t be switched off.
Analytics Cookies
These cookies help us better understand how visitors interact with our website and help us discover errors.
Preferences Cookies
These cookies allow the website to remember choices you've made to provide enhanced functionality and personalization.
Save