RGE500_技术文档

RGE Selection Guide

and Product Data

This section has two parts:

• A Selection Guide that walks you through the process of

selecting the correct RGE device for a circuit.

• Product Data that outlines electrical characteristics,

physical characteristics, agency recognitions, environmental

specifications, component layouts, tape and reel specifications,

and ordering information for RGE devices.

RGE Selection Guide

Follow these seven steps to select a PolySwitch RGE device for

a circuit:

1. Define the operating parameters for the circuit.

These include:

• Maximum ambient operating temperature

• Normal operating current

• Maximum operating voltage (RGE is 16 V maximum)

• Maximum interrupt current

4

2. Select the RGE device that accommodates the circuit’s maximum

ambient operating temperature and normal operating current.

3. Compare the RGE device’s maximum operating voltage and maxi-

mum interrupt current with the circuit’s to be sure the circuit does

not exceed the device ratings.

4. Check the RGE device’s time-to-trip be to sure it will protect the

circuit.

5. Verify that the circuit’s ambient operating temperatures are within

the RGE device’s operating temperature range.

6. Verify that the RGE device’s dimensions fit the application’s space

considerations.

7. Independently evaluate and test the suitability and performance

of the RGE device in the application.

®

TUV Rheinland

Raychem Circuit Protection Devices

RGE Devices 129

RGE

Radial Leaded

1. Define the circuit’s operating parameters.

Fill in the following information about the circuit:

Maximum ambient operating temperature

Normal operating current

______________

Maximum operating voltage (RGE is 16 V max.)

Maximum interrupt current

2. Select the PolySwitch RGE device that will accommodate the

circuit’s maximum ambient operating temperature and

normal operating current.

Look across the top of the table below to find the temperature that

most closely matches the circuit’s maximum ambient operating temper-

ature. Look down that column to find the value equal to or greater than

the circuit’s normal operating current. Now look to the far left of that

row to find the part number for the RGE device that will best accommo-

date the circuit.

4

The thermal derating curve located on the next page is a normalized

representation of the data in the table below.

I_Holdvs. temperature

Maximum ambient operating temperatures (°C)

Part

number –40°

–20°

4.0

0°

3.6

20°

3.1

25°

3.0

40°

2.6

50°

2.4

3.2

4.0

4.8

5.6

6.4

7.2

8.0

8.8

9.6

11.2

60°

2.1

2.8

3.6

4.2

5.0

5.6

6.4

7.0

7.8

8.4

9.8

70°

1.9

2.5

3.1

3.8

4.4

5.1

5.6

6.3

6.9

7.6

8.9

85°

1.4

1.9

2.4

2.8

3.3

3.7

4.2

4.7

5.2

5.6

6.5

RGE300

RGE400

RGE500

RGE600

4.4

5.9

7.3

8.8

New

5.3

4.8

4.1

4.0

3.5

6.6

6.0

5.2

5.0

4.4

8.0

7.2

6.2

6.0

5.2

RGE700 10.3

RGE800 11.7

RGE900 13.2

RGE1000 14.7

RGE1100 16.1

RGE1200 17.6

RGE1400 20.5

9.3

8.4

7.3

7.0

6.2

New

10.7

11.9

13.3

14.6

16.0

18.7

9.6

8.3

8.0

6.9

10.7

12.0

13.1

14.4

16.8

9.4

9.0

7.9

10.3

11.5

12.4

14.5

10.0

11.0

12.0

14.0

8.7

9.7

New

10.4

12.1

130 RGE Devices

Raychem Circuit Protection Devices

RGE

Radial Leaded

Thermal derating curve

200

150

100

50

0

–40

–20

0

20

40

60

80

Device’s ambient temperature (°C)

3. Compare maximum operating voltages and maximum

interrupt currents.

Look down the first column of the table below to find the part number

you selected in Step 1. Look to the right in that row to find the device’s

maximum operating voltage (V max.) and maximum interrupt current

4

(I

).

max.

Compare both ratings with the circuit’s to be sure the circuit’s ratings

do not exceed those of the RGE device.

Maximum device voltages and currents*

Part

V

I

max.

number

(volts)

(amps)

100

RGE300

RGE400

RGE500

RGE600

RGE700

RGE800

RGE900

RGE1000

RGE1100

RGE1200

RGE1400

16

New

16

New

16

New

16

*Device may withstand higher interrupt current at lower voltages. Each application will need to be

individually qualified.

Raychem Circuit Protection Devices

RGE Devices 131

RGE

Radial Leaded

4. Determine time-to-trip.

Time-to-trip is the amount of time it takes for a device to switch to a

high-resistance state once a fault current has been applied across the

device.

Identifying the RGE device’s time-to-trip is important in order to provide

the desired protection capabilities. If the device you choose trips

too fast, undesired or nuisance tripping will occur. If the device trips

too slowly, the components being protected may be damaged before

the device switches to a high-resistance state.

The chart below shows the typical time-to-trip at 25°C for each

PolySwitch RGE device. For example, the chart indicates that the typi-

cal time-to-trip for RGE500 at 10 A is 10 seconds.

On the chart below, find the typical time-to-trip for the RGE device you

selected. If the RGE device’s time-to-trip is too fast or too slow for the

circuit, go back to Step 2 and choose an alternate device.

Typical time-to-trip at 25°C

4

A

B C D EFGH I J K

1000

A = RGE300

B = RGE400

C = RGE500

D = RGE600

E = RGE700

F = RGE800

G = RGE900

H = RGE1000

I = RGE1100

J = RGE1200

K = RGE1400

100

10

1

0

.01

.001

1

10

100

Fault current (A)

132 RGE Devices

Raychem Circuit Protection Devices

RGE

Radial Leaded

5. Verify ambient operating conditions.

Ensure that your application’s minimum and maximum ambient

temperatures are within the operating temperature range of –40°C

and 85°C.

Maximum device surface temperature in the tripped state is 125°C.

6. Verify the RGE device’s dimensions.

Using dimensions from the table below, compare the dimensions of the

RGE device you selected with the application’s space considerations.

Product dimensions (millimeters/inches)

Part

number

A

max.

B

max.

C

typ.

D

min.

E

max.

F

typ.

RGE300

RGE400

RGE500

RGE600

RGE700

RGE800

RGE900

RGE1000

7.1 (0.28)

8.9 (0.35)

11.0 (0.43)

12.8 (0.50)

14.3 (0.56)

17.1 (0.67)

19.7 (0.78)

20.9 (0.82)

21.7 (0.85)

24.1 (0.95)

26.0 (1.02)

28.0 (1.10)

27.9 (1.10)

5.1 (0.20)

5.2 (0.20)

5.1 (0.20)

10.2 (0.40)

7.6 (0.30)

3.0 (0.12)

3.6 (0.14)

3.4 (0.13)

1.2 (0.05)

1.4 (0.06)

New

10.4 (0.41)

10.7 (0.42)

11.2 (0.44)

12.7 (0.50)

14.0 (0.55)

16.5 (0.65)

4

RGE1100 17.5 (0.69)

New

RGE1200

RGE1400

17.5 (0.69)

27.9 (1.10)

RGE300–RGE1400*

A

E

Lead Size

RGE300–RGE1100

0.81

(0.032)

Marking

B

D

* Kinked leads are

available for

RGE300 - RGE1400

20 AWG

RGE1200–RGE1400

1.0

(0.040)

18 AWG

C

F

C

L

Raychem Circuit Protection Devices

RGE Devices 133

RGE

Radial Leaded

RGE Product Data

Now that you have selected your RGE device, please review the

device’s characteristics in this section to verify that the device will

perform as required.

Electrical characteristics (25°C)

Initial

Post-trip

resistance

R min.

( Ω )

resistance

Max. time

to trip (s)

Part

Number

I

P_d

(W)

R max.

1

H

T

(A)

at 5xI

( Ω )

H

RGE300

RGE400

RGE500

RGE600

RGE700

RGE800

RGE900

RGE1000

RGE1100

RGE1200

RGE1400

3.0

5.1

2.0

2.3

2.4

2.6

2.8

3.0

3.3

3.7

4.2

4.6

0.034

0.020

0.014

0.009

0.006

0.005

0.004

0.003

0.002

0.105

0.063

0.044

0.030

0.021

0.018

0.015

0.012

0.010

0.009

0.008

New

4.0

6.8

3.5

5.0

8.5

3.6

New

6.0

10.2

11.9

13.6

15.3

17.0

18.7

20.4

23.8

5.8

7.0

8.0

9.0

12.0

12.5

13.5*

16.0

20.0

10.0

11.0

12.0

14.0

New

4

I

= Hold current—maximum current at which the device will not trip at 25°C.

= Trip current—minimum current at which the device will always trip at 25°C.

= Typical power dissipation—typical amount of power dissipated by the device when in tripped state in 25°C still air.

H

T

P

d

R min. = Minimum device resistance at 25°C prior to tripping.

R max. = Maximum device resistance at 25°C prior to tripping.

R

max. = Maximum device resistance at 25°C measured 1 hour post trip.

1

* Device tested at 60 A.

Physical characteristics

Lead material

RGE300—RGE1100: Tin lead-plated copper, 20 AWG, 0.81 mm/0.032 in

RGE1200—RGE1400: Tin lead-plated copper, 18AWG, 1.0 mm/0.04 in

Solderability per ANSI/J-STD-002

Soldering characteristics

Solder heat withstand per IEC 68-2-20:

RGE300, Test T^b; should be soldered to the printed circuit in less than

4 seconds at maximum temperature of 260°C ± 5°.

RGE500—RGE1400, Test Tb; can withstand 10 seconds at 260°C ±5°.

Insulating material

Cured, flame-retardant epoxy polymer; meets UL 94V-0 requirements

Note: Devices are not designed to be placed through a reflow process.

Agency recognitions

CSA

File # CA 78165C

Certificate # R9677540

File # E74889

¨

TUV

UL

134 RGE Devices

Raychem Circuit Protection Devices

RGE

Radial Leaded

Environmental specifications

Resistance

change

Test

Test method

Conditions

Passive aging

Raychem PS300

–40°C, 1000 hours

±5%

85°C, 1000 hours

±5%

Humidity aging

Thermal shock

Solvent resistance

Raychem PS300

85°C, 85% R.H., 1000 hours

85°C, –40°C (10 times)

MIL-STD-202, Method 215F

±5%

Raychem PS300

±5%

Raychem PS300, Method 215

No change

Component layouts

The dimensions in the table below provide the component layout for

each RGE device.

Component layout dimensions (millimeters/inches)

A

nom.

B

max.

B

A

Device

B

4

RGE300

RGE400

RGE500

RGE600

RGE700

RGE800

RGE900

RGE1000

RGE1100

RGE1200

RGE1400

5.1 (0.20)

10.2 (0.40)

1.2 (0.05)

1.4 (0.06)

1.6 (0.06)

1.7 (0.07)

1.8 (0.07)

2.0 (0.08)

2.4 (0.09)

1.5 (0.06)

1.9 (0.07)

New

Raychem Circuit Protection Devices

RGE Devices 135

RGE

Radial Leaded

RGE tape and reel specifications (dimensions in millimeters)

Product availability: RGE300–RGE700 (consult factory for higher hold current parts).

Devices taped using EIA468-B/IEC286-2 standards. See table below and Figures 1 and 2 for details.

Dimensions

Dimension

description

EIA

mark

IEC

mark

Dim. (mm)

Tol. (mm)

–0.5/+1.0

min.

Carrier tape width

W

W₄

W₆

W₅

D₀

H

W

18

Hold down tape width

W0

W₂

W₁

D₀

H

11

Top distance between tape edges

Sprocket hole position

3

max.

9

–0.5/+0.75

±0.2

Sprocket hole diameter

Abscissa to plane (straight lead)*

Abscissa to top RGE300 - RGE600

Abscissa to top RGE700*

Overall width w/lead protrusion RGE300 - RGE600

Overall width w/lead protrusion RGE700

Overall width w/o lead protrusion

Lead protrusion

4

18.5

±3.0

H₁

C₁

C₂

L₁

L

H₁

32.2

max.

36

max.

43.2

max.

C₁

46

max.

42.5

max.

I₁

L

1.0

max.

Protrusion of cut-out

11

max.

Protrusion beyond hold-down tape

Sprocket hole pitch

l₂

Not specified

P₀

12.7

±0.3

4

Device pitch

12.7

Pitch tolerance

20 consec.

±1

Tape thickness

t

0.9

max.

±0.3

±1.0

±1.3

±1.0

±0.8

max.

±3.25

±12.0

max.

Tape thickness with splice*

Splice sprocket hole alignment

Body lateral deviation

t₁

2.0

0

∆h

∆p

P₁

F

∆h

∆p

P₁

F

0

Body tape plane deviation

Ordinate to adjacent component lead*

Lead spacing*

0

3.81

5.08

56

Reel width RGE300–RGE500

Reel width RGE600–RGE700*

Reel diameter

w₂

a

w

63.5

370

d

Space between flanges less device*

Arbor hole diameter

w₁

c

4.75

26

f

Core diameter*

n

h

91

Box

56/372/372

None

0.1% max.

Consecutive missing places

Empty places per reel

*Differs from EIA specification

136 RGE Devices

Raychem Circuit Protection Devices

RGE

Radial Leaded

Figure 1: EIA Referenced Taped Component Dimensions

∆h

∆p

Reference plane

P₁

H₁

H₁C₁

C₂

F

H

H₀

A

B

L

W₅

W₄

W

I₂

D₀

P₀

Direction of unreeling

Cross section A - B

L₁

t

4

Figure 2: Reel Dimensions

Reel

Upper side

Tape

n

Direction

a

of

unreeling

Lower side

c

w

1

2

Cross section

Optional shape: Circular or polygonal

w

Raychem Circuit Protection Devices

RGE Devices 137

RGE

Radial Leaded

Ordering information

Product

Bag

Tape and reel AMMO

Standard

package

description

quantity

pack

2000

RGE300

500

10000

12500

10000

12500

10000

7500

RGE300-2

RGE300-AP

2500

New

RGE400

New

RGE400-2

2500

2000

1500

New

RGE400-AP

RGE500

RGE500-2

RGE500-AP

New

RGE600

New

RGE600-2

New

RGE600-AP

RGE700

RGE700-2

RGE700-AP

1500

7500

New

RGE800

500

*

10000

5000

RGE900

*

New

RGE1000

4

RGE1100

*

5000

New

RGE1200

5000

New

RGE1400

5000

*Consult Factory

Part numbering system

RGE

suffix

Blank = Packaged in bags

-2

= Tape and reel

= AMMO pack

= 25.4-mm (1.0-inch) minimum lead length

= Kinked leads

-AP

-1

K

Current rating

138 RGE Devices

Raychem Circuit Protection Devices

RGE

Radial Leaded

Part marking system

V

- 16

V

16

G500

MN8F

Voltage rating

Raychem symbol

G

Part ID

Example

Product family (RGE)

Lot number/Date code (may be on the back)

Part

description

Part

ID

RGE300

RGE400

RGE500

RGE600

RGE700

RGE800

RGE900

RGE1000

RGE1100

RGE1200

RGE1400

300

New

400

500

New

600

700

4

800

900

New

1000

1100

1200

1400

New

WARNING:

• Operation beyond maximum ratings or improper use may result

in device damage and possible electrical arcing and flame.

• These devices are intended for protection against occasional over-

current or overtemperature fault conditions, and should not be used

when repeated fault conditions are anticipated.

• Operation in circuits with inductive spikes can generate voltages

above the rated voltage of the devices and should be evaluated

for suitability.

Raychem Circuit Protection Devices

RGE Devices 139


型号：	RGE500
厂家：	ETC
描述：	MULTISICHERUNG RGE 5.0A 5ST MULTISICHERUNG RGE 5.0A 5ST\n
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RGE500 [ETC]

相关型号：

RGE500-1

RGE500-2

RGE500-AP

RGE500K

RGE600

RGE600-1

RGE600-2

RGE600-AP

RGE600K

RGE700

RGE700-1

RGE700-2