36TDQSJ16 [COOPER]
Electric Fuse, 16A, 36000VAC, 36000VDC, 35500A (IR), Inline/holder;型号: | 36TDQSJ16 |
厂家: | COOPER BUSSMANN, INC. |
描述: | Electric Fuse, 16A, 36000VAC, 36000VDC, 35500A (IR), Inline/holder 电路保护 |
文件: | 总6页 (文件大小:715K) |
中文: | 中文翻译 | 下载: | 下载PDF数据表文档文件 |
3.6kV – 36kV High Voltage DIN Distribution Fuses
Edison fuses exhibit considerable limitation of current and
DIN Dimension Fuses To Specification
DIN 43.625
This product group covers current limiting fuses with
dimensions to DIN 43.625 and performance in compliance
with IEC 282-1.
2
I t under short-circuit conditions. The stress on circuit
components is thereby minimized and the reduction of
energy release at the fault reduces fire risks.
Switching (arc) voltages are appreciably less than
permitted values and fall with lower values of recovery
voltage. The use of, for example, 12kV fuse on 6/7.2kV
systems is therefore permissible.
Advantages of Edison High Voltage Current - Limiting
Fuses
The low power dissipation of Edison fuses ensures low
temperature rise of switchgear in which they are
incorporated.
Striker Characteristics
The spring operated striker pin has a travel and energy
output in compliance with the requirements of DIN 43625
and IEC 282-1.
The elements use the ‘M’ (metallurgical) effect, similar to
that used in low voltage fuses. This ensures that, with
melting on long time overloads, excessive temperatures are
not reached and damage to switchgear components, such
as epoxy encapsulating enclosures, is thus prevented.
Fuses that do not employ this feature are not only hotter
running by comparison but also usually need to employ a
higher current rating of fuse for the same service; thus an
Edison 40A fuse is equivalent in terms of thermal
Recommended Fuse Clipss:
Refer to page 122 in this catalog.
performance to many other types of 63A rating.
Dimensions - Inches (mm)
Striker In
Operated Position
0.59"
15.0mm
1.77"
45.0mm
1.02"
Length
1.34"
26.0mm
34.0mm
For Diameter and Length Dimensions See Table Above
For additional information, visit www.edisonfuse.com
118
3.6kV – 36kV High Voltage DIN Distribution Fuses
Circuit Protection
IR RMS Sym
Ratings and Dimensions
kV
Catalog Numbers
3.6ADOSJ(amp)
3.6WDOSJ(amp)
3.6WFOSJ(amp)
3.6ADLSJ(amp)
3.6WDLSJ(amp)
3.6WFLSJ(amp)
3.6WKLSJ(amp)
7.2TDLSJ(amp)
7.2TFLSJ(amp)
7.2WKMSJ(amp)
12TDLEJ(amp)
12THLEJ(amp)
12TKLEJ(amp)
12TXLEJ(amp)
17.5TDLSJ(amp)
17.5TFLSJ(amp)
17.5TDMEJ(amp)
17.5THMEJ(amp)
17.5TKMEJ(amp)
24TDMEJ(amp)
24THMEJ(amp)
24TFMEJ(amp)
24TXMEJ(amp)
36TDQSJ(amp)
36TFQSJ(amp)
36TXQEJ(amp)
Amp Ratings
Dimensions - in (mm) Diameter x Length
2.00 x 7.56 (51 x 192)
2.00 x 7.56 (51 x 192)
3.00 x 7.56 (76 x 192
6.3, 10, 16, 20, 25, 31.5, 40
50, 63, 80, 100, 125
160, 200
3.6
25, 40
2.00 x 11.50 (51 x 292)
2.00 x 11.50 (51 x 292)
3.00 x 11.50 (76 X 292)
3.00 x 11.50 (76 X 292)
2.00 x 11.50 (51 x 292)
3.00 x 11.50 (76 x 292)
3.00 x 17.41 (76 x 442)
2.00 x 11.50 (51 x 292)
2.52 x 11.50 (64 x 292)
3.00 x 11.50 (76 x 292)
3.50 x 11.50 (88 x 292)
2.00 x 11.50 (51 x 292)
3.00 x 11.50 (76 x 292)
2.00 x 17.41 (51 x 442)
2.52 x 17.41 (64 x 442)
3.00 x 17.41 (76 x 442)
2.00 x 17.41 (51 x 442)
2.52 x 17.41 (64 x 442)
3.00 x 17.41 (76 x 442)
3.46 x 17.41 (88 x 442)
2.00 x 21.16 (51 x 537)
3.00 x 21.16 (51 x 537)
3.46 x 21.16 (88 x 537)
50kA
50, 63, 80, 100, 125
160, 200
250, 315, 400
6.3, 10, 16, 20, 25, 31.5, 40, 50, 63
7.2
12
80, 100, 125, 160
200, 225, 250, 315, 355
6.3, 10, 16, 20, 25, 31.5, 40, 50, 63
80, 100
40kA
63kA
125
160, 200
6.3, 10, 16, 20, 25, 31.5, 40
50
50kA
35.5kA
17.5
24
6.3, 10, 16, 20, 25, 31.5, 40, 50, 63
80, 100
125
6.3, 10, 16, 20, 25, 31.5, 40, 50
63
50kA
50kA
80, 100
125, 160
3.15, 6.3, 10, 16, 20, 25
31.5kA
35.5kA
36
31.5, 40, 50
63
20kA
Time-Current Characteristics–Average
For 3.6kV Fuses:
• 3.6ADOS 3.6WDLS
• 3.6WDOS 3.6WFLS
• 3.6ADLS 3.6WKLS
For 7.2kV Fuses:
• 7.2TDLSJ
• 7.2TFLSJ
• 7.2WKMSJ
CURVES RELATE TO MEAN PRE-ARCING TIME
WITH TOLERANCE 10% ON CURRENT
FUSE TYPES: TDL / TFL
TIME- CURRENT CHARACTERISTIC
FOR 7.2kV FUSE-LINKS
4
CURVES RELATE TO MEAN PRE_ARCING TIMES WITH A TOLERANCE OF 10% ON CURRENT
10000
1000
100
10
HOUR
3
160A
125A
100A
80A
63A
50A
40A
31.5A
25A
1
20A
16A
10A
10A
6.3A
0.1
6.3A
3.15A*
0.01
10
100
1000
10000
R.M.S. SYMMETRICAL PROSPECTIVE CURENT IN AMPS
RMS SYMMETICAL PROSPECTIVE CURRENT IN AMPS
*
†
Curve valid for all 3.15A ratings shown in the selection table.
Curve valid for all 6.3A ratings shown in the selection table.
For additional information, visit www.edisonfuse.com
119
3.6kV – 36kV High Voltage DIN Distribution Fuses
Time-Current Characteristics–Average
For 12kV Fuses:
• 12TDLEJ
• 12THLEJ
• 12TKLEJ
• 12TXLEJ
FUSE TYPES: THM / TKM / TFM
TIME- CURRENT CHARACTERISTIC
FOR 12kV FUSE-LINKS
FUSE TYPES: TDL/THL/TKL
TIME- CURRENT CHARACTERISTIC
FOR 12kV FUSE-LINKS
CURVES RELATE TO MEAN PRE_ARCING TIMES WITH A TOLERANCE OF 10% ON CURRENT
10000
1000
100
10
CURVES RELATE TO MEAN PRE_ARCING TIMES WITH A TOLERANCE OF 10% ON CURRENT
10000
1000
100
10
160A (TFM)
125A (TKM)
100A (THM)
125A
100A
80A
63A
50A
40A
31.5A
25A
20A
16A
10A
6.3A
1
1
0.1
0.1
0.01
10
100
1000
10000
R.M.S. SYMMETRICAL PROSPECTIVE CURENT IN AMPS
0.01
10
100
1000
10000
R.M.S. SYMMETRICAL PROSPECTIVE CURENT IN AMPS
FUSE TYPES: TXL
TIME- CURRENT CHARACTERISTIC
FOR 12kV FUSE-LINKS
CURVES RELATE TO MEAN PRE_ARCING TIMES WITH A TOLERANCE OF 10% ON CURRENT
10000
1000
100
10
160A
200A
1
0.1
0.01
10
100
1000
10000
R.M.S. SYMMETRICAL PROSPECTIVE CURENT IN AMPS
For additional information, visit www.edisonfuse.com
120
3.6kV – 36kV High Voltage DIN Distribution Fuses
Circuit Protection
Time-Current Characteristics–Average
For 17.5kV Fuses: • 17.5TDLSJ
• 17.5TFLSJ
• 17.5THMEJ
• 17.5TKMEJ
• 17.5TDMEJ
FUSE TYPES: TDL
TIME- CURRENT CHARACTERISTIC
FOR 17.5kV FUSE-LINKS
FUSE TYPES: TDM/THM/TKM
TIME- CURRENT CHARACTERISTIC
FOR 17.5kV FUSE-LINKS
CURVES RELATE TO MEAN PRE_ARCING TIMES WITH A TOLERANCE OF 10% ON CURRENT
CURVES RELATE TO MEAN PRE_ARCING TIMES WITH A TOLERANCE OF 10% ON CURRENT
10000
1000
100
10
10000
1000
100
10
125A
100A
80A
6.3A
10A
16A
20A
25A
63A
50A
40A
31.5A
25A
20A
31.5A
40A
16A
10A
6.3A
1
1
0.1
0.1
0.01
10
100
1000
10000
0.01
R.M.S. SYMMETRICAL PROSPECTIVE CURENT IN AMPS
10
100
1000
10000
R.M.S. SYMMETRICAL PROSPECTIVE CURENT IN AMPS
FUSE TYPES: TFL
TIME- CURRENT CHARACTERISTIC
FOR 17.5kV FUSE-LINKS
CURVES RELATE TO MEAN PRE_ARCING TIMES WITH A TOLERANCE OF 10% ON CURRENT
10000
1000
100
10
1
50A
0.1
0.01
10
100
1000
10000
R.M.S. SYMMETRICAL PROSPECTIVE CURENT IN AMPS
For additional information, visit www.edisonfuse.com
121
3.6kV – 36kV High Voltage DIN Distribution Fuses
Average Time-Current Curves
DIN Fuseclips
Suitable for use with all DIN HV fuses having 45mm
For 24-27.6kV Fuses:
• 24TDMEJ
• 24THMEJ
• 24TXMEJ
end fittings.
• 24TFMEJ
FUSE TYPES: TDM/THM/TFM
TIME- CURRENT CHARACTERISTIC
FOR 24kV FUSE-LINKS
A
0.99"
25.0mm
CURVES RELATE TO MEAN PRE_ARCING TIMES WITH A TOLERANCE OF 10% ON CURRENT
10000
1000
100
10
80A
63A
50A
40A
4.06"
103mm
31.5A
25A
20A
16A
10A
6.3A
1
0.43"
0.1
10.8mm
A
Part No. 270303
For Standard Duty (up to 200A)
0.01
10
100
1000
10000
R.M.S. SYMMETRICAL PROSPECTIVE CURENT IN AMPS
FUSE TYPES: TFM / TXM
TIME- CURRENT CHARACTERISTIC
FOR 24kV FUSE-LINKS
1.5"
38.1mm
0.38"
9.5mm
CURVES RELATE TO MEAN PRE_ARCING TIMES WITH A TOLERANCE OF 10% ON CURRENT
10000
1000
100
10
4.50"
114.3mm
100A
125A
160A
3.50"
88.9mm
1.77"
45.0mm
1
2.5"
63.5mm
1.19"
30.2mm
0.1
Part No. A3354745
Heavy Duty
0.01
10
100
1000
10000
R.M.S. SYMMETRICAL PROSPECTIVE CURENT IN AMPS
For additional information, visit www.edisonfuse.com
122
High Voltage DIN Distribution Fuses
Circuit Protection
General Guide to the Selection of Fuses.
For use in the Primary Circuit of Three-Phase Transformers
Transformer
3-ph kVA
Fuse kV
System kV
25
Fuse Reference and Rating in Amps
3.6kV
2.4kV
7.2kV
12kV
10kV
17.5kV
13.8kV
24kV
4.16kV
TDLSJ 10
TDLSJ 10
TDLSJ 16
TDLSJ 16
TDLSJ 20
TDLSJ 25
TDLSJ 25
TDLSJ 31.5
TDLSJ 31.5
TDLSJ 40
TDLSJ 50
TDLSJ 50
TDLSJ 63
TDLSJ 80
TFLSJ 80
TFLSJ 100
TFLSJ 125
TFLSJ 160
WKMSJ 200
WKMSJ 250
WKMSJ 315
–
6.9kV
12.47kV
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 16
TDMEJ 16
TDMEJ 16
TDMEJ 20
TDMEJ 31.5
TDMEJ 31.5
TDMEJ 31.5
TDMEJ 40
TDMEJ 50
TDMEJ 63
TDMEJ 80
TDMEJ 100
TKMEJ 125
–
13.2kV
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 16
TDMEJ 16
TDMEJ 16
TDMEJ 20
TDMEJ 25
TDMEJ 31.5
TDMEJ 31.5
TDMEJ 40
TDMEJ 50
TDMEJ 63
TDMEJ 80
TDMEJ 100
TKMEJ 125
–
15.5kV
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 16
TDMEJ 16
TDMEJ 20
TDMEJ 20
TDMEJ 25
TDMEJ 31.5
TDMEJ 31.5
TDMEJ 40
TDMEJ 50
TDMEJ 63
TDMEJ 80
TDMEJ 100
TKMEJ 125
20kV
24kV
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 20
TDMEJ 20
TDMEJ 20
TDMEJ 20
ADLSJ 16
ADLSJ 16
ADLSJ 20
ADLSJ 20
ADLSJ 31.5
ADLSJ 40
ADLSJ 40
ADLSJ 40
WDLSJ 50
WDLSJ 50
WDLSJ 63
WDLSJ 80
WDLSJ 100
WDLSJ 125
WFLSJ 160
WFLSJ 160
WFLSJ 200
WKLSJ 250
WKLSJ 315
WKLSJ 400
–
TDLSJ 6.3
TDLSJ 6.3
TDLSJ 10
TDLSJ 10
TDLSJ 16
TDLSJ 16
TDLSJ 20
TDLSJ 20
TDLSJ 25
TDLSJ 25
TDLSJ 31.5
TDLSJ 40
TDLSJ 40
TDLSJ 50
TDLSJ 63
TDLSJ 63
TFLSJ 80
TFLSJ 80
TFLSJ 125
TSFLSJ 160
TFLSJ 160
WKMSJ 250
WKMSJ 315
TDLEJ 6.3
TDLEJ 6.3
TDLEJ 6.3
TDLEJ 6.3
TDLEJ 10
TDLEJ 10
TDLEJ 10
TDLEJ 16
TDLEJ 16
TDLEJ 16
TDLEJ 20
TDLEJ 20
TDLEJ 25
TDLEJ 31.5
TDLEJ 40
TDLEJ 40
TDLEJ 50
TDLEJ 63
THLEJ 80
THLEJ 100
TKLEJ 125
–
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 16
TDMEJ 16
TDMEJ 16
TDMEJ 20
TDMEJ 25
TDMEJ 31.5
TDMEJ 31.5
TDMEJ 40
TDMEJ 40
TDMEJ 63
TDMEJ 80
TDMEJ 80
TKMEJ 125
–
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 6.3
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 10
TDMEJ 16
TDMEJ 20
TDMEJ 20
TDMEJ 25
TDMEJ 25
30
40
45
63
75
100
112
125
150
200
225
300
400
450
500
600
750
TDMEJ 31.5 TDMEJ 25
1000
1250
1500
2000
2500
TDMEJ 40
TDMEJ 31.5
TDMEJ 50
TDMEJ 40
THMEJ 63
TDMEJ 50
–
–
–
–
–
–
–
–
Selection of these fuses has been based on a compromise between the following:
1. The fuse should withstand transformer magnetizing inrush currents, taken as 12 times full load current for 0.1 second.
2. The fuse should coordinate with the highest rating of the secondary fuse likely to be used.
3. The fuse should operate reasonably quickly in the event of a transformer inter-turn fault or a fault in the secondary terminal zone of the transformer.
NOTES:
A. In general, the recommendations apply equally to the use of fuse in open air or in an encapsulated enclosure, since “1” and “2” above dictate the use of a
fuse current rating sufficiently above the transformer current rating to nullify any adverse thermal affect of encapsulation. However, if the transformer is
subjected to long time overcurrents, a higher rate of fuse may be required.
B. The above recommendations are not generally applicable to transformers feeding motor circuits with starting currents in excess of the rated current of the
fuse. In this event, please consult your local Edison representative.
C. Recommendations for other voltages are available on request.
D. While the above recommendations give a good general guide, recommendations for specific cases will be sent on receipt of full details of the application.
For additional information, visit www.edisonfuse.com
123
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