Product Description
NHF Hydraulic Safety Coupling With Flange
Description of NHF Hydraulic Safety Coupling With Flange
1.Simple and convenient assembly and disassembly;
2.No keyway and thrust ring are required on the shaft;
3.The stress on the entire contact surface is relatively uniform, and the stress concentration is not obvious;
4.When the vibration load of the shaft system changes, the shaft will not be worn;
5.The position of the coupling on the shaft is easy to ensure, and the connection accuracy is high;
6.Can be used repeatedly, with high interchangeability.
Dimensions of NHF Hydraulic Safety Coupling With Flange
|
|
d |
D |
L |
L1 |
Df |
Dc |
R |
t |
n |
ds |
Mt |
Mass |
|
mm |
mm |
mm |
mm |
mm |
mm |
mm |
mm |
mm |
kNm |
kg |
||
|
NHF100 |
100 |
170 |
215 |
40 |
265 |
230 |
9 |
21 |
8 |
19 |
26 |
26 |
|
NHF110 |
110 |
186 |
235 |
45 |
295 |
255 |
10 |
23 |
8 |
21 |
35 |
34 |
|
NHF120 |
120 |
202 |
250 |
50 |
315 |
275 |
11 |
25 |
8 |
23 |
46 |
42 |
|
NHF130 |
130 |
218 |
270 |
55 |
340 |
295 |
11 |
27 |
8 |
25 |
58 |
52 |
|
NHF140 |
140 |
234 |
290 |
60 |
355 |
310 |
12 |
29 |
10 |
24 |
72 |
64 |
|
NHF150 |
150 |
250 |
300 |
60 |
380 |
335 |
13 |
31 |
10 |
26 |
89 |
75 |
|
NHF160 |
160 |
266 |
320 |
65 |
405 |
355 |
14 |
33 |
10 |
28 |
108 |
91 |
|
NHF170 |
170 |
282 |
340 |
70 |
430 |
375 |
15 |
35 |
10 |
30 |
130 |
108 |
|
NHF180 |
180 |
298 |
355 |
75 |
440 |
390 |
15 |
37 |
12 |
29 |
154 |
124 |
|
NHF190 |
190 |
314 |
375 |
80 |
465 |
410 |
16 |
39 |
12 |
30 |
181 |
145 |
|
NHF200 |
200 |
330 |
390 |
80 |
490 |
435 |
17 |
41 |
12 |
32 |
211 |
167 |
|
NHF210 |
210 |
346 |
410 |
85 |
515 |
455 |
18 |
43 |
12 |
33 |
244 |
193 |
|
NHF220 |
220 |
362 |
425 |
90 |
535 |
475 |
19 |
45 |
12 |
35 |
281 |
219 |
|
NHF230 |
230 |
378 |
445 |
95 |
560 |
495 |
19 |
47 |
12 |
37 |
321 |
249 |
|
NHF240 |
240 |
394 |
465 |
100 |
580 |
515 |
20 |
49 |
12 |
38 |
365 |
282 |
|
NHF250 |
250 |
410 |
475 |
100 |
605 |
535 |
21 |
51 |
12 |
40 |
412 |
313 |
|
NHF260 |
260 |
426 |
495 |
105 |
630 |
560 |
22 |
53 |
12 |
42 |
464 |
352 |
|
NHF270 |
270 |
442 |
515 |
110 |
655 |
580 |
23 |
55 |
12 |
43 |
519 |
394 |
|
NHF280 |
280 |
458 |
530 |
115 |
675 |
600 |
23 |
57 |
12 |
45 |
579 |
434 |
|
NHF290 |
290 |
474 |
550 |
120 |
700 |
620 |
24 |
59 |
12 |
46 |
644 |
483 |
|
NHF300 |
300 |
490 |
565 |
120 |
720 |
640 |
25 |
61 |
12 |
48 |
713 |
528 |
|
NHF310 |
310 |
506 |
580 |
125 |
750 |
665 |
26 |
63 |
12 |
50 |
786 |
582 |
|
NHF320 |
320 |
522 |
600 |
130 |
770 |
685 |
27 |
65 |
12 |
51 |
865 |
638 |
|
NHF330 |
330 |
538 |
620 |
135 |
795 |
705 |
27 |
67 |
12 |
53 |
948 |
700 |
|
NHF340 |
340 |
554 |
635 |
140 |
815 |
725 |
28 |
69 |
12 |
54 |
1037 |
759 |
|
NHF350 |
350 |
570 |
650 |
140 |
840 |
745 |
29 |
71 |
12 |
56 |
1131 |
823 |
|
NHF360 |
360 |
586 |
670 |
145 |
835 |
750 |
30 |
73 |
16 |
50 |
1231 |
878 |
|
|
d |
D |
L |
L1 |
Df |
Dc |
R |
t |
n |
ds |
Mt |
Mass |
|
mm |
mm |
mm |
mm |
mm |
mm |
mm |
mm |
mm |
kNm |
kg |
||
|
NHF370 |
370 |
602 |
690 |
150 |
855 |
770 |
31 |
75 |
16 |
51 |
1337 |
951 |
|
NHF380 |
380 |
618 |
705 |
155 |
880 |
790 |
31 |
77 |
16 |
53 |
1448 |
1026 |
|
NHF390 |
390 |
634 |
725 |
160 |
900 |
810 |
32 |
79 |
16 |
54 |
1565 |
1108 |
|
NHF400 |
400 |
650 |
740 |
160 |
930 |
835 |
33 |
81 |
16 |
56 |
1689 |
1194 |
|
NHF410 |
410 |
666 |
755 |
165 |
950 |
855 |
34 |
83 |
16 |
57 |
1819 |
1277 |
|
NHF420 |
420 |
682 |
775 |
170 |
975 |
875 |
35 |
85 |
16 |
58 |
1955 |
1376 |
|
NHF430 |
430 |
698 |
795 |
175 |
995 |
895 |
35 |
87 |
16 |
60 |
2098 |
1474 |
|
NHF440 |
440 |
714 |
810 |
180 |
1571 |
915 |
36 |
89 |
16 |
61 |
2248 |
1574 |
|
NHF450 |
450 |
730 |
825 |
180 |
1040 |
935 |
37 |
91 |
16 |
63 |
2405 |
1674 |
|
NHF460 |
460 |
746 |
845 |
185 |
1060 |
955 |
38 |
93 |
16 |
64 |
2569 |
1787 |
|
NHF470 |
470 |
762 |
860 |
190 |
1085 |
975 |
39 |
95 |
16 |
65 |
2740 |
1900 |
|
NHF480 |
480 |
778 |
880 |
195 |
1105 |
995 |
39 |
97 |
16 |
67 |
2918 |
2571 |
|
NHF490 |
490 |
794 |
900 |
200 |
1130 |
1015 |
40 |
99 |
16 |
68 |
3105 |
2156 |
|
NHF500 |
500 |
810 |
910 |
200 |
1150 |
1035 |
41 |
101 |
16 |
70 |
3299 |
2267 |
|
NHF510 |
510 |
826 |
930 |
205 |
1175 |
1055 |
42 |
103 |
16 |
71 |
3501 |
2411 |
|
NHF520 |
520 |
842 |
950 |
210 |
1195 |
1075 |
43 |
105 |
16 |
72 |
3711 |
2554 |
|
NHF530 |
530 |
858 |
965 |
215 |
1220 |
1095 |
43 |
107 |
16 |
74 |
3929 |
2698 |
|
NHF540 |
540 |
874 |
985 |
220 |
1240 |
1115 |
44 |
109 |
16 |
75 |
4155 |
2852 |
|
NHF550 |
550 |
890 |
1000 |
220 |
1270 |
1140 |
45 |
111 |
16 |
77 |
4391 |
3014 |
|
NHF560 |
560 |
906 |
1571 |
225 |
1290 |
1160 |
46 |
113 |
16 |
78 |
4634 |
3180 |
|
NHF570 |
570 |
922 |
1035 |
230 |
1310 |
1180 |
47 |
115 |
16 |
79 |
4887 |
3338 |
|
NHF580 |
580 |
938 |
1055 |
235 |
1335 |
1200 |
47 |
117 |
16 |
81 |
5149 |
3524 |
|
NHF590 |
590 |
954 |
1075 |
240 |
1355 |
1220 |
48 |
119 |
16 |
82 |
5420 |
3708 |
|
NHF600 |
600 |
970 |
1085 |
240 |
1380 |
1240 |
49 |
121 |
16 |
84 |
5700 |
3877 |
|
NHF610 |
610 |
986 |
1105 |
245 |
1400 |
1260 |
50 |
123 |
16 |
85 |
5990 |
4072 |
|
NHF620 |
620 |
1002 |
1125 |
250 |
1425 |
1280 |
51 |
125 |
16 |
86 |
6289 |
4284 |
|
NHF630 |
630 |
1018 |
1140 |
255 |
1445 |
1300 |
51 |
127 |
16 |
88 |
6599 |
4477 |
|
NHF640 |
640 |
1034 |
1160 |
260 |
1465 |
1320 |
52 |
129 |
16 |
89 |
6918 |
4692 |
|
NHF650 |
650 |
1050 |
1175 |
260 |
1495 |
1345 |
53 |
131 |
16 |
91 |
7247 |
4917 |
|
NHF660 |
660 |
1066 |
1190 |
265 |
1515 |
1365 |
54 |
133 |
16 |
92 |
7587 |
5128 |
|
NHF670 |
670 |
1082 |
1210 |
270 |
1540 |
1385 |
55 |
135 |
16 |
93 |
7937 |
5375 |
|
NHF680 |
680 |
1098 |
1230 |
275 |
1560 |
1405 |
55 |
137 |
16 |
95 |
8298 |
5618 |
|
NHF690 |
690 |
1114 |
1245 |
280 |
1585 |
1425 |
56 |
139 |
16 |
96 |
8669 |
5860 |
|
NHF700 |
700 |
1130 |
1260 |
280 |
1605 |
1445 |
57 |
141 |
16 |
98 |
9052 |
6097 |
/* January 22, 2571 19:08:37 */!function(){function s(e,r){var a,o={};try{e&&e.split(“,”).forEach(function(e,t){e&&(a=e.match(/(.*?):(.*)$/))&&1
How Does a Flange Coupling Handle Angular, Parallel, and Axial Misalignment?
A flange coupling is designed to accommodate various types of misalignment that may occur between two shafts. Here’s how it handles different types of misalignment:
- Angular Misalignment: Flange couplings can handle angular misalignment by allowing a slight flexing or bending of the flexible elements. The coupling’s flexible components, such as elastomeric or metallic elements, can bend and compensate for angular misalignment between the shafts. This flexibility ensures that the coupling can transmit torque smoothly even when the shafts are not perfectly aligned in a straight line.
- Parallel Misalignment: Flange couplings can also accommodate parallel misalignment between the shafts. When the two shafts are slightly offset in a parallel direction, the flexible elements in the coupling can move laterally to accommodate this misalignment. This lateral movement helps prevent excessive forces and wear on the coupling and connected equipment, ensuring efficient power transmission even in slightly misaligned conditions.
- Axial Misalignment: Axial misalignment refers to the situation when two shafts are displaced along their common axis. Flange couplings are not specifically designed to handle large axial misalignment. However, certain types of flange couplings may have limited axial movement capabilities due to the flexibility of their components. In some cases, an additional feature like an end float or sliding flange design may be incorporated to accommodate limited axial movement.
It is important to note that while flange couplings can handle a certain degree of misalignment, excessive misalignment can lead to premature wear and failure of the coupling. Regular maintenance and proper alignment of the shafts are essential to ensure the coupling’s optimal performance and longevity.
What Role Does a Flange Coupling Play in Minimizing Wear and Tear on Connected Components?
A flange coupling plays a critical role in minimizing wear and tear on connected components in rotating machinery. It accomplishes this by effectively transmitting torque between two shafts while accommodating misalignment and reducing the transmission of shock and vibration. Here’s how a flange coupling achieves these benefits:
- Misalignment Compensation: Flange couplings are designed to accommodate both angular and parallel misalignment between the shafts they connect. As machinery operates, shafts may experience slight misalignment due to thermal expansion, manufacturing tolerances, or other factors. The flexible nature of certain flange coupling designs allows them to compensate for these misalignments, preventing excessive stress on connected components that could lead to wear.
- Shock and Vibration Damping: Flange couplings help dampen shock and vibration during machinery operation. When a machine experiences sudden impacts or vibrations, the flexibility of some flange coupling types absorbs and disperses these forces. By reducing the transfer of shocks and vibrations to the connected components, flange couplings protect the machinery from excessive stress and premature wear.
- Smooth Torque Transmission: Flange couplings provide a smooth and reliable means of transmitting torque from one shaft to another. The secure connection between the two shafts ensures that torque is efficiently transmitted without slippage or sudden jolts. This smooth torque transmission helps prevent unnecessary wear on the shafts and other connected components.
- Reduced Maintenance: By minimizing wear and tear on connected components, flange couplings contribute to reduced maintenance requirements. When components experience less stress and wear, their lifespan is extended, resulting in fewer maintenance interventions and decreased downtime for repairs or replacements.
- Protection Against Overloads: In cases of sudden overloads or torque spikes, flange couplings can act as a safety feature by allowing some degree of slippage or disengagement. This protects the connected machinery from potential damage caused by excessive loads.
In summary, a flange coupling’s ability to compensate for misalignment, dampen shocks and vibrations, provide smooth torque transmission, and protect against overloads makes it a crucial component in minimizing wear and tear on connected machinery. By choosing the appropriate flange coupling design for a specific application, engineers can enhance the reliability and longevity of the entire system while reducing maintenance and downtime costs.
How Does a Flange Coupling Protect Connected Equipment from Shock Loads and Vibrations?
A flange coupling plays a crucial role in protecting connected equipment from shock loads and vibrations by absorbing and dampening the impact and oscillations. The design and material properties of flange couplings contribute to their ability to mitigate shock and vibrations effectively. Below are the key factors explaining how flange couplings provide protection:
1. Flexibility: Flexible flange couplings are designed with elastomeric or metallic elements that offer flexibility between the connected shafts. When subjected to shock loads or vibrations, these elements can absorb and dissipate the energy, preventing it from transmitting to the connected equipment. The flexibility allows the coupling to accommodate misalignment and minor shocks, reducing the stress on the system.
2. Damping Properties: Elastomeric elements used in certain flange coupling designs possess inherent damping properties. These materials can absorb and dissipate vibrational energy, reducing resonance and preventing harmful vibrations from being amplified in the system.
3. Misalignment Compensation: Flange couplings with flexible elements can compensate for certain degrees of misalignment between the shafts. Misalignment can lead to additional forces and vibrations in the system, but the coupling’s ability to accommodate this misalignment reduces the impact on the connected equipment.
4. Resilience: Flange couplings made from materials like steel or other alloys have high resilience and can withstand sudden shock loads without permanent deformation. This resilience helps maintain the coupling’s integrity and allows it to continue functioning effectively after exposure to shock events.
5. Friction Damping: Some rigid flange coupling designs incorporate friction damping features. These couplings rely on friction between the mating surfaces to dampen vibrations and prevent resonant frequencies from causing issues in the system.
6. Material Selection: The choice of materials for both flexible and rigid flange couplings is critical in their ability to protect connected equipment from shock loads and vibrations. High-quality materials with appropriate mechanical properties, such as strength and elasticity, enhance the coupling’s ability to withstand shocks and vibrations.
7. Proper Installation: Correct installation and alignment of the flange coupling are essential to ensure it functions as intended. Properly installed couplings can effectively manage shocks and vibrations, while misaligned couplings may experience premature wear and transmit higher forces to the connected equipment.
8. Maintenance: Regular maintenance, including inspection, lubrication, and monitoring, ensures that the flange coupling continues to provide protection against shocks and vibrations throughout its service life.
In summary, flange couplings protect connected equipment from shock loads and vibrations by providing flexibility, damping properties, misalignment compensation, resilience, and friction damping. The selection of suitable materials, proper installation, and regular maintenance further enhance their performance in protecting industrial machinery and equipment from potential damage caused by dynamic forces.
editor by CX 2024-04-29