Why Balancing?
1) Balancing creates and enhances quality!
Unless it is corrected, the effect of unbalance will often only become noticeable in the finished product. If rotors are not balanced, they can cause undesired or even dangerous vibrations. They can also diminish the practical value of a machine, cause damage to the bearing, or fractures to the casing, suspension or foundation. Excessive noise and vibration may also irritate or annoy the user and lead them to conclude that the product is of poor quality. Thus, a product that is free from noise and vibration is always a sign of quality, precision and craftsmanship.
2) Increasing Demands!
More sophisticated technical development have lead to constantly increasing requirements with regard to balancing quality. Higher performance for applications such as high-speed tool spindles, electric motors, turbines, fans, universal joint shafts or paper rolls simply mean higher speed. The trend is clear, and in order to meet these requirements precision balancing is essential. Accurately balanced rotors allow us to safely reach higher speeds and deliver considerably higher performance.
Typical applications:
Auto: crankshaft, drive shaft, brakes, pulley, armature
Aerospace: generator, motor, transmission shaft, APU accessories, wheel
Blowers / Compressors / Turbine: ventilator, blower, compressor, turbine
Motor: electromotor, generator
Machine tool: machanical spindle, electric spindle, tool shank, grinding wheel
Pump: centrifugal pump, double suction pump, mixed flow pump, axial flow pump
Papermaking: drum dryer,pressing roller, guide roller
Textile: spinning cup, split wing, spindle, combing roller,slotted drum, carding machine roller
Railway / Vessel: electric motor, blower, marine crankshaft, turbocharger, wheel, train wheel pair
Horizontal Hard-Bearing Balancing Machine HM30N
TECHNICAL DATA (basic data)
provided the rotor weight is equally shared between the two bearings, rotor weight W
per bearing pedestal |
Max.
Max. |
700 kg
350 kg |
Rotor weight
(as long as an accommodation of the rotor is possible due to the geometric data and the minimum achievable residual unbalance is sufficient for the balancing task.) |
Min. |
unlimited |
Distance from coupling flange of drive shaft to centerline of farthest bearing with a base length of 2 500 mm (see also item 4) distance between bearing centers
distance between bearing centers |
Max.
Min. |
1 550 mm
50 mm |
rotor swing diameter above the machine base |
Max. |
1 260 mm |
journal bearing diameter |
Max.
Min. |
80 mm
10 mm |
Balancing speed of end-drive
(the speed range of the measuring unit must be taken into account. See item 2) |
37-370/59-590/89-890 rpm |
Wn2-value for permanent calibration |
Wn2 = 280x106kg/min2 |
Umar Minimum achievable residual unbalance (*according to ISO2953)
-each bearing plane 0.5 gmm per kg rotor weight
-but not better than the maximum measuring sensitivity of the measuring unit 3gmm
(* This value is refering to the measuring speed of 1000 rpm with CAB708, also influenced by the rotor characteristics and support bearing. see specification of the measuring unit) |
Unbalance reduction ratio (URR) |
≥ 95% |
Note:
The above mentioned data (especially the accuracy data) not means can be achieved the customer rotors, please find the definitions according to ISO 2953 or related international regulations.
The drive power chosen out is relative with the work pieces, due to the diversity of out-structure, moment of inertia and wind influence of different rotors, which means not all the biggest rotors can reach the balancing speed as we expected.
EXTENT OF DELIVERY: (basic delivery scope)
1 Machine base
2 Bearing pedestals
1 Shaft drive unit, design N, 3- speed
1 Reference pickup
Accessories:
Connect cables, tools, balancing plasticine, 1 set of technical documentation.
Language:
Technical documentation and lettering of the machine in English or Chinese.
Electrics:
3-phase, normal voltage 380 Volt ± 10%, frequency 50 Hz. (Special design on request.)
Colour finish:
according to SCHENCK standard