Sigma 6-16S - Acceleration and Deceleration Curves

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Laboratory Centrifuge Sigma 6-16S

11 Appendix

Version 07/2012, Rev. 1.22 of 08/05/2020 • sb

75 / 91

Translation of the original operating manual, part no. 0702002

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11.3 Acceleration and deceleration curves

Linear as well as quadratic curves are numbered in the direction of

increasing acceleration (from right to left).

The deceleration curves are inverted images of the acceleration curves and

are assigned the same numbers. An exception is curve 0. It decelerates

brakeless (spin-out).

In general, the runtime, until the set speed is reached, depends on the

moment of inertia of the rotor.

Linear curves

The slope of the fixed acceleration curves defines the time that is required

to accelerate the rotor by 1,000 rpm.

Curve 9 is a special case compared to the other curves. The centrifuge

accelerates with maximum power. The runtime, until the set speed is

reached, depends solely on the moment of inertia of the rotor.

Linear curve no.

Slope

4 [rpm/sec]

6 [rpm/sec]

8 [rpm/sec]

17 [rpm/sec]

25 [rpm/sec]

33 [rpm/sec]

50 [rpm/sec]

100 [rpm/sec]

200 [rpm/sec]

1.000 [rpm/sec]

Fig. 37: Slope of linear curves

Quadratic curves

Curve 19 is a special case compared to the other curves. The centrifuge

accelerates with maximum power. The runtime depends solely on the

moment of inertia of the rotor.

Quadratic curve no.

Time until 1,000 rpm

Slope as of 1,000 rpm

500 sec

4 [rpm/sec]

333 sec

6 [rpm/sec]

250 sec

8 [rpm/sec]

118 sec

17 [rpm/sec]

80 sec

25 [rpm/sec]

60 sec

33 [rpm/sec]

40 sec

50 [rpm/sec]

20 sec

100 [rpm/sec]

10 sec

200 [rpm/sec]

2 sec

1.000 [rpm/sec]

Fig. 38: Slope of quadratic curves

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