Casella CEL CEL-160 User Manual

AC OUTPUT: This provides the conditioned AC

signal at a level of 1.4 V RMS via 3.3 kW, for

FSD.

DC INPUT: DC inputs will be accepted by the

socket at a nominal sensitivity of 140 mV/dB

when the DC gain control (GAIN-CAL) is in the

'CAL' position. It must be noted that the

instrument assumes that the DC input signal is

in the log DC form and produces amplitude

annotations accordingly.

REMOTE: All the necessary control signals for

peripheral instrumentation are available from

this socket. Full details are given in Figure 2.

POWER: Both constant voltage and constant

current supplies provided by the CEL-3732 AC

Adaptor and NiCad Battery Charger are

connected to the Graphic Recorder via this

socket. Reference should be made to Section

2.2.2 and the CEL-3732 Operating Instructions.

CEL-160 Socket Connections

8-pin DIN Preamplifier
Pin No.

Function

1

150 V polarising voltage.

2

Signal from preamplifier. Input impedance 20 kW.
Maximum input ±8 V peak to peak.
Maximum DC offset 15 V.

3

-5V nominal, supply to preamplifier.
Maximum current 5mA.

4

0 V.

5

30 dB gain signal. Goes from -8 V to +8 V
when gain selected. Selected on bottom five
ranges.

6

+5 V nominal supply to preamplifier.
Maximum current 5 mA.

7

AC input. Impedance 240 k

Ω

.

Maximum input ±80 V peak to peak.
Maximum DC offset +15 V.
Attenuated 20 dB re. Pin 2.

8

Spare. (+18 V10 mA Accelerometer bias
option).

8-Pin Remote
Pin No.

Function

1

Input 1, normally 0 V.

2

Input 2, normally +5 V.
Control inputs presently used in filter programs
to sense state of filter.

3

Step filter, 5 to10

µ

S pulse to +8 V with 10 k

Ω

source impedance.

4

Reset filter, normally +8 V (via l0 k

Ω

). Shorted

to 0 V for 5 - 10

µ

S for reset.

5

Input 3, normally 0 V. Only available on Level
1 recorders. No present usage but available
for special software.

6

0 V.

7

+8 V output for special cables/interfaces.
Maximum current 10 mA.

8

Spare.

Figure 2: Pin functions

3.3

Scale Annotations

The CEL-160 records over a 50 mm span to a

resolution of 1% and accepts 25 m rolls of

electrosensitive paper. Both X and Y grids and

annotations are generated by the recorder and

are printed at the same time as the recorded

trace.

3.3.1 Amplitude Axis (Y)

Two kinds of amplitude scaling are provided by

the instrument. Firstly, an amplitude grid and

secondly amplitude annotation.

The amplitude grid is produced by

repeatedly firing every fifth pin in the writing

comb at half intensity. This produces 20

amplitude bands across the scale, the actual

value of which depends upon the measure-

ment configuration. For example, with log

RMS recording they would represent either

0.5, 1 or 2.5 dB divisions depending on

whether the dynamic range switch was in the

10, 20 or 50 dB positions. In the linear mode

they divide the chart into 5% bands and in the

AC mode between ± 100% in 10% steps. In

the AC waveform mode the amplitude grid is

reversed out when the recorder is producing

deflections crossing the grid position. This

produces the effect of a white grid line against

the black traces.

The scale annotations produced by the

instrument depend upon the mode of

operation and in all cases follow the first time

marker after a full time print. In the RMS log

and DC modes annotations of FSD and MSD

are produced as defined by the settings of the

dynamic range and range (dB) step attenuator

switches. In the RMS linear mode the

annotation is always 0-100 to represent

percentage scale deflections and it is

independent of the gain settings. In the AC

waveform mode the signal is balanced about

the centre line of the paper and no scale

annotations are provided. When in the real

time analyser mode each individual third

octave band is annotated with the band level in

alphanumeric form.

3.3.2 Time Axis (X)

The traditional method of recording time on

recorders is to relate the length of paper

consumed to the start time via the paper

speed. These arrangements can be extremely

inaccurate especially over long periods and

there is no method of recording absolute time.

The CEL-160 does not use distance as the

method of calculating elapsed time but records

real or elapsed time directly on to the chart. It

CEL-160 Graphic Recorder - Page 9