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– English

English

degrees of

latitude

of this location

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02.

On the graphs (North or South) supplied in the SOLEKIT instruction
manual, locate the curve for the location’s

latitude

(e.g: 45°N).

03.

Choose the

period of the year

on which to base the calculation, or

select the lowest point of the curve to calculate

the worst period

of the year;

then read the corresponding value

(e.g. December,

January: Am= 200).

Calculate the value of energy available

(produced by the panel)

multiplying

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• Calculating the energy consumed

To calculate the energy consumed by the automation, proceed as follows:

05.

On the table below, select the box corresponding to the intersection
between the line with the

weight

and the column with the

opening

angle

of the leaf. The box contains the value of the

severity index

(K) for each manoeuvre

(e.g. gearmotor with standard arm on leaf of

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Opening angle

with standard arm with short arm

Leaf weight

¦ ¦ ¦ ¦ ¦

< 80 kg

112

80-120 kg

128

200

120-150 kg

144

220

288

150-180 kg

126

220

motor

06.

On the

WDEOH

select the box corresponding to the intersection

between the line with the

value and the column with the

value.

The box contains the maximum possible number of cycles per day

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If the number obtained is too low for the envisaged use or is located in the
“area not recommended for use”, the use of 2 or more photovoltaic pan-
els may be considered, or the use of a photovoltaic panel with a higher
power. Contact the Nice technical assistance service for further informa-
tion.
The method described enables the calculation of the maximum possible
number of cycles

per day

that can be completed by the automation while

running on solar power. The calculated value is considered an average
value and the same for all days of the week. Considering the presence
of the battery, which acts as an energy “storage depot”, and the fact that
the battery enables automation autonomy also for long periods of bad
weather (when the photovoltaic panel produces very little energy) it may
be possible to exceed the calculated maximum possible number of cycles
per day, provided that the average of 10-15 days remains within the envis-
aged limits.

Table 5

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to the manoeuvre’s

severity index

(K), using

exclusively the energy

stored

by the battery. It is considered that initially the battery is com-

pletely charged (e.g. after a prolonged period of good weather or recharg-
ing via the optional PCB power supply unit) and that the manoeuvres are

performed within a period of 30 days.

When the battery runs out of the stored energy, the led starts to indicate

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by a “beep”.
If the “ALTO” is used on a single leaf gate (with only one gearmotor),
the maximum possible number of cycles corresponds to the value in the
tables, multiplied by

1.5.

For example, if the calculated number of cycles

is 30 and the gate has one leaf only, the number of cycles will be: 30 x

1,5

= 45.

A.6 - “Stand-by” function when the device PR200

and/or SOLEKIT is installed

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When the automation is powered by the backup battery PR200 or the
photovoltaic system SOLEKIT, the “standby” function is activated auto-
matically 60 seconds after completion of an automatic manoeuvre cycle.
This turns off the “BUS” output and all connected devices, the outputs
“Flash”, “Els” and all leds, with the exception of the BUS led which

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user sends a command, the control unit restores power and starts the
manoeuvre

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A.7 - Using the “BUS” input/output

Only devices compatible with ECSBus technology must be connected to
the terminal “BUS” (this is explained in detail in paragraph 3.3.3).

Impor-

tant – Following testing of the automation, each time new devices
are connected to (or removed from) the “BUS” terminal, the learn-
ing procedure must be performed as described in paragraph A.10.

A.8 - Using the “STOP” input

STOP is the input that causes immediate shutdown of the manoeuvre
(with brief inversion). This input can be connected to devices with contact
types Normally Open, Normally Closed (NC) or devices with a constant

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When set accordingly, more than one device can be connected to the
STOP input, also different from one another. For this function, refer to

Table 6

and the following notes to the table.

Note 1.

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1&DQG.ŭ

Note 2.

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parallel.

Note 3.

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