The structure is composed of a steel plate body equipped with
The structure is composed of a steel plate body equipped with
adjustable feet (max cm 10).
adjustable feet (max cm 10).
The internal covering of the combustion chamber is made from
The internal covering of the combustion chamber is made from
reproof material with a re bowl to correctly contain the em-
reproof material with a re bowl to correctly contain the em-
bers which must then be collected.
bers which must then be collected.
The structure is complete with a shell which creates a cavity for
The structure is complete with a shell which creates a cavity for
the circulation of the heating air.
the circulation of the heating air.
The heating air can circulate by natural convection (version N)
The heating air can circulate by natural convection (version N)
or by forced ventilation (Version V, air drawn from fan).
or by forced ventilation (Version V, air drawn from fan).
The system to allow combustion air into the replace has been
The system to allow combustion air into the replace has been
carefully designed to guarantee optimal combustion, a con-
carefully designed to guarantee optimal combustion, a con-
trolled ame and clean glass.
trolled ame and clean glass.
Primary air for combustion (A - Fig. 2) and glass cleaning
Primary air for combustion (A - Fig. 2) and glass cleaning
vetro enters through a duct (7 - Fig. 1), from the lower part
vetro
enters through a duct (7 - Fig. 1), from the lower part
of the replace, it heats up when passing on the sides of the
of the replace, it heats up when passing on the sides of the
combustion chamber, and leaves from the duct located in the
combustion chamber, and leaves from the duct located in the
top part of the combustion chamber.
top part of the combustion chamber.
The quantity of primary air can be regulated by means of a
The quantity of primary air can be regulated by means of a
lever (L - Fig. 3) installed under the door.
lever (L - Fig. 3) installed under the door.
The post-combustion air (C) enters the combustion chamber
The post-combustion air (C)
through the holes located inside the combustion chamber.
through the holes located inside the combustion chamber.
The air is taken up, through a duct (7 - Fig. 1), from the lower
The air is taken up, through a duct (7 - Fig. 1), from the lower
part of the replace, is heated during its ow through the back
part of the replace, is heated during its ow through the back
of the combustion chamber, due to the strong irradiation to
of the combustion chamber, due to the strong irradiation to
which it is subjected, and exits from a series of holes.
which it is subjected, and exits from a series of holes.
The air which exits from the holes, meeting the ow of fumes,
The air which exits from the holes, meeting the ow of fumes,
triggers off a second combustion process which burns the non-
triggers off a second combustion process which burns the non-
combusted elements and any carbon monoxide:
combusted elements and any carbon monoxide:
this process is called post-combustion.
this process is called post-combustion.
KEY: ( g. 1)
KEY:
( g. 1)
1) 1) fume exit connection
fume exit connection to connect to the ue
to connect to the ue
2) 2) steel structure
steel structure
3) 3) reproof inner part of the replace
reproof inner part of the replace, very thick in order to
increase the combustion temperature
increase the combustion temperature
4) 4) ceramic glass
ceramic glass, shockproof and heat resistant up to 800° C
, shockproof and heat resistant up to 800° C
5) 5) handle
handle
6) 6) re basin
re basin in which the embers burn and which gives
in which the embers burn and which gives
optimal combustion
optimal combustion
7) external air vent connection
7) external air vent connection
8) shell for heating air circulation
8) shell for heating air circulation
9) hot air output vent
9) hot air output vent (D)
(D)
GENERAL INFORMATION
enters the combustion chamber
, very thick in order to
4
5
Fig. 1
Fig. 2
Fig. 3
- 20
-
1
9
D
8
C
3
7
A
7
L
2
6