Information
-
Patent Grant
-
6793487
-
Patent Number
6,793,487
-
Date Filed
Wednesday, January 15, 200321 years ago
-
Date Issued
Tuesday, September 21, 200420 years ago
-
Inventors
-
Original Assignees
-
Examiners
Agents
- Nixon Peabody LLP
- Safran; David S.
-
CPC
-
US Classifications
Field of Search
US
- 431 8
- 431 10
- 431 351
- 431 353 O
- 431 187
- 431 188
- 239 499
-
International Classifications
-
Abstract
A burner, in particular, for a motor vehicle supplementary or parking heater, for the burning of liquid fuel, in the presence of combustion air, has a combustion chamber (10), with a jet for the atomization of liquid fuel, arranged before said chamber. The jet has a Venturi tube (11) at the largest diameter end of the diffuser section thereof, opening into the combustion chamber (10), and the liquid fuel is introduced into the Venturi region which is at a low pressure when compared with the upstream end of the diffuser section (12), and through the inlet section (13) of which the air is pumped.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The invention relates to a binary burner for an auxiliary motor vehicle heater, for combustion of liquid fuel in the presence of combustion air, with a combustion chamber which is downstream of a nozzle for atomization of liquid fuel, and a Venturi nozzle for atomization of liquid fuel.
2. Description of Related Art
German Patent DE 41 18 538 C2 discloses an example of a burner of the initially mentioned type. This burner is based on a dual-fuel nozzle for atomization of fuel which has a relatively complicated structure. In particular, this nozzle consists of an essentially cylindrical mixing chamber, a feed pipe coaxial to its lengthwise axis for the liquid fuel, and a combustion air medium feed. The mixing chamber of the nozzle is closed by a nozzle insert for discharge of the atomized fuel/combustion air mixture and has a central nozzle hole and a conical inner bevel which converges in the flow direction. The combustion air feed consists of a feed pipe which tangentially penetrates the mixing chamber wall, dips into it and discharges at a greater height above the nozzle insert than the feed pipe for the liquid fuel. Due to this complex structure of the dual-fuel nozzle, for its proper operation for atomization of the liquid fuel, a considerable air overpressure is required which must be applied by a correspondingly powerful fan.
In conjunction with the gas burners, use of Venturi tubes as a mixing means is known. Furthermore, U.S. Pat. No. 4,396,372 discloses a burner system in which liquid fuel in the form of kerosene is delivered by means of a nozzle to a vaporizer provided with electrical heating means, with a Venturi-shaped inlet area.
SUMMARY OF THE INVENTION
One object of this invention is to devise a burner or a Venturi nozzle for atomization of the liquid fuel which does not require a high air overpressure for atomization of the liquid fuel and which operates reliably.
This object is achieved by a burner with nozzle having a Venturi tube or a Venturi nozzle with an inlet part which tapers in the flow direction of the combustion air and with a diffuser part which widens in the flow direction of the combustion air, the larger diameter end of the diffuser part discharging the liquid fuel into the combustion chamber, in the underpressure area in the transition area from the inlet part to the diffuser part, and by a Venturi nozzle that is axially divided into a fuel/combustion air discharge part and a fuel/combustion air supply part, the two Venturi nozzle parts being heat insulated relative to one another.
Accordingly, in accordance with the invention, the complex nozzle used for the binary burner is replaced by an arrangement with a Venturi tube or a Venturi nozzle, which to prevent coking and heat losses is made at least partially of a ceramic material. As a result of the pressure recovery of the Venturi tube or the Venturi nozzle it is not necessary to deliver air with a high overpressure so that the strong fan or additional fan which had been necessary in the past for this purpose can be omitted. The Venturi tube (or Venturi nozzle) used in accordance with the invention, moreover, has the advantage that economical production is possible.
Both the installation cost as well as the production costs are advantageously reduced if at least the front section of the Venturi diffuser part or the Venturi nozzle is made integral with the combustion chamber.
In the simplest case, the diffuser part of the Venturi tube or Venturi nozzle is formed with a uniform opening angle. However, according to one advantageous development, this Venturi tube or Venturi nozzle diffuser part can have sections of different opening angles, the section with the greatest opening angle bordering the combustion chamber.
Advantageously, the fuel is supplied to the Venturi tube or Venturi nozzle via a fuel feed tube with downstream end projecting into the Venturi tube. This downstream end of the fuel feed tube can discharge into a downstream dual-fuel nozzle or into the underpressure area of a second smaller Venturi tube which is operated in turn by the pressure drop of the Venturi tube or Venturi nozzle and ends in its underpressure region in order to achieve pre-atomization. Furthermore, the fuel feed tube is advantageously located within the Venturi tube or Venturi nozzle running coaxially to its lengthwise center. The downstream end can be located at different locations of the Venturi tube or Venturi nozzle, for example, in the inlet part or in the diffuser part of the Venturi tube or the Venturi nozzle or at its narrowest site between the inlet part and diffuser part.
Furthermore, it is advantageously provided that the combustion chamber have at least one additional inlet for secondary air. This secondary combustion air inlet is preferably located in the plane of the combustion chamber in which the Venturi tube or Venturi nozzle discharges.
The invention is explained below by way of example using the drawings.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1
schematically shows half of a lengthwise section of the combustion chamber and Venturi tube according to one embodiment of the dual-fuel burner,
FIG. 2
shows a diagram of the axial pressure variation in the Venturi tube shown in
FIG. 1
,
FIG. 3
shows one variant to
FIG. 1
with a small Venturi tube instead of a nozzle for fuel atomization, and
FIG. 4
shows a Venturi tube with an axial separation site in the area of the diffuser.
DETAILED DESCRIPTION OF THE INVENTION
The dual-fuel burner in accordance with the invention comprises a combustion chamber
10
of a preferably cylindrical or cuboidal shape. A Venturi tube
11
is connected to the fuel/combustion air inlet side of the combustion chamber
10
. The Venturi tube
11
which forms the Venturi nozzle is formed preferably, at least in the connection area, integrally with the combustion chamber
10
.
The Venturi tube
11
, in the conventional manner, has a diffuser part
12
and an inlet part
13
. The diffuser part
12
has a longer axial extension than the inlet part
13
and preferably has a conical shape, the end with the largest diameter of the conical diffuser part
12
being connected to the fuel/combustion air inlet of the combustion chamber
10
. The inlet part
13
which, likewise, has a conical shape or at least one inlet radii with an optionally connected cylindrical part, with a section of greatest diameter pointing away from the combustion chamber
10
, adjoins the end of the diffuser part
12
which is smallest in diameter.
The Venturi tube
11
and the combustion chamber
10
are preferably on a common lengthwise central axis
14
. The fuel feed tube
15
, with a dual-fuel nozzle
16
being connected to its downstream end, is flush with this lengthwise central axis. The outlet opening of the dual-fuel nozzle
16
lies at the narrowest point between the diffuser part
12
and the inlet part
13
of the Venturi tube
11
, i.e., in an area at a lower pressure relative to the combustion chamber
10
, as illustrated in FIG.
2
.
Instead of the dual-fuel nozzle
16
, according to the version shown in
FIG. 3
, there can also be a small Venturi tube
19
at the same location which is operated by the pressure drop of the Venturi tube
11
and which ends in its underpressure area in order to achieve pre-atomization. In this case, the fuel feed tube
15
discharges in the smaller Venturi tube
19
by which air is likewise delivered.
Combustion air is fed into the inlet part
13
of the Venturi tube
11
by means of a fan (not shown) and which provides combustion air with only a small overpressure. The combustion air is delivered along the arrow
17
to the Venturi tube
11
.
The axial pressure characteristic in the Venturi tube
11
is shown in
FIG. 2
, in a diagram with the length ε of the Venturi tube
11
plotted on its x axis, and the pressure differential Δp in the Venturi tube
11
plotted on its y axis. Accordingly, the combustion air at the inlet point into the inlet part
13
of the Venturi tube
11
has a low overpressure which is achieved by the fan which delivers the combustion air. With flow through the inlet part
13
, due to the narrowing of the cross section the speed increases, at the same time the combustion air pressure drops, and in the transition to the subsequent diffuser part
12
, reaches a minimum value. This minimum absolute pressure corresponds to a maximum underpressure compared to the combustion chamber pressure level. This underpressure decreases downstream in the continuation of the diffuser part
12
so that the combustion air entering the combustion chamber
10
is roughly at the combustion chamber pressure.
The nozzle
16
has at least one radial hole
18
which discharges into the axial fuel delivery hole of the nozzle
16
. Via this radial hole
18
, air is introduced into the delivery path of the liquid fuel so that in the nozzle
16
swirling of the combustion air and liquid fuel occurs. This mixture then emerges atomized from the outlet opening of the nozzle
16
and mixes in the diffuser part
12
with the combustion air which is taken in along the arrow
17
and which is provided to the inlet part
13
by the fan with low pressure.
Moreover, preferably secondary combustion air is supplied to the combustion chamber
10
. For this purpose, at the point at which the diffuser part
12
of the Venturi tube passes into the combustion chamber
10
, distributed around the periphery, secondary air openings
20
are formed via which secondary air is fed into the combustion chamber
10
. There can also be secondary air openings alternatively or additionally on the jacket of the combustion chamber
10
.
FIG. 4
schematically shows, in a lengthwise section, the rear part of the combustion chamber of a burner equipped with an embodiment of a Venturi nozzle of the invention for an auxiliary motor vehicle heater.
The cylindrical combustion chamber
110
is connected downstream of the combustion air supply chamber
111
into which combustion air is supplied by means which are not shown, typically by means of a fan. The combustion chamber
110
, running coaxially to its lengthwise central axis L which is shown by the dot-dash line, has a connection opening
122
for connection of the downstream end of the Venturi nozzle
112
which is located completely within the combustion air supply chamber
111
. Around this connection opening
122
is a ring of smaller openings
123
for the passage of secondary combustion air into the combustion chamber
110
.
The Venturi nozzle
112
, in the downstream area, comprises a conical diffuser
113
which discharges into the combustion chamber
110
and which tapers in the upstream direction. In the upstream direction, the Venturi nozzle
112
comprises a conical inlet part
114
which has a diameter variation which is opposite the diffuser
113
, i.e., conically tapers in the direction toward the diffuser
113
. The outside end of the inlet part
114
adjoins a cylinder part
115
which discharges into the combustion air supply chamber
111
. The diffuser
113
and the inlet part
114
are connected via a cylinder part
116
which is small in diameter and into which a fuel feed tube
117
discharges. The fuel feed tube
117
runs coaxially to the lengthwise central axis of the Venturi nozzle
112
and is routed out of the combustion air supply chamber
111
at an angle outside of this nozzle.
In this arrangement of the combustion air supply chamber
111
and the Venturi nozzle
112
, liquid fuel is taken into the combustion air by the underpressure which prevails in the area of the narrowest point (in the area of the cylinder part
116
) and atomized. The combustion air supplied to the inlet part
114
from the combustion air supply chamber
111
, together with the atomized fuel from the Venturi nozzle
112
, is delivered into the combustion chamber
110
. The mist of fuel and combustion air is ignited in the combustion chamber
110
and burned as it is additionally mixed with additional secondary combustion air from the openings
123
. For this purpose, an ignition means
124
projects into the combustion chamber
110
and its end extends into the area of the exit of the conical diffuser
113
of the Venturi nozzle
112
.
According to the invention, the Venturi nozzle
112
is axially divided into two parts, specifically into a discharge part
118
which borders the combustion chamber
10
, and a supply part
119
which is located upstream of this discharge part
118
. The axial division of the Venturi nozzle
112
is made in the area of its diffuser
113
so that the supply part
119
is roughly twice as long as the discharge part
18
.
In the preferred embodiment shown in
FIG. 4
, the discharge part
118
and the supply part
119
are separated from one another by an annular gap
120
with a width which is typically between 0.1 and 0.8 mm. Preferably, the gap width is chosen to be roughly 0.3 mm. In the axial direction, the annular gap
120
is bordered by the facing annular end faces of the discharge part
118
and the feed part
119
and radially by a ring seal
121
which seals the annular gap
120
and thus the conical diffuser
113
relative to the outside. The material of the ring seal
121
is preferably a heat-insulating material such as, for example, a ceramic. The Venturi nozzle
112
is made of metal, but preferably is also at least partially made of a ceramic. The material for the two Venturi nozzle parts
118
,
119
can be the same. However, preferably, the material of the discharge part
118
has a lower thermal conductivity than the material of the supply part
119
in order to transfer as little heat as possible to the annular gap
120
between the two Venturi nozzle parts
118
,
119
.
Due to the heat-insulated division of the Venturi nozzle
112
of the invention, it has a cold and a hot part. The upstream cold supply part
119
is typically exposed to temperatures below 180° C. in operation due to the division of the Venturi nozzle into two parts so that cracking of the fuel cannot occur in this nozzle part
119
. On the other hand, the flame-side hot discharge part
118
of the Venturi nozzle
112
is typically exposed to temperatures above 500° C. so that liquid fuel striking its inside wall from the fuel feed tube
117
vaporizes without leaving crack residues. Thus, it is ensured that the Venturi nozzle
112
is not clogged with residues, and thus, its efficiency is not adversely affected.
The ring seal
121
can fill the entire annular gap
120
. Alternatively, it is also conceivable for the ring seal
121
to be completely omitted. For a very narrow annular gap
120
, there is almost no leakage of fuel-air mixture to the outside. Small leaks would be supplied to the combustion chamber with the secondary combustion air and burned there.
As a result of the low pollutant discharge which can be achieved with a burner equipped with the Venturi nozzle in accordance with the invention, a longer service life of the burner, and thus of the heater, and less environmnental impact are ensured. Finally, the starting behavior is optimum by the use of the Venturi nozzles according to the invention.
Claims
- 1. Venturi nozzle for atomization of liquid fuel for combustion of the fuel in the presence of combustion air in a combustion chamber of a burner, wherein the Venturi nozzle is axially divided into a fuel/combustion air discharge part and a fuel/combustion air supply part, and wherein the fuel/combustion air discharge part and the fuel/combustion air supply part are thermally insulated relative to one another;wherein facing annular end faces of the discharge and supply parts of the Venturi nozzle are separated from one another at least partially via an annular gap.
- 2. Venturi nozzle as claimed in claim 1, wherein the supply part of the Venturi nozzle has a greater axial extension than the discharge part.
- 3. Venturi nozzle as claimed in claim 2, wherein the supply part of the Venturi nozzle is roughly twice as long as the discharge part.
- 4. Venturi nozzle as claimed in claim 1, wherein the discharge part of the Venturi nozzle is made of a material with a thermal conductivity which is poorer than that of the supply part.
- 5. Venturi nozzle as claimed in claim 1, wherein the annular gap is radially bordered by a ring seal.
- 6. Venturi nozzle as claimed in claim 1, wherein the annular gap has a gap width between 0.1 and 0.8 mm.
- 7. Venturi nozzle as claimed in claim 1, wherein the annular gap has a gap width of roughly 0.3 mm.
- 8. Venturi nozzle as claimed in claim 1, wherein the fuel/combustion air discharge and a part and a fuel/combustion air supply part are separated from each other at a diffuser part of the Venturi nozzle.
- 9. Venturi nozzle as claimed in claim 1, wherein at least the discharge part is made of a ceramic material.
- 10. Venturi nozzle for atomization of liquid fuel for combustion of the fuel in the presence of combustion air in a combustion chamber of a burner, wherein the Venturi nozzle is axially divided into a fuel/combustion air discharge part and a fuel/combustion air supply part, and wherein the fuel/combustion air discharge part and the fuel/combustion air supply part are thermally insulated relative to one another;wherein the discharge part and the supply part are separated from one another by a ring seal which axially borders facing annular end faces of the discharge and supply parts essentially over the entire surface thereof.
- 11. Venturi nozzle as claimed in claim 10, wherein the ring seal is made of a thermally insulating material.
- 12. Venturi nozzle as claimed in claim 10, wherein the ring seal is made of a ceramic material.
- 13. Burner for an auxiliary motor vehicle heater, comprising:a combustion chamber for combustion of liquid fuel in the presence of combustion air; and a mixing means which comprises a nozzle for atomization of liquid fuel, the nozzle comprising a Venturi tube or a Venturi nozzle with an inlet part which tapers in flow direction of the combustion air and with a diffuser part which widens in the flow direction of the combustion air, the diffuser part having a larger diameter end which discharges into the combustion chamber in an underpressure area in a transition area from the inlet part to the diffuser part; wherein at least the diffuser part of the Venturi tube or Venturi nozzle is made of a ceramic material, wherein a fuel feed tube is provided for supplying fuel to the Venturi tube or Venturi nozzle, the fuel feed tube being located coaxially relative to a lengthwise center axis of the Venturi tube or Venturi nozzle and having an outlet opening located at the narrowest point between the supply Dart and the diffuser part.
- 14. Burner as claimed in claim 13, wherein at least the front section of the diffuser part is formed integrally with the combustion chamber.
- 15. Burner as claimed in claim 13, wherein the diffuser part diverges in a conical shape in toward the combustion chamber and has sections of differing opening angles.
- 16. Burner as claimed in claim 13, wherein the combustion chamber has at least one inlet for secondary combustion air.
- 17. Burner as claimed in claim 16, wherein the at least one inlet for secondary combustion air, viewed axially, is in an area of the combustion chamber in which the Venturi tube or Venturi nozzle discharges.
- 18. Burner as claimed in claim 13, wherein the Venturi tube or Venturi nozzle is a binary nozzle having one of a pre-atomization nozzle and a second smaller Venturi tube, an inlet and outlet opening of which is located in the Venturi tube or Venturi nozzle at a location at which a pressure drop produced by the Venturi tube or Venturi nozzle will create a flow therethrough.
- 19. Burner as claimed in claim 13, further comprising combustion air supply for delivering air to said inlet part.
Priority Claims (2)
Number |
Date |
Country |
Kind |
100 14 405 |
Mar 2000 |
DE |
|
100 14 347 |
Mar 2000 |
DE |
|
PCT Information
Filing Document |
Filing Date |
Country |
Kind |
PCT/EP01/03358 |
|
WO |
00 |
Publishing Document |
Publishing Date |
Country |
Kind |
WO01/71251 |
9/27/2001 |
WO |
A |
US Referenced Citations (7)
Foreign Referenced Citations (3)
Number |
Date |
Country |
41 18 538 |
Dec 1992 |
DE |
0 863 369 |
Sep 1998 |
EP |
WO 9828493 |
Jul 1998 |
WO |