Swirl chamber used in association with a combustion chamber for diesel engines
A swirl chamber used in association with a combustion chamber for diesel engines, includes a pair of sub-nozzle holes on the opposite sides of a main nozzle hole to supply a secondary air into the swirl chamber, the sub-nozzle holes being positioned such that the secondary air ejected therethrough is fully utilized for the combustion in the swirl chamber, thereby securing the complete combustion and the reduction of environmental contaminants such as NOx and fumes.
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The present invention relates generally to a combustion chamber for diesel engines, and more particularly, to improvements upon a swirl chamber used in association with a combustion chamber for diesel engines.
BACKGROUND ARTIn general, diesel engines are notorious as a major source of environmental contaminants such as NOx and fumes. However, no effective measures have been accomplished for solving those problems. It is known that these problems are due to the incomplete combustion in the engine occurring because of inadequate mixing of air and fuel. To solve these problems, swirl-aided combustion systems are commonly used. Here is one example for tackling this problem, which is disclosed in Japanese Patent Laid-open Application No. 07-97924. Referring to
In
Under the construction mentioned above, however, a major disadvantage is that the second air ejected through the sub-nozzle holes 112 does not reach the central part of the swirl chamber 108, thereby failing to bring about effective swirls therein. In this way the conventional sub-nozzle holes 112 are not conducive to the full utilization of the secondary air.
The disadvantages mentioned above is due to the following arrangement of the sub-nozzle holes 112: When a hypothetical sphere 115 is supposed about the center 107c of the open end 107b of the top-open recess 107a, and the radius of the open end 107b and that of the sphere 115 are respectively supposed to be 100% and 70%.
The sphere 115 having a radius of 70% passes outward, whereas the sphere 115 having a radius of 50% passes inward in
In another aspect, when the mouthpiece 107 is seen from just above, the sub-nozzle holes 112 have their upper openings 112c deviated from the center of the swirl chamber 108 so that even if every sub-nozzle hole is oriented vertically, the central axis 112a-112b of each sub-nozzle hole 112 cannot pass inside the 50% sphere 115.
Accordingly, an object of the present invention is to provide an improved swirl chamber capable of causing effective swirls to help air and fuel being well mixed, and dispersing the fuel well in the swirl chamber.
Another object of the present invention is to provide an improved swirl chamber capable of reducing the production of both NOx and fumes, not one or the other under the conventional system.
SUMMARY OF THE INVENTIONAccording to the The present invention, is directed to a swirl chamber used in association with a combustion chamber, wherein the for diesel engines. The combustion chamber is defined by a piston, a cylinder, and a cylinder head, includes a . A mouthpiece is fitted in a hole recess of the cylinder head, the hole having recess has a bottom-open recess, and the mouthpiece including includes a top-open recess, the . The bottom-open recess and the top-open recess constituting constitute a space for the swirl chamber; a . A main nozzle hole is produced through a base wall of the mouthpiece to allow the swirl chamber to effect communication between the combustion chamber and the swirl chamber; and a . A pair of sub-nozzle holes which are separated from the main nozzle hole, and are produced through the base wall of the mouthpiece, the . The holes being are positioned on opposite sides of the a central axis of the main nozzle hole when the mouthpiece is seen from just above; wherein each of the sub-nozzle holes is arranged to pass inside a hypothetical sphere depicted around a center of an upper circle of the top-open recess and having a radius of 70% of a diameter of the upper circle of the top-open recess . A hypothetical sphere is centered at a center of an upper circle of the top-open recess. The hypothetical sphere has a radius of 70% of a radius of the upper circle of the top-open recess and each of the sub-nozzle holes is arranged to pass a central axis of the sub-nozzles through an interior area of the hypothetical sphere.
Throughout the drawings like numerals are used to designate like components, and in
In
As best shown in
The principle underlying the combustion chamber 9 fixed with the swirl chamber 8 is as follows:
On the compression stroke the piston 2 rises, thereby introducing compressed air into the swirl chamber 8 to cause swirls therein. When the piston 2 reaches the top dead point, fuel is ejected through the ejection nozzle 19. The fuel is mixed with the air in the swirl chamber 8, and the charge of fuel and air is ignited, and burned in the chamber 8, and as a result, it expands in volume. The expanded gases pass into the combustion chamber 9 through the main nozzle hole 11. The fresh charge expands and rises as it goes away from the main nozzle hole 11 in the triangular recess 21. The fuel-content in the fresh charge mixes with air in the combustion chamber 9, and the mixture is ignited and burned.
The sub-nozzle holes 12 will be described:
In
Preferably, the radius of the sphere 15 is 70%; more preferably, 60%, and most preferably, 50%. In
In FIGS. 1A B and 1D, a hypothetical reference line 16 extends just upwards. The position of each hole 12 is determined in relation to this hypothetical reference line 16; that is, each sub-nozzle hole 12 is positioned such that its central axis 12a-12b coincides with the reference line 16 in every direction as viewed in
In this way the sub-nozzle holes 12 are positioned at various angles for the reference line 16 (FIGS. 1B and 1D). If it is positioned at a relatively small angle to the reference line 16, the sub-nozzle hole 12 can be short in length, thereby reducing frictional resistance to the flow of a secondary air passing through the sub-nozzle hole. In
In the embodiment illustrated in
The size of each sub-nozzle hole 12 is determined as follows:
It has been demonstrated that when the main nozzle hole 11 has an open end having an effective area is supposed to be 100%, the total area of the open ends of the two sub-nozzle holes should be in the range of 3% to 15%; preferably, 4 to 10%; more preferably, 6 to 10%, and most preferably, 7 to 9%. In short, the range of 3 to 15%, or preferably, of 5 to 15% is effective to reduce the production of NOx and fumes evenly.
The main nozzle hole 11 is constructed as follows:
Referring to
As best shown in
Referring
From
The efficiency of reducing exhaust gases depends upon the area of the open end of the sub-nozzle hole 12. Referring to
As shown in
Referring to
In the second embodiment shown in
In the third embodiment shown in
In the fourth embodiment shown in
Claims
1. A swirl chamber used in association with a combustion chamber for diesel engines, wherein the combustion chamber is defined by a piston, a cylinder, and a cylinder head, the swirl chamber comprising:
- a mouthpiece fitted in a hole recess of the cylinder head, the hole recess having a bottom-open recess, and the mouthpiece including a top-open recess, the bottom-open recess and the top-open recess constituting a space intended for the swirl chamber;
- a main nozzle hole produced through a base wall of the mouthpiece to effect communication between the combustion chamber and the swirl chamber; and
- a pair of sub-nozzle holes, which are separated from the main nozzle hole, produced through the base wall of the mouthpiece, the sub-nozzle holes being positioned on opposite sides of the a central axis of the main nozzle hole when the mouthpiece is seen from just above;
- wherein each of the sub-nozzle holes is arranged to pass inside a hypothetical sphere depicted around a center of an upper circle of the top-open recess having a radius of 70% of a diameter of the upper circle of the top-open recess and a hypothetical sphere, which is centered at a center of an upper circle of the top-open recess, the hypothetical sphere has a radius of 70% of a radius of the upper circle of the top-open recess, and each of the sub-nozzle holes being arranged to pass a central axis of the sub-nozzle holes through an interior area of the hypothetical sphere;
- wherein the main nozzle hole comprises a main groove and two side grooves, each of the side grooves is communicatively continuous with respect to the main groove through banks,
- the main groove and each of the side grooves extend forwardly and upwardly from the main combustion chamber to the swirl chamber through the bottom wall, and
- when the mouthpiece is viewed from above, each of the side grooves is arranged at a position rearwardly relative to an upper opening of the sub-nozzle holes.
2. The swirl chamber as recited in claim 1, wherein the hypothetical sphere has a radius of 60% of the diameter radius of the upper circle of the top-open recess.
3. The swirl chamber as recited in claim 1, wherein the hypothetical sphere has a radius of 50% of the diameter radius of the upper circle of the top-open recess.
4. The swirl chamber as recited in claim 1, wherein each of the sub-nozzle holes is positioned such that its respective a center of an upper open end of each of the sub-nozzle holes overlaps the hypothetical sphere having a radius of 50% of the diameter radius of the upper circle of the top-open recess when the mouthpiece is seen from just viewed from above the mouthpiece.
5. The swirl chamber as recited in claim 1, wherein each of the sub-nozzle holes is positioned such that its the central axis axes of the sub-nozzle holes passes within an angular range of 0° to 30° away from a hypothetical reference line extending just upwards when the mouthpiece is seen from a just lateral viewed from a side in a direction perpendicular to a center axis of the main nozzle hole of the mouthpiece.
6. The swirl chamber as recited in claim 1, wherein each of the sub-nozzle holes is positioned such that its the central axis passes axes of the sub-nozzle holes pass within an angular range of 0° to 15° away from a hypothetical reference line extending just upwards when the mouthpiece is seen in an immediately rearward direction with the main nozzle hole arranged to appear forwardly viewed from a rear.
7. The swirl chamber as recited in claim 1, wherein the a total area of the open ends of the sub-nozzle holes is in the a range of 3% to 15% of that a total area of an open end of the main nozzle hole.
8. The swirl chamber as recited in claim 7, wherein the total area of the open ends of the sub-nozzle holes is in the range of 4% to 10% of that the total area of the open end of the main nozzle hole.
9. The swirl chamber as recited in claim 1, wherein the main nozzle hole comprises a main groove and two side grooves each communicatively continuous to the main groove through banks.
10. The swirl chamber as recited in claim 9 1, wherein the side grooves are positioned such that their central axes exist of the side grooves are positioned rearward of that relative to a central axis of the main groove when the mouthpiece is seen from a just lateral side in a direction perpendicular to a center axis of the main nozzle hole viewed from a side of the mouthpiece.
11. The swirl chamber as recited in claim 10, wherein each of the central axes of the side grooves has its central axis is inclined at a smaller angle than an angle at which the central axis of the main groove is inclined with respect to the level an undersurface of the base wall of the mouthpiece when the mouthpiece is seen from a just lateral side in a direction perpendicular to a center axis of the main nozzle hole viewed from the side of the mouthpiece.
12. The swirl chamber as recited in claim 11, wherein the side grooves are positioned such that the a distance between them the central axes of the side grooves diminishes toward their a forward end of the side grooves.
13. The swirl chamber as recited in claim 9 1, wherein each of the side grooves has a progressively diminishing cross-sectional area toward its a forward end of the side grooves.
14. The swirl chamber as recited in claim 9, wherein when the mouthpiece is seen from just above, each of the side grooves is arranged at a position retreated from an upper opening of every sub-nozzle hole in parallel to the center axis of the main nozzle hole and immediately rearwards thereof.
15. The swirl chamber as recited in claim 1, wherein each of the sub-nozzle holes is positioned such that its a central axis of the sub-nozzle holes passes within an angular range of 0° to 30° away from a hypothetical reference line extending just upwards when the mouthpiece is seen from a just lateral side in a direction perpendicular to a center axis of the main nozzle hole and, the angular range is viewed from a side of the mouthpiece and, each of the sub-nozzle holes is arranged such that the central axes of the sub-nozzle holes passes within an angular range of 0° to 15° away from the hypothetical reference line extending just upwards when the mouthpiece is seen in an immediately rearward direction viewed with the main nozzle hole arranged to appear forwardly from the rear.
16. The swirl chamber as recited in claim 15, wherein the a total area of the open ends of the sub-nozzle holes is are in the range of 3% to 15% of that a total area of the main nozzle hole.
17. The swirl chamber as recited in claim 15, wherein the main nozzle hole comprises a main groove and two side grooves each communicatively continuous to the main groove through banks.
18. The swirl chamber as recited in claim 17, wherein when the mouthpiece is seen from just above, each of the side grooves is arranged at a position retreated from an upper opening of every sub-nozzle hole in parallel to the center axis of the main nozzle hole and immediately rearwards thereof.
19. The swirl chamber as recited in claim 1, wherein the sub-nozzle holes are positioned such that their central axes of the sub-nozzle holes are positioned upright on the base wall of the mouthpiece when the mouthpiece is seen from a just lateral side in a direction perpendicular to a center axis of the main nozzle hole viewed from a side.
20. The swirl chamber as recited in claim 1, wherein the sub-nozzle holes are positioned such that their central axes of the sub-nozzle holes are upright on the base wall of the mouthpiece when the mouthpiece is seen from an immediately rearward direction viewed with the main nozzle hole arranged to appear forwardly from a rear.
21. The swirl chamber as recited in claim 1, wherein the sub-nozzle holes are positioned such that their central axes of the sub-nozzle holes are upright on the base wall of the mouthpiece when the mouthpiece is seen from a just lateral side in a direction perpendicular to a center axis of the main nozzle hole viewed from a side, and
- the sub-nozzle holes are positioned such that their the central axes of the sub-nozzle holes are upright on the base wall of the mouthpiece when the mouthpiece is seen in an immediately rearward direction viewed with the main nozzle hole arranged to appear forwardly from a rear.
22. The swirl chamber as recited in claim 21, wherein the a total area of the open ends of the sub-nozzle holes is in the range of 3% to 15% of that a total area of the main nozzle hole.
23. The swirl chamber as recited in claim 21, wherein the main nozzle hole comprises a main groove and two side grooves each communicatively continuous to the main groove through banks.
24. The swirl chamber as recited in claim 23, wherein each of the side grooves is positioned such that its central axis is in parallel to, and rearward of, the central axis of the main groove.
25. The swirl chamber as recited in claim 1 wherein each of the side grooves is forwardly inclined at an angle of elevation the sub-nozzle holes extend generally forwardly and upwardly from a main the combustion chamber to the swirl chamber through the base wall.
26. The swirl chamber as recited in claim 1, wherein the each of the side grooves is rearward inclined at an angle of elevation sub-nozzle holes extend generally rearwardly and upwardly from a main the combustion chamber to the swirl chamber through the base wall.
27. The swirl chamber as recited in claim 1, wherein the sub-nozzle holes are positioned such that the a distance between them the sub-nozzle holes becomes narrower toward their proximate top open ends of the sub-nozzle holes.
28. The swirl chamber as recited in claim 1, wherein the sub-nozzle holes are positioned such that the a distance between them the sub-nozzle holes becomes wider toward their proximate top open ends of the sub-nozzle holes.
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Type: Grant
Filed: Nov 17, 2006
Date of Patent: May 25, 2010
Assignee: Kubota Corporation (Osaka)
Inventors: Koichi Funaki (Osaka), Seishiro Kubo (Osaka)
Primary Examiner: Erick Solis
Attorney: Panitch Schwarze Belisario & Nadel LLP
Application Number: 11/601,616
International Classification: F02B 19/18 (20060101);