The present invention relates to an exhaust gas muffler for an internal combustion engine, especially a two-cycle engine in a manually-guided implement such as a power saw, a cut-off machine, or the like.
An exhaust gas muffler is known from DE 696 18 194 T2, according to which exhaust gases exiting from the outlet flow out over a housing wall of the muffler. This is intended to achieve a good mixing of the exhaust gases with the cooling air of the internal combustion engine that is conveyed by a fan, so that the exhaust gas temperature drops. Due to the mixing of the exhaust gases with the cooling air stream, however, it is possible to achieve only a slight drop in the temperature of the exhaust gas. Furthermore, with exhaust gas mufflers having a catalytic converter, the exhaust gas is greatly reheated in the catalytic converter. No adequate drop in the temperature of the exhaust gases can be achieved by mixing the exhaust gases with cooling air. At the same time, the exhaust gas muffler is greatly heated up by the high exhaust gas temperatures, so that additional thermal insulation must be provided for the exhaust gas muffler. Such thermal insulation measures are expensive, and increase the overall size of the exhaust gas muffler.
It is therefore an object of the present invention to provide an exhaust gas muffler of the aforementioned general type that has a straightforward construction and a small overall size, and with which low exhaust gas temperatures can be achieved.
This object, and other objects and advantages of the present invention, will appear more clearly from the following specification in conjunction with the accompanying schematic drawings, in which:
The exhaust gas muffler of the present application comprises a housing having an inlet for receiving the exhaust gas from the internal combustion engine, an outlet out of the housing, and an outer wall, wherein the outlet and the outer wall are configured such that exhaust gas flows out of the outlet and over the outer wall, and wherein the exhaust gas that flows out of the outlet draws in atmospheric air between the exhaust gas and the outer wall of the housing.
For the cooling of gas turbines, it is known to use cooling air streams that flow into the hot surrounding air through openings in the surface that is to be cooled. With this type of cooling, an undesired effect can be that hot surrounding air is drawn in between the surface that is to be cooled and the cooling air streams, so that undesirably high temperatures result at the surface that is to be cooled. This effect is described, for example, in “DISCRETE-JET FILM COOLING: A COMPARISON OF COMPUTATIONAL RESULTS WITH EXPERIMENTS”, published by the ASME, or in “A Detailed Analysis Of Film-Cooling Physics: Part 1—Streamwise Injection With Cylindrical Holes”.
It is now proposed pursuant to the present invention to utilize the undesired effect known with the cooling of gas turbines for the cooling of mufflers. In this connection, the hot exhaust gases are used in order to draw in cool surrounding or atmospheric air against the wall of the muffler. This can be achieved by appropriate design of the discharge angle of the exhaust gases out of the muffler, as well as the flow velocity of the exhaust gas.
By drawing in atmospheric air along the housing wall, the housing wall of the exhaust gas muffler can be actively cooled. To achieve this effect, it is merely necessary to appropriately dimension the discharge angle and the flow velocity of the exhaust gas. Further structural measures are not necessary. In particular, channels or protective hoods on the outside of the housing of the muffler for guiding the exhaust gas along the outside of the housing can be eliminated. An active conveyance of the atmospheric air is also not necessary, since the atmospheric air is drawn in by the underpressure that results between the housing wall and the exhaust gases.
The exhaust gases in the interior of the housing advantageously flows along the outer wall of the housing. In so doing, the exhaust gases heat the outer wall of the housing and are themselves cooled by the heat transfer. The outer wall of the housing is actively cooled by the atmospheric air that is drawn in by the exiting stream of exhaust gas, so that the outer wall of the housing forms a heat exchanger. To achieve a high heat transfer to the atmospheric air, it is provided in particular that the exhaust gases in the interior of the housing, and the atmospheric air on the outside of the housing, flow along the outer wall of the housing in counter current relative to one another, so that a counter current heat exchanger is formed on the outer wall of the housing. Due to the transfer of heat from the exhaust gases to the housing wall, the discharge temperature of the exhaust gas out of the exhaust gas muffler is also considerably reduced. Advantageously formed in the interior of the housing is a channel that is delimited toward the outside of the housing by the outer wall of the housing, and through which flow the exhaust gases. The heat exchanger can be designed via the dimensions of the channel, and the flow velocity in the channel can be adapted to the flow velocity along the outside of the housing such that an optimum heat transfer results. The channel advantageously opens out at the outlet. To guide the exhaust gases over the outer wall of the housing, it is provided that the muffler have at least one hood on which the outlet is formed. The hood can have a straightforward construction, and makes it possible in a straightforward manner to fix the discharge angle of the exhaust gas. In particular, the exhaust gases flow out at the outlet at an angle relative to the outer wall of the housing. In this way, it is possible in a straightforward manner to ensure a drawing-in of atmospheric air between exhaust gases and the outer wall of the housing.
A ramp is advantageously disposed on the outer wall of the housing on that side that is opposite from the outlet. The ramp deflects the exhaust gases and the drawn-in atmospheric air, so that the exhaust gases are mixed with the atmospheric air, and in so doing a further cooling of the exhaust gases is effected. At the same time, by means of the ramp it is possible in a straightforward manner to achieve a prescribed discharge direction. Expediently disposed on the outer wall of the housing is a fin that extends parallel to the direction of flow of the exhaust gases along the outer wall of the housing. The fin forms a delimitation for the drawn-in atmospheric air, thus ensuring that the atmospheric air is passed by along the outer wall of the housing. At the same time, the surface of the exhaust gas muffler is increased via the fin. The exhaust gases flowing in the interior of the fin are also cooled by the drawn-in atmospheric air.
The exhaust gas muffler expediently has two chambers that are successively arranged in the direction of flow of the exhaust gases, whereby a catalytic converter is disposed between the two chambers. The catalytic converter effects an afterburning of the exhaust gases, so that prescribed exhaust gas emission values can be maintained, and the exhaust gas quality can be improved. A spark arrestor screen is expediently disposed in the flow path between the second chamber and the channel. The spark arrestor screen prevents glowing particles, which can be formed in the catalytic converter due to the high temperatures, from reaching the outside of the housing. By disposing the spark arrestor screen in the flow path directly after the catalytic converter, the temperatures at the spark arrestor screen are sufficiently high to burn any particles that might have been retained. A third chamber is advantageously disposed in the flow path between the second chamber and the outlet. In this connection, it is in particular provided that a portion of the exhaust gases flow through the third chamber, and a portion of the exhaust gases flow through the channel. Since not all of the exhaust gases flow through the channel, the flow velocity at the channel can be easily adapted to the flow velocity of the drawn-in atmospheric air, so that a good thermal discharge or removal is established at the heat exchanger. At the same time, the exhaust gases flowing into the third chamber are further cooled.
The muffler is advantageously constructed of two half shells, whereby the half shell that faces away from the internal combustion engine is designated the upper half, and the half shell that faces the internal combustion engine is designated the lower half. The outlet is expediently formed in the upper half, and the inlet is expediently formed in the lower half. In this connection, the outer wall of the housing is in particular a wall of the upper half of the muffler. A straightforward construction results if a first partition is disposed between the two half shells, with this partition separating the first chamber from the second chamber. In this connection, the catalytic converter is in particular disposed in the first partition. It is provided that the exhaust gas muffler have a second partition that is disposed between the first partition and the upper half. The third chamber is, in this connection, advantageously delimited by the second partition and the upper half. A setting of the quantity of exhaust gas flowing through the third chamber can be achieved in a straightforward manner by forming a gap between the second partition and the upper half through which the exhaust gases flow into the third chamber. By means of the flow cross-section of the gap, the quantity of exhaust gas flowing into the third chamber is determined. By means of the quantity of exhaust gas, the temperature of the upper half in the region of the third chamber can be established. The channel is advantageously delimited by the second partition and the upper half. Thus, no further components are required to form the channel. The spark arrestor screen is in particular disposed in the second partition.
Further specific features of the present application will be described in detail subsequently.
Referring now to the drawings in detail, the schematic illustration of
In operation, the exhaust gases flow in the direction of flow 22 out of the cylinder 14, into the first chamber 16, and through the catalytic converter 9 into the second chamber 17. The exhaust gases leave the second chamber 17 via the spark arrestor screen 21 and enter the channel 19. In the channel 19, the exhaust gases are guided along the outer wall 20 and essentially parallel thereto. The exhaust gases leave the exhaust gas muffler 1 at the hood 12 through the outlet 7. The hood 12 is disposed such that the exhaust gases out of the outlet 7 flow over the outer wall 20 of the housing. The direction of flow 22 of the exhaust gases flowing out of the outlet 7 is inclined at an angle α relative to the outer wall 20 of the housing 2. The direction of flow 22 of the exhaust gases along the outer wall 20 of the housing is such that atmospheric air is drawn in along the outer wall 20 of the housing in the direction of flow 23 between the outer wall 20 and the exhaust gases. The angle α is advantageously approximately 2° to approximately 10°. In particular, the angle α is about 4° to about 8°. An angle α of about 5° to about 7° is particularly advantageous
As shown in the side view of
As shown in
A third chamber 29 is formed between the raised portions 41 and 42. As shown in
As shown in
By means of the exhaust gas flowing out of the housing at the angle α, the atmospheric air is drawn in against the outer wall 20 of the housing 2, with this outer wall 20 delimiting the channel 19. At the region of the outer wall of the housing that delimits the chamber 29, no atmospheric air is drawn in, so that here no active cooling, and no heat exchange effect, result between the air flowing within the muffler through the chamber 29, and the surroundings. By establishing the proportion of the exhaust gases that flow through the chamber 29, and hence at most partially along the actively cooled outer wall 20 of the housing, the exhaust gas temperature can be established.
The specification incorporates by reference the disclosure of German priority document 103 35 864.1 filed Aug. 6, 2003.
The present invention is, of course, in no way restricted to the specific disclosure of the specification and drawings, but also encompasses any modifications within the scope of the appended claims.
Number | Date | Country | Kind |
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103 35 864.1 | Aug 2003 | DE | national |
This application is a continuation-in-part of pending application Ser. No. 10/913,029 filed Aug. 5, 2004.
Number | Date | Country | |
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Parent | 10913029 | Aug 2004 | US |
Child | 12555660 | US |