Exhaust silencer and communicating pipe thereof

Information

  • Patent Grant
  • 6241044
  • Patent Number
    6,241,044
  • Date Filed
    Friday, February 4, 2000
    24 years ago
  • Date Issued
    Tuesday, June 5, 2001
    23 years ago
Abstract
More than two damping chambers 2A to 2C), a communicating pipe (6) for intercommunicating the damping chambers (2A, 2B) and another communicating pipe (7) for intercommunicating the damping chambers (2B, 2C) are provided. Both ends of the communicating pipes (6, 7) are closed by an end plate (9) and the respective damping chambers (2A to 2C) and inside of the communicating pipes (6, 7) are intercommunicated by communicating holes (8A) on an outer circumference of the communicating pipes (6, 7). Exhaust gas flows from the damping chamber (2A) to communicating holes (8A1), inside of the communicating pipe (6), communicating holes (8A2), the damping chamber (2B), communicating holes (8A3), inside of the communicating pipe (7), communicating holes (8A4), and the damping chamber (2C), thus damping exhaust noise by repeated effective contraction and expansion.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to an exhaust silencer of an internal combustion engine used for construction equipment and the like and a communicating pipe thereof.




2. Description of Related Art




An exhaust silencer called a “muffler” is connected to an exhaust pipe of an internal combustion engine used for a construction equipment etc. for reducing exhaust noise from a combustion chamber.




Conventionally, various arrangements are known for the exhaust silencer. In an internal combustion engine of construction equipment, a multistage-expansion type in which sound is damped by repeating contraction and expansion of exhaust gas and a resonant type in which the exhaust gas is resonated for damping sound are known as conventional examples of the exhaust silencer.




A conventional example of the multistage-expansion type exhaust silencer is shown in FIG.


15


.




In

FIG. 15

, the conventional exhaust silencer


100


has three partitions


52


A to


52


C aligned in an axial direction for partitioning an inside of a drum-shaped body


51


into four chambers


51


A to


51


D, a communicating pipe


53


supported by the partitions


52


A to


52


C coaxially with the body


51


, an inlet pipe


54


with an end and intermediate portion thereof being secured to the body


51


to face the uppermost-stream chamber


51


A, and an outlet pipe


55


with an end and intermediate portion thereof being secured to the body


51


to face the lowermost-stream chamber


51


D.




Among the partitions


52


A to


52


C, a large opening


52


D to intercommunicate adjacent chambers is formed on the partitions


52


A and


52


C supporting both end sides of the communicating pipe


53


. Both ends


53


A of the communicating pipe


53


respectively facing the first chamber


51


A and the fourth chamber


51


D is closed, and a large number of communicating hole


53


B is formed on a circumference of the communicating pipe


53


.




An end


54


A of the inlet pipe


54


is closed and a plurality of communicating hole


54


B is formed on a circumference of the communicating pipe


54


. The outlet pipe


55


has a plurality of communicating hole


55


B and an end being open to the air.




Flow of the exhaust gas sent from the outlet pipe is straightened in radial direction by the communicating holes


54


B of the inlet pipe


54


and is sent to the first chamber


51


A, and the exhaust gas is damped by being sent from the first chamber


51


A to the second chamber


51


B through the opening


52


D. Subsequently, the exhaust gas flows to inside of the communicating pipe


53


through the communicating holes


53


B, circulates with angle thereof being changed into an axial direction, and is sent to the third chamber


51


C through the communicating holes


53


B. Further, the exhaust gas is sent from the third chamber


51


C to the fourth chamber


51


D through the opening


52


D to flow into the outlet pipe


55


through the communicating holes


55


B, which is discharged into the air.




Accordingly, the circulating exhaust gas repeatedly experiences total of four contractions and expansions by the two openings


52


D and the two communicating holes


53


B, thereby conducting so-called multistage-expansion type damping. Especially, the exhaust gas passes a predetermined length (a predetermined time) in the communicating pipe


53


while being contracted without full expansion, thus experiencing effective damping effect.




However, following disadvantage occurs in the multistage-expansion type exhaust silencer.




Though the opening


52


D for contracting the exhaust gas is formed on the partitions


52


A and


52


C for dividing adjacent chambers, sufficient damping effect cannot be obtained when the opening area of the opening


52


D is large.




More specifically, the opening


52


D is an opening formed on the partitions


52


A and


52


C and there is only small length in the gas flow direction. Accordingly, rectification effect is deteriorated when the opening are is enlarged in accordance with increase in flow velocity of the exhaust gas.




Accordingly, when the rectification effect is lowered by enlarging the opening


52


D of the respective partitions


52


A and


52


C in the conventional example, though there are apparently four damping chambers (the first chamber


51


A to the fourth chamber


51


D), only two practically effective damping chambers, i.e. upstream chamber and lower-stream chamber provided on both sides of the central partition


52


B, can be established, which deteriorates noise reduction effect.




A conventional example of resonant type exhaust silencer will be described below.




Generally, the resonant type exhaust silencer has a plurality of chamber inside drum-shaped body divided by partitions, a part of the plurality of chambers being a resonant chamber for damping the exhaust noise.




For example, the resonant chamber is formed on a position between two damping chambers. A communicating pipe stretches over the two damping chambers sandwiching the resonant chamber and passes through the resonant chamber. An intermediate portion of the communicating pipe is exposed to the resonant chamber, and a large number of communicating holes are formed on a circumference of the intermediate portion to intercommunicate an inside of the communicating pipe and an inside of the resonant chamber.




A substantial part of the exhaust gas sent from the upstream damping chamber is sent to the lower-stream chamber through the communicating pipe and the rest is sent to the resonant chamber through the communicating holes. The exhaust gas (pressure wave thereof) reflects in the resonant chamber to reduce energy thereof especially on a resonant range thereof. The exhaust gas returned from the resonant chamber to the communicating pipe by pulsation etc. joins the exhaust gas flowing toward the lower-stream dumping chamber.




However, following problems occur in the resonant type exhaust silencer.




First, only specific frequency of the exhaust noise is damped in the resonant chamber and noise reduction for the entire range of the exhaust noise cannot be expected.




Since the resonant chamber has to be tuned for each type of the internal combustion engine, which complicates design and deteriorates at none-tuned frequency.




Further, since a large space is required for the exhaust silencer to have the resonant chamber, the size of the exhaust silencer itself has to be made large.




A combination of the above multistage-expansion type and the resonant type has been developed.




Since the ordinary multistage-expansion type exhaust silencer alternately circulates the exhaust gas between the inside of the pipe and the damping chamber through a pipe hole to damp the exhaust noise, resistance is caused to raise backpressure by repeating contraction and expansion of the exhaust gas passing the pipe hole.




To solve the above disadvantage, a control valve has been used for controlling the backpressure (Japanese Patent Laid-Open Publication No. Hei 11-22444).




Though the above arrangement is basically a multistage-expansion type having a plurality of damping chamber inside a cylindrical shell, a communicating pipe passing through, for instance, three damping chambers are provided, and a controllably openable control valve is provided inside the communicating pipe to a position corresponding to an intermediate chamber.




At low engine speed, the control valve is closed to shut the communicating pipe. Accordingly, the exhaust gas passing the communicating pipe enters into the intermediate damping chamber from upstream side relative to the control valve and is discharged to lower-stream side of the communicating pipe relative to the control valve. In other words, the intermediate damping chamber functions as a multistage-expansion type exhaust silencer, so that damping effect can be improved.




On the other hand, the control valve is opened at high engine speed to release shutting of the communicating pipe. Accordingly, a part of the exhaust gas passing the communicating pipe directly flows into the lower-stream damping chamber and another part enters into and go out of the intermediate damping chamber, so that the intermediate damping chamber works as a resonant chamber. Accordingly, damping effect by the resonant chamber can be obtained while largely reducing the exhaust resistance at the communicating pipe.




However, there can be following disadvantage in the above arrangement.




Though pressure loss of exhaust gas can be avoided at a high engine speed, damping effect covering entire sound range as in the multistage-expansion type cannot be obtained and noise of specific frequency can only be reduced by the resonant effect.




Further, since the control valve is used, a movable portion is required in a high-temperature portion, thus lacking reliability.




SUMMARY OF THE INVENTION




An object of the present invention is to provide an exhaust silencer and communicating pipe thereof capable of sufficiently damping exhaust noise.




Another object of the present invention is to provide an exhaust silencer capable of reducing pressure loss of exhaust gas and sufficiently damping exhaust noise.




An exhaust silencer according to the present invention is connected to an outlet pipe of an internal combustion engine. The exhaust silencer includes: a plurality of damping chambers of more than two, the plurality of damping chambers having an uppermost-stream damping chamber having an exhaust gas inlet for directly introducing exhaust gas of the internal combustion engine, and lowermost-stream damping chamber having an exhaust gas outlet for discharging the exhaust gas; and a communicating pipe for intercommunicating predetermined space of the plurality of damping chambers, the communicating pipe having an end plate on both ends and a number of communicating holes on an outer circumference at a predetermined position corresponding to the damping chamber to be interconnected.




According to the present invention, the exhaust gas generated in the internal combustion engine initially directly flows into the exhaust gas inlet to be sent to the upper-most damping chamber for expansion, thus damping the exhaust noise. Since the predetermined space of the plurality of (more than two) damping chambers including the uppermost-stream damping chamber is intercommunicated by the communicating tube and the communicating tube has the end plates on both sides and a large number of communicating holes on a circumference thereof, the exhaust gas flowed into the uppermost-stream damping chamber is sent from the radial direction to the inside of the pipe while being contracted by the communicating holes. Subsequently, the exhaust gas moves in the pipe in the axial direction and is sent and expanded into the next damping chamber after being contracted by the communicating holes. Further, the exhaust gas is sent into the damping chamber, the next damping chamber and, finally, the lowermost-stream damping chamber through the communicating pipe and is discharged to the outside through the exhaust gas outlet.




In other words, the exhaust gas experiences repeated contraction and expansion by the communicating holes of the communicating pipe when the exhaust gas is sent to the lower-stream damping chamber, so that the pressure thereof is lost and the energy is damped by changing flow in the axial direction and the radial direction, thus obtaining sufficient dumping effect.




Especially, the exhaust gas is always kept in a contracted status between the damping chambers for a predetermined length by the communicating pipe, thereby obtaining secure damping effect.




In the present invention, a total opening area of the communicating holes on the communicating pipe open to the uppermost-stream damping chamber may preferably smaller than respective total opening area of the communicating holes open to lower-stream damping chamber.




According to the above arrangement, since the exhaust gas enters from a small opening and flows out from a large opening, the exhaust gas is substantially expanded, thus obtaining good noise reduction effect of the exhaust gas and the jet noise generated in the upstream side does not remain to the lower-stream side.




In the present invention, a volume of the damping chamber on the uppermost-stream side may preferably be the largest of the plurality of damping chambers.




According to the above arrangement, since the damping chamber on the uppermost-stream side has a sufficient volume, the exhaust gas just introduced into the exhaust silencer from the outside rapidly expands, thus reducing the exhaust noise more effectively.




In the present invention, a volume of a damping chamber to which the communicating holes of the communicating pipe having the least total opening area directly opens may preferably the largest.




According to the above arrangement, since the exhaust gas contracted to the minimum by the communicating pipe having the least total opening area is introduced into the damping chamber having the largest volume, the exhaust gas sent into the damping chamber rapidly expands, thus more effectively reducing the exhaust noise.




In the present invention, a communicating portion for flowing the exhaust gas in an axial direction may preferably be provided to the end plates on either or both ends of the communicating pipe.




In other words, the end plates on both sides of the communicating pipe may not be necessarily completely closed, but may have semi-closed structure having the communicating portion such as small holes on the end plates as long as the flow-in and flow-out of the exhaust gas from the communicating holes on the outer circumference of the communicating pipe can be substantially conducted.




According to the above arrangement, the communicating portion provided to the end plates of the communicating pipe can be used as an aid of the communicating holes provided to a circumference of the communicating tube.




In the present invention, a cross section of the upstream communicating pipe may preferably be smaller than lower-stream communicating pipe.




When the cross-section becomes larger toward the lower-stream, the flow velocity of the exhaust gas in the communicating pipe can be lowered as going down to the lower-stream or the exhaust gas in the communicating pipe expands, thus reducing jet noise generated in the communicating pipe.




In the present invention, an entirety of the communicating pipe may preferably be formed of a single consecutive communicating pipe; and a communicating pipe cutoff partition may preferably be formed to an intermediate position of respective damping chambers except for the uppermost-stream damping chamber and the lowermost-stream damping chamber.




According to the above arrangement, since it is not required to dispose the plurality of the communicating pipe in the same damping chamber parallel in axial direction, the size of the exhaust silencer can be reduced. Further since the structure is simple, the silencer can be provided at a low cost.




In the above arrangement, a partitioning wall for partitioning a part of the respective damping chambers may preferably be provided to an outer circumference of the cutoff partition.




According to the above arrangement, since the exhaust gas flowing out of the upstream communicating holes of the cutoff partition flows into the lower-stream communicating holes passing over the partitioning wall, the exhaust gas seemingly goes through another damping chamber, thus performing sufficient damping effect.




In the present invention, an opening area of the communicating holes of the communicating pipe may preferably become smaller toward lower-stream side in exhaust flow direction.




According to the above arrangement, though the exhaust gas sent in the communicating pipe in the axial direction tries to concentrate around the lower-stream partition to flow out from the communicating holes, since the opening area of the communicating holes becomes smaller toward the lower-stream of the communicating pipe, the exhaust gas does not concentrate to a predetermined portion but flows out uniformly from the communicating holes aligned in the axial direction, thus reducing jet noise generated in the communicating pipe. In other words, the exhaust gas can more easily flow out as approaching toward the upper-stream, and an effect similar to narrowing the lower-stream pipe can be obtained.




In the present invention, a communicating portion for bypassing the exhaust gas may preferably provided to a partitioning portion for partitioning mutually adjacent damping chambers.




In other words, the partitioning portion for dividing the mutually adjacent damping chambers may not be completely closed but may be semi-closed for by-passing the exhaust gas by the communicating portion such as small holes formed on the partitioning portion.




According to the above arrangement, the communicating portion provided to the partitioning portion can be used as an aid for the communicating holes provided to the communicating pipe.




Another aspect of the present invention is a communicating pipe used for an exhaust silencer having a plurality of damping chamber; the plurality of damping chambers having an uppermost-stream damping chamber an exhaust gas inlet for directly introducing exhaust gas of the internal combustion engine, and lowermost-stream damping chamber having an exhaust gas outlet for discharging the exhaust gas. The communicating pipe is used for intercommunicating a predetermined chambers of the plurality of damping chambers, which is characterized in having: an end plate provided at least to a lower-stream end; and a large number of communicating holes provided to a predetermined position on an outer circumference corresponding to the chamber to be intercommunicated, the end plate on the lower-stream end being a hollow plate dented toward inside.




Conical shape, spherical shape can be listed as an example of the configuration of the hollow plate.




Ordinarily, since the exhaust gas flowing in the communicating pipe in the axial direction bumps into the end plate to flow out of the communicating holes adjacent to the end plate, when the velocity distribution and the outflow distribution flowing out from the communicating holes of the communicating pipe are observed, the velocity distribution or the outflow distribution adjacent to the end plate is large, which becomes smaller as far from the end plate. Accordingly, uniform flow cannot be obtained at a position adjacent to the end plate.




On the other hand, the exhaust gas sent in the axial direction inside the communicating pipe more easily flows in the radial direction by the end plate formed of the hollow plate according to the present invention. Further, since the flow path becomes narrower as approaching toward the lower-stream, the exhaust gas flowing out of the pipe by bumping into the end plate can easily flow in the radial direction from the communicating holes, thus reducing jet noise generated in the communicating pipe.




A further aspect of the present invention is an exhaust silencer connected to an outlet pipe of a combustion engine for damping exhaust noise by contracting and expanding a flow path for exhaust gas to be circulated, comprising: a main flow path for circulating majority of the exhaust gas; and at least one by-path flow path for constantly circulating a part of the exhaust gas.




According to the present invention, since a part of the exhaust gas discharged from the internal combustion engine flows through the by-path flow path as well as the main flow path, loss caused by exhaust pressure applied to the main flow path can be prevented from being excessively high. When a by-pass flow path having on-off valve is provided in addition to the main flow path, a large backpressure is applied to the main flow path by shutting the by-pass flow path accidentally by the on-off valve. However, when the exhaust gas constantly circulates in the by-path flow path, large backpressure is not applied to the main flow path.




Further, since the exhaust gas joins after separately circulating the main flow path and the by-path flow path so that the exhaust noise (sound wave) mutually interferes and damps, the exhaust noise can be reduced.




In the present invention, cross section of the sub flow path may preferably be defined so that amount of the exhaust gas circulating therein is 5 to 30% of total exhaust gas circulating in the entire silencer.




According to the present invention, the effect of the above arrangement can be more securely attained by setting the amount of the exhaust gas in the by-path flow path.




Specifically, when the above value is less than 5%, the pressure loss of exhaust gas becomes too high, and when the above value exceeds 30%, the damping effect obtained by contraction and expansion of the flow path for circulating the exhaust gas becomes insufficient.




In the present invention, the exhaust silencer may further include a plurality of damping chamber, a partition for dividing the plurality of the damping chamber, and a communicating pipe for intercommunicating the plurality of the damping chamber, the partition having at least one communicating portion for circulating the exhaust gas.




According to the above arrangement, since the exhaust silencer is composed of the damping chambers, the partition and the communicating pipe, and the communicating portion constituting the by-path flow path are formed on the partition, the size of the entire silencer can be made small.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a cross section showing entire structure of an exhaust silencer according to first embodiment of the present invention;





FIG. 2

is a side elevation of

FIG. 1

;





FIG. 3

is a cross section showing entire structure of an exhaust silencer according to a second embodiment of the present invention;





FIG. 4

is a cross section showing entire structure of an exhaust silencer according to third embodiment of the present invention;





FIG. 5

is a cross section showing entire structure of an exhaust silencer according to fourth embodiment of the present invention;





FIG. 6

is a cross section showing entire structure of an exhaust silencer according to fifth embodiment of the present invention;





FIG. 7

is a cross section taken along VII—VII line in

FIG. 6

viewed in allow-indicating direction;




FIG.


8


(A) is a graph showing a relationship between ratio to total gas and noise value;




FIG.


8


(B) is a graph showing a relationship between ratio to total gas and exhaust resistance;





FIG. 9

is a cross section showing entire structure of an exhaust silencer according to sixth embodiment of the present invention;





FIG. 10

is a side elevation of

FIG. 9

;





FIG. 11

is a cross section showing entire structure of an exhaust silencer according to seventh embodiment of the present invention;





FIG. 12

is a cross section showing entire structure of an exhaust silencer according to eighth embodiment of the present invention;





FIG. 13

is a cross section showing entire structure of an exhaust silencer according to ninth embodiment of the present invention;




FIGS.


14


(A) to FIG.


14


(D) are cross sections showing modifications of the present invention; and





FIG. 15

is a cross section showing a conventional example.











DETAILED DESCRIPTION OF PREFERRED EMBODIMENT(S)




Embodiments of the present invention will be described below with reference to attached drawings. In respective embodiments, the same reference numerals are applied to the same components to omit or simplify description therefor.




First Embodiment




First embodiment of the present invention is shown in

FIGS. 1 and 2

.




In the figures, an exhaust silencer


10


of the first embodiment is connected to an exhaust pipe (not shown) of a diesel engine for construction equipment. The exhaust silencer


10


includes: a body


2


having a shape of both-end-bottomed cylinder having both ends being closed by end plates


1


, i.e., drum-shape; first and second partitions


3


A and


3


B disposed parallel in an axial direction of the body


2


for partitioning the body


2


into first to third damping chambers


2


A to


2


C; an exhaust gas inlet pipe


4


in communication with the first damping chamber


2


A and having the exhaust pipe connected thereto; a first damping chamber


2


A and having the exhaust pipe connected thereto; a tail pipe


5


in communication with the third damping chamber


2


C; first communicating pipe


6


with an intermediate portion being supported by the first partition


3


A and an end being supported by the second partition


3


B; and second communicating pipe


7


with an end being supported by the first partition


3


A and an intermediate portion being supported by the second partition


3


B.




The first and second partitions


3


A and


3


B respectively have a disk


3


D, a peripheral portion


3


E standing on a periphery of the disk


3


D and abutting inner circumference of the body


2


, and a support


3


F for supporting the two communicating pipes


6


and


7


at a central portion of the disk


3


D.




One peripheral portion


3


E of the partitions


3


A and


3


B are secured to the inner circumference of the body


2


by welding etc, and the other peripheral portion


3


E of the partitions


3


A and


3


B is press-fitted to the inner circumference of the body


2


movably in axial direction.




The exhaust gas inlet pipe


4


is secured by welding etc. to an outer circumference of the body


2


so that an axis thereof becomes orthogonal with axial direction of the body


2


. An end portion open to first damping chamber


2


A at the uppermost-stream side is an exhaust gas inlet


4


A for introducing the exhaust gas generated by the diesel engine through a connecting pipe.




Incidentally, though the exhaust gas inlet


4


is depicted as being opposite (below in the figure, 180 degrees position) to the tail pipe


5


sandwiching the axis of the body


2


, it is just for clarifying the relationship between the exhaust gas inlet pipe


4


and the first damping chamber


2


A. In actual implementation, the tail pipe


5


may be attached in approximately 90 degrees position relative to the exhaust gas inlet pipe


4


around the axis of the body


2


, as shown in FIG.


2


.




The tail pipe


5


is fixed to the outer circumference of the body


2


so that an axis thereof becomes orthogonal with axial direction of the body


2


. An end portion open to third damping chamber at the most lower-stream side is an exhaust gas outlet


5


A for discharging the exhaust gas to the outside.




The first communicating pipe


6


is composed of a cylindrical member


8


having an axis parallel to the axial direction of the body


2


and an end plate


9


disposed on both ends of the cylindrical member


8


.




An outer circumference of the cylindrical member


8


has a large number of communicating hole


8


A


1


to a portion facing the first damping chamber


2


A, and another large number of communicating hole


8


A


2


to a portion facing the second damping chamber


2


B. The number of the communicating holes


8


A


1


open to the first damping chamber


2


A is less than the number of the communicating holes


8


A


2


open to the second damping chamber


2


B. Accordingly, in the first communicating pipe


6


, total opening area of the communicating holes


8


A


1


is less than total opening area of the communicating holes


8


A


2


open to the second damping chamber


2


B. More specifically, the total area of the communicating holes


8


A


1


open to the first damping chamber


2


A is smaller than cross sectional area of the first communicating pipe


6


and the total area of the communicating holes


8


A


2


open to the second damping chamber


2


B is larger than cross sectional area of the first communicating pipe


6


. The end plate


9


is not restricted to have completely closed structure, but may have semi-closed structure having communicating portion such as small holes as long as flow-in and flow-out of the exhaust gas from the communicating holes


8


A on the outer circumference of the communicating pipe


6


can be substantially conducted. When the end plate


9


has the semi-closed structure, the end plate


9


disposed to the first damping chamber


2


A may preferably have semi-closed structure for reducing flow resistance of the exhaust gas.




Similarly to the first communicating pipe


6


and


7


, the second communicating pipe


7


has a cylindrical member


8


having an axis parallel to the axial direction of the body


2


and end plates


9


disposed to both ends of the cylindrical member


8


.




On an outer circumference of the cylindrical member


8


of the second communicating pipe


7


, a large number of communicating holes


8


A


3


is formed to a portion open to the second damping chamber


2


B and another large number of communicating holes


8


A


4


is formed to a portion open to the third damping chamber


2


C. The number of the communicating holes


8


A


3


open to the second damping chamber


2


B is the same or less than the number of the communicating holes


8


A


4


open to the third damping chamber


2


C. Accordingly, the total opening area of the communicating holes


8


A


3


open to the second damping chamber


2


B of the second communicating pipe


7


is the same or less than the total opening area of the communicating holes


8


A


4


open to the third damping chamber


2


C.




As in the first communicating pipe


6


, the end plate


9


of the second communicating pipe


7


may have completely closed structure, or alternatively, semi-closed structure. However, semi-closed structure is preferable for the end plate


9


disposed to the third damping chamber


2


C for reducing the resistance of the exhaust gas flow.




The first and second partitions


3


A and


3


B form a partitioning, which is not restricted to the completely closed structure but may have semi-closed structure having communicating portion such as small holes for bypassing a part of the exhaust gas as long as flow-in and flow-out of the exhaust gas from the communicating holes


8


A


1


to


8


A


4


on the outer circumference of the communicating pipes


6


and


7


can be substantially conducted.




The first damping chamber


2


A is positioned uppermost-stream side and has volume ratio to volume of the entire damping chambers, i.e. total volume of the first to third damping chambers


2


A to


2


C, of 40 to 50%, which is the largest volume among the first to the third damping chambers


2


A to


2


C.




When the volume ratio of the first damping chamber


2


A to the entire damping chambers is less than 40%, the exhaust noise damped when the exhaust gas flows from the exhaust gas inlet pipe


4


to be expanded in the first damping chamber


2


A is reduced. On the other hand, when the volume ratio exceeds 50%, the size of the entire exhaust silencer


10


is made large on account of balance against the other damping chambers


2


B and


2


C, thus deteriorating damping effect relative to enlarged proportion of the silencer.




In other words, since a volume exceeding a predetermined amount is required for the other damping chambers


2


B and


2


C in accordance with flow velocity of the exhaust gas flowing into the exhaust gas inlet pipe


4


, when the size of the first damping chamber


2


A exceeds 50% of the total volume while retaining the volume, the size of the body


2


is increased, thus making the entire exhaust silencer


10


large.




The volume ratio of the second damping chamber


2


B and the third damping chamber


2


C may be arranged in any manner, that is, the volume of the second damping chamber


2


B may be larger than the volume of the third damping chamber


2


C, or may be smaller, or may be the same.




In order to construct the exhaust silencer


10


, a sub-assembly of the first and the second partition


3


A and


3


B having the first communicating pipe


6


and the second communicating pipe


7


attached in advance is inserted to the inside of the body


2


with the side plate


1


being detached. With the end face of the body


2


is made open, the first and second partitions


3


A and


3


B are centered by fine adjustment relative to the body


2


. Subsequently, one of the first and the second partitions


3


A and


3


B are fixed to the body


2


by welding etc. and the other is press-fitted to the body


2


. Finally, both ends of the body


2


is closed by the end plate


1


, the exhaust gas inlet pipe


4


and the tail pipe


5


are attached to outer circumference of the body


2


, and the exhaust pipe of the diesel engine is connected to the exhaust gas inlet pipe


4


.




Next, a function of the first embodiment will be described below.




The exhaust gas generated by the diesel engine is sent to the exhaust gas inlet pipe


4


through the exhaust pipe. The exhaust gas sent to the exhaust gas inlet pipe


4


is blown into the first damping chamber


2


A positioned at the uppermost-stream side while being rapidly expanded, so that exhaust noise including low-frequency component is removed.




The exhaust gas sent to the first damping chamber


2


A is transferred to the inside of the first communicating pipe


6


while being contracted by the communicating holes


8


A


1


of the first communicating pipe


6


, during which the exhaust noise is damped. The second damping function is effected during the step where the exhaust gas enters the inside of the first communicating pipe


6


through the communicating holes


8


A


1


of the first communicating pipe


6


.




The flow of the exhaust gas flowing into the inside of the first communicating pipe


6


in radial direction through the communicating holes


8


A


1


is straightened inside the pipe with a direction thereof being turned in an axial direction. After the flowing direction is changed to a right angle by the communicating holes


8


A


2


and the flow is straightened, the exhaust gas is sent to the second damping chamber


2


B while being expanded to reduce pressure fluctuation of the exhaust gas.




The exhaust gas sent to the second damping chamber


2


B is blown into the inside of the second communicating pipe


7


while being contracted by the communicating holes


8


A


3


of the second communicating pipe


7


, during which the exhaust noise is damped.




The exhaust gas flowing into the inside of the second communicating pipe


7


from radial direction through the communicating holes


8


A


3


circulates inside the pipe by changing direction thereof in an axial direction, thereby reducing pressure fluctuation of the exhaust gas. Subsequently, after the flow of exhaust gas is straightened by the communicating holes


8


A


4


on the lower-stream side, the exhaust gas is sent to the third damping chamber positioned to the lowermost-stream side while being expanded, thus reducing pressure fluctuation of the exhaust gas.




The exhaust gas sent into the third damping chamber


2


C is discharged to the outside through the tail pipe


5


.




Incidentally, when the pressure fluctuation is reduced, diameter, size etc. of the communicating holes


8


A


1


to


8


A


4


of the communicating pipes


6


and


7


are defined so that the pressure loss of the exhaust gas caused when the flow turns in axial direction in the first communicating pipe


6


, when the flow is discharged from the first communicating pipe


6


into the second communicating pipe


7


, when the flow turns in axial direction in the second communicating pipe


7


and when the flow is discharged from the second communicating pipe


7


to the third damping chamber


2


C, and becomes approximately equal to a value proportionally dividing the rest of the pressure loss caused on entering into the first and second communicating pipes


6


and


7


.




According to the above-described first embodiment, following effects (1) to (10) can be obtained.




(1) Since the exhaust silencer


10


has the first to the third damping chambers


2


A to


2


C, the first damping chamber


2


A positioned at the uppermost-stream having the exhaust gas introduction hole


4


A for directly introducing the exhaust gas of the diesel engine, the exhaust gas introduced from the exhaust gas introduction hole


4


A to the first damping chamber


2


A expands to damp the exhaust noise. Further, since the first and the second communicating pipes


6


and


7


for intercommunicating adjacent spaces of the damping chambers


2


A to


2


C are provided, the communicating pipes


6


and


7


having end plates


9


on both side thereof and having a large number of communicating holes


8


A


1


to


8


A


4


to a predetermined position of the outer circumference corresponding to the chambers for intercommunication, the exhaust gas loses pressure thereof by experiencing repeated contraction and expansion by the communicating holes


8


A


1


to


8


A


4


of the communicating pipes


6


and


7


to damp energy thereof. Accordingly, the exhaust noise can be effectively damped.




In other words, since sufficient damping effect can be established with a comparatively small damping chamber, the size of the entire silencer can be reduced.




(2) Since the volume of the first damping chamber


2


A located at the uppermost-stream side has the largest volume of 40 to 50% of total volume, the exhaust gas introduced from the exhaust gas introduction hole


4


A to the first damping chamber


2


A rapidly expands, thus enhancing damping effect of the exhaust noise including low-frequency component.




(3) Since the total opening area of the communicating hole


8


A open to the upstream damping chambers


2


A and


2


B of the communicating pipes


6


and


7


is smaller than the total opening area of the communicating holes


8


A open to the lower-stream damping chambers


2


B and


2


C, large exhaust noise reduction effect can be obtained, and the jet noise generated at the upstream side does not remain to the lower-stream side.




(4) Since the total area of the communicating holes


8


A


1


open to the first damping chamber


2


A is smaller than the cross section of the first communicating pipe


6


and the total area of the communicating holes


8


A


2


open to the second damping chamber is larger than the cross section of the first communicating pipe


6


, the flow velocity of the exhaust gas on the lower-stream side can be lowered to reduce the pressure loss and jet noise.




More specifically, since the exhaust gas flows in axial direction inside the first communicating pipe


6


and the communicating holes


8


A


1


and


8


A


2


are opened to be orthogonal with the flow, the flow velocity on lower-stream side can be excessive when the total area of the lower-stream communicating holes


8


A


2


is less than the cross section of the communicating pipe


6


. Since the pressure loss is affected by a square of the flow velocity and is also affected by whether the flow is inside the communicating pipe


6


or passing the communicating holes


8


A


2


, the pressure loss is caused when the total area of the lower-stream communicating holes


8


A


2


is not larger than the cross section of the communicating pipe


6


to increase jet noise.




(5) Since the communicating holes


8


A is formed so that the pressure loss of the exhaust gas is the largest at the entrance of the first communicating pipe


6


(one third to half of the entire pressure loss), the pressure loss can be effectively generated at the upstream side having the largest energy of the exhaust gas, thereby obtaining great damping effect.




(6) When the end plates


9


on both ends of the communicating pipes


6


and


7


has semi-closed structure by forming small holes, the pressure loss can be reduced by using the small holes provided to the end plates


9


as an aid for the communicating holes


8


A.




(7) When a part of the exhaust gas is bypassed by forming small holes to the partitions


3


A and


3


B as partitioning, the small holes provided to the partitions


3


A and


3


B can be used as an aid of the communicating holes


8


A


1


to


8


A


4


formed on the communicating pipes


6


and


7


to reduce pressure loss.




(8) Since two partitions


3


A and


3


B are used for forming the three damping chambers and positioning of the two partitions


3


A and


3


B to the inner circumference of the body


2


is easy, assembly work can be easily conducted. On the other hand, in order to assemble the conventional exhaust silencer


100


, the communicating pipe


53


attached with the partitions


52


B to


52


C are mounted to a cylindrical inner circumference of the drum-shaped body


51


. At this time, the position of the partitions


52


A to


52


C has to be determined by moving in an axial direction of the body


51


and position adjustment of the partition


52


A and the communicating pipe


53


is difficult, thus complicating assembly work of the silencer.




(9) For constructing the exhaust silencer


10


, the first communicating pipe


6


and the second communicating pipe


7


are secured to the first and the second partitions


3


A and


3


B to be one component (sub-assembly), which is attached to the inside of the body


2


. Subsequently, the first and the second partitions


3


A and


3


B are finely adjusted in axial direction for defining position thereof. Accordingly, the assembly work can be easily and accurately conducted.




(10) Since one of the first and the second partitions


3


A and


3


B is fixed to the body


2


by welding etc. and the other is press-fitted, when the communicating pipes


6


and


7


are expanded by a heat of the exhaust gas, the thermal expansion of the communicating pipes


6


and


7


can be absorbed by relative movement of the press-fitted partitions


3


A and


3


B against the body


2


.




Incidentally, following arrangement is possible as a modification of the first embodiment.




The first damping chamber


2


A is the damping chamber having the largest volume in FIG.


1


. However, in the first embodiment, as long as the total area of the communicating holes


8


A


1


of the first communicating pipe


6


is smaller than the total area of the other communicating holes


8


A


2


to


8


A


4


, the volume of the chamber having the communicating holes


8


A


2


opening directly after the first communicating pipe


6


with the communicating holes


8


A


1


having the smallest opening area, i.e. second damping chamber


2


B, may be the largest.




According to the above arrangement, the same effects (1) and (3) to (10) as the first embodiment can be obtained, and following effect similar to the effect (2) can be obtained.




(2′) Since the volume of the second damping chamber


2


B in direct communication with the communicating pipe


6


having the communicating holes


8


A


1


with the minimum total opening area is the largest through the communicating pipe


8


A


2


, the exhaust gas contracted to the minimum by the communicating holes


8


A


1


with minimum total opening area is rapidly expanded by being introduced to the second damping chamber


2


B having the largest volume, thereby enhancing the damping effect of the exhaust gas including low-frequency component.




Such modification of the damping chamber having the largest volume can be respectively applied to each following embodiment.




Second Embodiment




Next, second embodiment of the present invention will be described below with reference to FIG.


3


.




The second embodiment differs from the first embodiment in that the communicating pipe is a single continuous communicating pipe, and the rest basic arrangement is the same as the first embodiment.




In

FIG. 3

showing entire structure, the exhaust silencer


20


of the second embodiment has a drum-shaped body


2


, first and second partitions


3


A and


3


B for partitioning the body


2


into the first to third damping chamber


2


A to


2


C, an exhaust gas inlet pipe


4


provided to the body


2


, a tail pipe


5


provided to the body


2


, a communicating pipe


16


supported by the first partition


3


A and the second partition


3


B respectively, a cutoff partition


17


provided to an axially intermediate position of the communicating pipe


16


corresponding to intermediary of the second damping chamber


2


B, and a partitioning wall


19


provided to an outer circumference of the cutoff partition


17


.




The communicating pipe


16


is composed of a cylindrical member


18


having an axis parallel to the axial direction of the body


2


, and end plates


9


provided to both ends of the cylindrical member


18


. The end plate


9


and the partitions


3


A and


3


B may be completely closed or semi-closed as in the first embodiment.




A large number of communicating holes


8


A


1


and


8


A


2


are formed to the outer circumference of the cylindrical member


18


on a portion facing the first damping chamber


2


A and the second damping chamber


2


B respectively on upstream side relative to the cutoff partition


17


of the communicating pipe


16


. The number of the communicating holes


8


A


1


open to the first damping chamber


2


A is smaller than the number of the communicating holes


8


A


2


open to the second damping chamber


2


B. Accordingly, the total opening area of the communicating holes


8


A


1


open to the first damping chamber


2


A is smaller than the total opening area of the communicating holes


8


A


2


open to the second damping chamber


2


B.




A large number of communicating holes


8


A


3


and


8


A


4


having the same configuration are respectively formed to the outer circumference of the cylindrical member


18


on a position facing the second damping chamber


2


B and the third damping chamber


2


C on lower-stream side relative to the cutoff partition


17


of the communicating pipe


16


. The number of the communicating holes


8


A


3


open to the second damping chamber


2


B is the same as or smaller than the communicating holes


8


A


4


open to the third damping chamber


2


C. Accordingly, the total opening area of the communicating holes


8


A


3


open to the second damping chamber


2


B is the same as or smaller than the total opening area of the communicating holes


8


A


4


open to the third damping chamber


2


C.




The cutoff partition


17


is configured in an approximate dish-shape with a peripheral portion


17


B abutting inner circumferential surface of the communicating pipe


16


and standing on a periphery of a disk member


17


A.




The cutoff partition


17


is provided for using the single communicating pipe


16


as two communicating pipes, in which upstream portion relative to the cutoff partition


17


corresponds to the first communicating pipe


6


of the first embodiment and the lower-stream portion relative to the cutoff partition


17


corresponds to the second communicating pipe


7


of the first embodiment.




The partitioning wall


19


is provided coplanarly to the cutoff partition


17


and includes a ring-shaped member


19


A facing the second damping chamber


2


B, a peripheral portion


19


B standing on a periphery of the ring-shaped member


19


A, and a support


19


C for supporting the communicating pipe


16


at the center of the ring-shaped member


19


A.




Next, an effect of the second embodiment will be described below.




In the second embodiment, the pressure fluctuation component of the exhaust noise is reduced when the exhaust gas sent to the exhaust gas inlet pipe


4


is blown into the first damping chamber


2


A on the uppermost-stream side while being rapidly expanded, as in the first embodiment.




The exhaust gas blown into the first damping chamber


2


A is sent to an inside of the communication pipe


16


while being contracted by the communicating holes


8


A


1


of the communicating pipe


16


, during which sound of the exhaust gas is damped. The pressure fluctuation component is reduced to damp the sound by energy consumption of the exhaust gas (pressure loss) in the following respective portions, which is the same as the first embodiment.




The exhaust gas flown into the inside of the communicating pipe


16


from radial direction through the communicating holes


8


A loses pressure thereof by being circulated in axial direction inside the pipe. Subsequently, after the flow of the exhaust gas is straightened by the communicating holes


8


A in upstream side of the cutoff partition


17


, the exhaust gas is expanded and sent to the second damping chamber


2


B, thereby reducing pressure fluctuation of the exhaust gas to damp the sound thereof. The exhaust gas sent from the upstream side of the cutoff partition


17


to the second damping chamber


2


B flows into the lower-stream communicating holes


8


A bypassing the partitioning wall


19


while being contracted. Since the exhaust gas thus detours, the exhaust gas flows to the lower-stream side of the partitioning wall


19


just like via another damping chamber (expansion chamber), thus damping the sound thereof and also damping the sound through the contracting step by the communicating holes


8


A.




The pressure fluctuation of the exhaust gas blown into the inside of the communicating pipe


16


through the communicating holes


8


A from radial direction is reduced by being circulated in axial direction in the pipe. Subsequently, on the lower-stream side, after the flow of the exhaust gas is straightened by the communicating holes


8


A, the pressure fluctuation of the exhaust gas is further reduced by being expanded and sent to the third damping chamber


2


C located at the lowermost-stream side. The exhaust gas sent into the third damping chamber


2


C is discharged to the outside through the tail pipe


5


.




According to the second embodiment, in addition to the effects (1) to (10) of the first embodiment, following effects can be obtained.




(11) Since the entire communicating pipe


16


is composed of a single continuous communicating pipe and the communicating pipe cutoff partition


17


is formed on an approximate center of the second damping chamber


2


B other than the first damping chamber


2


A on the uppermost-stream side and the third damping chamber


2


C on the lowermost-stream side, a plurality of communicating pipe is not required to be disposed parallel in radial direction in the same damping chamber, thus reducing the size of the exhaust silencer




(12) Since the partitioning wall


19


for partitioning a part of the second damping chamber


2


B is provided to the outer circumference of the cutoff partition


17


, the exhaust gas discharged from the communicating holes


8


A on the upstream side of the cutoff partition


17


flows into the communicating holes


8


A on the lower-stream side bypassing the partitioning wall


19


, the second damping chamber


2


B can function just like two damping chambers by the partitioning wall


19


, thus enhancing damping effect.




[Third Embodiment]




Next, third embodiment of the present invention will be described below with reference to FIG.


4


.




The third embodiment is a variation of the second embodiment.




In

FIG. 4

showing the entire structure, the exhaust silencer


30


of the third embodiment has a body


2


divided into first to fourth damping chambers


2


A to


2


D by first to third partitions


3


A to


3


C, a substantially single communicating pipe


26


supported by the partitions


3


A to


3


C, and first and second partitioning member


29


A and


29


B.




The third partition


3


C has the same structure as the first and the second partitions


3


A and


3


B.




The communicating pipe


26


has first to third cylindrical member


28


A to


28


C, an end plate


9


disposed to one end of the first cylindrical member


28


A and the third cylindrical member


28


C. The first partitioning member


29


A is inserted between the other end of the first cylindrical member


28


A and one end of the second cylindrical member


28


B, and the second partitioning member


29


B is inserted between the other end of the second cylindrical member and the other end of the cylindrical member


28


C.




The partitioning members


29


A and


29


B are secured to the end surface of the cylindrical members


28


A to


28


C by welding etc, of which peripheral portion larger than the cross section of the cylindrical members


28


A to


28


C works as the partitioning wall


19


of the second embodiment.




The function of the third embodiment is the same as the second embodiment.




In the third embodiment, in addition to the effects (1) to (7), (9), (11) and (12) of the second embodiment, following effects can be obtained.




(13) Since the four damping chambers, i.e. the first to the fourth damping chambers


2


A to


2


D, are provided, damping effect can be improved.




(14) Since the communicating pipe cutoff partition and each of the partitioning wall are formed by one partitioning member


29


A and


29


B, the number of parts can be decreased and manufacture thereof can be facilitated thereby reducing production cost.




[Fourth Embodiment]




Next, the fourth embodiment of the present invention will be described below with reference to FIG.


5


.




The fourth embodiment differs from the first to third embodiments in lower-stream end configuration of the communicating pipe, and the rest of the basic arrangement is the same as the first to third embodiments.




In

FIG. 5

showing the entire structure, the exhaust silencer


40


of the fourth embodiment has a drum-shaped body


2


, the first and the second partitions


3


A and


3


B for dividing the body


2


into the first to the third damping chambers


2


A to


2


C, the exhaust gas inlet pipe


4


provided to the body


2


, the tail pipe


5


provided to the body


2


, first communicating pipe


36


with an intermediate portion supported by the first partition


3


A and the intermediate portion supported by the second partition


3


B.




The first communicating pipe


36


includes the cylindrical member


8


having a large number of the communicating holes


8


A, an end plate


9


provided to the upstream side end of the cylindrical member


8


, and a hollow plate


39


provided to lower-stream side of the cylindrical member


8


as a partition.




The hollow plate


39


is dented to inside of the first communicating pipe


36


, of which configuration may be spherical as shown in solid line in

FIG. 5

, or may be conic as shown is fictitious line of FIG.


5


.




The second communicating pipe


37


has the same structure as the first communicating pipe


36


, which includes the cylindrical member


8


having a large number of communicating holes


8


A, an end plate


9


provided to upstream end portion of the cylindrical member


8


, and a hollow plate


39


provided to upstream end portion of the cylindrical member


8


, and a hollow plate


39


provided to the lower-stream side of the cylindrical member


8


as a partition.




Next, an effect of the fourth embodiment will be described below.




in the fourth embodiment, as in the first embodiment, the pressure fluctuation component of the exhaust noise is reduced when the exhaust gas send to the exhaust gas inlet pipe


4


is sent into the first damping chamber


2


A positioned to the uppermost stream side while rapidly expanding.




The exhaust gas blown into the first damping chamber


2


A flows into the inside of the pipe while being contracted by the communicating holes


8


A of the first communicating pipe


36


, during which the sound of the exhaust gas is damped.




The exhaust gas flowed into the inside of the first communicating pipe


36


from radial direction through the communicating holes


8


A decreases pressure fluctuation thereof by being circulated in axial direction inside the pipe and further flows toward the hollow plate


39


.




Conventionally, since the exhaust gas flowing in the communicating pipe in axial direction flows out of the communicating holes adjacent to the partition by being bumped into the partition, in observing velocity distribution and outflow distribution of the exhaust gas flowing out of the communicating holes of the communicating pipe, the velocity distribution or the outflow distribution adjacent to the partition is larger and becomes smaller as being separated from the partition. On the other hand, in the fourth embodiment, the exhaust gas flowing toward the hollow plate


39


is contracted by the hollow plate


39


, and is expanded and sent to the second damping chamber


2


B after being leveled by the communicating holes


8


A of the second communicating holes


37


. The exhaust gas flowed into the second communicating pipe


37


circulates in axial direction inside the pipe, which is contracted by the hollow plate


39


to be leveled by the communicating holes


8


A and sent to the third damping chamber


2


C while being expanded. Subsequently, as in the first embodiment, the exhaust gas is discharged to the outside from the third damping chamber


2


C through the tail pipe


5


.




According to the fourth embodiment, following effects van be obtained as well as effects (1) to (10) of the first embodiment.




(15) Since the lower-stream partition of the first and the second communicating pipes


36


and


37


is the hollow plate


39


dented to the inside, the exhaust gas sent in the axial direction inside the communicating pipe can be more easily flowed in radial direction by the partition formed of the hollow plate


39


. Accordingly, the exhaust gas can be more easily flowed out in the axial direction from the communicating holes


8


A, thereby reducing the jet noise generated in the communicating pipe.




[Fifth Embodiment]




In

FIG. 6

, a basic arrangement of exhaust silencer


50


of the fifth embodiment is the same as the above-described second embodiment. Accordingly, the same reference numeral is attached to the common components to omit description therefor. Components peculiar to the present embodiment will be described below.




In

FIG. 6

, a disk


3


D of the first and second partitions


3


A and


3


B has a plurality of small hole


31


as a communicating portion.




As shown in

FIG. 7

, the small holes


31


are disposed around the communicating pipe


16


being spaced apart at a predetermined interval with each other.




In the fifth embodiment, a main flow path for circulating a majority of the exhaust gas is formed by the first damping chamber


2


A, the communicating holes


8


A


1


, inside of the communicating pipe


16


, the communicating holes


8


A


2


, the second damping chamber


2


B, the communicating holes


8


A


3


, inside of the communicating pipe


16


, the communicating holes


8


A


4


and the third damping chamber


2


C. And a by-path flow path for constantly circulating a part of the exhaust gas is formed by the small holes


31


formed on the partitions


3


A and


3


B.




Cross section (opening area) of the by-path flow path is arranged so that the amount of the exhaust gas circulating therein is 5 to 30%, more preferably, 10 to 20% of the exhaust gas flowing the inside of the entire silencer.




In other words, the total opening area of the small holes


31


on the first partition


3


A constituting the by-path flow path is 5 to 30%, more preferably, 10 to 20% of the sum of the total area of the small holes


31


and total opening area of the communicating holes


8


A


1


constituting the main flow path.




In the same manner, the total opening area of the small holes


31


on the second partition


3


B constituting the by-path flow path is 5 to 30%, more preferably, 10 to 20% of the sum of the total area of the small holes


31


and total opening area of the communicating holes


8


A


3


structuring the main flow path.




When the amount of the exhaust gas is less than 5% of the exhaust gas circulating inside the entire silencer, the pressure loss of exhaust gas increases to raise backpressure, which can result in black smoke. On the other hand, when the amount of the exhaust gas exceeds 30% of the exhaust gas circulating inside the entire silencer, sufficient damping effect cannot be obtained.




That 10 to 20% value is preferable for the ratio of the exhaust gas circulating in the by-path flow path to the total gas amount (the exhaust gas amount circulating in the entire silencer) will be described based on a graph of FIG.


8


(A) to


8


(D). FIG.


8


(A) is a graph showing relationship between noise value and a ratio of the exhaust gas of the by-path flow path to the total gas amount, and FIG.


8


(B) is a graph showing relationship between exhaust resistance and a ratio of the exhaust gas of the by-path flow path relative to the total gas amount.




As shown in FIG.


8


(B), the exhaust resistance in inverse proportion to increase in the ratio to the total gas amount. However, as shown in FIG.


8


(A), the noise value decreases as the ratio to the total gas amount increases from 0 to 10%, which remains within low level up to 20% and rapidly increases exceeding 20%.




Next, a function of the fifth embodiment will be described below.




The exhaust gas generated by the diesel engine flows into the exhaust gas inlet pipe


4


through the exhaust pipe. The exhaust noise including low-frequency component is removed from the exhaust gas flowed into the exhaust gas inlet pipe


4


when the exhaust gas is blown into the first damping chamber


2


A located on the uppermost-stream side while being rapidly expanded.




Majority of the exhaust gas flowing into the first damping chamber


2


A passes the main flow path and the rest passes the small holes


31


constituting the by-path flow path.




In other words, the majority of the exhaust gas flows into the inside of the communicating pipe


16


by being contracted by the communicating holes


8


A


1


of the communicating pipe


16


. The sound of the exhaust gas flowed into the inside of the communicating pipe


16


is damped during the contraction process by the communicating holes


8


A


1


. Subsequently, the flow of the exhaust gas is straightened with flow direction thereof being changed in the pipe after flowing into the inside of the communication pipe


16


and, on lower-stream side, the exhaust gas again turns direction thereof in a right angle by the communicating holes


8


A


2


to straighten the flow thereof, which is discharged to the second damping chamber


2


B while being expanded. Accordingly, the pressure fluctuation of the exhaust gas is reduced.




In the second damping chamber


2


B, the exhaust gas passing the small holes


31


of the first partition


3


A joins with the exhaust gas passing the main flow path. Though the damping effect of the exhaust gas passing the small holes


31


is not so high of itself, the exhaust noise of the main flow path and the by-path flow path mutually interferes, thus being damped.




The majority of the exhaust gas flowed into the second damping chamber


2


B is contracted by the communicating holes


8


A


3


on the lower-stream side to flow into the pipe for damping sound thereof. Subsequently, the exhaust gas circulates in the pipe turning direction thereof in the axial direction to reduce pressure fluctuation of the exhaust gas. After the flow of the exhaust gas is further straightened by the communicating holes


8


A


4


, the exhaust gas flows out into the third damping chamber


2


C located at the lowermost-stream side while being expanded, thus reducing pressure fluctuation of the exhaust gas.




On the other hand, the rest of the exhaust gas flows into the third damping chamber


3


C through the small holes


31


of the second partition


3


B to be joined with the exhaust gas passing the main flow path in the third damping chamber


3


C to be interfered with each other for damping sound thereof.




The exhaust gas flowed into the third damping chamber


2


C is discharged to the outside through the tail pipe


5


.




According to the fifth embodiment, following effects can be obtained.




(16) Since a part of the exhaust gas discharged from internal combustion engine circulates in the by-path flow path as well as the main flow path, the loss by the exhaust pressure applied to the main flow path can be prevented from being too high.




(17) Since the exhaust gas is divided to flow in the main flow path and the by-path flow path and is joined thereafter, the exhaust noise (sound wave) mutually interferes with each other and is damped, thereby reducing exhaust noise.




(18) By setting the amount of the exhaust gas on the by-path flow path at the most appropriate value, the effect of the present embodiment can be more securely achieved.




(19) Since the exhaust silencer is composed of the damping chamber, the partition and the communicating pipe, the partition having holes constituting the by-path flow path, the size of the entire silencer can be reduced.




(20) Since the exhaust silencer


50


includes the first to third damping chambers


2


A to


2


C, the first damping chamber


2


A at the uppermost-stream side having the exhaust gas introduction hole


4


A for directly introducing the exhaust gas of the diesel engine, the exhaust gas introduced from the exhaust gas introduction hole


4


A to the first damping chamber


2


A is expanded to damp the exhaust noise.




(21) Since the communicating pipe


16


in communication with the damping chambers


2


A to


2


C are provided and the communicating pipe


16


has the end plates


9


on both sides, and since a large number of communicating holes


8


A


1


to


8


A


4


are provided at a predetermined position on the outer circumference corresponding to the chambers to be intercommunicated, the exhaust gas loses pressure after experiencing repeated contraction and expansion by the communicating holes


8


A


1


to


8


A


4


of the communicating pipe


16


to damp energy thereof when the exhaust gas is sent into the mutually adjacent damping chambers


2


A to


2


C. Accordingly, the exhaust noise can be effectively damped.




In other words, since sufficient damping effect can be obtained with relatively small damping chamber, the size of the entire silencer can be reduced.




(22) Since two partitions


3


A and


3


B are used for forming three damping chambers, positioning of the partitions


3


A and


3


B relative to inner circumference of the body


2


is facilitated, thereby easily conducting assembly work.




(23) Since the communicating pipe


16


is formed by a single consecutive communicating pipe and the communicating pipe cutoff partition


17


is formed on an approximate center of the second damping chamber


2


B other than the first damping chamber


2


A on the uppermost-stream and the third damping chamber


2


C on the lowermost-stream, a plurality of communicating pipe is not required to be disposed in parallel in the same damping chamber, thus reducing size of the exhaust silencer


50


.




[Sixth Embodiment]




Next, sixth embodiment of the present invention will be described below with reference to

FIGS. 9 and 10

.




In

FIG. 9

, an exhaust silencer


60


of the sixth embodiment has the same basic arrangement as the above-described first embodiment and the same reference numerals are used to the same components to omit description therefor. Portions peculiar to the present embodiment will be described below.




In

FIG. 9

, a disk


3


D of the first and the second partition


3


A and


3


B has a plurality of the small holes


31


as in the fifth embodiment.




As shown in

FIG. 10

, the small holes


31


are disposed around the first communicating pipe


6


and the second communicating pipe


7


being spaced apart at a predetermined interval.




In the sixth embodiment, the main flow path for circulating the majority of the exhaust gas is formed by the first damping chamber


2


A, the communicating holes


8


A


1


, the inside of the first communicating pipe


6


, the communicating holes


8


A


2


, the second damping chamber


2


B, the communicating holes


8


A


3


, the inside of the second communicating pipe


7


, the communicating holes


8


A


4


and the third damping chamber


2


C, and the by-path flow path for circulating a part of the exhaust gas is formed by the small holes


31


formed on the partitions


3


A and


3


B.




As in the fifth embodiment, the cross section (opening area) of the by-path flow path is arranged so that the amount of the exhaust gas circulating therein is 5 to 30%, more preferably, 10 to 20% of the exhaust gas flowing the inside of the entire silencer.




A function of the sixth embodiment will be briefly described below.




The exhaust gas introduced from the diesel engine into the exhaust gas inlet pipe


4


flows into the first damping chamber


2


A, of which majority passes the main flow path and the rest passes the small holes


31


constituting the by-path flow path.




In the main flow path, the exhaust gas flows into the inside of the communicating pipe


6


by being contracted by the communicating holes


8


A


1


of the communicating pipe


6


. Subsequently, the flow of the exhaust gas flowing into the inside of the communicating pipe


6


is straightened with flow direction thereof being turned in the axial direction in the pipe and, on lower-stream side, the exhaust gas again turns direction thereof in a right angle by the communicating holes


8


A


2


to straighten the flow thereof, which is discharged to the second damping chamber


2


B while being expanded.




In the second damping chamber


2


B, the exhaust gas passing the small holes


31


of the first partition


3


A joins with the exhaust gas passing the main flow path, where the exhaust noise of the main flow path and the by-path flow path mutually interferes, thus being damped.




The majority of the exhaust gas flowed into the second damping chamber


2


B passes the main flow path and the rest passes the small holes


31


constituting the by-path flow path.




In the main flow path, the exhaust gas initially passes the communicating holes


8


A


3


of the second communicating pipe


7


to be flowed thereinto. Subsequently, the exhaust gas turns direction thereof in the axial direction to be circulated, and after being straightened flow thereof by the communicating holes


8


A


4


, the exhaust gas is discharged to the third damping chamber


2


C while being expanded.




On the other hand, the rest of the exhaust gas flows into the third damping chamber


3


C through the small holes


31


of the second partition


3


B to be joined with the exhaust gas passing the main flow path in the third damping chamber


3


C thus being interfered with each other for damping sound thereof.




The exhaust gas flowed into the third damping chamber


2


C is discharged to the outside through the tail pipe


5


.




According to the above sixth embodiment, effects shown in (16) to (21) of the fifth embodiment can be attained.




[Seventh Embodiment]




Next, seventh embodiment of the present invention will be described with reference to FIG.


11


.




The seventh embodiment differs from the sixth embodiment in a location of the by-path flow path and the rest of the basic arrangement is the same as the sixth embodiment.




In

FIG. 11

, an exhaust silencer


70


according to the seventh embodiment has a plurality of small hole


31


as a by-path flow path to lower-stream side end plate


9


of the first communicating pipe


6


and upstream side end plate of the second communicating pipe


7


.




In the seventh embodiment, the main flow path is formed as in the sixth embodiment.




The cross section (opening area) of the by-path flow path of the seventh embodiment is arranged so that the amount of the exhaust gas circulating therein is 5 to 30%, more preferably, 10 to 20% of the exhaust gas flowing the inside of the entire silencer as in the fifth and sixth embodiment.




A function of the seventh embodiment will be briefly described below.




In the seventh embodiment, the majority of the exhaust gas flowed from a diesel engine into the first damping chamber


2


A through the exhaust gas inlet pipe


4


passes the inside of the first communicating pipe


6


by being contracted by the communicating hole


8


A


1


of the first communicating pipe


6


and the rest flows into the inside of the second communicating pipe


7


through the small holes


31


.




The exhaust gas flowed into the inside of the first communicating pipe


6


turns direction thereof inside the pipe to be straightened flow thereof. Subsequently, after the majority of the exhaust gas again turns circulation direction in a right angle by the lower-stream communicating holes


8


A


2


and is straightened the flow thereof, the majority of the exhaust gas is flowed out into the second damping chamber


2


B and the rest flows out into the third damping chamber


3


C through the small holes


31


.




The exhaust gas flowed into the second damping chamber


2


B is sent into the inside of the second communicating pipe


7


through the communicating holes


8


A


3


, which joins with the exhaust gas passing from the first damping chamber


2


A through the small holes


31


of the second communicating pipe


7


for mutual interference of the exhaust noise to be damped.




Further, the exhaust gas circulates inside the second communicating pipe


7


after turning in the axial direction, where the flow thereof is straightened by the communicating hole


8


A


4


to be discharged to the third damping chamber


2


C.




In the third damping chamber


3


C, the exhaust gas passing the small holes


31


of the first communicating pipe


6


and the exhaust gas passing through the communicating holes


8




a




4


of the second communicating pipe


6


join together to be interfere with each other for damping sound thereof.




The exhaust gas flowed into the third damping chamber


2


C is discharged to the outside through the tail pipe


5


.




According to the above seventh embodiment, effects (16) to (17) and (21) to (23) of the fifth embodiment can be obtained.




[Eighth Embodiment]




Next, eighth embodiment of the present invention will be described below with reference to FIG.


12


.




In

FIG. 12

, the exhaust silencer


80


of the eighth embodiment has the same basic arrangement as the above-described conventional example (see

FIG. 15

) and the same reference numeral will be applied to the same components to omit description therefor. Accordingly, only components peculiar to the present embodiment will be described below.




A partition


52


B disposed at the center has a plurality of small holes


31


as the by-path flow path.




In the eighth embodiment, the main flow path is composed of the inside of the inlet pipe


54


, the communicating holes


54


B, the first damping chamber


51


A, the opening


52


D, the second damping chamber


51


B, the communicating hole


8


A


1


, the inside of the communicating pipe


6


, the communicating hole


8


A


2


, the third damping chamber


51


C, the opening


52


D, the fourth damping chamber, the communicating holes


55


B and the inside of the outlet pipe


55


.




As in the above respective embodiments, the cross section (opening area) of the by-path flow path of the eighth embodiment is arranged so that the amount of the exhaust gas circulating therein is 5 to 30%, more preferably, 10 to 20% of the exhaust gas flowing the inside of the entire silencer.




A function of the eighth embodiment will be briefly described below.




In the eighth embodiment, the exhaust gas introduced from the outlet pipe flows out into the first damping chamber


51


A after the flow thereof is straightened in radial direction by the communicating holes


54


B of the inlet pipe


54


, and flows out from the first damping chamber


51


A to the second damping chamber


51


B through the opening


52


D. Subsequently, the majority of the exhaust gas flows into the inside of the communicating pipe


6


after being contracted passing through the communicating holes


8


A


1


, and the rest of the exhaust gas flows into the third damping chamber


51


C through the small holes


31


of the partition


52


B.




The exhaust gas flowed inside the communicating pipe


6


circulates with the direction thereof being turned into the axial direction, which is expanded and flowed out to the third damping chamber


51


C through the communicating holes


8


A


2


.




In the third damping chamber


51


C, the exhaust gas passing through the communicating holes


8


A


2


constituting the main flow path and the exhaust gas passing through the small holes


31


constituting the by-path flow path join together to interfere with each other to damp the exhaust noise.




Thereafter, the exhaust gas flows from the third damping chamber


51


C to the fourth damping chamber


51


D through the opening


53


D, which further flows into the outlet pipe


55


through the communicating holes


55


B to be discharged into the air.




According to the above eighth embodiment, effects similar to (16) to (20) and (22) of the fifth embodiment can be obtained.




[Ninth Embodiment]




Next, the ninth embodiment of the present invention will be described with reference to FIG.


13


.




The ninth embodiment differs from the eighth embodiment in the arrangement of the damping chamber and the communicating pipe, and the rest of the arrangement is the same as the eighth embodiment.




In

FIG. 13

, an exhaust silencer


90


of the ninth embodiment has two partitions


62


A and


62


B for dividing the inside of the drum-shaped body


51


into three damping chambers


51


A to


51


C disposed parallel in axial direction. First and second communicating pipes


66


and


67


are supported by the partitions


62


A and


62


B parallel to the axis of the body


51


. An end portion and intermediate portion of the inlet pipe


54


is fixed to the body


51


to face the uppermost-stream damping chamber


51


A, and an end portion and intermediate portion of the outlet pipe


55


is fixed to the body


51


to face the lowermost-stream damping chamber


51


C.




The first communicating pipe


66


has a cylindrical member


18


having a large number of communicating holes


66


A facing the second damping chamber


51


B on a circumference thereof, and an end plate


9


for closing an open end facing the third damping chamber


51


C of the cylindrical member


18


.




The second communicating pipe


67


has the cylindrical member


18


having the communicating holes


67


A formed on a circumference thereof and the end plate


9


for closing the opening end of the cylindrical member


18


facing the first damping chamber


51


A.




A plurality of small holes


31


as the by-path flow path is formed on the partitions


62


A and


62


B.




In the ninth embodiment, the main flow path is formed of the inside of the inlet pipe


54


, the communicating hole


54


B, the first damping chamber


51


A, the inside of the first communicating pipe


66


, the communicating holes


66


A, the second damping chamber


51


B, the communicating holes


67


A, the second communicating holes


67


, the third damping chamber


51


C, the communicating holes


55


B and the inside of the outlet pipe


55


.




As in the above respective embodiments, the cross section (opening area) of the by-path flow path of the eighth embodiment is arranged so that the amount of the exhaust gas circulating therein is 5 to 30%, more preferably, 10 to 20% of the exhaust gas flowing the inside of the entire silencer.




A function of the ninth embodiment will be briefly described.




In the ninth embodiment, the exhaust gas introduced from the outlet pipe flows out into the first damping chamber


51


A through the communicating holes


54


B of the inlet pipe


54


into the first damping chamber


51


A. The majority of the exhaust gas passes the first communicating pipe


66


constituting the main flow path and the rest flows to the second damping chamber


51


B through the small holes


31


of the partition


62


A as the sub flow path.




The exhaust gas passing through the inside of the first communicating pipe


66


is contracted by the communicating holes


66


A to flow into the second damping chamber


51


B, which joins with the exhaust gas passing through the small holes


31


of the partition


62


B to interfere with each other to be damped.




The majority of the exhaust gas of the second damping chamber


51


B is contracted inside the second communicating pipe


67


through the communicating holes


67


A as the main flow path, which flows into the third damping chamber


51


C. The rest directly flows into the third damping chamber


51


C through the small holes


31


as the by-path flow path.




The exhaust gas separately flowed from the main flow path and the by-path flow path join together in the third damping chamber


51


C to interfere with each other for sound damping.




Further, the exhaust gas flows into the outlet pipe


55


from the third damping chamber


51


C to the outlet pipe


55


through the communicating holes


55


B to be discharged into the air.




According to the ninth embodiment, effects similar to (16) to (18) and (23) of the fifth embodiment can be obtained.




Incidentally, the scope of the present invention is not limited to the above-described embodiments, but includes modification and improvement as long as an object of the present invention can be achieved.




In the present invention, the size and location of the communicating holes


8


A


1


to


8


A


4


is not limited to the above embodiments. For instance, though the number and the total opening area of the communicating holes


8


A


1


on the position into which the exhaust gas flows is smaller than the number and the total opening area of the communicating holes


8


A


2


from which the exhaust gas flows out in the above embodiment, reverse arrangement is possible in the present invention, or alternatively, the communicating holes may be arranged equally to the communicating pipe without deviation.




Though the cylindrical members


8


and


18


are formed in straight shape having uniform cross section along axial direction in the aforesaid embodiments, the cylindrical member


8


and


18


may be configured in a tapered shape having larger diameter in upstream side than lower-stream side as shown in FIG.


14


(A), or as shown in FIG.


14


(B), the cylindrical member may have straight shape from the upstream side to the intermediate portion and tapered shape with a cross section enlarged from the intermediate portion to the lower-stream side. A large number of the communicating holes


8


A is formed on the entire surface of the outer circumference of the cylindrical member


8


and


18


.




As described above, since the outer circumferences of the communicating pipe


6


,


7


and


16


are formed in a tapered shape, the flow velocity of the exhaust gas in the communicating pipes


6


,


7


and


16


can be reduced as going down to the lower stream, or the exhaust gas can be expanded in the communicating pipes


6


,


7


and


16


, thus reducing jet noise generated in the communicating pipes.




In the present invention, the opening area of the communicating holes


8


A may be reduced adjacent to lower-stream side of the communicating pipes


6


and


7


as shown in FIG.


14


(C) in order to attain effects similar to the communicating pipes


36


and


37


in FIG.


5


. Alternatively, disposition interval of the communicating holes


8


A may be widened adjacent to the lower-stream side of the communicating pipes


6


and


7


as shown in FIG.


14


(D). In other words, the opening area of the communicating holes


8


A of the communicating pipes


6


and


7


may be reduced toward the lower-stream of the exhaust flow.




According to the above arrangement, since the exhaust gas can more easily flow out as approaching toward the upstream side, the exhaust gas does not concentrate to a specific point, thus obtaining effects similar to contracting the pipe on lower-stream side.




In the second embodiment, the partitioning wall


19


may not be necessarily required. When the partitioning wall


19


is provided, the location thereof is not required to be the outer circumference of the cutoff partition


17


, but may be separated from the cutoff partition


17


in a predetermined distance in the axial direction. The cutoff partition


17


may have profile of other configuration such as rectangular and polygonal.




in the above fifth, sixth, seventh and ninth embodiments, the by-path flow path is constituted of the small holes


31


formed on the partition and, in the seventh embodiment, the by-path flow path is formed by the small holes


31


formed on the end plate


9


of the communicating pipes


16


and


17


. However, the small holes


31


may be formed on both of the partition and the end plate


9


to constitute the by-path flow path, or alternatively, a by-pass channel of a pipe in communication with mutually adjacent damping chambers may be provided for forming the by-path flow path.




When the by-path flow path is formed of the small holes


31


, the number is not limited and the sub flow path can be formed of, for instance, one small hole


31


.




The respective exhaust silencers


10


to


90


may also have a resonant chamber.




Though the exhaust silencers


10


to


90


are applied to a diesel engine, they may be applied to internal combustion engine such as a gasoline engine and the combustion engine is not limited to be used for construction equipment but may be used for passenger car etc.



Claims
  • 1. An exhaust silencer to be connected to an outlet pipe of an internal combustion engine, comprising:a plurality of damping chambers of more than two, the plurality of damping chambers having an uppermost-stream damping chamber having an exhaust gas inlet for directly introducing exhaust gas of the internal combustion engine, and lowermost-stream damping chamber having an exhaust gas outlet for discharging the exhaust gas; and a communicating pipe for intercommunicating predetermined space of the plurality of damping chambers, the communicating pipe having an end plate on both ends and a number of communicating holes on an outer circumference at a predetermined position corresponding to the damping chamber to be intercommunicated, wherein a total opening area of the communicating holes on the communicating pipe open to the uppermost-stream damping chamber is smaller than respective total opening area of the communicating holes open to lower-stream damping chamber.
  • 2. The exhaust silencer according to claim 1, wherein a volume of the damping chamber on the uppermost-stream side is the largest of the plurality of damping chambers.
  • 3. The exhaust silencer according to claim 1, wherein a volume of a damping chamber to which the communicating holes of the communicating pipe having the least total opening area directly opens is the largest.
  • 4. The exhaust silencer according to claim 1, further comprising a communicating portion for flowing the exhaust gas in an axial direction is provided to the end plates on either or both ends of the communicating pipe.
  • 5. The exhaust silencer according to claim 1, wherein a cross section of the upstream communicating pipe is smaller than lower-stream communicating pipe.
  • 6. The exhaust silencer according to claim 1, wherein an entirety of the communicating pipe is formed of a single consecutive communicating pipe; and wherein a communicating pipe cutoff partition is formed to an intermediate position of respective damping chambers except for the uppermost-stream damping chamber and the lowermost-stream damping chamber.
  • 7. The exhaust silencer according to claim 6, wherein a partitioning wall for partitioning a part of the respective damping chambers are provided to an outer circumference of the cutoff partition.
  • 8. The exhaust silencer according to claim 1, wherein an opening area of the communicating holes of the communicating pipe becomes smaller toward lower-stream side in exhaust flow direction.
  • 9. The exhaust silencer according to claim 1, further comprising a communicating portion for by-passing the exhaust gas is provided to a partitioning portion for partitioning mutually adjacent damping chambers.
  • 10. A communicating pipe used for an exhaust silencer having a plurality of damping chamber; the plurality of damping chambers having an uppermost-stream damping chamber an exhaust gas inlet for directly introducing exhaust gas of the internal combustion engine, and lowermost-stream damping chamber having an exhaust gas outlet for discharging the exhaust gas, the communicating pipe being used for intercommunicating a predetermined chambers of the plurality of the damping chambers, comprising:an end plate provided at least to a lower-stream end; and a large number of communicating holes provided to a predetermined position on an outer circumference corresponding to the chamber to be intercommunicated, the end plate on the lower-stream end being a hollow plate dented toward inside, wherein a total opening area of the communicating holes on the communicating pipe open to the uppermost-stream damping chamber is smaller than respective total opening area of the communicating holes open to lower-stream damping chamber.
  • 11. An exhaust silencer connected to an outlet pipe of a combustion engine for damping exhaust noise by contracting and expanding a flow path for exhaust gas to be circulated, comprising:a main flow path for circulating majority of the exhaust gas; and at least one by-path flow path for constantly circulating a part of the exhaust gas, wherein cross section of the by-path flow path is defined so that amount of the exhaust gas circulating therein is 5 to 30% of total exhaust gas circulating in the entire silencer.
  • 12. The exhaust silencer according to claim 11, further comprising:a plurality of damping chamber; a partition for dividing the plurality of the damping chamber; and a communicating pipe for intercommunicating the plurality of the damping chamber; the partition having at least one communicating portion for circulating the exhaust gas.
Priority Claims (2)
Number Date Country Kind
11-029207 Feb 1999 JP
11-350315 Dec 1999 JP
US Referenced Citations (11)
Number Name Date Kind
3987868 Betts Oct 1976
4149611 Taguchi Apr 1979
4192403 Nakagawa et al. Mar 1980
4296832 Kicinski Oct 1981
4341284 Moore et al. Jul 1982
4367808 Oberg Jan 1983
4450932 Khosropour et al. May 1984
4487289 Kicinski et al. Dec 1984
5183976 Plemons, Jr. Feb 1993
5902970 Ferri May 1999
6116377 Dugan Sep 2000
Foreign Referenced Citations (3)
Number Date Country
2 589 195 Apr 1987 FR
60-132014 Jul 1985 JP
11-22444 Jan 1999 JP