WO2013079523A1

WO2013079523A1 - Cooling system for actively cooling an exhaust gas system

Info

Publication number: WO2013079523A1
Application number: PCT/EP2012/073824
Authority: WO
Inventors: Bernd Helferich
Original assignee: Deere & Company
Priority date: 2011-12-02
Filing date: 2012-11-28
Publication date: 2013-06-06
Also published as: EP2785993A1; US20150128578A1; DE102011087675A1; EP2785993B1

Abstract

The invention relates to a cooling system (10) for actively cooling an exhaust gas system (12), comprising an exhaust pipe (14) for leading away an exhaust gas flow (22) of an internal combustion engine (16) and an air-conducting element (18), which is arranged across from the exhaust pipe (14) such as to form an air-conducting channel (20) in order to cool the exhaust pipe (14) by introducing an air flow (24) into the air-conducting channel (20).

Description

Cooling system for the active cooling of an exhaust gas system

The invention relates to a cooling system for actively cooling an exhaust system, comprising an exhaust pipe for discharging an exhaust gas stream of an internal combustion engine and an air guide element which is arranged opposite the exhaust pipe to form an air duct to cool the exhaust pipe by supplying an air flow into the air duct.

As a result of today's emissions legislation, exhaust aftertreatment systems are used in combustion power arrangements to reduce pollutant emissions. The internal combustion engines in these arrangements can, for example, operate on the diesel principle. In certain operating states, the exhaust gases of these internal combustion engines can reach high temperatures. For example, the exhaust aftertreatment systems may include a diesel particulate filter (DPF) for filtering soot particulate emissions from the internal combustion engine. In this case, the soot particles are deposited in the porous filter wall of the DPF, so that the exhaust backpressure increases with increasing degree of clogging of the DPF. To regenerate the DPF, the deposited soot particles are burnt at regular intervals so that the degree of clogging decreases again. For this purpose, the temperature of the engine exhaust gas stream is temporarily increased to temperatures of more than 600 ° C by appropriate measures. In this case, correspondingly high surface temperatures can occur at the exhaust pipe of the exhaust system. For example, if the exhaust pipe is part of an exhaust system of an agricultural machine, it is typically arranged so that an operator of the machine could come in contact with the exhaust pipe, which can result in burns at such high surface temperatures. Furthermore, such a hot exhaust pipe could cause a fire in an immediate environment, for example when parking the machine in a barn. Finally, deposited on the hot exhaust pipe dirt can lead to uncontrolled spontaneous combustion of these deposits. From DE 1 027 084 a jacketed exhaust pipe is known. During driving, fresh air bypassing the exhaust pipe, depending on the speed, absorbs heat emitted by the exhaust pipe between the exhaust pipe and the jacket by convection and leads it to the outside.

Such an arrangement, which can be referred to as a passive cooling system, can be unfavorable, especially for normally slow-moving or stationary operation at power output via PTO (PTO) agricultural machinery, such as tractors, as lack of wind sufficient cooling air supply is not given is.

On this basis, the object of the present invention is to provide a largely independent of the driving speed cooling system for an exhaust system.

The object is achieved by a cooling system for active cooling of an exhaust system, comprising an exhaust pipe for discharging an exhaust gas stream of an internal combustion engine and an air guide element, which is arranged opposite the exhaust pipe to form an air duct to cool the exhaust pipe by supplying an air flow into the air duct, wherein blower means are provided which cause the supply of air flow into the air duct.

By this arrangement is advantageously ensured that the cooling capacity of the active cooling of the exhaust pipe is at least largely independent of a driving speed and only depends on the cooling capacity of the fan means. As a result, even with field work under load with an agricultural machine with typical speeds of less than 10km / h or in stationary mode with power output via the PTO active cooling via an air flow, which is introduced by the fan means in the air duct, guaranteed. The fan means preferably compress the air flow to a pressure level which is higher than an ambient pressure. This ensures advantageously even at low speeds that a pressure gradient can be used to initiate the air flow in the air duct. Here, ambient pressure is the prevailing atmospheric air pressure.

In a preferred embodiment, the blower means lead a cooling exhaust air flow of the internal combustion engine as air flow to the air duct. It is advantageous that the air flow entering the air duct is already filtered, since it has already been passed as a cooling exhaust air stream of the internal combustion engine through a corresponding filter system of a cooling system of the internal combustion engine.

In a further preferred embodiment, the air guide element has an air inlet opening to the air duct, wherein the air duct is connected via the air inlet opening with an engine compartment of the internal combustion engine for supplying the cooling exhaust air flow. Through the engine compartment ensures that an increased pressure level can be set, which then can pass the cooling exhaust air flow through the air inlet opening in the air duct. The engine compartment is an enclosure of the internal combustion engine, wherein the

Housing may consist of a hood and one or more trim parts, including the dashboard of a driver's cab can count. The engine compartment is encapsulated as far as possible air-tight except for an air supply opening to the fan unit and with the air inlet opening of the air duct corresponding air outlet opening.

The fan means preferably comprise a fan unit of a refrigeration cycle internal combustion engine. Since a cooling circuit of an internal combustion engine regularly has a fan unit, can advantageously by existing means, namely the fan unit in the form of a mechanically or electrically driven Cooling fan, the increased pressure level or the pressure gradient are generated in the direction of the exhaust system.

In a further preferred embodiment, the air guide element has at least two outlet openings for the air duct, the first outlet opening being arranged in the region of an outlet opening of the exhaust pipe and the second outlet opening being arranged upstream of the outlet opening. Due to the second outlet opening, an excessively high back pressure in the air duct is advantageously avoided.

Preferably, the exhaust pipe has a Venturi nozzle arrangement for the intake of air, which surrounds the exhaust pipe, wherein the air guide element forms an annular gap downstream of the Venturi nozzle arrangement. As a result, it is advantageously ensured that cooling air is supplied to the exhaust gas via the Venturi nozzle in the exhaust pipe, whereby the high exhaust gas temperatures during regeneration of the DPF are reduced in order to counteract the formation of undesired nitrogen oxides in the exhaust pipe due to the high temperatures.

Preferably, the annular gap between two outlet openings of the air guide elements is arranged. This ensures that over the second outlet opening any existing overpressure is reduced to a certain extent, so that no cooling air is blown off via the annular gap, but via the chimney effect, which adjusts downstream of the annular gap, further cooling air is sucked from the outside.

Preferably, the annular gap is designed as Venturi nozzle arrangement for the intake of ambient air into the air duct. Here, the Venturi nozzle arrangement in combination with the chimney effect, which adjusts downstream in the exhaust pipe, can be used to suck in ambient air to support the cooling. A preferred embodiment of the invention will be described below with reference to the figures. Show here

Figure 1 is an overall perspective view of a cooling system according to the invention for the active cooling of an exhaust system and

2 shows a cross section through an inventive cooling system for the active cooling of an exhaust system.

1 shows a detail of an agricultural utility vehicle 48 in the form of a tractor with a cabin 50, a frame 52 and an only indicated internal combustion engine 16 with an exhaust system 12 for discharging an exhaust gas stream 22. The internal combustion engine 16 is arranged in a conventional manner within an engine compartment 34. The exhaust system 16 comprises a soot particle filter 52, which is only indicated in its position, an exhaust pipe 14 and an air guide element 18 which encloses the exhaust pipe 14 to form an air duct 20. The exhaust system 12 may include other components, not shown, such as one or more catalytic converters.

The internal combustion engine 16 has in a conventional manner via a likewise only indicated liquid cooling circuit 30 with a high-temperature heat exchanger, which is acted upon by means of a fan unit 28 with cooling air, which is sucked in via a grille and downstream filter trays from the environment. By the filter trays the guided into the engine compartment 34 cooling air is largely freed of impurities. The caused by the fan assembly 28 compression of the cooling air leads to a relative to the atmospheric pressure increased pressure level of the cooling air in the engine compartment 34. The guided through the high-temperature heat exchanger and the engine compartment 34 cooling air is as Kühlabluftstrom 26 for active cooling of the exhaust system 12 in the air duct 20, the by the formed as a jacket relative to the exhaust pipe 14 arranged air guide element 18 is initiated.

For cooling the exhaust gas flow 22 downstream of the soot particle filter 52, the exhaust gas pipe 14 has a venturi nozzle arrangement 42, as can be seen in FIG. The venturi assembly 42 is formed by forming the exhaust pipe 14 in two parts and the upstream exhaust pipe member 54 forms an orifice portion 56 which extends nozzle-shaped into the open end 58 of the downstream exhaust pipe member 60 of the exhaust pipe 14. The Venturi nozzle arrangement 42 essentially has a circular cross section. By the Venturi principle, a negative pressure is generated, is sucked through the air from the air duct 20 into the exhaust pipe 14 in order to cool the exhaust gas stream 22.

The air guide element 18 is designed in four parts in the illustrated embodiment, consisting of a motor-side protective cover 62, a two covers 64, 64 'comprehensive horizontal protective cover 66 and a vertical protective cover 68. The number of parts from which the air guide element is formed, in others Embodiments of the invention vary.

The air guide element 18 surrounds the exhaust pipe 14 and thus forms with the exhaust pipe 14 an air duct 20. The air duct 20 is connected via an air inlet opening 32 to the engine compartment 34. The air inlet opening 32 is formed by an air gap 72 is formed between the exhaust pipe 14 and the side engine cover 70, which is covered with respect to the environment with the vertical protective cover 66 which is formed in a half-shell-shaped. The two cover shells 64, 64 'of the horizontal protective cover 66 form in the assembled state the second outlet opening 38, which is directed down to the ground and is arranged on the downstream end of the protective cover 66. Characterized in that the second outlet opening 38 is directed downwards, both the sound and the warm Kühlabuftstrom is discharged downward towards the ground. The transition region from the horizontal protective cover 66 to the vertical protective cover 68 forms an annular gap 44. In the present embodiment, the annular gap 44 is designed as a venturi nozzle arrangement 46. Here, the horizontal protective cover 66 has a downstream tapered mouth portion 74 which projects nozzle-shaped into the open end 76 of the vertical protective cover 68. As a result, a suction region is formed between the mouth region 74 and the open end 76, in which a negative pressure relative to the environment is generated according to the venturi principle when a cooling exhaust air stream passes through the air duct 20, so that ambient air is drawn into the air duct 20. Via the outlet opening 36 in the region of the mouth opening 40 of the exhaust gas pipe 14, the cooling exhaust air stream enters the environment.

Furthermore, in the region of the annular gap 44 or in the intake region of the Venturi nozzle arrangement 46, a filter element not shown in more detail, for example in the form of a perforated grid, can be provided in order to retain primarily coarser impurities and to prevent clogging of the air conduction channel 20.

Thus, the air guide element 18 serves both as protection against contact for a hot exhaust pipe 14, in which it completely encases this, as well as the formation of an air duct 20 around the exhaust pipe 14, through which an actively introduced air flow ensures cooling.

LIST OF REFERENCE NUMBERS

10 cooling system

12 exhaust system

14 exhaust pipe

16 internal combustion engine

18 air guide element

20 air duct

22 exhaust gas flow

24 airflow

26 cooling exhaust air flow

28 fan unit

30 cooling circuit

32 air intake opening

34 engine compartment

36 outlet opening

38 outlet opening

40 mouth opening

42 Venturidusen arrangement

44 annular gap

46 Venturi nozzle arrangement

48 agricultural utility vehicle

50 cab Rußpartikelfilter

Exhaust pipe element

Mouth area open end

Exhaust pipe element

protective cover

cover shell

protective cover

engine cover

air gap

Mouth area open end

Claims

claims

A cooling system (10) for actively cooling an exhaust system (12), comprising an exhaust pipe (14) for discharging an exhaust stream (22) of an internal combustion engine (16) and an air guide element (18) opposite the exhaust pipe (14) to form a Air duct (20) is arranged to cool by supplying an air flow (24) into the air duct (20), the exhaust pipe (14), characterized in that blower means (28) are provided, the supply of the air flow (24) in the Air duct (20) effect.

2. Cooling system according to claim 1, characterized in that the blower means (28) compress the air flow (24) to a relative to an ambient pressure increased pressure level.

3. Cooling system according to claim 1 or 2, characterized in that the blower means a Kühlabluftstrom (26) of Verbrennungskraftma- Feed the machine (16) as air flow (24) to the air duct (20).

4. Cooling system according to claim 3, characterized in that the air guide element (18) has an air inlet opening (32) to the air duct (20), wherein the air duct (20) via the air inlet opening (32) with an engine compartment (34) of the internal combustion engine ( 16) for supplying the cooling exhaust air stream (26) is connected.

5. Cooling system according to one of claims 1 to 4, characterized in that the fan means (28) comprise a fan unit of a cooling circuit (30) of the internal combustion engine (16).

6. Cooling system according to one of claims 1 to 5, characterized in that the air guide element (18) has at least two outlet openings (36, 38) for the air duct (20), wherein one of the outlet openings (36, 38) upstream of an orifice area (36). 56) of the exhaust pipe (14) is arranged.

7. Cooling system according to one of claims 1 to 6, characterized in that the exhaust pipe (14) has a Venturi nozzle arrangement (42) for intake of air, which surrounds the exhaust pipe (14), wherein the air guide element (18) forms an annular gap (44) downstream of the Venturi nozzle arrangement (42).

8. Cooling system according to claim 1 to 7, characterized in that an annular gap (44) between two outlet openings (36, 38) of the air guiding element (18) is arranged.

9. Cooling system according to claim 8, characterized in that the annular gap is designed as Venturi nozzle arrangement (46) for sucking ambient air into the air duct (20).