DE102015118469A1 - valve unit - Google Patents

Abstract

A valve unit is mounted on an inlet and outlet system (2). The valve unit supplies a low-pressure EGR gas, which is a low-pressure exhaust gas flowing through a turbine (21) of the turbocharger (4), to a suction air flow and directs the low-pressure EGR gas into a compressor (22). a turbocharger (4). The valve unit includes a conduit forming member (32), a first valve body (27) and a second valve body (25). The conduit forming member (32) includes a first conduit (30) through which the suction air flows, and a second conduit (31) communicating with the first conduit (30). The conduit forming member (32) introduces the low pressure EGR gas into the second conduit (31) and controls the EGR gas to flow with the suction air flowing through the first conduit (30).

Description

The present disclosure relates to a valve unit included in a low-pressure EGR device.

A low-pressure EGR device conventionally carries a portion of low-pressure exhaust gas that has passed through a turbine contained in a turbocharger of an engine intake and exhaust system, back to a suction air flow, and directs the exhaust gas into a supercharger of the turbocharger.

The low-pressure EGR device includes a suction passage through which the intake air flows, and an exhaust passage through which the EGR gas flows.

The low-pressure EGR device further includes an intake throttle valve body that regulates a negative pressure generated at a confluence portion between the intake passage and the low-pressure EGR passage, and a low-pressure EGR control valve body that has an opening degree the low-pressure EGR line regulated. The intake throttle valve body is a first valve body, and the low-pressure EGR control valve body is a second valve body.

According to the patent JP 2013-096286 A For example, the first valve body is disposed in the vicinity of the second valve body so as to constitute a valve unit, so that a total number of elements and connection parts can be reduced.

The valve unit includes a conduit forming member that includes a first conduit that is part of the suction conduit and that includes a second conduit that is part of the low pressure EGR conduit. The first valve body is received in the first conduit, and the second valve body is received in the second conduit.

Recently, in order to minimize the size of the valve unit, it has been considered to arrange the first valve body in the vicinity of the second valve body and to dispense with an upstream portion of a rotation area of the first valve body in the passage forming member.

In this case, since the first valve body is disposed in the vicinity of the second passage through which the EGR gas flows, there is a high probability that the EGR gas collides with the first valve body.

When the EGR gas is returned to the suction air in a case where a temperature of the suction air is in a low-temperature region in a case, the first valve body exposed to the suction air is cooled down to have a low temperature. In this case, when the EGR gas collides with the first valve body having a low temperature, the water vapor contained in the EGR gas is cooled down, so that water is generated in the first valve body. Thus, there is a possibility that the water erodes the compressor of the turbocharger.

It is an object of the present disclosure to provide a valve unit which prevents generation of water on a first valve body and which prevents erosion of a compressor of a turbocharger due to the water even if a temperature of a suction air is low is.

A valve unit is mounted on an intake and exhaust system that charges a suction air that is drawn into a machine by use of a turbocharger.

The valve unit supplies a low-pressure EGR gas, which is a low-pressure exhaust gas flowing through a turbine of the turbocharger, to a suction air flow and introduces the low-pressure EGR gas into a compressor of the turbocharger.

The valve unit includes a conduit forming member, a first valve body and a second valve body.

The conduit forming member includes a first conduit through which the suction air flows and a second conduit communicating with the first conduit. The conduit forming element introduces the low pressure EGR gas into the second conduit and controls the EGR gas to flow together with the suction air flowing through the first conduit.

The first valve body is received in the first conduit and is rotatably driven, so that the Saugluftströmung is throttled.

The second valve body is received in the second conduit and is rotatably driven, so that a flow of the low-pressure EGR gas is throttled.

The second conduit is cylindrically shaped and has an axis corresponding to a straight line.

When the second valve body is moved toward the first conduit in a direction parallel to the axis in a case where the second valve body completely closes the second conduit, a region through which the second valve body moves becomes a conduit region designated. At least part of a rotation area of the first valve body is located in the conduit area.

A downstream introduction portion is disposed on at least one of the first valve body, a wall of the first pipe, or a wall of the second pipe. The downstream introduction portion passes the low-pressure EGR gas flowing from the second conduit to the first conduit so as to flow toward a downstream position of the first conduit.

In the valve unit, generation of water on the first valve body is prevented because the EGR gas is prevented from reaching the first valve body.

Thus, even if a temperature of the suction air is low, the generation of erosion of the supercharger of the turbocharger due to the water can be prevented.

The foregoing and other aspects, features, and advantages of the present disclosure will become more apparent from the following detailed description made with reference to the accompanying drawings. Show it:

1 12 is a schematic diagram showing an engine intake and exhaust system including a turbocharger according to a first embodiment and a second embodiment of the present disclosure;

2 a schematic diagram showing a valve unit according to the first embodiment;

3 a schematic diagram showing the valve unit according to the first embodiment;

4A a plan view showing a first valve body according to the second embodiment;

4B a schematic diagram showing the valve unit according to the second embodiment; and

5 a plan view showing the first valve according to a modification example.

The embodiments of the present disclosure will be described below with reference to the drawings. In the embodiments, a part corresponding to a matter described in a previous embodiment may be given the same reference numerals, so that a repetitive description of the part may be omitted. In one embodiment, when only a portion of one configuration is described, another prior embodiment may apply to the other portions of the configuration. The parts can be combined even if the description does not explicitly state that the parts can be combined. The embodiments may in part be combined even if the description does not expressly indicate that the embodiments can be combined, provided that the combination is not dangerous.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.

First Embodiment

With reference to 1 becomes an engine intake and exhaust system 2 that is a valve unit 1 includes, described according to a first embodiment of the present disclosure.

The engine intake and exhaust system 2 is an intake and exhaust system that uses an intake air by using a turbocharger 4 into a machine 3 is absorbed, charges. The engine intake and exhaust system 2 further includes a high pressure EGR device 5 and a low pressure EGR device 6 ,

According to the present embodiment, the machine is 3 a diesel engine that drives a vehicle, and it includes a suction line 7 , which introduces the suction air into a cylinder, and an exhaust pipe 8th which discharges exhaust gas generated in the cylinder to the atmosphere.

The high pressure EGR device 5 communicates with the exhaust pipe 8th at a position upstream of a DPF9 in the exhaust air, which is an area where a relatively high exhaust pressure is generated, and with the suction pipe 7 at a position downstream of a throttle valve 10 in the suction air, which is an area where a relatively high intake negative pressure is generated. The high pressure EGR device 5 is an exhaust air recirculation device that supplies an EGR gas in a large amount to the engine 3 can lead back.

The high pressure EGR device 5 includes a high pressure EGR line 12 , which is a part of the exhaust air to the suction line 7 as the EGR gas is returning.

As in 1 is shown in the high pressure EGR device 5 an outlet end of the high pressure EGR line 12 with an exhaust manifold connected, and an inlet end of the high-pressure EGR pipe 12 is with a compressed air tank 13 an intake manifold connected.

As in 1 is shown includes the high pressure EGR device 5 a high pressure EGR control valve body 15 , a high pressure EGR cooler 16 , a diversion 17 and a switching valve 18 working in the high pressure EGR pipe 12 are arranged. The high pressure EGR control valve body 15 regulates an opening degree of the high pressure EGR pipe 12 for regulating a flow rate of the EGR gas. The high pressure EGR cooler 16 cools the EGR gas that goes to the suction line 7 is returned. The diversion 17 directs the EGR gas coming from the high pressure EGR cooler 16 to the suction line 7 is attributed to. The switching valve 18 switches between the high pressure EGR cooler 16 and the diversion 17 ,

In addition, the in 1 shown configuration is a specific example, and the high-pressure EGR device 5 Must have the high-pressure EGR cooling device 16 , the diversion 17 and the switching valve 18 do not include.

The low pressure EGR device 6 communicates with the exhaust pipe 8th at a position downstream of the DPF 9 in the exhaust air, which is an area where a relatively low exhaust pressure is generated, and the suction pipe 7 at a position upstream of the throttle valve 10 in the suction air, which is an area where a relatively low intake negative pressure is generated. The low pressure EGR device 6 is an exhaust air recirculation device that supplies the EGR gas in a small amount to the engine 3 can lead back. The low pressure EGR device 6 includes a low pressure EGR line 20 that take a portion of the exhaust gas as the EGR gas to the suction line 7 returns.

In particular, the low pressure EGR conduit includes 20 an exhaust end connected to the exhaust pipe 8th at a position downstream of the DPF 9 is connected in the exhaust air, and an inlet end connected to the suction line 7 at a position upstream of a compressor 22 of the turbocharger 4 is connected in the suction air. The low pressure EGR pipe 20 directs a portion of the exhaust gas passing through a turbine 21 of the turbocharger 4 and the DPF 9 flows into the compressor 23 of the turbocharger 4 one.

The low pressure EGR device 6 further includes a low pressure EGR control valve body 25 and a low pressure EGR cooler 26 , The low pressure EGR control valve body 25 Regulates an opening degree or angle of the low pressure EGR pipe 20 for regulating a flow rate of the EGR gas. According to the present embodiment, the low-pressure EGR control valve body 25 to the second valve body 25 , The low-pressure cooling device 26 Cools the EGR gas down to the suction line 7 is supplied.

The low pressure EGR device 6 further includes an intake throttle valve body 27 , which has an intake negative pressure at a confluence portion between the suction pipe 7 and the low pressure EGR pipe 20 generated. According to the present embodiment, the intake throttle valve body 27 a first valve body 27 ,

Since the intake negative pressure according to the first valve body 27 may generate a differential pressure in the low-pressure EGR device 6 be ensured, and the low pressure EGR device 6 can the EGR gas in a large amount to the machine 3 traced.

When the first valve body 27 the suction line 7 completely throttles, is part of the suction line 7 still open. In other words, the first valve body 27 for opening a part of the suction line 7 provided when the first valve body 27 is in a closed state. In particular, when the first valve body 27 is in the closed state, are still 10% of the suction line 7 opened, and the suction can through the suction line 7 stream.

According to the present embodiment, the first valve body 27 and the second valve body 25 in the valve unit 1 includes.

The valve unit 1 is in the low pressure EGR device 6 includes. As in 2 is shown, includes the valve unit 1 a conduit forming element 32 , The conduction element 32 forms a first line 30 out, through which the suction air flows, and a second line 31 that with the first line 30 communicated. The conduction element 32 directs the EGR gas into the second line 31 and controls the EGR gas so that it has flowed together with the suction air passing through the first conduit 30 flows.

The first line 30 is a part of the suction line 7 , and the second line 31 is part of the low pressure EGR gas pipe 20 ,

The first valve body 27 is a butterfly valve, which is plate-shaped and in the first line 30 is included. The first valve body 27 becomes integral with a first wave 33 rotatably driven, so that a flow of suction air is throttled. The first wave 33 is through the conduit forming element 33 rotatably mounted.

The second valve body 25 is a butterfly valve, which is plate-shaped and in the second line 31 is included. The second valve body 25 becomes integral with a second shaft 34 rotatably driven, so that a flow of the EGR gas is throttled. The second wave 34 is through the conduit forming element 32 rotatably mounted.

The first wave 33 is arranged so that it is parallel to the second shaft 34 is. That is, an axial direction of the first shaft 33 parallel to an axial direction of the second shaft 34 is.

The valve unit 1 further includes an electric actuator 35 and a linking device 36 , The electric actuator 35 drives the second valve body 25 rotatable. The linking device 36 changes a discharge property of the electric actuator 35 so that the first valve body 27 is rotatably driven. In other words, the valve unit is driving 1 the first valve body 27 depending on the output characteristic of the electric actuator 35 on, by the linking device 36 is transmitted.

The linking device 36 includes a property-changing portion that controls the output characteristic of the electric actuator 35 changes and transmits the discharge property after passing through the first valve body 25 has been changed. When an opening degree or angle of the second valve body 25 exceeds a predetermined angle, the property-changing portion changes an opening degree or angle of the first valve body 27 such that it corresponds to an increase in the opening degree or angle of the second valve body 25 decreases.

The electric actuator 35 includes an electric motor 38 and a reduction mechanism 39 , The electric motor 38 is a DC motor that produces a rotation output when energized. The reduction mechanism 39 is a reduction mechanism that controls the rotational output of the electric motor 38 reduced and increased output torque. A release of the reduction mechanism 39 drives the second valve body 25 rotatably and drives the first valve body 27 through the linking device 36 rotatable.

The linking device 36 at a position outside of the conduit forming element 32 is arranged, converts a rotation property that the output characteristic of the electric actuator 35 is, and drives the first valve body 27 at. The linking device 36 includes a cam plate 40 , which is integral with the second valve body 25 turns, and a follower arm 41 that integrates with the first valve body 27 rotates.

The cam plate 40 is plate-shaped and made of a material having an effective abrasion resistance, such as. B. a nylon-based resin. The cam plate 40 is fixed so that it is perpendicular to the axial direction of the second shaft 34 is.

The follower arm 41 is also plate-shaped and is also made of a material having an effective abrasion resistance, such as. B. a nylon-based resin. The follower arm 41 is fixed so that it is perpendicular to the axial direction of the first shaft 33 is. The follower arm 41 includes a rotation end, that of the cam plate 40 is separated by a predetermined gap distance and a part of the cam plate 40 in the axial direction of the first shaft 33 overlaps.

The property changing section includes a cam groove 43 and an engagement portion 45 , The cam groove 43 is at a position separate from a pivot point of the cam plate 40 arranged. The engagement section 45 is at a position separate from a pivot point or a rotation axis of the follower arm 41 arranged and takes with the cam groove 43 Intervention.

The engagement section 45 includes a role 45a and a shaft section 45b , The role 45a is cylindrically shaped and takes with the cam groove 43 Intervention. The shaft section 45b is at the rotation end of the follower arm 41 attaches and stores the roll 45a rotatable.

The camshaft 43 includes a first cam groove 43a and a second cam groove 43b , A cam profile of the cam groove 43 that the engagement section 45 drives, is set up so that it is the first cam groove 43a with the second cam groove 43b smoothly connects. The first cam groove 43a serves to maintain the opening degree or angle of the first valve body 27 , The second cam groove 43b serves to drive the first valve body 27 used.

The first cam groove 43a is an arcuate groove that coincides with the cam plate 40 is concentric. The first cam groove 43a may be the opening angle of the first valve body 27 in a rotation range from a fully closed opening angle θ0 of the second valve body 25 to an intermediate opening angle θ1, which is predetermined, maintained at a maximum value. In this case, the fully-closed opening degree θ0 of the second valve body is 25 an opening angle where the second line 31 completely throttled.

The second cam groove 43b is with one end of the first cam groove 43a seamlessly connected and is an arcuate groove, which coincides with the cam plate 40 is not concentric. The second cam groove 43b rotates the follower arm 41 in a rotation range of the intermediate opening angle θ1 of the second valve body 25 to a maximum opening angle θ2 of the second valve body 25 and rotates the opening angle of the first valve body 27 from a maximum opening angle in a closing direction of the first line 30 ,

With reference to 3 becomes a configuration of the valve unit 1 described.

The first line 30 is cylindrical in shape and has an axis α. The second line 31 is cylindrical and has an axis β.

According to the present embodiment, the axis α and the axis β are straight and perpendicular to each other.

When the second valve body 25 towards the first line 30 is moved in a direction parallel to the axis β in a case where the second valve body 25 the second line 31 fully closes, becomes an area through which the second valve body 25 moved, referred to as a conduction region γ. A part of a rotation range δ of the first valve body 27 overlaps a part of the line area γ in the axial direction of the first shaft 33 , That is, a part of the rotation range δ is located in the conduction region γ.

The rotation range δ is a range through which the first valve body 27 turns and moves when the first valve body 27 is driven.

To minimize the dimensions of the valve unit 1 becomes the first valve body 27 at a position near the second conduit 31 arranged, and on a part of the conductive element 32 , the upstream of the first line 30 is arranged is waived.

A projection section 50 which protects a part of the rotation range δ from the flow of the EGR gas is on a wall of the second pipe 31 upstream of the first line 30 arranged.

When the projecting portion 50 towards the first line 30 is moved in a direction parallel to the axis β, becomes an area through which the projection portion 50 is referred to as a protrusion passing region ε. A part of the projection passing area ε overlaps a part of the rotation area δ in the axial direction of the first shaft 33 ,

In addition, the protrusion section needs 50 integral with the second conduit 31 be arranged. That is, the protrusion portion 50 in the second line 31 is included. Alternatively, the projection portion 50 be arranged as an element extending from the second line 31 differentiates and then on the second line 31 is attached.

According to the present embodiment, in the valve unit 1 the second line 31 cylindrically shaped and has the axis β. When the second valve body 25 towards the first line 30 is moved in a direction parallel to the axis β in a case where the second valve body 25 the second line 31 completely closes, becomes an area through which the second valve body 25 moved, referred to as the line area γ. A part of a rotation range δ of the first valve body 27 is located in the line area γ.

The protrusion section 50 which protects a part of the rotation range δ from the flow of the EGR gas is on a wall of the second pipe 31 upstream of the first line 30 arranged.

Thus, the protrusion portion works 50 as a downstream introduction section 51 , which prevents the flow of EGR gas from that of the second conduit 31 to the first line 30 flows, and thereby towards the first valve body 27 flows and introduces the EGR gas, causing it to flow downstream from the first conduit 30 flows. In particular, z. B. the projecting portion 50 the EGR gas is directed toward a position downstream of the first valve body 27 in the first line 30 flows.

There also in the valve unit 1 prevents the EGR gas from the first valve body 27 achieved, there will be a generation of water on the first valve body 27 prevented.

Even if thus a temperature of the suction air is low, the emergence of erosion of the compressor can 22 of the turbocharger 4 be prevented due to the water.

Second Embodiment

With reference to 4A and 4B A second embodiment of the present invention will be described. The substantially identical parts and components as in the first embodiment are given the same reference numeral.

4A is a plan view of the first valve body 27 shows.

The first valve body 27 is a butterfly valve that is plate-shaped. The first valve body 27 includes through holes 52 which are arranged so that they are the first valve body 27 in a thickness direction of the first valve body 27 penetrate.

The first valve body 27 revolves around a pivot point or a center of rotation, which represents an axis ζ. The axis ζ is a center of rotation of the first shaft 33 , The through holes 52 are arranged in two lines which are parallel to the axis ζ, and the axis ζ is arranged between the two lines. Each of the through holes 52 is elliptical in shape and has a major axis parallel to the axis ζ.

Because the suction through the through holes 52 flows, the EGR gas can be prevented from the first valve body 27 reached. The through holes 52 function as the downstream initiation step 51 that is the EGR gas coming from the second line 31 in the first line 30 flows, thus initiating it towards a position downstream of the first conduit 30 flows. In particular, the through holes conduct 52 the EGR gas is directed toward a position downstream of the first valve body 27 in the first line 30 flows.

Because the through holes 52 are arranged in two lines which are parallel to the axis ζ, and each of the through hole 52 is elliptical in shape and has a major axis parallel to the axis δ, an air curtain like flow is created. Thus, it can be further prevented that the EGR gas, the first valve body 27 reached.

As in the first embodiment, according to the second embodiment, in the valve unit 1 prevents water on the first valve body 27 can arise because the EGR gas is prevented from the first valve body 27 reached.

Thus, even if the temperature of the suction air is low, erosion of the compressor due to the water can be prevented 22 of the turbocharger 4 comes about.

The present disclosure is not limited to the above-mentioned embodiments and can be applied to various embodiments within the scope of the present disclosure.

According to the above embodiments, z. B. the first wave 30 arranged in the line region γ. The first wave 33 however, it may be disposed at a position outside the conduction region γ.

According to the first embodiment, the protrusion portion 50 on a wall of the second pipe 31 arranged. The protrusion section 50 However, on a wall of the first pipe 30 be arranged.

According to the first embodiments, the first valve body 27 and the second valve body 25 through the electric actuator 35 via the linking device 36 rotatably driven. The first valve body 27 and the second valve body 25 However, the different electric actuators can be driven. In this case, the two electric actuators 35 for rotatably driving the first valve body 27 and the second valve body 25 be used.

Alternatively, the first valve body 27 and the second valve body 25 through the electric motor 38 without using the linking device 36 and by the reduction mechanism 39 are driven. In this case, the reduction mechanism drives 39 the first valve body 27 and the second valve body 25 in different ways.

According to the above embodiments, the axis α is the first line 30 perpendicular to the axis β of the second line 31 , The first line 30 and the second line 31 However, they can be connected together at a predetermined angle. That is, the axis α crosses the axis β at the predetermined angle.

Alternatively, the first line 30 and the second line 31 be joined together so that the axis α does not cross the axis β.

According to the second embodiment, a plurality of through holes 52 provided so that they are arranged in lines parallel to the axis ζ. As in 5 however, two through-holes can be shown 52 which extend in a direction parallel to the axis ζ and are slit-shaped.

According to the above embodiments, the valve unit includes 1 one of the projecting portion 50 and the through hole 52 as the downstream introduction section 51 , The valve unit 1 However, both the projection portion 50 as well as the through hole 52 as the downstream introduction section 51 include.

Although the present disclosure has been described with reference to embodiments thereof, it should be understood that the disclosure is not limited to the embodiments and constructions. The The present disclosure is intended to cover various modification and equivalence arrangements.

Moreover, while the various combinations and configurations are preferred, other combinations and configurations that include more, less, or only a single element are also within the scope of the present disclosure.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2013-096286A [0005]

Claims (5)

Valve unit connected to an intake and exhaust system ( 2 ), which is a suction air, which in a machine ( 3 ) by using a turbocharger ( 4 ), wherein the valve unit recirculates a low-pressure EGR gas, which is a low-pressure exhaust gas and which is passed through a turbine ( 21 ) of the turbocharger ( 4 ) flows to a flow of the suction air, and the low-pressure EGR gas into a compressor ( 22 ) of the turbocharger ( 4 ), the valve unit comprising: a conduit-forming element ( 32 ), which is a first line ( 30 ), through which the suction air flows, and a second line ( 31 ), with which the first line ( 30 ), wherein the conductive element ( 32 ) introduces the low pressure EGR gas into the second line ( 31 ) and the EGR gas so that it flows together with the suction air through the first line ( 30 ) flows; a first valve body ( 27 ), in the first line ( 30 ) and is rotatably driven, so that the flow of the suction air is throttled; and a second valve body ( 25 ), in the second line ( 31 ) and is rotatably driven so that a flow of the low-pressure EGR gas is throttled, wherein the second line ( 31 ) is cylindrically shaped and has an axis (β) which is a straight line when the second valve body ( 25 ) in the direction of the first line ( 30 ) is moved in a direction parallel to the axis (β) in a case where the second valve body (FIG. 25 ) the second line ( 31 ) completely closes, an area through which the second valve body 25 moved, is referred to as a line region (γ), at least part of a rotation range (δ) of the first valve body ( 27 ) is in the line region (γ), a downstream introduction section ( 51 ) on at least one of the first valve body ( 27 ), a wall of the first line ( 30 ) or a wall of the second line ( 31 ), and the downstream introduction section (FIG. 51 ) the low pressure EGR gas coming from the second line ( 31 ) to the first line ( 30 ) initiates, so that it is in the direction of a downstream position of the first line ( 30 ) flows. A valve unit according to claim 1, wherein said downstream introduction portion (16) 51 ) a projecting portion ( 50 ), which is on one of the wall of the first line ( 30 ) and the wall of the second line ( 31 ) is arranged, and the projecting portion ( 50 ) protects at least a portion of the range of rotation from the flow of low pressure EGR gas. Valve unit according to claim 1, wherein the first valve body ( 27 ) is plate-shaped and the downstream introduction section ( 51 ) at least one through hole ( 52 ) penetrating the first valve body in a thickness direction of the first valve body. Valve unit according to claim 3, wherein the first valve body ( 27 ) rotates about a rotation center that is an axis (ζ), and a plurality of through holes ( 52 ) is arranged in a line parallel to the axis (ζ). Valve unit according to claim 3, wherein the first valve body ( 27 ) rotates about a center of rotation that is an axis (ζ), and the through hole ( 52 ) extends in a direction parallel to the axis (ζ).

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