JP5146556B2 - Low pressure EGR valve unit - Google Patents

Description

  The present invention is used in a low pressure EGR device, and relates to a low pressure EGR valve unit equipped with both a low pressure EGR adjustment valve and an intake negative pressure generating valve.

[Conventional technology]
A high-pressure EGR device that suppresses generation of NOx (nitrogen oxide) in exhaust gas by suppressing the combustion temperature of the engine is known.
This high-pressure EGR device is conventionally called an EGR device, and a part of the exhaust gas flowing through the exhaust passage is used as EGR gas, and the intake valve downstream side (high intake negative pressure) of the throttle valve in the intake passage. This is a technique in which EGR gas, which is an incombustible gas, is mixed into a part of the intake air to reduce the combustion temperature of the engine combustion chamber and effectively suppress the generation of NOx.

  In the high pressure EGR device, the high pressure EGR flow path for returning the EGR gas to the intake side is provided with a high pressure EGR adjustment valve for adjusting the opening of the high pressure EGR flow path. The opening degree is controlled by an ECU (abbreviation of engine control unit) so as to obtain an EGR amount (exhaust gas recirculation amount per unit time) according to the state (engine speed, engine load, etc.).

On the other hand, the engine is always required to have a technique for reducing the generation of NOx.
In recent years, as a technique for reducing the generation of NOx in a wide operation range, a technique for mounting a low-pressure EGR device in addition to the high-pressure EGR device has been proposed (for example, see Patent Document 1).
The low pressure EGR device returns a part of the exhaust gas in the low exhaust pressure range (the range where the exhaust pressure is low) in the exhaust passage to the low intake negative pressure generation range (the range where the intake negative pressure is weak) in the intake passage. This is a device that returns a small amount of EGR gas to the intake side of the engine.
For this reason, it is possible to suppress the generation of NOx even in an operation region where low-concentration EGR gas is required, such as an operation region where the engine load is large, which is difficult to realize with a high-pressure EGR device.

  In the low pressure EGR device, the low pressure EGR flow path for returning the EGR gas to the intake side is provided with a low pressure EGR adjustment valve for adjusting the opening of the low pressure EGR flow path. As with the EGR adjustment valve, the opening degree is controlled by the ECU so that an EGR amount corresponding to the engine operating state (engine speed, engine load, etc.) can be obtained.

[Problem 1 of the prior art]
The low pressure EGR device returns a part of the exhaust gas in the low exhaust pressure range in the exhaust passage to the low intake negative pressure generation range in the intake passage.
For this reason, even if there is an engine operating region in which a large amount of EGR gas is required to be returned to the engine using the low-pressure EGR device, the request cannot be met.

  Therefore, an intake negative pressure generating valve (intake throttle valve) capable of generating intake negative pressure is provided in the intake passage where the low pressure EGR device returns EGR gas, and a large amount of EGR gas is returned to the engine using the low pressure EGR device. In the operation region, it is conceivable to control the intake negative pressure generating valve in the closing direction (the direction in which the intake negative pressure is generated). That is, in an operation region where it is desired to obtain a large EGR amount using the low pressure EGR device, it is conceivable that a large amount of EGR gas is returned to the engine by generating an intake negative pressure with the intake negative pressure generating valve.

For this reason, it is conceivable that the low pressure EGR adjustment valve and the intake negative pressure generating valve are provided in a common valve housing to form a unit.
That is, it is conceivable to provide the low pressure EGR adjustment valve and the intake negative pressure generation valve as one low pressure EGR valve unit.

Here, the low-pressure EGR regulating valve is separated from the low-pressure EGR shaft that is rotatably supported with respect to the valve housing and the low-pressure EGR valve body that is disposed in the low-pressure EGR flow path due to restrictions in assembly. The low pressure EGR valve body is attached to the low pressure EGR shaft inside the low pressure EGR flow path.
As with the low pressure EGR adjustment valve, the intake negative pressure generation valve is also provided with an intake throttle shaft that is rotatably supported with respect to the valve housing and an intake throttle valve body disposed in the intake passage. The intake throttle valve body is attached to the intake throttle shaft inside the intake passage.

On the other hand, since the valve housing in which the low pressure EGR adjustment valve and the intake negative pressure generating valve are assembled is mounted on the vehicle, the valve housing is restricted in mounting on the vehicle.
As a result, the low pressure EGR flow path and the intake passage formed in the valve housing are also subject to restrictions on vehicle mounting.

As described above, the low pressure EGR flow path and the intake passage formed in the valve housing are restricted in terms of mounting on the vehicle, and there is a problem that the assembling property of the intake throttle valve body is deteriorated.
Specifically, the intake throttle body is disposed at the back of the valve housing. The low pressure EGR flow path and the intake passage formed in the valve housing are bent or lengthened due to restrictions on mounting on the vehicle, so that it is difficult for tools to reach the intake throttle shaft from the outside of the valve housing. Moreover, visual observation becomes difficult. As a result, it becomes difficult to fix the intake throttle valve body to the intake throttle shaft assembled to the valve housing.

[Problem 2 of the prior art]
Since the EGR gas is a part of the exhaust gas, the temperature is high. For this reason, it is necessary to provide a member for forming the low pressure EGR flow path with metal, and the intake passage side is also manufactured with metal (aluminum or the like).
As a result, the weight of the valve housing increases and the cost increases.

[Problem 3 of the prior art]
When one of the low pressure EGR adjustment valve or the intake negative pressure generating valve fails, all of the low pressure EGR valve units are replaced. For this reason, there has been a problem that the replacement cost (cost required for repair) for a failure is high.

[Problem 4 of the prior art]
As described above, the valve housing is subject to various restrictions on vehicle mounting. For this reason, valve housings corresponding to the specifications of the engine and the specifications of the manufacturer and vehicle type are required. That is, it is necessary to provide complicated valve housing shapes (complex low pressure EGR flow paths and intake passages) according to different specifications.
For this reason, every time the specification is changed, all of the complicated and large valve housings must be newly created, which necessitates the production cost of complicated and large molds, which increases the cost of changing the specification. There was a bug that would

[Problem 5 of the prior art]
When the low pressure EGR adjustment valve and the intake negative pressure generating valve are connected via a link device and driven by one actuator, the link device is provided in a common valve housing. There is no degree of freedom in assembling the cam groove of the cam plate and the connecting part of the driven pin.
For this reason, assembly and disassembly (separation) of the link coupling portion in the link device become difficult, and there is a problem that the assembling property and the maintenance property are deteriorated.

JP 2008-150955 A

  The present invention has been made in view of the above problems, and an object of the present invention is to set an intake throttle body even if a low-pressure EGR flow path and an intake passage formed in a valve housing are restricted in mounting on a vehicle. The object is to provide a low-pressure EGR valve unit that does not cause deterioration in attachment.

[Means of claim 1]
2. The low pressure EGR valve unit employing the means of claim 1, wherein the valve housing on which the low pressure EGR adjustment valve and the intake negative pressure generating valve are mounted is provided by connecting two members, and a joint surface between the two members Is provided in the vicinity of the intake throttle shaft.
In particular, the two members are an EGR-side housing that forms a low-pressure EGR flow path, and an intake-side housing that forms an intake passage, and the intake-side housing before the EGR-side housing is assembled has an opening that forms the low-pressure EGR flow path It is characterized by the fact that the intake throttle shaft can be seen.
For this reason, even if the low pressure EGR flow path and the intake passage formed in the valve housing are subject to restrictions on mounting in the vehicle, the “state before joining the EGR side housing and the intake side housing” If it exists, it will be easy to reach tools from the opening part which comprises a low voltage | pressure EGR flow path, and an intake throttle shaft, and visual observation will also become easy. As a result, the work of fixing the intake throttle valve body to the intake throttle shaft assembled to the intake side housing can be easily performed.
That is, even if the low pressure EGR flow path and the intake passage of the valve housing are longer or bent due to restrictions on vehicle mounting, the deterioration of the assembling performance of the intake throttle body is avoided. be able to.

  Further, since the low pressure EGR adjustment valve is provided in the EGR side housing and the intake negative pressure generation valve is provided in the intake side housing, even if one of the low pressure EGR adjustment valve or the intake negative pressure generation valve fails, the low pressure EGR valve unit It is not necessary to replace all of the above, and only one (the failure side) can be replaced. For this reason, it becomes possible to keep the replacement cost for a failure low.

Furthermore, when changing the specifications of the low pressure EGR flow path or the intake passage according to the vehicle type, etc., it is not necessary to change the specifications of all of the valve housings, but only one (housing on which the specification change is required) is changed. Can be supported.
That is, it is not necessary to newly create a complicated and large valve housing, and only one of the EGR side housing and the intake side housing needs to be changed in specification. As a result, the production cost of the mold can be reduced, and the cost required for changing the specification can be kept low.

[Means of claim 2 ]
In the low pressure EGR valve unit employing the means of claim 2 , the EGR side housing is formed of a metal material, and the intake side housing is formed of a resin material.
As described above, by providing the intake side housing out of the valve housing with the resin material, the weight of the valve housing can be reduced, and as a result, the low pressure EGR valve unit can be reduced in weight.
Further, by providing the intake side housing with a resin material, the material cost of the valve housing can be suppressed, and as a result, the cost of the low pressure EGR valve unit can be suppressed.

[Means of claim 3 ]
The low-pressure EGR valve unit employing the means of claim 3 has one actuator for driving the low-pressure EGR regulating valve, and a characteristic converter for changing the output characteristic of the actuator, and the output changed by the characteristic converter. And a link device for driving the intake negative pressure generating valve.

Further, by combining this claim 3 with the above-mentioned claim 1 (a technique in which the low pressure EGR adjusting valve is provided in the EGR side housing and the intake negative pressure generating valve is provided in the intake side housing), For example, assembly of the cam groove of the cam plate and the coupling portion of the driven pin) and disassembly (detachment in maintenance or the like) can be easily performed. For this reason, while being able to improve the assembly | attachment property of a low pressure EGR valve unit, the maintainability of a low pressure EGR valve unit can be improved.

It is a cross-sectional perspective view of a low pressure EGR valve unit. It is the upper view and principal part sectional drawing of a low pressure EGR valve unit. It is explanatory drawing which shows the assembly | attachment of an intake throttle body. It is a schematic explanatory drawing of the intake / exhaust system of an engine. It is a graph which shows the relationship between the EGR flow volume according to the rotation angle of a low pressure EGR regulating valve, and an intake air flow rate. It is explanatory drawing of EGR control in a high voltage / low pressure EGR amount control program.

[Description of Embodiments] [Mode for carrying out the invention] will be described with reference to the drawings.
The low pressure EGR valve unit 1 includes a valve housing 4 having a junction of the low pressure EGR flow path 2 and the intake passage 3, and a low pressure EGR adjustment valve 5 that is provided in the valve housing 4 and adjusts the opening degree of the low pressure EGR flow path 2. And an intake negative pressure generating valve 6 that is provided in the valve housing 4 and generates an intake negative pressure at the merging portion of the intake passage 3.

The low-pressure EGR valve unit 1 includes one electric actuator 7 that drives the low-pressure EGR adjustment valve 5 and a link device 8 that drives the intake negative pressure generating valve 6 by changing the output characteristics of the electric actuator 7. . Then, the low pressure EGR adjustment valve 5 is driven by one electric actuator 7 and the output of one electric actuator 7 is transmitted to the intake negative pressure generating valve 6 via the link device 8.
Here, the link device 8 is provided with a characteristic conversion unit 9 that changes the output characteristic of the electric actuator 7 and transmits it to the intake negative pressure generating valve 6 so that the low pressure EGR adjustment valve 5 becomes larger than a predetermined opening. After that, the opening degree of the intake negative pressure generating valve 6 is decreased in conjunction with the opening degree increase of the low pressure EGR adjustment valve 5 (the intake passage 3 is throttled to increase the negative pressure).

The low-pressure EGR adjustment valve 5 includes a low-pressure EGR shaft 11 that is rotatably supported with respect to the valve housing 4 and a low-pressure EGR valve body 12 that is disposed in the low-pressure EGR flow path 2. A low pressure EGR valve body 12 is attached to the low pressure EGR shaft 11 inside the low pressure EGR flow path 2.
The intake negative pressure generating valve 6 includes an intake throttle shaft 13 that is rotatably supported with respect to the valve housing 4 and an intake throttle valve body 14 that is disposed in the intake passage 3. An intake throttle valve body 14 is attached to the intake throttle shaft 13 in the intake passage 3.

  The valve housing 4 is provided by coupling an EGR side housing 15 that forms the low pressure EGR flow path 2 and an intake side housing 16 that forms the intake passage 3. That is, in this embodiment, the low pressure EGR valve unit 1 is provided by connecting the EGR side housing 15 provided with the low pressure EGR adjustment valve 5 and the intake side housing 16 provided with the intake negative pressure generating valve 6. The joint surface M between the EGR side housing 15 and the intake side housing 16 is provided between the EGR side housing 15 and the intake side housing 16 (portion close to the intake throttle shaft 13).

Next, a specific example of the low pressure EGR valve unit 1 will be described with reference to FIGS. In the present embodiment, the same reference numerals as those in the [DETAILED DESCRIPTION OF THE INVENTION] denote the same functional objects.
[Outline of engine intake and exhaust system]
First, an engine intake / exhaust system will be described with reference to FIGS.

The engine intake / exhaust system is provided with a high pressure EGR device 21 and a low pressure EGR device 22.
The high pressure EGR device 21 includes an exhaust passage 24 in a high exhaust pressure range (a range where high exhaust pressure is generated on the exhaust upstream side of the DPF 23) and a high intake negative pressure generation range (on the intake downstream side of the throttle valve 25). It is an exhaust gas recirculation device that is good at returning a large amount of EGR gas to the engine by connecting the inside of the intake passage 3 in a range where high intake negative pressure is generated), and a part of the exhaust gas is EGR gas. Is provided with a high pressure EGR passage 26 that returns to the intake downstream side of the intake passage 3.
As a specific example, the high-pressure EGR flow path 26 of FIG. 4 has an exhaust passage 24 side connected to an exhaust manifold and an intake passage 3 side connected to a surge tank of the intake manifold.

In the high pressure EGR device 21 shown in FIG. 4, a high pressure EGR adjustment valve 27 that adjusts the flow rate of the EGR gas by adjusting the opening degree of the high pressure EGR passage 26 in the middle of the high pressure EGR passage 26, and returned to the intake side. The high pressure EGR cooler 28 that cools the EGR gas, the high pressure cooler bypass 29 that bypasses the EGR gas returned to the intake side from the high pressure EGR cooler 28, and the high pressure EGR cooler that switches between the high pressure EGR cooler 28 and the high pressure cooler bypass 29. A switching valve 30 is provided.
FIG. 4 is a specific example, and the high pressure EGR cooler 28, the high pressure cooler bypass 29, and the high pressure EGR cooler switching valve 30 may not be mounted.

The low pressure EGR device 22 includes a low exhaust pressure range (a range where low exhaust pressure is generated on the exhaust downstream side of the DPF 23) and a low intake negative pressure generation range (on the intake upstream side of the throttle valve 25) This is an exhaust gas recirculation device that is good at returning a small amount of EGR gas to the engine by connecting to the inside of the intake passage 3 in a range where low intake negative pressure is generated), and a part of the exhaust gas is EGR gas. The low pressure EGR flow path 2 returning to the intake upstream side of the intake passage 3 is provided.
As a specific example, the low-pressure EGR flow path 2 in FIG. 4 has an exhaust passage 24 side connected to an exhaust pipe downstream of the DPF 23 and an intake passage 3 side connected to an intake pipe upstream of the compressor 31 of the turbocharger. Has been.

The low-pressure EGR device 22 includes a low-pressure EGR adjustment valve 5 that adjusts the flow rate of the EGR gas by adjusting the opening degree of the low-pressure EGR flow path 2 in the middle of the low-pressure EGR flow path 2, and the EGR gas that is returned to the intake side. And a low-pressure EGR cooler 32 for cooling the air.
Further, the low pressure EGR device 22 is provided with an intake negative pressure generating valve 6 for generating an intake negative pressure at the junction of the intake passage 3 and the low pressure EGR flow path 2.

  The intake negative pressure generating valve 6 is provided so as to open a part of the intake passage 3 even when the intake passage 3 is squeezed to the maximum. Specifically, even if the intake negative pressure generating valve 6 is in a state where the intake passage 3 is squeezed to the maximum, for example, about 10% of the intake passage 3 is opened (solid line Y in FIG. 5). Refer to the minimum flow rate).

Next, the ECU that controls the high pressure EGR device 21 and the low pressure EGR device 22 will be described.
The ECU is equipped with an EGR control program for controlling the operation of the high pressure EGR device 21 and the low pressure EGR device 22.
This EGR control program is
(I) a high-pressure EGR cooler switching program for switching the high-pressure EGR cooler switching valve 30 based on the warm-up state of the engine (for example, the temperature of engine cooling water);
(Ii) a high-pressure / low-pressure EGR amount control program for controlling the opening of the high-pressure EGR adjustment valve 27, the low-pressure EGR adjustment valve 5, and the intake negative pressure generation valve 6 according to the engine speed and engine load (engine torque). ing.

An outline of the high pressure / low pressure EGR amount control program will be described with reference to FIG.
The high pressure / low pressure EGR amount control program is
(I) In the operating range below the solid line α shown in FIG. 6 (engine operating range based on the relationship between the engine speed and the engine torque), the low pressure EGR device 22 is stopped and the high pressure EGR adjustment valve 27 of the high pressure EGR device 21 is opened. EGR control is performed only by degree control (specifically, the low pressure EGR flow path 2 is closed by the low pressure EGR adjustment valve 5, and the high pressure EGR adjustment valve 27 is controlled to an opening degree corresponding to the relationship between the engine speed and the engine torque. )
(Ii) Opening control of the high pressure EGR adjustment valve 27 of the high pressure EGR device 21, the low pressure EGR adjustment valve 5 of the low pressure EGR device 22, and the intake negative pressure in the operation region between the solid line α and the solid line β shown in FIG. EGR control is performed by both opening control of the generating valve 6 (specifically, the high pressure EGR adjusting valve 27 is controlled to an opening corresponding to the relationship between the engine speed and the engine torque, and the low pressure EGR adjusting valve 5 and The intake negative pressure generating valve 6 is controlled to an opening corresponding to the relationship between the engine speed and the engine torque),
(Iii) EGR control is performed only by opening control of the low pressure EGR adjusting valve 5 and the intake negative pressure generating valve 6 of the low pressure EGR device 22 in the operation region above the solid line β shown in FIG. (Specifically, the high-pressure EGR flow path 26 is closed by the high-pressure EGR adjustment valve 27, and the low-pressure EGR adjustment valve 5 and the intake negative pressure generation valve 6 are controlled to an opening degree corresponding to the relationship between the engine speed and the engine torque. Control program.

Since the low pressure EGR device 22 is for returning the EGR gas in the low exhaust pressure range to the low intake negative pressure generation range, it is good at returning a small amount of EGR gas to the engine. However, even if there is an operation region where a large amount of EGR gas is desired to be returned to the engine using the low pressure EGR device 22, the low pressure EGR device 22 having a structure for returning the EGR gas to the low intake negative pressure generation range causes the engine to supply a large amount of EGR gas. It is difficult to return.
Therefore, the low pressure EGR device 22 is provided with an intake negative pressure generating valve 6 for actively generating intake negative pressure in the intake passage 3 for returning the EGR gas, and the low pressure EGR device 22 is in an operation region where a large EGR amount is desired. Then, the opening degree is controlled in the direction in which the intake negative pressure generating valve 6 is closed (the direction in which the intake negative pressure is generated), so that a large amount of EGR can be controlled in the low pressure EGR device 22.

However, (i) when in a “low concentration control state” in which a small amount of EGR gas is returned to the engine using the low-pressure EGR device 22, the intake negative pressure generating valve 6 has a maximum opening (fully opened opening) so as not to generate negative pressure. ) And it is necessary to control the opening degree of only the low pressure EGR regulating valve 5,
(Ii) In the “high concentration control state” in which a large amount of EGR gas is returned to the engine using the low pressure EGR device 22, the opening of the low pressure EGR adjustment valve 5 is increased and the intake negative pressure is generated to increase the negative pressure. It is necessary to reduce the opening of the valve 6.

Thus, in the “low concentration control state”, the intake negative pressure generating valve 6 is fixed fully open and only the low pressure EGR adjustment valve 5 is controlled in opening degree. In the “high concentration control state”, the opening degree of the low pressure EGR adjustment valve 5 is controlled. In response to this, the opening degree of the intake negative pressure generating valve 6 also changes.
For this reason, a dedicated actuator for driving the low pressure EGR regulating valve 5 and a dedicated actuator for driving the intake negative pressure generating valve 6 are required. However, if a dedicated actuator is installed in each, the cost increases. , Physique up and weight up.

  Therefore, as shown in FIG. 2, the low pressure EGR device 22 of the first embodiment changes the output characteristics of one electric actuator 7 that drives the low pressure EGR adjustment valve 5 and generates negative intake pressure. And a link device 8 for driving the valve 6, and the intake negative pressure generating valve 6 is driven by the output of the electric actuator 7 transmitted through the link device 8.

The link device 8 is provided with a characteristic conversion unit 9 that changes the output characteristic of the electric actuator 7 and transmits it to the intake negative pressure generating valve 6 so that the low-pressure EGR adjustment valve 5 is adjusted after the low-pressure EGR adjustment valve 5 becomes larger than a predetermined opening. The opening of the intake negative pressure generating valve 6 is set to be reduced in conjunction with the opening of the valve 5 (see FIG. 5).
5 indicates the change in the EGR flow rate with respect to the rotation angle of the low pressure EGR adjustment valve 5, and the solid line Y in FIG. 5 indicates a change in the intake flow rate by the intake negative pressure generating valve 6 with respect to the rotation angle of the low pressure EGR adjustment valve 5. Is shown.

[Description of Low Pressure EGR Valve Unit 1]
As described above, the low pressure EGR adjustment valve 5 and the intake negative pressure generation valve 6 are connected via the link device 8 and driven by the common electric actuator 7.
For this reason, the low pressure EGR regulating valve 5 and the intake negative pressure generating valve 6 are provided as one low pressure EGR valve unit 1.

The low-pressure EGR valve unit 1 includes the above-described low-pressure EGR adjustment valve 5, intake negative pressure generating valve 6, electric actuator 7 and link device 8 in a valve housing 4 having a junction of the low-pressure EGR flow path 2 and the intake passage 3. It is to be installed.
Below, the outline of the low pressure EGR regulating valve 5, the intake negative pressure generating valve 6, the electric actuator 7 and the link device 8 mounted on the low pressure EGR valve unit 1 will be described in order.

  The low-pressure EGR adjustment valve 5 is a butterfly valve, and includes a low-pressure EGR shaft 11 that is rotatably supported with respect to the valve housing 4 and a low-pressure EGR valve body 12 that is disposed in the low-pressure EGR flow path 2. In the low pressure EGR flow path 2, the low pressure EGR valve body 12 is attached to the low pressure EGR shaft 11 using the screw 33.

The intake negative pressure generating valve 6 is a butterfly valve, and includes an intake throttle shaft 13 that is rotatably supported with respect to the valve housing 4, and an intake throttle valve body 14 that is disposed in the intake passage 3. In the intake passage 3, the intake throttle body 14 is attached to the intake throttle shaft 13 using a screw 34.
The low pressure EGR shaft 11 and the intake throttle shaft 13 are arranged in parallel.

The electric actuator 7 is a combination of an electric motor (for example, a DC motor) that generates rotational output when energized and a speed reduction mechanism (for example, a gear speed reduction mechanism) that reduces the rotational output of the electric motor and increases output torque. It is. The low pressure EGR shaft 11 is driven by the output of the speed reduction mechanism, and the intake throttle shaft 13 is driven via the link device 8.
In addition, the code | symbol 7a in FIG. 1 is the accommodation space of the electric motor formed in the EGR side housing 15 mentioned later.

The link device 8 drives the intake negative pressure generating valve 6 by changing the output characteristic (rotation characteristic) of the electric actuator 7, and includes a cam plate 35 that rotates integrally with the low pressure EGR shaft 11, and the intake throttle shaft 13. And a driven arm 36 that rotates integrally therewith.
The cam plate 35 has a plate shape and is formed of a material (for example, nylon resin) having excellent wear resistance, and is fixedly disposed at a right angle to the low pressure EGR shaft 11.
The driven arm 36 has a plate shape and is formed of a material having excellent wear resistance (for example, nylon resin). The driven arm 36 has a rotating end side with respect to the cam plate 35 with a predetermined gap. Are fixedly arranged at right angles to the intake throttle shaft 13 so as to overlap with each other.

The characteristic converter 9 that changes the output characteristics of the electric actuator 7 in the link device 8 is provided at a position away from the rotation center of the cam arm 37 and the driven arm 36 at a position away from the rotation center of the cam plate 35. And a driven pin 38 fitted into the cam groove 37.
The driven pin 38 includes a shaft portion fixed to the rotation end side of the driven arm 36 and a roller (rotational difference absorber) rotatably mounted on the outer periphery of the shaft portion. Note that the shaft portion that supports the roller may be provided integrally with the driven arm 36 or may be provided separately and fixed to the driven arm 36.

The cam profile of the cam groove 37 that applies a driving force to the driven pin 38 is a combination of two groove shapes.
The “one groove shape” in the cam groove 37 is an arc groove having the same center as the rotation center of the cam plate 35, and the opening degree of the low pressure EGR adjustment valve 5 that restricts the low pressure EGR flow path 2 to the maximum (FIG. 5). In the opening range from the EGR side rotation angle = 0 ° to the predetermined switching opening Z (opening angle 0 ° to opening Z angle range), the opening degree of the intake negative pressure generating valve 6 is kept at the maximum opening degree. It is provided as follows.

  The “other groove shape” in the cam groove 37 is an angle changing groove that changes at a predetermined angle with respect to an arc groove having the same center as the rotation center of the cam plate 35, and the opening degree of the low pressure EGR adjustment valve 5 is switched to a predetermined value. As the opening degree Z changes to the maximum opening degree (EGR side rotation angle = 90 ° in FIG. 5), the driven arm 36 is rotated to change the opening degree of the intake negative pressure generating valve 6 from the maximum opening degree to the intake passage 3. Is provided so as to rotate in the closing direction.

  Here, since the valve housing 4 in which the low pressure EGR adjusting valve 5 and the intake negative pressure generating valve 6 are assembled is mounted on a vehicle, the valve housing 4 is restricted on mounting on the vehicle. For this reason, the low pressure EGR flow path 2 and the intake passage 3 formed in the valve housing 4 are also subject to restrictions on vehicle mounting.

As described above, the low pressure EGR flow path 2 and the intake passage 3 formed in the valve housing 4 are restricted in mounting on the vehicle, so that the assembling property of the intake throttle body 14 is deteriorated.
Specifically, the intake throttle body 14 is disposed in the back of the valve housing 4. The low pressure EGR passage 2 and the intake passage 3 formed in the valve housing 4 are bent or lengthened due to restrictions on mounting on the vehicle, so that the tools reach from the outside of the valve housing 4 to the intake throttle shaft 13. It becomes difficult to see, and visual observation is also difficult. As a result, it has been difficult to fix the intake throttle body 14 to the intake throttle shaft 13 assembled to the valve housing 4.

[Characteristics of Example 1]
In order to solve the above problems, in the low pressure EGR valve unit 1 according to the first embodiment, the two members (15, 16) are coupled to provide the valve housing 4, and the two members (15, 16) are joined. The surface M is provided in the vicinity of the intake throttle shaft 13.
Specifically, as shown in FIG. 1, an EGR side housing 15 that forms the low pressure EGR flow path 2 and an intake side housing 16 that forms the intake passage 3 are provided independently of each other, and both are combined to provide a valve. A housing 4 is provided. That is, in this embodiment, the low pressure EGR valve unit 1 is provided by connecting the EGR side housing 15 provided with the low pressure EGR adjustment valve 5 and the intake side housing 16 provided with the intake negative pressure generating valve 6.

A joint surface M between the EGR side housing 15 and the intake side housing 16 is provided between the low pressure EGR shaft 11 and the intake throttle shaft 13. Thus, the joint surface M is provided in the vicinity of the intake throttle shaft 13 by providing the joint surface M between the low pressure EGR shaft 11 and the intake throttle shaft 13.
Further, the joint surface M between the EGR side housing 15 and the intake side housing 16 is parallel to the low pressure EGR shaft 11 and the intake throttle shaft 13, and further provided in parallel to the flow direction of the intake passage 3 at the merging portion. ing.

As shown in FIG. 2, the EGR side housing 15 and the intake side housing 16 are coupled by a plurality of bolts 39 (an example of a fastening member). As will be described later, the intake side housing 16 is made of a resin material. In FIG. 2B, a bolt fastening nut 41 (a metal female screw member) is insert-molded in the intake side housing 16. It shows the state. Here, FIG.2 (b) is sectional drawing of the site | part shown by the arrow A in Fig.2 (a).
The valve housing 4 includes a seal member 42 that prevents leakage from the joint surface M between the EGR side housing 15 and the intake side housing 16. Specifically, in FIG. 2B, an O-ring is shown as an example of the seal member 42, but another member such as a gasket may be used.

(Effect 1 of Example 1)
As shown in the first embodiment, since the valve housing 4 is formed by fastening the EGR side housing 15 and the intake side housing 16, as shown in FIG. In this state, the tools from the opening forming the low pressure EGR flow path 2 to the intake throttle shaft 13 can be easily reached, and visual observation is also facilitated. As a result, the operation of fixing the intake throttle body 14 to the intake throttle shaft 13 assembled to the intake side housing 16 (the operation of fastening the intake throttle body 14 to the intake throttle shaft 13 using the screw 34) is facilitated. Can be implemented.
That is, even if the low pressure EGR flow path 2 and the intake passage 3 of the valve housing 4 are longer or bent due to restrictions on mounting on the vehicle, the assemblability of the intake throttle body 14 is improved. Deterioration can be avoided.

(I) FIG. 3A is a view showing that the intake throttle shaft 13 can be seen from the opening part forming the low-pressure EGR flow path 2.
(Ii) FIG. 3B is a diagram showing that the state in which the intake throttle body 14 is fastened with the screw 34 can be seen from the opening that forms the low pressure EGR flow path 2.
(Iii) FIG. 3C is a cross-sectional view taken along the line I-I in FIG. 3B, and the entry of the tool for fastening the screw 34 from the opening portion forming the low pressure EGR flow path 2 to the intake throttle shaft 13. It is a figure which shows that is easy.
Further, reference numeral 34 a shown in FIG. 3A is a screw hole into which the screw 34 is screwed, and is formed on a mounting plane of the intake throttle valve body 14 on the intake throttle shaft 13.

(Effect 2 of Example 1)
Here, the EGR side housing 15 that forms the low pressure EGR flow path 2 through which the high temperature EGR gas flows is required to be formed of a metal material such as aluminum in order to ensure heat resistance.
On the other hand, since the EGR gas is mixed with the intake air even if the EGR gas is supplied from the low pressure EGR flow channel 2, the member that forms the intake passage 3 can be provided with resin. Therefore, in this embodiment, the intake side housing 16 is formed of a resin material such as nylon resin.

Thus, by providing the intake side housing 16 of the valve housing 4 with a resin material, the weight of the valve housing 4 can be reduced, and as a result, the low pressure EGR valve unit 1 can be reduced in weight.
Further, by providing the intake side housing 16 with a resin material, the material cost of the valve housing 4 can be suppressed, and as a result, the cost of the low pressure EGR valve unit 1 can be suppressed.

(Effect 3 of Example 1)
In this embodiment, as described above, the low pressure EGR valve unit 1 is provided by fastening the EGR side housing 15 provided with the low pressure EGR regulating valve 5 and the intake side housing 16 provided with the intake negative pressure generating valve 6. It is done.
For this reason, even if one of the low-pressure EGR adjustment valve 5 or the intake negative pressure generating valve 6 fails due to some factor, it is not necessary to replace all of the low-pressure EGR valve units 1, and only one (failed side) is replaced. Can be repaired.
That is, the faulty side (“one of the low pressure EGR regulating valve 5 including the EGR side housing 15” or “the intake negative pressure generating valve 6 including the intake side housing 16”) is replaced, and the normal side that is not faulty (“EGR side The low-pressure EGR regulating valve 5 including the housing 15 or the “intake negative pressure generating valve 6 including the intake-side housing 16”) can be reused without replacement.
Thereby, the replacement cost for the failure can be kept low.

(Effect 4 of Example 1)
In this embodiment, as described above, the valve housing 4 is provided from the EGR side housing 15 and the intake side housing 16.
For this reason, when changing the specifications of the low pressure EGR flow path 2 or the intake passage 3 (shape change, diameter change, etc.) according to the vehicle type or the like, it is not necessary to change the specifications of all the valve housings 4, while A change can be made by changing only one of the required EGR side housing 15 or intake side housing 16).
In other words, the specification of “one of EGR side housing 15 or intake side housing 16” can be changed, and “the other of EGR side housing 15 or intake side housing 16” can be used as it is.
As a result, the production cost of the mold can be reduced, and the cost required for changing the specification can be kept low.

(Effect 5 of Example 1)
In this embodiment, the EGR side housing 15 of the low pressure EGR regulating valve 5 provided with the cam plate 35 and the intake side housing 16 of the intake negative pressure generating valve 6 provided with the driven pin 38 are fastened to thereby connect the low pressure EGR valve unit. 1 is provided.
For this reason, it is easy to assemble and disassemble the link coupling portion (the coupling portion between the cam groove 37 of the cam plate 35 and the driven pin 38 fitted in the cam groove 37) in the link device 8. Can be implemented. Thereby, the assembling property of the low pressure EGR valve unit 1 can be improved, and the maintainability of the low pressure EGR valve unit 1 can be improved.

In the above embodiment, the example in which the joint surface M of the valve housing 4 (the separation surface of the valve housing 4) is provided between the low pressure EGR shaft 11 and the intake throttle shaft 13 has been shown.
However, as one of reference examples to which the present invention is not applied, unlike the above-described embodiment, the valve housing 4 is provided with two members on the upstream side and the downstream side of the intake passage 3 and a joint surface M between the two members is provided. It may be provided in the vicinity of the intake throttle shaft 13. As described above, even when the intake passage 3 is separated on the upstream side and the downstream side, it is possible to avoid the deterioration of the assembling property of the intake throttle body 14 as in the first embodiment.

In the above-described embodiment, an example in which the present invention is applied to an engine intake / exhaust system equipped with a turbocharger has been shown as a specific example. However, another intake supercharger (such as a supercharger) is installed instead of the turbocharger. The present invention may be applied to an intake / exhaust system for an engine, or the present invention may be applied to an intake / exhaust system for an engine not equipped with an intake supercharger such as a turbocharger.
In the above-described embodiment, an example in which the present invention is applied to an intake / exhaust system of a diesel engine has been described. However, the present invention may be applied to an intake / exhaust system of another engine (such as a gasoline engine) different from a diesel engine.
In the above description, an example in which NOx is reduced by returning the EGR gas to the intake air and lowering the combustion temperature is shown, but knocking may be prevented by returning the EGR gas to the intake air and lowering the combustion temperature. .

DESCRIPTION OF SYMBOLS 1 Low pressure EGR valve unit 2 Low pressure EGR flow path 3 Intake passage 4 Valve housing 5 Low pressure EGR adjustment valve 6 Intake negative pressure generating valve 7 Electric actuator 8 Link device 9 Characteristic conversion part 13 Intake restrictor shaft 14 Inlet restrictor body 15 EGR side housing (One of the two members)
16 Intake side housing (the other of the two members)
M joint surface

Claims (3)

A valve housing (4) comprising a confluence of a low pressure EGR flow path (2) through which EGR gas is guided and an intake passage (3) through which intake air passes;
A low pressure EGR adjustment valve (5) provided in the valve housing (4) for adjusting the opening of the low pressure EGR flow path (2);
An intake negative pressure generating valve (6) provided in the valve housing (4) for generating an intake negative pressure at the merging portion of the intake passage (3);
In the low pressure EGR valve unit (1) comprising:
The intake negative pressure generating valve (6) includes an intake throttle shaft (13) rotatably supported with respect to the valve housing (4) and an intake throttle body (14) disposed in the intake passage (3). )
The valve housing (4) is provided by connecting two members (15, 16),
The joint surface (M) of the two members (15, 16) is provided in the vicinity of the intake throttle shaft (13) ,
The two members are an EGR side housing (15) that forms the low pressure EGR flow path (2), and an intake side housing (16) that forms the intake passage (3),
The low pressure EGR valve characterized in that the intake throttle shaft (13) can be seen from the opening forming the low pressure EGR flow path (2) in the intake side housing (16) before the EGR side housing (15) is assembled. unit. In the low pressure EGR valve unit (1) according to claim 1,
The EGR side housing (15) is formed of a metal material,
The intake side housing (16) is made of a resin material, and is a low pressure EGR valve unit. In the low pressure EGR valve unit (1) according to claim 1 or claim 2,
This low pressure EGR valve unit (1)
One actuator (7) for driving the low pressure EGR regulating valve (5);
A link device (8) having a characteristic converter (9) for changing the output characteristics of the actuator (7) and driving the intake negative pressure generating valve (6) by the output changed by the characteristic converter (9). )When,
The low-pressure EGR valve unit, characterized in that it comprises a.

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