KR20200028286A - Flow control valve for exhaust gas recirculation - Google Patents

Abstract

A flow control valve (60) for exhaust gas recirculation (EGR) includes: a housing (61); an exhaust reflux passage (51) provided in the housing; and a valve body (63) which is placed in the passage and is rotated or moved by a shaft (62) to open and close the passage. When the valve body is in contact with the passage and is in a closed valve state, the valve body further includes a coating layer (65) of an elastic body provided on at least one contact unit of the valve body or the passage. The coating layer includes a rubber layer (66), a fluorine resin binder layer (67) formed on the rubber layer, and a fluorine resin surface layer (68) formed on the binder layer.

Description

Flow control valve for exhaust gas recirculation device {FLOW CONTROL VALVE FOR EXHAUST GAS RECIRCULATION}

The present invention relates to a flow control valve for EGR (exhaust gas recirculation device).

Patent document 1 discloses a valve device used in a vehicle. In this valve arrangement, a rubber seal member is used on the outer edge of the flap to ensure that the rubber seal member comes into close contact with the flow path when the valve is closed.

Patent Document 1: JP 2018-506816 A

EGR (exhaust gas recirculation system) valves are used in high temperature environments, and when the engine is stopped, the valves are completely closed and exposed to condensate where water vapor in the exhaust gas aggregates. Since the exhaust gas contains nitrogen oxide (NOx), for example, when nitrogen oxide is dissolved in the aggregated water, the aggregated water becomes acidic. When the valve device described in Patent Literature 1 is used as a flow control valve for EGR, there is a possibility that deterioration occurs in the rubber seal member due to coagulation water. In addition, since the exhaust gas is high temperature, the rubber seal member adheres to the flow path, and there is a fear that the valve opening may fail or the rubber seal member may be damaged when the valve is opened. However, techniques for improving these problems have not been sufficiently studied.

According to one aspect of the invention, a flow control valve 60 is provided. The flow control valve includes a housing 61, a flow path 51 for exhaust reflux provided in the housing, and a valve body 63 disposed on the flow path and rotated or moved by the shaft 62 to open and close the flow path. When the valve body is in a closed valve state in contact with the flow path, the valve body further includes an elastic coating layer 65 provided on at least one of the valve body or flow path. The coating layer includes a rubber layer 66, a binder layer 67 of fluorine resin formed on the rubber layer, and a surface layer 68 of fluorine resin formed on the binder layer. According to this configuration, the coating layer includes a rubber layer, a binder layer of a fluorine resin formed on the rubber layer, and a surface layer of a fluorine resin formed on the binder layer. Therefore, even if the aggregated water is generated, the rubber layer does not deteriorate and does not adhere to other members even at high temperatures. In other words, coagulation resistance and high temperature resistance can be improved.

1 is an explanatory view showing a schematic configuration of an engine system.
It is explanatory drawing which shows the cross section of the intake flow path of the EGR flow control valve of 1st Example.
It is explanatory drawing which shows the structure of a valve seat.
4 is an explanatory view showing a cross-sectional configuration of the coating layer.
5 is an explanatory view showing the evaluation results for the configuration of the coating layer.
6 is an explanatory diagram showing a schematic configuration of a flow control valve for EGR of the second embodiment.
7 is an explanatory view showing an enlarged coating layer configuration of the second embodiment.
8 is an explanatory view showing a schematic configuration of a flow control valve for EGR in the third embodiment.
9 is an explanatory view showing an enlarged coating layer configuration of the third embodiment.
10 is an explanatory diagram showing a schematic configuration of a flow control valve for EGR of the fourth embodiment.
11 is an explanatory diagram showing an enlarged coating layer configuration of the fourth embodiment.
It is explanatory drawing which shows schematic structure of the flow control valve for EGR of 5th Example.
13 is an explanatory view showing an enlarged coating layer configuration of the fifth embodiment.
14 is an explanatory view showing a schematic configuration of a flow control valve for EGR in the sixth embodiment.
15 is an explanatory diagram showing an enlarged coating layer configuration of the sixth embodiment.

(First Example)

As shown in FIG. 1, the engine system 10 includes an engine 20 that is an internal combustion engine having a control unit 15, a supercharger 45, an intake system 30, an exhaust system 40, and a reflux system 50. It includes.

The engine 20 includes a cylinder 21, a piston 22, a cylinder head 23, a combustion chamber 24, a spark plug 25, an intake valve 26 and an exhaust valve 27. The combustion chamber 24 is a space surrounded by the cylinder 21, the piston 22 and the cylinder head 23. Air required for combustion is supplied to the combustion chamber 24 through the intake valve 26. Fuel may be supplied to the combustion chamber 24 through the intake valve 26, or directly to the combustion chamber through an injector (not shown). The spark plug 25 ignites the fuel supplied to the combustion chamber 24. After combustion, exhaust gas is discharged from the exhaust valve 27.

The intake system 30 includes an intake passage 31, an air cleaner 32, a compressor 47 of the supercharger 45, an intake pipe 33, an intercooler 34, a throttle 35, and an intake manifold 36 It includes. The intake passage 31 is a passage connecting the air cleaner 32 to the engine 20. The air cleaner 32 removes dust and dirt when air in the air is inhaled. The compressor 47 compresses air using the pressure of the exhaust gas and sends it to the intake pipe 33. The intercooler 34 cools air that has been compressed and has increased temperature. The throttle 35 controls the amount of air supplied to the engine 20. The intake manifold 36 distributes air to a plurality of cylinders of the engine 20.

The exhaust system 40 includes an exhaust gas flow path 41, an exhaust manifold 42, an exhaust pipe 43, an exhaust purification unit 44 and a turbine 46 of the supercharger 45. The exhaust gas flow path 41 is a flow path of the exhaust gas that connects the engine 20 to the atmosphere. The exhaust manifold 42 collects exhaust gas discharged from a plurality of cylinders and sends it to the turbine 46. The turbine 46 is connected to the compressor 47 by the shaft 48, rotates by the pressure of the exhaust gas, and drives the compressor 47 through the shaft 48. The exhaust pipe 43 is connected to the downstream side of the turbine 46, and the exhaust purification unit 44 is provided to the exhaust pipe 43. The exhaust purification unit 44 purifies exhaust gas. The exhaust gas contains nitrogen oxides NOx, HC and CO, and the exhaust purification unit 44 purifies them. When the engine 20 is a natural intake engine, the supercharger 45 may be omitted.

The reflux system 50 is a system for recirculating a part of the exhaust gas into an intake system, and includes a reflux flow path 51 and a flow control valve 60 for EGR (hereinafter referred to as "flow control valve 60"). . "EGR" stands for Exhaust Gas Recirculation. The reflux flow passage 51 is an exhaust gas recirculation flow passage connecting the downstream side of the exhaust purification unit 44 to the flow control valve 60, and includes a reflux pipe 52. The reflux pipe 52 is provided with an EGR cooler 53 to lower the temperature of the recirculated exhaust gas. The flow control valve 60 is a three-way valve located between the air cleaner 32 and the compressor 47 of the intake system 30.

The flow control valve 60 shown in FIG. 2 includes a housing 61, a rotating shaft 62, a valve body 63, and a valve seat 64. The valve body 63 is a rotary valve body that rotates around the rotation shaft 62 by rotation of the rotation shaft 62. When the valve body 63 is not seated on the valve seat 64, the flow of exhaust gas from the reflux flow passage 51 to the intake flow passage 31 in the housing 61 is enabled. When the valve body 63 is seated on the valve seat 64, the flow of exhaust gas from the reflux flow passage 51 to the intake flow passage 31 in the housing 61 is blocked.

3 shows the configuration of the valve seat. 3, the valve seat 64 is provided at the end of the reflux flow passage 51, and the shape of the end is formed to engage the valve body 63 when the valve body is closed. The valve seat 64 includes a coating layer 65 at the end, which is the contact portion in contact with the valve body 63.

4, the coating layer 65, from the base 69 side to the contact side with the valve body 63, the rubber layer 66, the binder layer 67 of the fluororesin, and the surface layer 68 of the fluororesin ) In order. The rubber of the rubber layer 66 is selected from, for example, vinylidene fluoride rubber, hydrogenated nitrile rubber, hydrin rubber, and the like. When the binder layer 67 of the fluororesin and the surface layer 68 of the fluororesin are formed, the firing temperature is about 300 ° C or higher. In this embodiment, heating is performed locally for a short time using a laser or infrared light, and firing is completed before the lower rubber layer 66 is deteriorated by heat of about 300 ° C or higher. Therefore, the coating layer 65 can be fired without deteriorating the rubber layer 66.

In the flow control valve 60, the water vapor contained in the exhaust gas is condensed to generate aggregated water. Since the exhaust gas contains nitrogen oxides (NOx), even if the exhaust purification unit 44 is provided, the nitrogen oxides are dissolved in the aggregated water and the aggregated water becomes acidic. 5, when the binder layer 67 of the fluororesin and the surface layer 68 of the fluororesin are formed on the rubber layer 66, the coagulation resistance of the coating layer 65 is improved. do. At the same time, even when heated by the high temperature of the exhaust gas, the coating layer 65 does not adhere to the valve body 63, and the high temperature resistance is also improved. When the rubber layer 66 is formed of acid-resistant rubber, or when the rubber layer 66 is coated, at least the cohesion resistance can be improved.

As described above, according to the first embodiment, the flow control valve 60 includes a coating layer 65 of an elastic body provided in a portion of the reflux flow passage 51 that contacts the valve body 63. Since the coating layer 65 includes a rubber layer 66, a binder layer 67 of fluorine resin formed on the rubber layer, and a surface layer 68 of fluorine resin formed on the binder layer 67, aggregated water is generated and becomes high temperature. Even in the environment, deterioration of the rubber layer 66 due to coagulation water and adhesion due to high temperature can be suppressed. In other words, it is possible to improve coagulation resistance and high temperature resistance.

In the first embodiment, the coating layer 65 may be provided on a portion of the reflux flow passage 51 in contact with the valve body 63. However, the coating layer 65 may be provided on a portion of the valve body 63 in contact with the reflux flow passage 51, for example, on the outer edge of the valve body 63. In addition, the coating layer 65 may be provided on both the portion of the reflux passage 51 that contacts the valve body 63 and the portion of the valve body 63 that contacts the reflux passage 51.

Further, the coating layer 65 may be provided only in the contact portion where the valve body 63 contacts other members during the opening / closing operation of the valve body 63, or may be provided beyond the contact portion contacting the other members. When the coating layer 65 is provided only in the contact portion contacting other members during the opening / closing operation of the valve body 63, the amount of the coating layer 65 to be formed can be reduced. Can be reduced. On the other hand, when the coating layer 65 is provided beyond the contact portion contacting the other member, in a range other than the contact portion contacting the other member, for example, deterioration due to coagulation water can be suppressed.

(Second example)

6 and 7 show a flow control valve 70 according to the second embodiment. The flow control valve 70 is a butterfly valve rotated by the rotating shaft 72, and the flow path 75 formed in the housing 71 is closed and opened by the valve body 73. The lip 74 is provided at the end of the valve body 73 and contacts the inner wall of the flow path 75 when the valve body 73 is closed. The lip 74 includes a coating layer of an elastic body, and the coating layer includes a rubber layer, a binder layer of a fluororesin formed in the rubber layer, and a surface layer of a fluororesin formed in the binder layer. Therefore, even in the flow control valve 70 that is a butterfly valve, in an environment in which aggregated water is generated and becomes high temperature, deterioration of the rubber layer due to aggregated water and adhesion due to high temperature can be suppressed. In other words, coagulation resistance and high temperature resistance can be improved.

(Example 3)

8 and 9 show a flow control valve 80 according to the third embodiment. The flow control valve 80 is a butterfly valve rotated by the rotation shaft 82, and the flow path 84 formed in the housing 81 is closed and opened by the valve body 83. The groove 85 is formed in the flow path 84, and an elastic seal member 86 is installed in the groove 85. By providing the seal member 86 in the groove 85, it is possible to suppress the displacement of the seal member 86 due to the opening and closing of the valve body 83. The seal member 86 may not be provided in the groove 85. The coating layer 87 may be formed on the inner side of the flow path 84 of the seal member 86. When the valve body 83 is closed, the outer edge of the valve body 83 contacts the coating layer 87. The coating layer 87 includes a rubber layer, a binder layer of a fluorine resin formed on the rubber layer, and a surface layer of a fluorine resin formed on the binder layer. Therefore, even in the flow control valve 80 which is a butterfly valve including the valve body 83, in an environment in which condensate is generated and becomes high temperature, deterioration of the rubber layer due to condensation water and adhesion due to high temperature can be suppressed. In other words, coagulation resistance and high temperature resistance can be improved.

(Example 4)

10 and 11 show a flow control valve 90 according to the fourth embodiment. The flow control valve 90 is a valve that closes or opens the flow path 95 formed in the housing 91 by a valve body 93 that is rotated by the rotation shaft 92. The valve seat 94 is disposed in the flow path 95, and an elastic coating layer 96 is provided on the valve seat 94. When the valve body 93 is closed, the outer edge of the valve body 93 contacts the coating layer 96. The coating layer 96 includes a rubber layer 97, a fluorine resin binder layer 98 formed on the rubber layer 97, and a fluorine resin surface layer 99 formed on the binder layer 98. Therefore, in an environment where aggregated water is generated and becomes high temperature, deterioration and adhesion of the rubber layer 97 can be suppressed. In other words, coagulation resistance and high temperature resistance can be improved. As can be seen from the second, third and fourth embodiments, the coating layer may be formed on the valve body or the flow path. In addition, the coating layer may be formed on both the valve body and the flow path.

(Example 5)

12 and 13 show a flow control valve 100 according to the fifth embodiment. The flow control valve 100 has a valve body 103 at the end of the shaft 102. When the shaft 102 moves in the direction along the shaft 102, the valve body 103 is seated on or detached from the valve seat 104. Accordingly, the flow path 106 formed in the housing 101 is closed or opened. In the flow control valve 100, the coating layers (not shown) described in the first to fourth embodiments are provided in the vicinity of the valve body 103. The flow control valve 100 further includes an oil chamber 105 in a portion where the shaft 102 protrudes from the flow path 106 toward the housing 101. The oil chamber 105 has a coating layer 107, such as the coating layers described in the first to fourth embodiments, in the portion in contact with the shaft 102. The coating layer includes a rubber layer, a binder layer of a fluorine resin formed on the rubber layer, and a surface layer of a fluorine resin formed on the binder layer. Therefore, in an environment in which condensate is generated and becomes high temperature, deterioration and adhesion of the rubber layer in the oil chamber can be suppressed. In other words, coagulation resistance and high temperature resistance can be improved. The coating layers described in the first to fourth embodiments may not be provided in the vicinity of the valve body 103.

(Example 6)

14 and 15 show a flow control valve 110 according to the sixth embodiment. The flow control valve 110 according to the sixth embodiment has a valve body 113 at the end of the shaft 112. By rotating the shaft 112 around the shaft 112, the valve body 113 can be seated on the valve seat 114 or detached from the valve seat 114, thereby closing the flow path formed in the housing 111. Or open. In the flow control valve 110, the coating layers (not shown) described in the first to fourth embodiments are provided in the vicinity of the valve body 113. The flow control valve 110 further includes an oil chamber 115 in a portion where the shaft 112 protrudes from the flow path toward the housing 111. The oil chamber 115 has a coating layer 116, such as the coating layers described in the first to fourth embodiments, in the portion in contact with the shaft 112. The coating layer includes a rubber layer, a binder layer of a fluorine resin formed on the rubber layer, and a surface layer of a fluorine resin formed on the binder layer. Therefore, even in an environment where aggregated water is generated and becomes high temperature, deterioration and adhesion of the rubber layer of the oil chamber 115 can be suppressed. In other words, coagulation resistance and high temperature resistance can be improved. As is apparent from the fifth and sixth embodiments, a coating layer may be provided not only in the valve body and the valve seat for opening and closing the flow path, but also in the oil chamber of the shaft rotating and moving the valve body. The coating layer may include a rubber layer, a fluorine-based binder layer formed on the rubber layer, and a surface layer of the fluorine resin formed on the binder layer. The coating layers described in the first to fourth embodiments may not be provided in the vicinity of the valve body 113.

The present invention can be realized in the following forms.

(1) According to an embodiment of the present invention, a flow control valve 60 is provided. The flow control valve includes a housing 61, an exhaust flow path 51 provided in the housing, and a valve body 63 disposed on the flow path and rotated or moved by an axis 62 to open and close the flow path do. When the valve body is in a closed valve state in contact with the flow path, the valve body further includes a coating layer 65 of an elastic body provided on at least one contact portion of the valve body or flow path. The coating layer includes a rubber layer 66, a binder layer 67 of fluorine resin formed on the rubber layer, and a surface layer 68 of fluorine resin formed on the binder layer.

(2) In the above embodiment, the valve body is a rotary valve body that opens and closes a flow path by rotating by an axis, and an end portion of the flow path has a shape capable of engaging the valve body when the valve body is closed, The end may include a coating layer. According to this configuration, even in a flow control valve having a rotary valve body, in an environment where high temperature is generated and aggregated water is generated, deterioration of the coating layer can be suppressed. In addition, coagulation resistance and high temperature resistance can be improved.

(3) In the above configuration, an oil chamber 105 for sealing the outer circumference of the shaft is further provided, and the oil chamber may have a layer such as a coating layer on a portion in contact with the shaft. According to this configuration, even in an environment in which high temperature is generated and aggregated water is generated, deterioration of the oil chamber and adhesion of the oil chamber can be suppressed.

(4) According to an embodiment of the present invention, a flow control valve 100 is provided. The flow control valve is a housing 101, a flow path 106 for exhaust reflux provided in the housing, a valve body 103 installed on the flow path and rotated or moved by the shaft 102 to open and close the flow path, and the outer periphery of the shaft It includes an oil chamber 105 for sealing. The oil chamber 105 includes a coating layer having a rubber layer, a binder layer of a fluorine resin formed on the rubber layer, and a surface layer of a fluorine resin formed on the binder layer. According to this configuration, even in an environment in which high temperature and coagulation water are generated, deterioration of the oil chamber and adhesion of the oil chamber can be suppressed.

(5) In the above embodiment, the rubber layer may be formed of any one of vinylidene fluoride rubber, hydrogenated nitrile rubber, and hydraulic rubber. According to this configuration, even in an environment where high temperature and coagulation water are generated, rubber of any one of vinylidene fluoride rubber, hydrogenated nitrile rubber, and hydrin rubber is used as the rubber layer. It is possible to do.

(6) In the above configuration, a coating layer may be provided only on a contact portion contacting another member during the opening and closing operation of the valve body. According to this configuration, the amount of the coating layer used can be reduced, which can reduce the cost.

It is possible to realize the present invention in various forms. For example, the present invention can be realized not only by a flow control valve, but also by a seal structure of a flow control valve, a method for protecting the seal, and the like.

Claims (6)

Housing 61;
An exhaust flow passage 51 provided in the housing;
A valve body 63 disposed in the flow path and rotated or moved by the shaft 62 to open and close the flow path; And
When the valve body is in contact with the flow path to be in a closed state, and includes a coating layer 65 of an elastic body provided on at least one contact portion of the valve body or the flow path,
The coating layer includes a rubber layer 66, a binder layer 67 of fluorine resin formed on the rubber layer, and a surface layer 68 of fluorine resin formed on the binder layer.
Flow control valve for exhaust gas recirculation system.
According to claim 1,
The valve body is a rotary valve body that opens and closes a flow path by being rotated by an axis,
The end of the flow path has a shape that can be engaged with the valve body when the valve body is closed,
The coating layer is provided at the end of the flow path
Flow control valve for exhaust gas recirculation system.
According to claim 1,
Further provided with an oil chamber (105) configured to seal the outer periphery of the shaft,
The oil chamber has the same layer as the coating layer in a portion in contact with the shaft,
Flow control valve for exhaust gas recirculation system.
Housing 101;
An exhaust flow passage 106 provided in the housing;
A valve body 103 disposed in the flow path and rotated or moved by the shaft 102 to open and close the flow path; And
It includes an oil chamber (105) configured to seal the outer periphery of the shaft,
The oil chamber includes a rubber layer, a binder layer of a fluorine resin formed on the rubber layer, and a surface layer of a fluorine resin formed on the binder layer.
Flow control valve for exhaust gas recirculation system.
The method according to any one of claims 1 to 4,
The rubber layer is formed of any one of vinylidene fluoride rubber, hydrogenated nitrile rubber, and hydrin rubber.
Flow control valve for exhaust gas recirculation system.
The method according to any one of claims 1 to 4,
When the valve body is opened and closed, the coating layer is provided only in a contact portion contacting another member.
Flow control valve for exhaust gas recirculation system.

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