KR20180096874A - Electronic bypass valve - Google Patents

Abstract

The present invention relates to an electronic bypass valve capable of precisely controlling recirculation of exhaust gas. According to the present invention, the electronic bypass valve comprises a valve body, a flap installed in the valve body, and an actuator to turn the flap. The valve body comprises an intake port connected to an exhaust manifold; a first exhaust port connected to an intake manifold and a second exhaust port connected to an exhaust gas recirculation (EGR) cooler. A gas transfer passage to connect the intake port with the first and second exhaust ports is formed in the valve body. The flap to selectively connect the intake port is installed on the gas transfer passage. In other words, the flap is installed on the gas transfer passage to be able to turn, and connects the intake port to the first or second exhaust port when being turned. The actuator comprises an electric motor installed on one side of the valve body and a gear module to transfer driving force of the electric motor to the flap. The gear module comprises: a driving gear coupled to the electric motor; a driven gear coupled to a shaft of the flap; and an electro-motion gear to connect between the driving and driven gears.

Description

[0001] ELECTRONIC BYPASS VALVE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a bypass valve provided in an exhaust gas recirculation system, and more particularly to an electronic bypass valve that operates by an externally applied electrical signal.

In general, the exhaust gas (emission) is a gas that is generated during the mixing the combustion exhaust through the exhaust pipe to the outside, contains harmful substances such as carbon monoxide (CO), nitrogen oxides (NO _X), unburned hydrocarbons (HC).

Among these harmful substances contained in the exhaust gas, nitrogen oxides have a causal relationship with carbon monoxide and hydrocarbons. That is, nitrogen oxides are most generated when fuel is completely burned and carbon monoxide and hydrocarbons are least discharged.

Accordingly, various technologies for reducing the pollutants of exhaust gas have been developed as the permissible amount of pollutants including nitrogen oxides is regulated as related laws. One of them is Exhaust Gas Recirculation (EGR).

The exhaust gas recirculation system described above is a system for reducing the generation of nitrogen oxide by lowering the maximum combustion temperature while minimizing the reduction of the output by recirculating a part of the exhaust gas. In more detail, if the exhaust gas containing carbon dioxide (CO ₂ ) having a higher heat capacity than nitrogen (N ₂ ) is mixed in the mixer at a suitable ratio, the maximum combustion temperature of the engine can be lowered, It is possible to reduce the generation amount.

A typical exhaust gas recirculation system includes a recirculation pipe for recirculating a part of the exhaust gas discharged through the exhaust manifold to the intake manifold and an easy-cooler assembly installed on the recirculation pipe for cooling the recirculated exhaust gas do.

The recirculation pipe is composed of an inlet pipe connected to one end of the easy-cooler assembly to receive a high-temperature exhaust gas, and an outlet pipe connected to the other end of the easy-cooler assembly to discharge exhaust gas cooled through the easy- do. At this time, an easy valve for recirculating the exhaust gas and a bypass valve for selectively introducing the exhaust gas introduced through the inlet pipe are provided on the inlet pipe.

However, the conventional bypass valve has a disadvantage in that it can not precisely control the recirculated exhaust gas, which is operated by the vacuum pressure generated by the engine, that is, the engine negative pressure. Especially, when the bypass valve operated by the negative pressure of the engine is used for a long time, there is a fear of malfunction or deformation.

Korean Patent No. 10-0955213 (Apr. 21, 2010)

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems of the prior art and it is an object of the present invention to provide an exhaust gas recirculation system, A bypass valve is provided.

According to an aspect of the present invention, there is provided an electronic bypass valve including a valve body, a flap installed inside the valve body, and an actuator for rotating the flap.

The valve body is formed with an intake port connected to the exhaust manifold, a first exhaust port connected to the intake manifold, and a second exhaust port connected to the idle cooler. In addition, a gas transfer path for connecting the inlet port, the first exhaust port, and the second exhaust port is formed in the valve body.

A flap for selectively connecting the inlet port is provided on the gas transfer path. That is, the flap is rotatably installed on the gas transfer path and connects the inlet port to the first exhaust port or to the second exhaust port when the flap is rotated.

The actuator includes an electric motor provided at one side of the valve body and a gear module for transmitting a driving force of the electric motor to the flap. The gear module includes a driving gear coupled to the electric motor, a driven gear coupled to the shaft of the flap, and an electric motor coupled to the driving gear and the driven gear. In addition, the gear module may further include a housing in which the driving gear, the driven gear, and the transmission gear are received, and the housing is provided with a stopper for restricting rotation of the driven gear.

The present invention configured as described above can precisely control the recirculation of the exhaust gas by driving the actuator for rotating the flap by an electric signal applied from the outside.

In addition, according to the present invention, a stopper is provided in the gear module to limit the rotation of the driven gear connected to the flap, so that there is no fear of malfunction or deformation when used for a long time, and the durability is excellent.

1 is a perspective view of an electronic bypass valve according to an embodiment of the present invention;
2 is an exploded perspective view of an electronic bypass valve according to an embodiment of the present invention;
3 and 4 are sectional views of a valve body of an electronic bypass valve according to an embodiment of the present invention.
5 and 6 are diagrams showing the inside of a gear module of an electronic bypass valve according to an embodiment of the present invention.
7 is an enlarged view of a gear module of an electronic bypass valve according to an embodiment of the present invention.
8 and 9 are operational states of an electronic bypass valve according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to the accompanying drawings, embodiments of the present invention will be described in detail. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

An electronic bypass valve according to an embodiment of the present invention is a valve installed on an inlet pipe of an exhaust gas recirculation system and recirculating a part of exhaust gas discharged through an exhaust manifold to an intake manifold side, And discharges the exhaust gas directly to the intake manifold side or the exhaust gas cooler side depending on the temperature of the exhaust gas.

1 and 2, the electronic bypass valve according to the present embodiment includes a valve body 100 installed on an inlet pipe (not shown) of an exhaust gas recirculation system, And an actuator 200 installed at one side (upper part in the figure) for controlling the discharge direction of the recirculated exhaust gas.

The valve body 100 and the actuator 200 are coupled and fixed through a plurality of bolts 310 and a heat insulating material 320 having a predetermined thickness is interposed between the valve body 100 and the actuator 200.

Generally, the valve body 100 is made of a metal material so as to withstand a high temperature exhaust gas. Meanwhile, the housing 210 of the actuator 200 is made of synthetic resin to accommodate the gear modules 240 to 260. Therefore, when the housing 210 is brought into direct contact with the valve body 100, the housing 210 may be deformed by the heat of the exhaust gas.

In this embodiment, the heat of the exhaust gas is prevented from being transmitted between the valve body 100 and the actuator 200 through the heat insulating material 320 to the housing 210 side through the valve body 200, It is possible to prevent deformation.

An intake port 110 connected to an exhaust manifold is formed on the left side of the valve body 100. A first exhaust port 120 connected to an intake manifold is formed on the right side of the valve body 100, And a second exhaust port 130 connected to the idle cooler (300 of FIG. 9) is formed. A gas transfer path 140 connecting the intake port 110, the first exhaust port 120, and the second exhaust port 130 is formed in the valve body 100.

The second exhaust port 130 connected to the idle cooler 300 includes an outlet 132 for exhausting the exhaust gas toward the alaser cooler 300 and an outlet 132 for introducing the exhaust gas from the alaser cooler 300 134). That is, when the flap 150 rotates and the intake port 110 and the second exhaust port 130 are connected to each other, the exhaust gas flowing in from the intake port 110 is transferred to the air cooler 300 through the outlet 132, Cooled to a predetermined temperature in the easy-cooler 300, and then is transferred to the first exhaust port 120 through the inlet 134. [

The gas transfer path 140 is formed in a Y-shape so as to connect the intake port 110, the first exhaust port 120, and the second exhaust port 130 with each other. A flap 150 for controlling the discharge direction of the exhaust gas is provided in the interruption of the gas transfer path 140, that is, in the interruption of connecting the intake port 110, the first exhaust port 120, and the second exhaust port 130 .

4, the flap 150 is coupled to a shaft 160 passing through the valve body 100 to control the exhaust direction of the exhaust gas when the shaft 160 rotates. That is, when the flap 150 rotates in the counterclockwise direction, the second exhaust port 130 is blocked to connect the inlet port 110 and the first exhaust port 120 (see FIG. 8). On the other hand, when the flap 150 rotates clockwise, the first exhaust port 120 is blocked to connect the inlet port 110 and the second exhaust port 130 (see FIG. 9).

For example, when the temperature of the exhaust gas flowing in the exhaust manifold (not shown) is lower than a set value, the intake port 110 and the first exhaust port 120 are connected to directly exhaust the exhaust gas toward the intake manifold (See FIG. 8).

On the other hand, when the temperature of the exhaust gas flowing in the exhaust manifold (not shown) is equal to or higher than the set value, the intake port 110 and the second exhaust port 130 are connected to each other, and the exhaust gas passes through the first exhaust port 120) (see Fig. 9). The exhaust gas discharged to the outlet 132 of the second exhaust port 130 is cooled to a temperature equal to or lower than a predetermined value in the idle cooler 300 and then discharged through the inlet 134 of the second exhaust port 130 to the first And is then transferred to the exhaust port 120.

The shaft 160 is coupled to pass through the valve body 100 and the housing 210. A driven gear 260 is coupled to an upper end of a shaft 160 positioned inside the housing 210 and a flap 150 is coupled to an end of a shaft 160 positioned in the gas transfer path 140. A sealing member 170 is provided between the driven gear 160 and the flap 150 to prevent leakage of the exhaust gas.

4 to 7, the actuator 200 includes a case 210, 220 coupled to the valve body 100, an electric motor 230 installed at one side of the case 210, 220, an electric motor 230 And gear modules 240 to 260 for transmitting the rotational force of the shaft 160 to the shaft 160.

The cases 210 and 220 include a housing 210 having a space for accommodating the gear modules 240 to 260 and a cover 220 coupled to an open top surface of the housing 210. At this time, the housing 210 and the cover 220 are fixed by a C-shaped clamp 212 to facilitate assembly and disassembly.

The gear modules 240 to 260 include a driving gear 240 coupled to the electric motor 230, a transmission gear 250 that transmits the rotational force of the driving gear 240, a shaft 160 of the flap 150, And a driven gear 260 coupled to the driven gear 260. The drive gear 240, the transmission gear 250, and the driven gear 260 are spur gears formed on the outer circumferential surface of which the teeth are formed in parallel with the rotation axis. Such a spur gear is not only excellent in transmission efficiency but also suited for power transmission because no thrust is generated.

The driving gear 240 is a pinion gear coupled to the rotating shaft of the driving motor 230 and formed to have a smaller diameter than the transmission gear 250 and the driven gear 260 so as to transmit a large rotational force.

The transmission gear 250 is a reduction gear for reducing the rotational speed of the drive gear 240 and increasing the rotational force. The transmission gear 250 includes a first transmission gear 252 that is engaged with the drive gear 240 and a pair of gears provided between the drive gear 240 and the driven gear 260, 2 transmission gear 254.

The first transmission gear 252 and the second transmission gear 254 have a multi-stage spur gear shape for adjusting the reduction ratio (rotation speed and rotational force). The first transmission gear 252 is a multi-stage spur gear type in which gears (small gears) having small diameters are located on the upper side and gears (large gears) A standby gear is located at the top and a small gear is a multi-stage spur gear type provided at the bottom. At this time, the driving gear 240 is engaged with the large gear of the first transmission gear 252, the driven gear 260 is engaged with the small gear of the second transmission gear 254, The gears of the second transmission gear 254 are arranged in an interlocking manner.

The driven gear 260 rotates the flap 150 by transmitting the rotational force adjusted through the electric gear 250 to the shaft 160. More specifically, the flap 150 installed on the gas transfer path 140 rotates and reciprocates between predetermined angles, so that any one of the first exhaust port 120 and the second exhaust port 130 is connected to the inlet port 110 To be connected.

The driven gear 260 is manufactured in the form of a bimetal gear having a cutout 262 formed on one side thereof and a stopper 270 for restricting the rotation of the driven gear 260 within the rotation radius of the driven gear 260, .

The cutout portion 262 is formed in a fan shape extending from the center of the driven gear 260 and the stopper 270 is formed in a fan shape protruding from the one side of the housing 210 toward the driven gear 260. At this time, the central angle of the cutout portion 262 is formed to be larger than the central angle of the stopper 270, so that the driven gear 260 can be stopped after a certain angular rotation (clockwise or counterclockwise).

8, the interruption of the gas transfer path 240 in which the flap 150 is installed has a triangular structure so as to connect the intake port 110, the first exhaust port 120, and the second exhaust port 130 with each other. Thus, the flap 150 is rotated at an angle of about 55 to 65 degrees during its rotation, and the driven gear 260 is formed to have a greater rotation angle, for example, about 50 to 70 degrees.

On the other hand, a structure for reducing and absorbing impact generated when the driven gear 260 and the stopper 270 are in contact with each other is applied to the actuator 200 of the present embodiment.

The inner side surface 264 of the cutout portion 262 and the outer side surface 272 of the stopper 270 are formed so as to be parallel to or not to be mutually shifted in a state where the driven gear 260 and the stopper 270 are in contact with each other (See FIG. 7). When the inner surface 264 of the cutout portion 262 and the outer surface 272 of the stopper 270 are displaced from each other as described above, the driven gear 260 comes into line contact with the stopper 270, So that the impact generated upon contact can be reduced.

The stopper 270 is provided with a buffer material 280 of an elastic material having a predetermined thickness. The cushioning material 280 absorbs impact generated when the driven gear 260 is in contact with the driven gear 260, thereby preventing durability deterioration due to long-term use.

8 and 9 illustrate the operation of the electronic bypass valve according to the present embodiment.

The exhaust gas recirculation system measures the temperature of the exhaust gas discharged through an exhaust manifold (not shown), and controls the operation of the electronic bypass valve according to the temperature.

For example, when the temperature of the exhaust gas is equal to or lower than a preset value, the flap 150 is rotated counterclockwise to connect the inlet port 110 and the first exhaust port 120. Therefore, the exhaust gas flowing through the intake port 110 is directly transferred to the first exhaust port 120 through the gas transfer path 140. That is, the exhaust gas flowing in from the inlet port 110 is discharged to the first exhaust port 120 without changing the temperature (refer to FIG. 8).

On the other hand, when the temperature of the exhaust gas is equal to or higher than the preset value, the flap 150 is rotated clockwise to connect the inlet port 110 and the second exhaust port 120. The exhaust gas flowing in the intake port 110 is discharged to the easy alum cooler 300 through the outlet 132 of the second exhaust port 130 via the gas transfer path 140, And is then transferred to the first exhaust port 120 through the inlet 134 of the second exhaust port 130. [ That is, the exhaust gas flowing in the intake port 110 is cooled in the isothermal cooler 300 and then discharged to the first exhaust port 120 (see FIG. 9).

While the present invention has been particularly shown and described with reference to preferred embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Those skilled in the art will understand. Therefore, the scope of protection of the present invention should be construed not only in the specific embodiments but also in the scope of claims, and all technical ideas within the scope of the same shall be construed as being included in the scope of the present invention.

100: valve body 110: intake port
120: first exhaust port 130: second exhaust port
140: gas transfer path 150: flap
160: shaft 200: actuator
210: housing 220: cover
230: electric motor 240: drive gear
250: transmission gear 260: driven gear
270: Stopper 280: Cushioning material

Claims (10)

A bypass valve provided in an exhaust gas recirculation system,
An exhaust port connected to the exhaust manifold, a first exhaust port connected to the intake manifold, a second exhaust port connected to the idle cooler, and a gas transfer path connecting the intake port, the first exhaust port, and the second exhaust port, A formed valve body;
A flap installed on the gas transfer path and selectively connecting the inlet port to the first exhaust port or the second exhaust port upon rotation; And
An electric motor provided at one side of the valve body, and an actuator configured to transmit a driving force of the electric motor to the flap.
The method according to claim 1,
Wherein the gear module comprises: a driving gear coupled to the electric motor; a driven gear coupled to the shaft of the flap; and an electric motor coupled to the driving gear and the driven gear.
The method of claim 2,
Wherein the gear module further includes a housing in which the drive gear, the driven gear, and the transmission gear are accommodated,
Wherein the housing is provided with a stopper for restricting rotation of the driven gear.
The method of claim 3,
Wherein the driven gear is a half-moon gear having a cut-out portion at one end thereof, and the stopper is positioned within a turning radius of the driven gear.
The method of claim 4,
Wherein the cut-out portion is formed in a fan shape, the stopper is formed in a fan shape corresponding to the cut-out portion,
And the central angle of the cutout portion is larger than the central angle of the stopper.
The method of claim 5,
And an inner side surface of the cut-out portion is in line contact with an outer side surface of the stopper.
The method of claim 6,
And a cushioning material for absorbing an impact upon contact with the follower gear is provided on the stopper.
The method of claim 7,
Wherein the gear module further comprises a cover for covering the housing,
Wherein the housing and the cover are fixed by a clamp.
The method according to any one of claims 3 to 8,
Wherein the housing is coupled to one side of the valve body, and a heat insulating material is interposed between the valve body and the housing.
The method according to any one of claims 3 to 8,
Wherein the driven gear is coupled to one end of the shaft passing through the valve body, the flap is coupled to an end of the shaft, and a sealing member is provided between the flap and the driven gear.

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