This application is based upon and claims the benefit of priority from the prior Japanese Patent Application No. 2017-215417 filed on Nov. 8, 2017, the entire contents of which are incorporated herein by reference.
The present disclosure relates to an EGR (Exhaust Gas Recirculation) gas distributor to be attached to an intake manifold in use to distribute EGR gas to a plurality of cylinders of an engine.
As the above type of technique, conventionally, there has been known an EGR gas distribution part provided in an intake device (an intake manifold) disclosed in Japanese unexamined patent application publication No. 2016-089687 (JP2016-089687A). This intake manifold will be mounted together with an engine in a vehicle and is provided with a surge tank and a plurality of intake pipes (branch pipes) branched from the surge tank in one-to-one correspondence to cylinders of the engine. The EGR gas distribution part is configured to distribute EGR gas to each of the branch pipes. This EGR gas distribution part includes a gas inflow pipe connected to an EGR gas supply source, an upstream-side gas distribution pipe bifurcated from the gas inflow pipe, a gas chamber to collect EGR gas flowing from this gas distribution pipe, and a plurality of downstream-side gas distribution pipes branched from the gas chamber and connected to each of the branch pipes. This EGR gas distribution part has a bilaterally symmetrical shape with respect to the center axis of the gas inflow pipe to allow EGR gas introduced into the gas chamber through the gas inflow pipe to be distributed to each of the branch pipes through the corresponding downstream-side gas distribution pipes.
However, in the EGR gas distribution part disclosed in JP2016-089687A, for example, during cold start or the like of the engine, condensed water may be generated in the gas chamber from water or moisture contained in the EGR gas. This condensed water may adhere to an inner wall of the gas chamber or flow down by its own weight along the inner wall and accumulate in a lower area (a lowermost portion) of the gas chamber. If the amount of the condensed water generated therein increases, the condensed water may flow in the downstream-side gas distribution pipe(s) and further into the corresponding branch pipe(s) and then be sucked into the cylinder(s) of the engine. This suction of condensed water into the engine may cause misfire in the engine.
The present disclosure has been made to address the above problems and has a purpose to provide an EGR gas distributor capable of preventing the condensed water generated in a gas chamber from being sucked into an engine through gas distribution pipes and branch pipes of an intake manifold.
To achieve the above-mentioned purpose, one aspect of the present disclosure provides an EGR gas distributor that is an attachment device to be attached to an intake manifold and is configured to distribute EGR gas to each of a plurality of branch pipes constituting the intake manifold, the EGR gas distributor comprising: a chamber case including a gas chamber configured to allow the EGR gas to flow therein, the chamber case extending in a direction traversing the plurality of branch pipes; a gas inflow pipe provided in the chamber case and configured to introduce the EGR gas into the gas chamber; a plurality of gas distribution pipes branched from the chamber case and arranged at intervals in a longitudinal direction of the chamber case to distribute the EGR gas to the plurality of branch pipes; and a condensed-water flow restraining unit configured to restrain condensed water generated in the gas chamber from flowing into the gas distribution pipes.
The foregoing configuration can restrain condensed water generated in the gas chamber from being sucked into the engine through the gas distribution pipe and the branch pipes of the intake manifold and thus prevent misfire in the engine due to suction of the condensed water.
A detailed description of a first embodiment of an EGR gas distributor will now be given referring to the accompanying drawings.
(Relationship Between EGR Gas Distributor and Intake Manifold)
(Outline of EGR Gas Distributor)
The EGR gas distributor 1 is provided, in appearance as shown in
(Heating Part)
The heating part 18 is configured to allow cooling water (hot water) of the engine to flow through the heating part 18 in order to heat the gas distribution part 17. Specifically, the heating part 18 is constituted of a passage case 22 having a water passage 21 in which engine cooling water (hot water) flows. The passage case 22 is formed with the foregoing pipe joints 13A and 13B. In the present embodiments, as shown in
(Gas Distribution Part)
The gas distribution part 17 includes: a chamber case 32 having a gas chamber 31 configured to allow EGR gas to flow therein and extend in a direction traversing the plurality of branch pipes 4; the foregoing gas inflow pipe 11 provided in the chamber case 32 and configured to introduce EGR gas into the gas chamber 31; and the plurality of gas distribution pipes 12A to 12D branched from the chamber case 32 and arranged at intervals in the longitudinal direction of the chamber case 32 to distribute the EGR gas from the gas chamber 31 to each of the branch pipes 4. In the present embodiment, the gas chamber 31 includes a lowermost portion P1 which will be located at a lowermost position in a usage state of the gas chamber 31. Each gas distribution pipe 12A to 12D opens toward an outlet port of each corresponding branch pipe 4. In the present embodiment, as shown in
Herein, the gas distribution part 17 is provided with a plurality of condensed-water flow restraining units configured to restrain condensed water generated in the gas chamber 31 from flowing in the gas distribution pipes 12A to 12D. In the present embodiment, these condensed-water flow restraining units include different types of condensed-water flow restraining units. Specifically, the first type of the condensed-water flow restraining units is provided as a plurality of ribs 33 formed on an inner wall 32a of the chamber case 32 so that each rib 33 is located between adjacent two of the gas distribution pipes 12A to 12D and extends in a circumferential direction around the longitudinal direction (i.e., the central axis) of the chamber case 32. Herein, when a vehicle mounted with an engine makes for example a sharp turn, a centrifugal force also acts on the EGR gas distributor 1. Thus, each rib 33 has only to be designed with a height enough to at least prevent the condensed water adhering to the inner wall 32a of the chamber case 32 from climbing over the rib(s) 33 even if the condensed water is moved on the inner wall 32a by the centrifugal force acting in the longitudinal direction of the chamber case 32. The second type of the condensed-water flow restraining units is constituted of an upper end portion 12e of each of the gas distribution pipes 12A to 12D, each upper end portion 12e being formed to protrude into the gas chamber 31. Herein, the upper end portions 12e each have only to be designed with a protruding height enough to at least prevent the condensed water that may accumulate in the lowermost portion P1 of the gas chamber 31 within a predetermined period from overflowing beyond the upper end portion 12e. The third type of the condensed-water flow restraining units is a groove 34 formed in the chamber case 32 along the longitudinal direction thereof in correspondence with the lowermost portion P1 of the gas chamber 31 to trap condensed water. Herein, the groove 34 has only to be designed with a depth enough to prevent the condensed water that may accumulate in the groove 34 within a predetermined period from overflowing from the groove 34.
According to the configuration of the present embodiment described above, the EGR gas distributor 1 is attached to the intake manifold 2 mounted on the engine. In this attached state, EGR gas introduced into the gas chamber 1 of the gas distribution part 17 through the gas inflow pipe 11 is distributed from the gas chamber 31 to the branch pipes 4 through the corresponding gas distribution pipes 12A to 12D. Herein, during cold start of the engine, condensed water may be generated in the gas chamber 31 from EGR gas introduced into the gas chamber 31. Further, this condensed water may adhere to the inner wall 32a of the chamber case 32, flow down by its own weight along the inner wall 32a and collect in the lowermost portion P1 of the gas chamber 31. Herein, the EGR gas distributor 1 is provided with the condensed-water flow restraining units configured to restrain the condensed water generated in the gas chamber 31 from flowing in the gas distribution pipes 12A to 12D. Accordingly, the condensed-water flow restraining units restrain flowing of the condensed water into the gas distribution pipes 12A to 12D, thereby making it less likely to cause the condensed water to flow in each branch pipe 4. This configuration can therefore restrain the condensed water generated in the gas chamber 31 from being sucked into the engine through the gas distribution pipes 12A to 12D and the branch pipes 4 of the intake manifold 2. Consequently, it is possible to prevent misfire in the engine due to suction of the condensed water.
According to the configuration of the present embodiment, as the first type of the condensed-water flow restraining units, the ribs 33 are formed on the inner wall 32a of the chamber case 32 in the circumferential direction around the longitudinal direction of the chamber case 32. Thus, even if the condensed water on the inner wall is moved in the longitudinal direction of the chamber case 32 by action of the centrifugal force and the like, the movement of the condensed water is restricted by each rib 33 and thus the condensed water will not lean to one end part of the chamber case 32 in the longitudinal direction. It is thus possible to restrain the condensed water that leans to and accumulates in the end part of the chamber case 32 from flowing in specific gas distribution pipes 12A and 12D, i.e., the gas distribution pipes 12A and 12D located near the end part of the chamber case 32. Thus, the condensed water will not ununiformly flow into the branch pipes 4 corresponding to the gas distribution pipes 12A and 12D. This configuration can restrain the condensed water generated in the gas chamber 31 from being sucked into the engine through the specific gas distribution pipes 12A and 12D near the end part of the chamber case 32 and the corresponding branch pipes 4.
According to the configuration of the present embodiment, as the second type of the condensed-water flow restraining units, the upper end portion 12e of each of the gas distribution pipes 12A to 12D is formed to protrude into the gas chamber 31. Thus, the condensed water generated in the gas chamber 31 collects by its own weight into the lowermost portion P1 that is a lower area of the gas chamber 31; however, the upper end portions 12e of the gas distribution pipes 12A to 12D protruding into the gas chamber 31 restrain the collected condensed water from flowing in the gas distribution pipes 12A to 12D, so that the condensed water is less likely to flow in each branch pipe 4. Accordingly, this configuration can prevent the condensed water generated in the gas chamber 31 from being sucked into the engine through the gas distribution pipes 12A to 12D and the branch pipes 4.
According to the configuration of the present embodiment, as the third type of the condensed-water flow restraining units, the groove 34 is formed in the longitudinal direction of the chamber case 32 in correspondence with the lowermost portion P1 of the gas chamber 31. Thus, the condensed water generated in the gas chamber 31 that flows down by its own weight is trapped in the groove 34, so that the condensed water is less likely to flow in each of the gas distribution pipes 12A to 12D. Accordingly, this configuration can prevent the condensed water generated in the gas chamber 31 from being sucked into the engine through the gas distribution pipes 12A to 12D and the branch pipes 4.
According to the configuration of the present embodiment, the heating part 18 is provided adjacent to the gas distribution part 17. Thus, the inner wall 32a of the chamber case 32 of the gas distribution part 17 is heated by the heating part 18 and thus the EGR gas in the gas chamber 31 is warmed up. This configuration can therefore reduce the generation of condensed water in the gas chamber 31 and also promote evaporation of condensed water, even if generated.
In the EGR gas distributor 1 in the present embodiment, as the condensed-water flow restraining units, (1) the ribs 33 are formed on the inner wall 32a of the chamber case 32 and extend in the circumferential direction of the chamber case 32, (2) the upper end portions 12e are formed in the gas distribution pipes 12A to 12D and protrude into the gas chamber 31, and (3) the groove 34 is formed in the longitudinal direction of the chamber case 32 in correspondence with the lowermost portion P1 of the gas chamber 31. In addition, (4) the heating part 18 for heating the chamber case 32 is provided adjacent to the chamber case 32. In the present embodiment, furthermore, the above configurations (1) to (4) act synergistically on the special effects that can prevent the condensed water that has been generated or is generated in the gas chamber 31 from being sucked into the engine through the gas distribution pipes 12A to 12D and the branch pipes 4. However, the EGR gas distributor 1 has only to include at least one of the configurations (1) to (3) as a base configuration to ensure the foregoing special effects.
Next, a second embodiment of the EGR gas distributor will be described below with reference to the accompanying drawings.
In the following description, similar or identical components to those in the first embodiment are assigned the same reference signs and their details are omitted. The following description is thus given with a focus on differences from the first embodiment.
(Configuration of EGR Gas Distributor)
Accordingly, the configuration of the EGR gas distributor 1 in the present embodiment can also achieve the operations and effects substantially equivalent to those in the first embodiment. In the present embodiment, additionally, the condensed water trapped in the groove 34 is drained out by the condensed-water discharging unit (the discharge passage 41, the electromagnetic valve 42, and the ECU 43) as needed, so that the condensed water does not accumulate in the chamber case 32. In other words, the condensed water trapped in the groove 34 of the chamber case 32 flows down into the discharge passage 41. Herein, when the electromagnetic valve 42 is in a valve-closed state, condensed water will accumulate mainly in the groove 34 and the discharge passage 41. In contrast, when the electromagnetic valve 42 is opened, condensed water is allowed to flow in the cooling-water passage through the electromagnetic valve 42 and the discharge passage 41 and then flow out of the EGR gas distributor 1. This configuration can prevent the condensed water from being sucked into the engine through the gas distribution pipes 12A to 12D and the branch pipes 4, and hence can prevent misfire in the engine due to suction of condensed water.
Next, a third embodiment of the EGR gas distributor will be described below with the accompanying drawings.
(Configuration of EGR Gas Distributor)
Consequently, the configuration of the EGR gas distributor 1 in the present embodiment can also achieve the operations and effects substantially equivalent to those in the second embodiment. In the present embodiment, additionally, the check valve 46 is used instead of the electromagnetic valve 42 to discharge condensed water, so that the electrical configuration including the ECU 43 and wiring or others to those components can be omitted, resulting in simplification of the condensed-water discharging unit.
Next, a fourth embodiment of the EGR gas distributor will be described below with the accompanying drawings.
(Configuration of EGR Gas Distributor)
Accordingly, the configuration of the EGR gas distributor 1 in the present embodiment can also achieve the operations and effects substantially equivalent to those in the second embodiment. In the present embodiment, additionally, the condensed water generated in the gas chamber 31 collects by its own weight in the lowermost portion P1 of the gas chamber 31. This condensed water that collects in the lowermost portion P1 is appropriately discharged outside through the condensed-water discharging unit (the gas inflow pipe 11, the EGR valve 48, the EGR cooler 49, the EGR passage 50, acid the ECU 43), so that the condensed water does not accumulate in the chamber case 32. In other words, the condensed water that collects in the lowermost portion P1 of the gas chamber 31 flows down to the EGR valve 48 through the gas inflow pipe 11. Herein, when the EGR valve 48 is in a valve-closed state, the condensed water accumulates mainly in the gas inflow pipe 11 and the lowermost portion P1. In contrast, when the EGR valve 48 is opened, the condensed water is allowed to flow to the discharge passage through the EGR valve 48, the EGR cooler 49, and the EGR passage 50 and then the condensed water is discharged outside. This configuration can prevent the condensed water from being sucked into the engine through the gas distribution pipes 12A to 12D and the branch pipes 4, and hence can prevent misfire in the engine due to suction of condensed water.
The present disclosure is not limited to each of the aforesaid embodiments and may be embodied in other specific forms without departing from the essential characteristics thereof.
In the first embodiment, as shown in
In each of the foregoing embodiments, the EGR gas distributor 1 is used to distribute EGR gas to each of the branch pipes 4 of the intake manifold 2. As an alternative, this EGR gas distributor 1 may also be used to distribute auxiliary gas (e.g., PCV gas) different from EGR gas to each branch pipe 4 of the intake manifold 2.
In each of the foregoing embodiments, the upper end portion 12e of each of the gas distribution pipes 12A to 12D is configured to protrude in the gas chamber 31, but this configuration may be omitted.
In each of the foregoing embodiments, the ribs 33 are provided on the inner wall 32a of the chamber case 32, but these ribs 33 may be omitted.
In each of the foregoing embodiments, the heating part 18 is provided to heat the gas distribution part 17, but this heating part 18 may be omitted.
The present disclosure is utilizable in an EGR device and a PCV device provided in an engine system.
Number | Date | Country | Kind |
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2017-215417 | Nov 2017 | JP | national |