KR102129762B1 - Water cooling type urea injection module - Google Patents

Abstract

The present invention discloses a water-cooled urea water injection module capable of realizing an improvement in cooling performance by increasing a contact area with cooling water by applying a cooling method for an injector unit applied to a selective catalytic reduction system in a three-stage separation structure. .
The above-described water-cooled urea water injection module is provided on the inner core 30 disposed outside the injector unit 10, the middle sleeve 40 disposed outside the inner core 30, and on the outside of the intermediate sleeve 40. The outer jacket 50 to be arranged, a divided cooling unit for dividing the flow space of the cooling water into a plurality over the longitudinal direction of the injector unit 10 between the intermediate sleeve 40 and the outer jacket 50, and Between the inner core 30 and the intermediate sleeve 40 is provided with an integrated cooling unit for integrating the flow space of the cooling water over the longitudinal direction of the injector unit (10).

Description

WATER COOLING TYPE UREA INJECTION MODULE}

The present invention relates to a water-cooled urea water injection module, and more particularly, to improve the cooling method for an injector unit applied to a selective catalytic reduction system for reducing nitrogen oxides through injection of urea water inside an exhaust pipe to improve exhaust. It relates to a water-cooled urea water injection module capable of realizing normal performance even when exposed to a high temperature environment for a long time.

In general, an internal combustion engine that uses fossil fuels such as gasoline or diesel contains substances that can pollute the environment in exhaust gas generated after combustion of the fuel. In particular, in the case of a commercial vehicle such as a bus or a truck, since it is driven by a diesel engine, harmful substances such as carbon monoxide (CO) and hydrocarbons (HC), particulate matter and nitrogen oxides (NOx) are included in the exhaust gas. It is included in large quantities.

Accordingly, in the exhaust system of a diesel engine, various types of exhaust such as Diesel Oxidation Catalyst (DOC), Diesel Particulate matter Filter (DPF), and Selective Catalyst Reduction (SCR), and Lean NOx Trap (LNT) are used to reduce harmful substances. A gas post-treatment device is optionally provided.

Among them, in the exhaust gas post-treatment device to which the selective catalytic reduction system (SCR) is applied, the nitrogen oxide contained in the exhaust gas is reduced to nitrogen and water by spraying a reducing agent such as urea water into the exhaust pipe. That is, in the conventional selective catalytic reduction system (SCR), when injection of urea water as a reducing agent is made into the exhaust pipe, the injected urea water is converted to ammonia (NH ₃ ) by the heat of the exhaust gas, and then exhausted by the SCR catalyst Through the catalytic reaction of nitrogen oxides and ammonia in the gas, nitrogen oxides are reduced to nitrogen gas (N ₂ ) and water (H ₂ O), which are harmless to the human body.

In this selective catalytic reduction system, urea water is injected from a high temperature environment of the exhaust system together with a system for storing a certain amount of urea water and supplying an appropriate amount of urea water when necessary to inject urea water into the exhaust pipe. Separate cooling equipment must be provided to protect the injector unit.

That is, in the selective catalytic reduction system, since the injector unit that implements proper injection of urea water is directly exposed to the high temperature thermal environment, cooling of the injector unit is an important consideration factor in ensuring and maintaining the proper performance of the device. It is inevitable.

However, the cooling device applied to the conventional selective catalytic reduction system not only has insufficient performance to effectively cool all parts of the injector unit, but also lacks in protecting the injector unit from vibration transmitted to the exhaust system. There is a great demand for improvement in Korea.

Registered Patent No. 10-1294031 EP01662108B1

The technical problem to be solved by the present invention is to apply a cooling method for an injector unit applied to a selective catalytic reduction system in a three-stage separable structure, a water-cooling element capable of realizing an improvement in cooling performance by increasing a contact area with cooling water. It is to provide a water injection module.

Another technical problem to be solved by the present invention is a water-cooled type that can more actively protect the injector unit from vibration of the exhaust system generated during exhaust of combustion gas through stable support by three-point support for the injector unit inside the case. It is to provide a urea water injection module.

The present invention for solving the above technical problem is an injector unit for spraying urea water, an inner core disposed outside the injector unit, an intermediate sleeve disposed outside the inner core, and disposed outside the intermediate sleeve An outer jacket, and a water-cooled cooling unit formed by dividing a flow space of cooling water between the inner core and the middle sleeve and the outer jacket, wherein the water-cooled cooling unit is located between the intermediate sleeve and the outer jacket, the injector unit And a divided cooling unit for dividing a plurality of cooling water flow spaces in a longitudinal direction, and an integrated cooling unit for integrating a cooling water flow space in the longitudinal direction of the injector unit between the inner core and the intermediate sleeve, It is preferable that the divided cooling unit and the integrated cooling unit are configured to be mutually communicable for circulation of cooling water.

In the present invention, the split-type cooling unit is a first chamber and a third chamber formed by dividing the flow space of the cooling water in the vertical direction across the entire circumference of the injector unit by bonding between the intermediate sleeve and the outer jacket. It is preferably composed of.

In the present invention, it is preferable that the first chamber is configured to communicate with the inflow pipe of the cooling water, and the third chamber is configured to communicate with the outlet pipe of the cooling water at a position spaced apart from the first chamber.

In the present invention, the integrated cooling unit is composed of a second chamber that extends integrally over the entire area in the vertical direction between the inner core and the intermediate sleeve, the flow space of the cooling water over the entire circumference of the injector unit. desirable.

In the present invention, the first chamber and the second chamber communicate with each other via the first communication hole of the intermediate sleeve, and the second chamber and the third chamber mediate the second communication hole of the intermediate sleeve. It is desirable to communicate with each other.

In the present invention, the first communication hole is provided in a radially arranged structure over the lower circumferential portion of the intermediate sleeve, and the second communication hole is connected to the outlet pipe at the upper end of the intermediate sleeve. It is preferably configured to be located on the opposite side.

In the present invention, the first chamber is located below the intermediate sleeve and the outer jacket, the third chamber is located above the first chamber between the intermediate sleeve and the outer jacket, the inlet pipe It is preferable that the cooling water flowing into and circulating through the first chamber is circulated sequentially through the second chamber and the third chamber, and then discharged to the outside through the outlet pipe.

In the present invention, the inner core is provided with a guide bush installed in close contact with the outer circumferential surface of the lead pipe of the injector unit on the inner circumferential surface, the inner core is a guide portion of a linear structure on the installation portion of the guide bush, and It is preferable to have a tapered portion bent so that a cross-sectional area extends from the lead pipe toward the outside on the guide portion.

The present invention further includes a case for accommodating the injector unit therein, and coupled to the inner core and the upper end of the intermediate sleeve and the outer jacket, wherein the injector unit includes a plurality of the guide bush and the inside of the case. It is preferable to be supported by a guide ring.

The water-cooled urea water injection module according to an embodiment of the present invention seeks to improve the cooling performance by increasing the contact area with the cooling water by changing the cooling method for the injector unit provided in the selective catalytic reduction system to a three-stage separation structure, Through this, it is possible to realize the normal operation of the parts even when exposed for a long time in a high temperature installation environment of the exhaust system.

In addition, the water-cooled urea water injection module according to an embodiment of the present invention is a three-point support structure using a guide bush and a plurality of guide rings inside the case, so that the injector unit can be stably supported. It is possible to more actively protect the injector unit from system vibration.

1 is a front view showing a water-cooled urea water injection module according to an embodiment of the present invention.
FIG. 2 is a view for explaining a flow space of cooling water set outside the injector unit in the water-cooled urea water injection module according to an embodiment of the present invention, and is a longitudinal cross-sectional view of FIG. 1.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached exemplary drawings.

1 and 2, a water-cooled urea water injection module according to an embodiment of the present invention is installed in an exhaust system of a vehicle and is operated and controlled to inject appropriate urea water into an exhaust pipe (not shown). The injector unit 10, the case 20 installed to accommodate the injector unit 10 therein and fixed to the exhaust pipe, and the water cooling type provided in the case 20 for cooling of the injector unit 10 It comprises a cooling unit.

The injector unit 10 exhausts the urea water supplied through the urea water supply connecting portion 12 and the urea water supply connecting portion 12 connected to an external supply unit (not shown) so as to receive urea water on the upper part. A lead pipe (14) incorporating main components including nozzles injected into the pipe, a connector (16) connected to a cable for receiving a control signal for opening and closing of a nozzle located inside the lower side of the lead pipe (14) It is configured to include.

That is, the injector unit 10 is an injector nozzle 18 for injecting urea water into the inside of the exhaust pipe on the inner bottom side of the lead pipe 14, and a solenoid () for controlling opening and closing of the injector nozzle 18 19) It consists of various parts related to spraying.

The case 20 is configured to accommodate the injector unit 10 therein and to mount the water-cooled cooling unit at the lower end. At this time, the injector unit 10 is installed to be inserted into the exhaust pipe.

The water-cooled cooling unit includes an inner core 30, an intermediate sleeve 40, and an outer jacket 50. The inner core 30, an intermediate sleeve 40, and an outer jacket 50 are respectively cylindrical in shape. It is configured to be sequentially arranged toward each other with a proper interval in a concentric circle based on the center of the lead pipe 14 of the injector unit 10.

That is, the inner core 30 is disposed to the outside at a suitable distance to the lead pipe 14 of the injector unit 10, the intermediate sleeve 40 is suitable for the inner core 30 The outer jacket 50 is disposed at a predetermined distance, and the outer jacket 50 is configured to be disposed outside at an appropriate interval with respect to the intermediate sleeve 40. In particular, the outer jacket 50 is installed to be inserted into the exhaust pipe through the mounting bracket 60 coupled to the outer peripheral surface.

In addition, the water-cooled cooling unit is configured to divide the flow space of the cooling water between the inner core 30 and the intermediate sleeve 40 and the outer jacket 50, in particular, the water-cooled cooling unit is the middle A split type cooling unit that divides and forms a plurality of coolant flow spaces in the vertical direction between the sleeve 40 and the outer jacket 50 in the longitudinal direction of the injector unit 10, and the inner core Between the 30 and the intermediate sleeve 40 is configured to have a three-stage separation type cooling structure including an integrated cooling unit for forming a flow space of cooling water over the entire length of the injector unit 10 in the longitudinal direction. . In this case, the divided cooling unit and the integrated cooling unit are configured to communicate with each other for circulation of cooling water.

Here, a detailed configuration of the split type cooling unit and the integrated type cooling unit is as follows.

First, the divided cooling part vertically moves the flow space of cooling water over the entire circumferential part of the injector unit 10 by a junction W made at a local part between the intermediate sleeve 40 and the outer jacket 50. It is composed of a first chamber (C-1) and a third chamber (C-3) of a ring shape formed by dividing independently in the direction. In this case, the first chamber (C-1) is configured to communicate with the inlet pipe 22 of the cooling water at a position adjacent to the lower outlet corresponding to the tip portion of the injector unit 10, and the third chamber (C) -3) is configured to communicate with the outlet pipe 24 of the coolant at a position spaced upward from the first chamber (C-1).

That is, the inlet pipe 22 is provided at a position adjacent to the lower end of the lead pipe 14 corresponding to the tip portion where the nozzle 18 is located in the injector unit 10, and the outlet pipe 24 is the inlet It is spaced upward from the pipe line 22 and is provided at a position adjacent to the upper end of the lead pipe 14. Accordingly, the inlet pipe 22 is installed to be able to communicate with the inside of the outer jacket 50 to serve to supply cooling water to the interior of the first chamber C-1, and the outlet pipe ( 24) is installed to be able to communicate with the inside of the outer jacket 50 to serve to discharge the cooling water in the inside of the third chamber (C-3) to the outside.

In addition, at least one of the outer circumferential surface of the intermediate sleeve 40 and the inner circumferential surface of the outer jacket 50 is connected to the flow of cooling water made inside the first chamber C-1 and the third chamber C-3. In order to provide a specific directionality to each surface, it is configured to be provided with a helical protrusion (not shown) protruding outwardly from each surface to guide the flow of cooling water in a certain direction.

In addition, the integrated cooling unit integrally extends to cover the flow space of the cooling water over the entire circumferential portion of the injector unit 10 between the inner core 30 and the intermediate sleeve 40 over the entire region in the vertical direction. It is composed of a second chamber (C-2) in the form of a ring that is formed. That is, the second chamber (C-2) is configured to extend long in the vertical direction so as to completely cover the entire circumferential portion of the injector unit 10 in the longitudinal direction.

In this case, at least one of the outer circumferential surface of the inner core 30 and the inner circumferential surface of the intermediate sleeve 40 is respectively provided to provide a specific directionality to the flow of cooling water made inside the second chamber C-2. It is configured to protrude toward the outside from the surface of the spiral projection (not shown) to guide the flow of the cooling water in a constant direction.

In addition, the first chamber (C-1) and the second chamber (C-2) communicate with each other via a first communication hole (42) located at the lower end of the intermediate sleeve (40), the second chamber The (C-2) and the third chamber (C-3) communicate with each other via the second communication hole 44 located at the upper end of the intermediate sleeve 40.

In addition, the first communication hole 42 is provided in a plurality of quantities as a radially arranged structure over the entire lower circumferential portion of the intermediate sleeve 40, the second communication hole 44 is the intermediate sleeve 40 It is configured to be located on the opposite side of the connection portion with the outlet pipe 24 on the upper side of ). At this time, the second communication hole 44 may not be limited in its quantity if it is a part located on the opposite side from the connecting portion with the outlet pipe 24. However, of course, the number and diameter of the cooling water may be appropriately adjusted in consideration of the cooling efficiency including the flow rate, which may be equally applied to the first communication hole 42.

Accordingly, the cooling water provided through the inlet pipe 22 flows into the first chamber C-1 formed between the intermediate sleeve 40 and the outer jacket 50, and the first chamber Cooling water introduced into the interior of (C-1) is through the first communication hole 42 to the interior of the second chamber (C-2) formed between the inner core 30 and the intermediate sleeve 40 The flow of the coolant flowing into the inside of the second chamber (C-2) flows through the entire circumferential portion of the inner core (30) and then rises, and then the second communication hole (44) flows. It can be introduced into the inside of the third chamber (C-3) formed between the intermediate sleeve 40 and the outer jacket 50 through the circulating flow, and then discharged to the outside through the outlet pipe 24 There will be.

The inner core 30 has a hollow guide bush 32 that is in close contact with the outer circumferential surface of the lead pipe 14 of the injector unit 10 on the inner circumferential surface. In this case, the guide bush 32 may be made of carbon graphite foil material to protect the injector unit 10 and the water-cooled cooling unit from high temperature exhaust gas flowing along the inside of the exhaust pipe and vibration of the exhaust system. There will be. In particular, the guide bush 32 is configured to perform a role to more actively block the backflow of high-temperature exhaust gas into the interior of the injector unit 10 and the water-cooled cooling unit.

In addition, the inner core 30 forms a guide portion 30a of a straight structure for the installation of an effective seating support for the guide bush 32, and the lead pipe 14 on top of the guide portion 30a It is configured to protect the lead pipe 14 from a high temperature exhaust environment by integrally forming a tapered portion 30b that is bent so that its cross-sectional area is expanded to secure a wider thermal insulation space toward the outside.

In this case, the lower ends of the inner core 30 and the outer jacket 50, which are supported by the guide bush 32, are appropriately bent toward the outer circumferential surface of the lead pipe 14 so as to be coupled in close contact. By being configured, it is possible to block the inflow of exhaust gas into the water-cooled urea water injection module.

On the other hand, the case 20 accommodates the injector unit 10 therein, and the inner core 30 and the intermediate sleeve 40 and the outer jacket 50 are coupled to the upper ends thereof to secure them. By mounting, a three-point support structure mediated by the installation of a plurality of guide rings 34 together with the guide bush 32 inside is configured to have a structure capable of completely suppressing the flow of the injector unit 10 do.

In this case, the guide bush 32 firmly supports the lower end of the lead pipe 14 with respect to the inner circumferential surface of the inner core 30, and the guide ring 34 has an upper end of the injector unit 10. In addition to being firmly supported on the inside of the case 20, the intermediate portion of the injector unit 10 is firmly supported on the inner circumferential surface of the inner core 30. It is not limited to the embodiments of the invention, but may be implemented as various modified embodiments.

Therefore, the water-cooled urea water injection module according to the embodiment of the present invention configured as described above can maximize the cooling efficiency by increasing the contact area with the cooling water by applying the cooling method for the injector unit 10 as a three-stage separation structure. In this way, it is possible to ensure the normal operation of the parts even when the injector unit 10 is exposed for a long time in a high temperature installation environment of the exhaust system.

That is, the water-cooled cooling unit of the present invention is a split-type cooling unit for dividing the flow space of the cooling water into a plurality over the vertical direction with respect to the longitudinal direction of the injector unit 10 between the intermediate sleeve 40 and the outer jacket 50, And an integrated cooling unit including an integrated cooling unit for integrating the flow space of the cooling water with respect to the longitudinal direction of the injector unit 10 between the inner core 30 and the intermediate sleeve 40, so that the cooling water is the first chamber. (C-1) and the second chamber (C-2) and the third chamber (C-3) in the flow through the sequence in order to absorb heat from the inside or block heat that is transferred from the outside of the injector unit (10) It is possible to cool the entire area uniformly and effectively.

In addition, the water-cooled urea water injection module according to an embodiment of the present invention is a three-point support structure, which is guided by a guide bush 32 and a plurality of guide rings 34 inside the case 20. Since it can be stably supported, it is possible to block the inflow of exhaust gas into the interior of the injector unit 10 and at the same time to more actively protect the injector unit 10 from vibration of the exhaust system generated during exhaust of combustion gas. .

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and variations without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. In addition, the scope of protection of the present invention should be interpreted by the following claims, and all technical spirits within the equivalent range should be interpreted as being included in the scope of the present invention.

10-injector unit 12-connector for urea water supply
14-lead pipe 16-connector
18-injector nozzle 20-case
22-inflow pipeline 24-outflow pipeline
30-inner core 32-guide bush
40-middle sleeve 42-first communication hole
44- second communication hole 50- outer jacket
60-mount bracket

Claims (10)

An injector unit for spraying urea water;
An inner core disposed outside the injector unit;
An intermediate sleeve disposed outside the inner core;
An outer jacket disposed outside the intermediate sleeve; And
It has a water-cooled cooling unit formed by dividing the flow space of the cooling water between the inner core and the intermediate sleeve and the outer jacket,
The water-cooled cooling unit includes a divided cooling unit for dividing a plurality of flow spaces of cooling water between the intermediate sleeve and the outer jacket in the longitudinal direction of the injector unit, and between the inner core and the intermediate sleeve of the injector unit. It has an integrated cooling unit for integrating the flow space of the cooling water over the longitudinal direction, the divided cooling unit and the integrated cooling unit is configured to be mutually communicative for circulation of the cooling water,
The split-type cooling unit is formed by dividing the flow space of the cooling water in the vertical direction over the entire circumferential portion of the injector unit by joining at a local portion between the intermediate sleeve and the outer jacket, to a first chamber and a third chamber. Is composed,
The integrated cooling unit is composed of a second chamber that extends integrally over the entire area in the vertical direction between the inner core and the intermediate sleeve, the flow space of the cooling water over the entire circumference of the injector unit,
The inner core has a guide portion of a straight structure with respect to an installation portion of a guide bush that is in close contact with an outer circumferential surface of the lead pipe of the injector unit on an inner circumferential surface, and a cross-sectional area is extended from the lead pipe to the outside on top of the guide portion A water-cooled urea water injection module having a tapered portion that is bent, and the second chamber is configured such that a cross-sectional area between the guide portion and the intermediate sleeve is set larger than a cross-sectional area between the tapered portion and the intermediate sleeve. delete The method according to claim 1,
The first chamber is in communication with the inlet pipe of the cooling water, the third chamber is a water-cooled urea water injection module, characterized in that configured to communicate with the outlet of the cooling water at a position spaced from the first chamber. delete The method according to claim 3,
The first chamber and the second chamber communicate with each other through the first communication hole of the intermediate sleeve, and the second chamber and the third chamber communicate with each other through the second communication hole of the intermediate sleeve. Characterized by water-cooled urea water injection module. The method according to claim 5,
The first communication hole is provided in a radially arranged structure over the entire circumferential portion of the lower side of the intermediate sleeve, and the second communication hole is configured to be located on the opposite side of the connection portion with the outlet pipe at the upper side of the intermediate sleeve. Water-cooled urea water injection module, characterized in that. The method according to claim 3,
The first chamber is located below the intermediate sleeve and the outer jacket, and the third chamber is located above the first chamber between the intermediate sleeve and the outer jacket, and the first through the inlet passage. The cooling water flowing into the chamber and circulating is circulated sequentially through the second chamber and the third chamber, and then is configured to be discharged to the outside through the outlet pipe. delete delete The method according to claim 1,
The injector unit accommodates therein, and further includes a case coupled with the inner core, the intermediate sleeve, and an upper portion of the outer jacket, wherein the injector unit includes the guide bush and a plurality of guide rings inside the case. Water-cooled urea water injection module, characterized in that supported by the medium.

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