KR102145332B1 - Reducing agent dosing module and selective catalyst reduction system using the same - Google Patents

Abstract

The reducing agent dosing module has a nozzle tip for injecting a reducing agent and is located between the injector having an injection surface with the nozzle tip installed, the mounting end of the mixing pipe connected to the exhaust pipe and the injection surface of the injector to prevent the outflow of exhaust gas It includes a gasket and an adapter interposed between the injection surface of the gasket and the injector or between the mounting end of the gasket and the mixing pipe to provide surface pressure to one surface of the gasket and to separate the injection surface of the injector by a predetermined distance from the mixing pipe. I can. The adapter separates the nozzle tip of the injector from the mixing pipe heated by the exhaust gas, thereby protecting the nozzle tip from heat damage caused by high heat. In addition, since the adapter has a structure that can be cooled by air cooling, the nozzle tip can be sufficiently cooled.

Description

Reducing agent dosing module and selective catalytic reduction system using the same {REDUCING AGENT DOSING MODULE AND SELECTIVE CATALYST REDUCTION SYSTEM USING THE SAME}

The present invention relates to a reducing agent dosing module and a selective catalytic reduction system using the same. More specifically, it relates to a reducing agent dosing module for exhaust gas post-treatment and a selective catalytic reduction system using the same.

The exhaust system of the engine may have devices for reducing pollutants contained in the exhaust gas. The pollutants may include particulate matter (PM), nitrogen oxides (NOx), and the like. For example, an exhaust gas post-treatment device such as a diesel oxidation catalyst (DOC) device and a selective catalyst reduction (SCR) device may be provided.

In the selective catalytic reduction system, the reducing agent may be injected in the flow direction of the exhaust gas from the reducing agent dosing module. The selective catalytic reduction system catalytically reacts the reducing agent and the nitrogen oxide by using heat of the exhaust gas to reduce the nitrogen oxide to nitrogen gas and water.

In this case, there is a problem in that the nozzle tip portion of the reducing agent dosing module is deteriorated due to heat of the exhaust gas, and thus the operational reliability of the reducing agent dosing module is greatly deteriorated.

An object of the present invention is to provide a reducing agent dosing module with high operational reliability.

Another object of the present invention is to provide a selective catalytic reduction system including a reducing agent dosing module having high operational reliability.

The reducing agent dosing module for achieving one object of the present invention described above includes an injector having a nozzle tip for injecting a reducing agent and having an injection surface on which the nozzle tip is installed, a mounting end of a mixing pipe connected to the exhaust pipe, and the injector. A gasket positioned between the injection surfaces to prevent the outflow of exhaust gas, and interposed between the gasket and the injection surface of the injector or between the gasket and the mounting end of the mixing pipe to provide a surface pressure to one surface of the gasket, And an adapter for separating the injection surface of the injector by a predetermined distance from the mixing pipe.

In example embodiments, the adapter may have a first thickness in the range of 5mm to 8mm.

In example embodiments, the gasket may have a second thickness smaller than the first thickness.

In example embodiments, the adapter may include stainless steel.

In example embodiments, the gasket may include mica.

In example embodiments, the adapter may have a shape corresponding to the gasket.

In example embodiments, when the adapter is interposed between the gasket and the mounting end of the mixing pipe, a plate may be further included between the gasket and the injection surface of the injector.

In example embodiments, when the adapter is interposed between the gasket and the mounting end of the mixing pipe, the adapter may have a shape protruding from the mounting end of the mixing pipe.

In example embodiments, the exhaust pipe may include an inlet through which the exhaust gas is introduced, an outlet through which the exhaust gas is discharged, and a curved portion connecting the inlet and the outlet and having a curvature. The mixing pipe may be formed outside the curved portion of the exhaust pipe so that the curved portion faces the outlet.

The selective catalytic reduction system for achieving another object of the present invention described above includes an exhaust pipe provided with a selective reduction catalyst and for discharging exhaust gas, a mixing pipe extending from the exhaust pipe to the outside in front of the selective reduction catalyst, and It may include a reducing agent dosing module installed at the mounting end of the mixing pipe to inject a reducing agent into the exhaust pipe through the mixing pipe. The reducing agent dosing module is located between the injector having a nozzle tip for injecting the reducing agent and having an injection surface on which the nozzle tip is installed, the mounting end of the mixing pipe in communication with the exhaust pipe and the injection surface of the injector A gasket preventing the outflow of the exhaust gas, and interposed between the gasket and the injection surface of the injector or between the gasket and the mounting end of the mixing pipe to provide a surface pressure to one surface of the gasket, and the injector It may include an adapter for separating the injection surface of the mixing pipe by a predetermined distance.

In example embodiments, the adapter may have a first thickness in the range of 5mm to 8mm.

In example embodiments, the gasket may have a second thickness smaller than the first thickness.

In example embodiments, the adapter may include stainless steel.

In example embodiments, the adapter may have a shape corresponding to the gasket.

In example embodiments, when the adapter is interposed between the gasket and the mounting end of the mixing pipe, a plate may be further included between the gasket and the injection surface of the injector.

In example embodiments, when the adapter is interposed between the gasket and the mounting end of the mixing pipe, the adapter may have a shape protruding from the mounting end of the mixing pipe.

However, the problem to be solved by the present invention is not limited to the above-described problems, and may be variously expanded without departing from the spirit and scope of the present invention.

The reducing agent dosing module according to exemplary embodiments may include an adapter between the gasket and the injector. The adapter separates the nozzle tip of the injector from the mixing pipe heated by the exhaust gas, thereby protecting the nozzle tip from thermal damage caused by high heat. In addition, since the adapter has a structure that can be cooled by air cooling, the nozzle tip can be sufficiently cooled.

Since the adapter has a shape corresponding to the shape of the gasket, a sufficient surface pressure can be formed on one surface of the gasket. In addition, since the adapter is sufficiently cooled, oxidation and hardening of the gasket containing mica can be reduced by high heat.

However, the effects of the present invention are not limited to the above-mentioned effects, and may be variously extended without departing from the spirit and scope of the present invention.

1 is an exploded perspective view of a reducing agent dosing module according to exemplary embodiments.
2 is an exploded cross-sectional view of the reducing agent dosing module of FIG. 1.
3 is a perspective view of the reducing agent dosing module of FIG. 1.
4 is a plan view of an adapter of a reducing agent dosing module according to exemplary embodiments.
5 is an exploded perspective view of a reducing agent dosing module according to exemplary embodiments.
6 is an exploded cross-sectional view of the reducing agent dosing module of FIG. 5.
7 is a perspective view of the reducing agent dosing module of FIG. 5.
8 is a cross-sectional view of a selective catalytic reduction system according to exemplary embodiments.

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

With respect to the embodiments of the present invention disclosed in the text, specific structural or functional descriptions have been exemplified only for the purpose of describing the embodiments of the present invention, and the embodiments of the present invention may be implemented in various forms. It should not be construed as being limited to the embodiments described in.

In the present invention, various modifications may be made and various forms may be applied, and specific embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific form of disclosure, it is to be understood as including all changes, equivalents, or substitutes included in the spirit and scope of the present invention.

1 is an exploded perspective view of a reducing agent dosing module according to exemplary embodiments. 2 is an exploded cross-sectional view of the reducing agent dosing module of FIG. 1. 3 is a perspective view of the reducing agent dosing module of FIG. 1. 4 is a plan view of an adapter of a reducing agent dosing module according to exemplary embodiments.

1 to 4, the reducing agent dosing module 10 is interposed between the injector 100 for injecting the reducing agent, the injector 100 and the mixing pipe 210 in which the injector 100 is installed, It may include a gasket 110 to prevent leakage, and an adapter 120 positioned between the injector 100 and the gasket 110 to cool the nozzle tip 106 included in the injector 100.

The injector 100 may include a nozzle tip 106 for injecting the reducing agent into the mixing pipe 210. For example, the nozzle tip 106 may include a plurality of nozzle holes (not shown). In addition, the nozzle tip 106 may spray the reducing agent through the spray hole 124 of the adapter 120 to be described later.

In example embodiments, the nozzle tip 106 may be provided on the injection surface 108 of the injector 100. In addition, a ring (not shown) is provided on the injection surface 108 of the injector 100 to form pressure on one surface of the adapter 120 to prevent the outflow of the exhaust gas.

A plurality of injector fastening members 104 are respectively coupled to the mounting end 216 of the mixing pipe 210 through a plurality of injector fastening holes 102 provided in the injector 100, so that the injector 100 is a mixing pipe. It can be fixed to 210. For example, the injector fastening members 104 may be fixing members such as bolts.

The gasket 110 may be positioned between the mounting end 216 of the mixing pipe 210 communicated with the exhaust pipe 200 and the injection surface 108 of the injector 100 to prevent the exhaust gas from flowing out. Specifically, the gasket 110 is interposed between the mounting end 216 of the mixing pipe 210 and the adapter 120, and one surface of the mounting end 216 of the mixing pipe 210 and one surface of the adapter 210 Outflow of the exhaust gas can be prevented by the pressures respectively formed in.

In example embodiments, the gasket 110 may include mica or the like that can withstand a high temperature environment. In addition, the injector fastening members 104 may be inserted into the gasket fastening holes 112 provided in the gasket 100 to be fastened to the mounting end fastening holes 212 of the mixing pipe 210. In addition, the reducing agent injected from the injector 100 may be injected into the mixing pipe 210 through the gasket injection hole 114 of the gasket 110.

The exhaust pipe 200 may be a flow path of the exhaust gas. For example, the exhaust pipe 200 may include stainless steel.

In exemplary embodiments, the exhaust pipe 200 connects the inlet 202 through which the exhaust gas is introduced, the outlet 204 through which the exhaust gas is discharged, and the inlet 200 and the outlet 204, and has a curvature. It may include a curved portion 206 formed to have a.

The mixing pipe 210 may be fixed by welding to the outer peripheral surface of the exhaust pipe 200 so as to communicate with the exhaust pipe 200. The mixing pipe 210 may be provided as a member to which the reducing agent dosing module 10 can be mounted on the exhaust pipe 200.

Mounting end fastening holes 212 for mounting the reducing agent dosing module 10 may be formed at the mounting end 210 of the mixing pipe 210. In addition, a mounting end injection hole 214 through which the reducing agent sprayed by the reducing agent dosing module 10 passes and is injected into the exhaust pipe 200 may be formed at the mounting end 210 of the mixing pipe 210.

In exemplary embodiments, the mixing pipe 210 is welded to and fixed to the outer peripheral surface of the curved portion 206 of the exhaust pipe 200 so as to face the outlet 204 from the curved portion 206 of the exhaust pipe 200 Can be. A flow of the exhaust gas is formed from the curved portion 206 of the exhaust pipe 200 toward the outlet 204. The reducing agent is injected in the flow direction of the exhaust gas so that the nitrogen oxide in the exhaust gas and the reducing agent act in the same direction, so that a selective catalytic reduction reaction may be further promoted.

The adapter 120 may be interposed between the gasket 110 and the injection surface 108 of the injector 100 to provide a surface pressure to one surface of the gasket 110. In addition, the adapter 120 may separate the injection surface 108 of the injector 100 by a predetermined distance from the mixing pipe 210.

In exemplary embodiments, the adapter 120 is an adapter injection hole 124 into which the nozzle tip 106 of the injector 100 is inserted and cooled, and an adapter into which the injector fastening members 104 are inserted. It may include fastening holes 122. For example, one surface of the adapter 120 may have a shape corresponding to the shape of the gasket 122. In addition, the adapter 120 may include stainless steel or the like having excellent heat insulation effect.

3 and 4, the reducing agent dosing module 10 may be sequentially assembled with an injector 100, an adapter 120, and a gasket 100. A part of the nozzle tip 106 of the injector 100 may be inserted into the adapter injection hole 124. In addition, the injector fastening members 104 may be inserted into adapter fastening holes 122, gasket fastening holes 112, and mounting end fastening holes 212 of the mixing pipe 210 to be fastened.

In addition, the reducing agent injected from the injector 100 is exhaust pipe through the nozzle tip 106, the adapter injection hole 124, the gasket injection hole 114, the mounting end injection hole 214, and the mixing pipe 210. It can be sprayed into 200.

In example embodiments, the adapter 120 may have a first thickness in the range of 5mm to 8mm. For example, the injection surface 106 of the injector 100 may be spaced apart from the mixing pipe 210 by the first thickness of the adapter 120.

When the thickness of the adapter 120 is less than 5 mm, the nozzle tip 106 of the injector 100 may be damaged due to insufficient cooling of the adapter 120. In addition, when the thickness of the adapter 120 is greater than 8 mm, the reducing agent, in particular, urea water is not properly injected into the exhaust pipe 200, so that a wall wetting phenomenon, that is, urea water crystals are formed around the nozzle tip 106. May cause the nozzle tip to become clogged.

In example embodiments, the gasket 110 may have a second thickness smaller than the first thickness. For sufficient cooling of the nozzle tip 106 of the injector 100, it is preferable that the first thickness of the adapter 120 is greater than the second thickness of the gasket.

The reducing agent dosing module 10 according to exemplary embodiments may include an adapter 120 between the gasket 110 and the injector 100. The adapter 120 may protect the nozzle tip 106 from heat damage by separating the nozzle tip 106 of the injector 100 from the mixing pipe 210 heated by the exhaust gas. In addition, in addition to the dosing module cooling line (not shown) for cooling the injector 106, the adapter 100 has an air-cooled structure, so that there is an additional cooling effect.

In particular, since the nozzle tip 106 is inserted into the adapter spray hole 124 of the adapter 120, the adapter 120 made of stainless steel having excellent insulation effect is located adjacent to the nozzle tip 106. Thus, the nozzle tip 106 can be sufficiently cooled.

Since the adapter 120 has a shape corresponding to the shape of the gasket 110, sufficient surface pressure can be formed on one surface of the gasket 110. In addition, since the adapter 110 is sufficiently cooled, it is possible to reduce oxidation and hardening of the gasket 110 including mica due to high heat.

5 is an exploded perspective view of a reducing agent dosing module according to exemplary embodiments. 6 is an exploded cross-sectional view of the reducing agent dosing module of FIG. 5. 7 is a perspective view of the reducing agent dosing module of FIG. 5. The reducing agent dosing module according to exemplary embodiments includes substantially the same components as the reducing agent dosing module of FIG. 1 except for a location where the adapter is interposed. Accordingly, the same components are denoted by the same reference numerals, and repeated descriptions of the same components are omitted.

5 to 7, the reducing agent dosing module 30 is interposed between the injector 100 for injecting the reducing agent, the injector 100 and the mixing pipe 210 in which the injector 100 is installed, A gasket 110 to prevent leakage, and an adapter 120 for cooling the nozzle tip 106 included in the injector 100 by being positioned between the gasket 110 and the mounting end 216 of the mixing pipe 210 It may include.

The injector 100 may include a nozzle tip 106 for injecting the reducing agent into the mixing pipe 210. For example, the nozzle tip 106 may include a plurality of nozzle holes (not shown). In addition, the nozzle tip 106 may spray the reducing agent through the spray hole 124 of the adapter 120 to be described later.

A plurality of injector fastening members 104 are respectively coupled to the mounting end 216 of the mixing pipe 210 through a plurality of injector fastening holes 102 provided in the injector 100, so that the injector 100 is a mixing pipe. It can be fixed to 210. For example, the injector fastening members 104 may be fixing members such as bolts.

In example embodiments, the nozzle tip 106 may be provided on the injection surface 108 of the injector 100. In addition, a plate 130 may be further included between the gasket 110 and the injection surface 108 of the injector 100. The plate 130 may prevent exhaust gas from leaking by forming a surface pressure on one surface of the gasket 110.

For example, the plate 130 may include stainless steel or the like excellent in thermal insulation. In addition, the plate 130 may include a plate injection hole 134 and a plurality of plate fastening holes 132.

In addition, a ring (not shown) may be provided on the injection surface 108 of the injector 100 to form pressure on one surface of the plate 130 to prevent the exhaust gas from flowing out.

The gasket 110 may be positioned between the mounting end 216 of the mixing pipe 210 communicated with the exhaust pipe 200 and the injection surface 108 of the injector 100 to prevent the exhaust gas from flowing out. Specifically, the gasket 110 is interposed between the adapter 120 and the plate 130 to prevent the outflow of the exhaust gas by pressures formed on one surface of the adapter 210 and one surface of the plate 130, respectively. I can.

In example embodiments, the gasket 110 may include mica or the like that can withstand a high temperature environment. In addition, the injector fastening members 104 may be inserted into the gasket fastening holes 112 provided in the gasket 100 to be fastened to the mounting end fastening holes 212 of the mixing pipe 210. In addition, the reducing agent injected from the injector 100 may be injected into the mixing pipe 210 through the gasket injection hole 114 of the gasket 110.

The mixing pipe 210 may be fixed by welding to the outer peripheral surface of the exhaust pipe 200 so as to communicate with the exhaust pipe 200. The mixing pipe 210 may be provided as a member to which the reducing agent dosing module 10 can be mounted on the exhaust pipe 200. In addition, mounting end fastening holes 212 for mounting the reducing agent dosing module 10 may be formed at the mounting end 210 of the mixing pipe 210. In addition, a mounting end injection hole 214 through which the reducing agent sprayed by the reducing agent dosing module 10 passes and is injected into the exhaust pipe 200 may be formed at the mounting end 210 of the mixing pipe 210.

The adapter 120 is an adapter injection hole 124 through which the nozzle tip 106 of the injector 100 is inserted and cooled, and adapter fastening holes into which the injector fastening members 104 of the injector 100 are inserted. (122) may be included. For example, one surface of the adapter 120 may have a shape corresponding to the shape of the gasket 122. In addition, the adapter 120 may include stainless steel or the like having excellent heat insulation effect.

As shown in FIG. 7, in the reducing agent dosing module 30, the injector 100, the plate 130, and the gasket 100 may be sequentially assembled. In addition, the reducing agent dosing module 30 may be assembled including an adapter 120.

A part of the nozzle tip 106 of the injector 100 may be inserted into the adapter injection hole 124. In addition, the injector fastening members 104 of the injector 100 are plate fastening holes 132, gasket fastening holes 112, adapter fastening holes 122, and mounting end fastening holes of the mixing pipe 210 Each can be inserted into and fastened to (212).

In example embodiments, the adapter 120 may have a first thickness in the range of 5mm to 8mm. In addition, the gasket 110 may have a second thickness smaller than the first thickness.

In example embodiments, the adapter 120 may have a shape protruding from the mounting end 216 of the mixing pipe 210. For example, the adapter 120 may be manufactured and provided when the mixing pipe 210 is manufactured in a casting process. Alternatively, the adapter 120 may be fixed by welding to the mixing pipe 210.

The reducing agent dosing module 30 according to exemplary embodiments separates the nozzle tip 106 of the injector 100 from the mixing pipe 210 heated by the exhaust gas by means of the adapter 120. ) To prevent heat damage.

In addition, since the adapter 120 has a structure capable of air cooling, the nozzle tip 106 inserted into the adapter injection hole 124 can be sufficiently cooled.

In particular, since the adapter 120 may be manufactured together with the mixing pipe 210 by a casting process, the gasket 110 including mica may also be spaced apart. Accordingly, it is possible to prevent the gasket 110 from being cured by high heat and deteriorating the sealing performance.

Hereinafter, a selective catalytic reduction system including a reducing agent dosing module according to exemplary embodiments will be described.

8 is a cross-sectional view of a selective catalytic reduction system according to exemplary embodiments.

Referring to FIG. 8, the selective catalytic reduction system is provided with a selective reduction catalyst 300 and extends from the exhaust pipe 200 in front of the exhaust pipe 200 for discharging exhaust gas and the selective reduction catalyst 300 to the outside. It may include a mixing pipe 210 and a reducing agent dosing module 10.

When the reducing agent is injected into the exhaust pipe 200, the selective reduction catalyst 300 converts to ammonia (NH3) by heat of the exhaust gas using the reducing agent, and nitrogen oxide and ammonia contained in the exhaust gas undergo a catalytic reaction. Do it.

The diesel oxidation catalyst 400 may be connected to the selective reduction catalyst 300 through the exhaust pipe 200. The diesel oxidation catalyst 400 may reduce particulate matters, carbon monoxide, and hydrocarbon concentrations by oxidizing reducing substances in the exhaust gas.

The exhaust pipe 200 is positioned between the selective reduction catalyst 300 and the diesel oxidation catalyst 400 to allow the exhaust gas that has passed through the diesel oxidation catalyst 400 to pass through the selective reduction catalyst 300. For example, the exhaust pipe 200 may include stainless steel or the like.

In exemplary embodiments, the exhaust pipe 200 connects the inlet 202 through which the exhaust gas is introduced, the outlet 204 through which the exhaust gas is discharged, and the inlet 200 and the outlet 204, and has a curvature. It may include a curved portion 206 formed to have.

The mixing pipe 210 may extend outward from the exhaust pipe 200 in front of the selective reduction catalyst 300. The mixing pipe 210 may be provided as a member in which the reducing agent dosing module 10 can be mounted on the exhaust pipe 200, and the reducing agent injected from the reducing agent dosing module 10 through communication with the exhaust pipe 200 is exhausted. It may be introduced into the pipe 200.

In exemplary embodiments, the mixing pipe 210 is welded to the outer circumferential surface of the curved portion 206 of the exhaust pipe 200 so as to be fixed from the curved portion 206 of the exhaust pipe 200 toward the outlet 204. I can. A flow of the exhaust gas is formed from the curved portion 206 of the exhaust pipe 200 toward the outlet 204. The reducing agent is injected in the flow direction of the exhaust gas so that the nitrogen oxide in the exhaust gas and the reducing agent act in the same direction, so that a selective catalytic reduction reaction may be further promoted.

The reducing agent dosing module 10 may include substantially the same components as the reducing agent dosing module described with reference to FIGS. 1 to 4. Therefore, the same components are denoted by the same reference numerals, and repeated descriptions of the same components are omitted.

In the reducing agent dosing module 10, the reducing agent is injected in the flow direction of the exhaust gas, and the selective reduction catalyst 300 uses the reducing agent to reduce nitrogen oxides contained in the exhaust gas, based on EM (emission). Etc. can be satisfied.

Although the above has been described with reference to embodiments of the present invention, those skilled in the art will be able to variously modify and change the present invention without departing from the spirit and scope of the present invention described in the following claims. You will understand that you can.

100: injector 106: nozzle tip
108: spray surface 110: gasket
120: adapter 130: plate
200: exhaust pipe 210: mixing pipe
300: selective reduction catalyst 400: diesel oxidation catalyst

Claims (10)

An injector having a nozzle tip for injecting a reducing agent and having an injection surface on which the nozzle tip is installed;
A gasket positioned between the mounting end of the mixing pipe communicated with the exhaust pipe and the injection surface of the injector to prevent the outflow of exhaust gas; And
Interposed between the gasket and the injection surface of the injector or between the gasket and the mounting end of the mixing pipe to provide a surface pressure to one surface of the gasket, and the injection surface of the injector by a predetermined distance from the mixing pipe Includes an adapter for spacing,
The adapter has a shape corresponding to the gasket,
The adapter includes an adapter injection hole at a position corresponding to the nozzle tip,
The nozzle tip is formed to protrude from the injection surface of the injector, and a part of the nozzle tip is inserted into the adapter injection hole to cool the nozzle tip through the adapter. delete The reducing agent dosing module according to claim 1, wherein the gasket has a second thickness less than the first thickness of the adapter. delete delete The injector according to claim 1, wherein the injector, the adapter, and the gasket are respectively inserted into and fastened to the adapter fastening holes of the adapter, the gasket fastening holes of the gasket, and the mounting end fastening holes of the mixing pipe. A reducing agent dosing module, characterized in that the assembly. 7. A plate according to any one of claims 1, 3 and 6, wherein when the adapter is interposed between the gasket and the mounting end of the mixing pipe, a plate is further provided between the gasket and the injection surface of the injector. Reducing agent dosing module comprising a. The method according to any one of claims 1, 3 and 6, wherein when the adapter is interposed between the gasket and the mounting end of the mixing pipe, the adapter protrudes from the mounting end of the mixing pipe. Reducing agent dosing module, characterized in that it has a shape. The method according to any one of claims 1, 3 and 6, wherein the exhaust pipe is
An inlet through which the exhaust gas is introduced;
An outlet through which the exhaust gas flows; And
And a curved portion connecting the inlet and the outlet and having a curvature,
The mixing pipe is a reducing agent dosing module, characterized in that formed outside the curved portion of the exhaust pipe so as to face the outlet from the curved portion. An exhaust pipe provided with a selective reduction catalyst and for discharging exhaust gas;
A mixing pipe extending outward from the exhaust pipe in front of the selective reduction catalyst; And
A reducing agent dosing module installed at the mounting end of the mixing pipe and injecting a reducing agent into the exhaust pipe through the mixing pipe,
The reducing agent dosing module
An injector having a nozzle tip for injecting the reducing agent and having an injection surface on which the nozzle tip is installed;
A gasket positioned between the mounting end of the mixing pipe and the injection surface of the injector to prevent leakage of the exhaust gas; And
Interposed between the gasket and the injection surface of the injector or between the gasket and the mounting end of the mixing pipe to provide a surface pressure to one surface of the gasket, and a predetermined distance from the mixing pipe of the injection surface of the injector Includes an adapter for spaced apart,
The adapter has a shape corresponding to the gasket,
The adapter includes an adapter injection hole at a position corresponding to the nozzle tip,
The nozzle tip is formed to protrude from the injection surface of the injector, and a part of the nozzle tip is inserted into the adapter injection hole to cool the nozzle tip through the adapter.

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