DE102015218182A1 - Reductant supply device and injector - Google Patents

Abstract

(Problem) A reducing agent supply apparatus and an injection nozzle are to be provided in which the injection holes after reduction control, which takes place after decommissioning of an internal combustion engine, are not clogged by crystallized urea water solution. (Means for Solving the Problem) A reducing agent supply apparatus which injects with a pump, which absorbs the pressure reducing agent contained in the storage container and under pressure, an injection nozzle, which injects the said, under pressure promoted reducing agent into the exhaust passage of an internal combustion engine, and from a nozzle body and a liquid droplet guide member disposed in an area where, when the tip of said nozzle body is axially coincident with said plate, and which are close to one another, there is a plate arranged at the tip of the nozzle body and provided with at least one injection hole is arranged on said plate or connected to said plate is provided.

Description

(Technical field)

The invention relates to a Reduktionsmittelzuführgerät for injecting a reducing agent in the exhaust passage of an internal combustion engine and an injection nozzle, which is used for such a Reduktionsmittelzuführgerät. (Background Art)

An exhaust gas from an in-vehicle combustion engine such as a diesel engine contains NOx (nitrogen oxides). As a device for purifying the exhaust gas, the urea-SCR (Selective Catalytic Reduction) system is used in practice, which Nox by reduction in nitrogen, water vapor u.a. disassembled. In the urea SCR system, urea water solution is used as the reducing agent, and NOx in the exhaust gas is decomposed by reaction with ammonia.

Such urea SCR system comprises a selective reduction catalyst disposed in the exhaust passage and a reductant supply device which injects the urea water solution into the exhaust passage at the upper reaches of the selective reduction catalyst. The selective catalyst has the function of adsorbing ammonia generated by decomposing the urea water solution and promoting the reduction reaction of NOx in the inflowing exhaust gas with ammonia. The reducing agent supply means includes a pump that pressurizes the urea water solution stored in the storage tank, an injection valve that injects the urea water solution supplied by the pump, and a controller that controls the pump and the injection valve.

Urea water solution used in the urea-SCR system has different freezing temperatures depending on their concentration. But their lowest freezing temperature is about -11 ° C. If the urea water solution freezes during parking, so that the volume grows, the pump, the injection valve or the pipe through which the urea water solution flows, can be damaged. Therefore, with the internal combustion engine remaining, the urea water solution remaining in the apparatus is returned to the storage tank. The recirculated urea water solution is filled again at the next start of the engine in the device.

(Citations)

(Patent Documents)

• (Patent Document 1) Japanese Laid-Open Patent Application 2014-012992

(Overview of the invention)

(Technical tasks to be solved)

At the tip of the injection valve, a plate is provided, which is provided with injection holes. When urea water solution is injected through the injector, liquid drops may adhere to the plate. During operation of the internal combustion engine, the exhaust passage or the exhaust pipe is heated to a temperature of 200 ° C or above, and also the tip of the injection valve is hot. However, while controlling the injection of the urea solution, the urea water solution maintained at a relatively low temperature serves as the cooling center, and it removes the heat of the plate upon injection. In addition, the liquid urea water solution adheres to the plate with each injection, so that virtually no crystallization of the urea water solution comes.

But in the recycling of the urea water solution, no new liquid drops of the liquid urea water solution are formed. In addition, immediately after stopping the engine, the tip of the injection valve is still hot, and the injection of the urea water solution, which can serve as a coolant, is stopped. Therefore, the urea water solution, which adheres to the plate when it is returned, may crystallize during the stoppage of the injection. When the urea water solution adhered to the plate crystallizes, the injection holes arranged in the plate become clogged. This would mean that it may take a long time until the urea water solution is allowed to be injected the next time the internal combustion engine starts up.

The present invention has been made in view of the above problem, and has an object to provide a reducing agent supply apparatus and an injection nozzle in which the injection holes are not clogged by the urea water solution crystallization after recycling the urea water solution.

(Means to solve the tasks)

In order to achieve the above object, according to one aspect of the present invention, there is provided a reducing agent supply apparatus which injects with a pump which absorbs the reducing agent contained in the storage container and delivers pressure, an injection nozzle which injects said pressure-promoted reducing agent into the exhaust passage of an internal combustion engine , and a nozzle body, arranged at the tip of the nozzle body, provided with at least one injection hole plate, and a liquid droplet guide part, which in a region is arranged, in which, it is seen, the tip of said nozzle body in the axial direction coincides with said plate, and which is arranged close to said plate or connected to said plate is provided.

The liquid droplet guide member may be arranged at least lower in the direction of gravity than the center of said plate.

Said liquid-droplet guide member may be disposed in a region where, when the tip of said nozzle body in the axial direction is seen, it does not coincide with said injection hole.

There may be provided a plurality of said liquid droplet guide members.

Said liquid droplet guide member may substantially comprise a circular disk provided with an opening having a diameter smaller than the diameter of said plate.

The outer periphery of the tip of said injector may be provided with a seal and said liquid droplet guide member forming part of said seal.

The outer periphery of the tip of said injector may be provided with a seal and said liquid droplet guide member may be attached to said seal.

The liquid droplet guide member may be a protrusion formed on the plate.

The liquid droplet guide member may be attached to the plate.

The liquid droplet guide member may be attached to the nozzle body,

In order to achieve the object, according to another aspect of the present invention, there is provided an injection nozzle for injecting the reducing agent into the exhaust passage and provided with a nozzle body, a plate disposed at the tip of said nozzle body, and at least one injection hole and a liquid droplet guide member disposed in a region where, when the tip of said nozzle body is axially coincident with said plate, and disposed close to said plate or connected to said plate , Effect of the Invention

As explained above, according to the present invention, it is possible to prevent the injection holes from being clogged by the crystallization of the urea water solution after the recirculation of the urea water solution takes place when the internal combustion engine is stopped. (Brief description of the drawings)

( 1 A schematic representation of the entire SCR system provided with a reductant supply apparatus according to the embodiment of the present invention.

( 2 ) Section and front view of a construction example of the tip portion of an injection nozzle according to the same embodiment.

( 3 ) Sketch showing how the urea water solution is injected from an injector provided with a liquid-droplet guide member.

( 4 ) Sketch showing how urea water solution adheres to the outer surface of the plate.

( 5 ) Sketch showing the urea water solution crystallized on the plate.

( 6 ) Sketch showing how urea water solution adheres to the tip of an injector provided with a liquid droplet guide member.

( 7 ) Sketch showing how the urea water solution moves into the liquid drop guide part.

( 8th ) Sketch showing the urea water solution crystallized on the liquid drop guide part.

( 9 ) Section and front view of a construction example of the tip region of an injection nozzle according to variant 1.

( 10 ) Sketch showing the urea water solution crystallized on the liquid drop guide part according to Variant 1.

( 11 ) Section and front view of a construction example of the tip region of an injection nozzle according to variant 2.

( 12 ) Section and front view of a construction example of the tip region of an injection nozzle according to variant 3.

( 13 ) Section and front view of a construction example of the tip region of an injection nozzle according to variant 4.

( 14 ) Section and front view of another construction example of the tip portion of an injection nozzle according to variant 4.

( 15 ) Section and front view of a construction example of the tip region of an injection nozzle according to variant 5.

( 16 ) Section of another construction example of the tip region of an injection nozzle according to variant 5.

( 17 ) Section of another construction example of the tip region of an injection nozzle according to variant 6.

(Embodiments of the invention)

Hereinafter, advantageous embodiments of the present invention will be explained with reference to the accompanying drawings. Devices having substantially the same functions are given the same reference numerals throughout the specification and drawings to avoid repetition.

(1. An Exemplary Overall Structure of the SCR System)

First, based on the 1 an exemplary overall design of the urea SCR system 10 with a reducing agent supply device 20 is provided according to the embodiment of the present invention will be explained. 1 is a schematic representation of the urea SCR system 10 , The urea SCR system 10 is with a reduction catalyst 13 and a reducing agent supply device 20 Mistake. The urea SCR system 10 is also with a control unit 100 provided that the the Reduktionsmittelzuführgerät 20 controlling controls.

The urea SCR system 10 is a system that reduces and decomposes Nox in the exhaust gas by means of urea water solution as a reducing agent. For example, urea water solution may have a urea concentration of 32.5% at which the freezing temperature is lowest. The freezing temperature is approx. -11 ° C.

The reduction catalyst 13 is at a point of the combustion engine 5 connected exhaust pipe 11 arranged, and has the function in the exhaust gas from the internal combustion engine 5 selectively reduce Nox. In the present embodiment, ammonia, which is formed by decomposing the urea water solution injected from the reducing agent supply device, from the reduction catalyst 13 Adsorbed, and Nox, in the reduction catalyst 13 inflowing exhaust gas is selectively reduced by ammonia.

Reduktionsmittelzuführgerät 20 urea water solution injects as reducing agent into the exhaust pipe 11 at the point at the upper run of the reduction catalyst 13 lies. The injection amount of the urea water solution is determined by the concentration of nitrogen oxides contained in the exhaust gas and that of the reduction catalyst 13 adsorbable amount of ammonia, etc. regulated so that no nitrogen oxides or ammonia at the lower reaches of the reduction catalyst 13 leak ..

In the exhaust pipe 11 is at the upper reaches of the reducing agent supply device 13 a temperature sensor 15 attached to determine the exhaust gas temperature. The exhaust gas temperature by means of the temperature sensor 15 is also determined to estimate the temperature at the reduction catalyst 13 used. However, the position of the temperature sensor becomes 15 not limited to those in this example. In addition, in the exhaust pipe 11 except the temperature sensor 15 also a NOx concentration sensor, ammonia concentration sensor or the like which are not shown here, be arranged.

(2nd Construction Example of Reductant Supply Device)

Then, an exemplary overall structure of the reducing agent supply apparatus is to be described 20 be explained. Like in the 1 shown is the reductant delivery device 20 with an injection valve 31 at the upper reaches of the reduction catalyst 13 at the exhaust pipe 11 is attached, and a pump module 40 which is a pump 41 containing the urea water solution from the storage tank 50 to the injection valve 31 promotes, contains, provides.

The injection valve 31 and the pump module 40 are via the first supply channel 57 connected. The first supply channel 57 is with a pressure sensor 43 for determining the pressure of the injection valve 31 provided urea water solution supplied. The storage tank 50 and the pump module 40 are via the second supply channel 58 connected. The pump module 40 and the storage tank 50 are also via the circulation channel 59 connected. The circulation channel 59 branches from the first supply channel 57 off, and to the storage tank 50 connected. The circulation channel 59 is in one place with a shutter 45 Mistake. The aperture 45 on the one hand receives the pressure in the first supply channel 57 upright, on the other hand, has the function of superfluous urea water solution on the side of the storage tank 50 pass.

The pump 41 in the pump module 40 is installed, for example, is an electric diaphragm pump or a motor pump. The performance of the pump 41 is with the control signal from the controller 100 controlled. In the present embodiment, the controller controls 100 the power of the pump 41 by feedback so that the basis of the pressure sensor 43 determined pressure of the urea water solution is maintained at the setpoint.

As injector 31 For example, a solenoid injector that is opened and closed by turn-on control is used. Such an injection valve 31 has an actuator including a coil which moves the valve body by the magnetic force generated by energizing the coil, and the valve opens. As described above, the pressure of the injection valve 31 supplied urea water solution kept at a certain height, and the control unit 100 regulates the valve opening time according to the target injection quantity of the urea water solution.

The pump module 40 is with a flow path switching valve 71 Mistake. The flow path switching valve 71 Switches the flow direction of the urea water solution coming from the pump 41 is promoted with pressure. As the urea water solution is injected into the exhaust passage, the flow path switching valve shifts 71 so that the urea water solution from the side of the storage tank 50 to the side of the injection valve 31 , In the process, the inlet opening of the pump becomes 41 with the second supply channel 58 connected, and the outlet opening of the pump 41 comes with the first supply channel 57 connected. When returning the urea water solution to the storage tank 50 switches the flow path switching valve 71 so that the urea water solution from the side of the injector 31 to the side of the storage tank 50 flows. In the process, the inlet opening of the pump becomes 41 with the first supply channel 57 connected, and the opening of the pump 41 is connected to the second supply channel 58 connected.

However, the method is to return the urea water solution to the storage tank 50 is not limited to the method in which the switching of the flow path by means of a flow path switching valve 71 he follows. For the return of urea water solution can be used as a pump 41 use a reversible in their conveying direction pump. Or provide a special channel for the recirculation of the urea water solution, which is equipped with a pump for controlling urea water solution recirculation.

The reducing agent supply device 20 according to the embodiment is further provided with a first cooling water channel 85 and a second cooling water channel 87 , which are designed so that the cooling water for the internal combustion engine 5 circulate. The first cooling water channel 85 and the second cooling water channel 87 branches off the cooling water channel 86 , in the combustion engine 5 provided engine cooling unit 60 off, and come wierder in the cooling water channel 86 together. The first cooling water channel 85 is through the interior of the storage tank 50 guided. The second cooling water channel 87 becomes the injection valve 31 guided around. In the first cooling water channel 85 , at the underflow of the branch point from the cooling water channel 87 is a switching valve 81 angerdnet. The switching valve 81 is through the control unit 100 switched to the opening / closing of the first cooling water channel 85 to effect.

In addition, heaters such as an electric heater can defrost the frozen urea water solution at appropriate locations in the pump module 40 , in the first supply channel 57 or in the second supply channel 58 be arranged.

(3rd construction example of the injector)

Now, the structure of the Reduktionsmittelzuführgerät 20 built-in injector 31 explained in more detail. As in 1 shown is the injector 31 in the present embodiment at the end of the exhaust pipe 11 attached branch pipe 12 attached. Here is the injector 31 via a seal on the branch pipe 12 attached to avoid the actuator of the injector 31 by heat transfer via the branch pipe 12 and exhaust heat in the exhaust duct is damaged.

2 shows the tip area of the injector 31 enlarged in section and in front view. In the present embodiment, the injection valve is 31 in a cooling housing 39 having a cooling water passage (not shown) forming part of the second cooling water passage 87 forms, accommodates and fixes. During operation of the internal combustion engine 5 circulates the cooling water for the internal combustion engine 5 inside the cooling water housing 39 to prevent overheating of the injector.

The injection valve 31 has a cylindrical nozzle body 33 on, and at the top of the nozzle body 33 is a plate 37 attached, with at least one injection hole 37a is provided. In the 2 shown plate 37 has 3 Injection holes 37a on. In the nozzle body 33 are a valve body whose forward and backward movement is controlled by means of an actuator, and a valve seat against which the valve body rests arranged. While the valve body is separated from the valve seat, urea water solution becomes through the injection holes 37a injected, and while the valve body rests against the valve seat, the injection is the Urea water solution stopped. In 2 the actuator, the valve body and the valve seat are not shown.

At the injection valve 31 and at the top of the cooling housing 39 is a seal 35 intended. The seal 35 reduces the heat transfer to the injection valve 31 and to the cooling housing 39 , and suppresses the intrusion of exhaust particles into the gap between the injection valve 31 and the cooling housing 39 , The seal 35 has an opening 35a on, the size of the outer diameter of the nozzle body 33 roughly equivalent. The edge of the opening 35a is in the direction of the injection valve 31 bent and receding. The position of the tip of the nozzle body 33 essentially corresponds to the position of the edge of the opening 35a the seal 35 , This largely prevents the nozzle body 33 the exhaust heat is exposed directly.

In the present embodiment, at the end of the injection valve 31 Liquid droplets guide parts 110a . 110b attached, which is close to the outer surface of the plate 37 lie. These liquid droplet guide parts 110a . 110b lead after stopping the internal combustion engine 5 the on the outside surface of the plate 37 adhering urea water solution, so that their accumulation on the plate 37 is prevented. This clogging of the injection holes 37a is suppressed by crystallized urea water solution. The leading edges of the liquid droplet guide parts 110a . 110b not only close to the plate 37 lie, but they can also be attached to it.

In the present embodiment, the liquid droplet guide members are 110a . 110b by expanding a part of the gasket 35 in the direction of the inner diameter of the nozzle body 33 educated. A liquid drop guide part 110a is above the middle of the plate 37 arranged in the direction of gravity, while the other liquid droplet guide part 110b below the middle of the plate 37 arranged in the direction of gravity. The liquid drop guide parts 110a . 110b can also be in position, neither above nor below the middle of the plate 37 be arranged in the direction of gravity. However, because of the plate 37 sticking liquid droplets down in the direction of gravity, it is advantageous to the liquid droplet guide parts 110a . 110b at least below the middle of the plate 37 to arrange in the direction of gravity.

In order to prevent the spray of the urea water solution from being greatly prevented during the control of the urea water solution injection, the liquid droplet guide parts become 110a . 110b arranged so that, this one sees the tip of the nozzle body 33 in the axial direction, not with the injection holes 37a coincide. For example, as in 3 shown when urea water solution U from the injector 31 is injected, the spraying of the urea water solution U is not through the liquid droplet guide parts 110a . 110b prevented. In addition, can be by this arrangement of the liquid droplet guide parts 110a . 110b largely prevent crystallization on the liquid droplet guide parts 110a . 110b Adhesive urea water solution injection holes 37a be clogged. The width of the liquid droplet guide parts 110a . 110b will be set in a proper way.

The following is intended to explain how the clogging of the injectors 37a through the liquid droplet guide parts 110a . 110b is suppressed. First, it will be explained how the urea water solution crystallizes when no liquid drop guide part is provided. Subsequently, the crystallization of the urea water solution is divided with the liquid droplet guide present 110a . 110b explained.

4 and 5 show the tip area of the injector 31 in which no liquid droplet guide member is provided increases in section. When no liquid droplet guide member is provided, liquid droplets accumulate the urea water solution after the injection control of the urea water solution on the plate is stopped 37 liable, as in 4 shown at the plate 37 at. The urea water solution will change over time, as in 5 shown at the plate 37 crystallize, and the crystals C of the urea water solution become the injection holes 37a clog. This will cause the injection of urea water solution at the next start of the engine 5 can not start immediately.

6 - 8th are sketches that show how the urea water solution at the top of the injector 31 looks when the injection control of urea water solution with the engine stopped 5 is stopped. When the injection control of urea water solution is stopped, as in 6 shown, liquid drops of urea water solution U on the outer surface of the plate 37 be liable. As close to the plate 37 Liquid droplets guide parts 110a . 110b are provided, which is on the outer surface of the plate 37 adherent urea water solution U not on the plate 37 but via the liquid droplet guide parts 110a . 110b flow. With the internal combustion engine stationary 5 are the liquid droplet guide parts 110a . 110b hot so that the urea water solution on the liquid droplet guide parts 110a . 110b can be crystallized in a very short time.

As in 7 As the crystals C of the urea water solution U can easily absorb the liquid urea water solution U, the urea water solution U moves on the plate 37 continuing in the direction of liquid droplet guide parts 110a . 110b , This movement and the crystallization of the urea water solution U are repeated, and the urea water solution U on the plate 37 moves within a short time in the liquid droplet guide parts 110a . 110b , In this way, as in 8th shown, the crystals C wake up to the liquid droplet guide parts 110a . 110b and at the seal 35 ,

After the next startup of the internal combustion engine 5 When the injection control of urea water solution starts, the crystals of the urea water solution melt on the liquid droplet guide parts 110a . 110b and at the seal 35 through the liquid urea water solution. Therefore, it is not that the crystals of the urea water solution grow permanently; rather, as described above, each time the injection control of urea water solution is stopped, it stops at the plate 37 Adhesive urea water solution on the liquid droplet guide parts 110a . 110b and at the seal 35 be crystallized. Therefore, even after stopping the injection control of urea water solution, urea water solution is allowed in the tip portion of the injector 31 remains, the clogging of injection holes 37a prevent by the crystals C of the urea water solution.

(4. Variants of liquid droplet guide parts)

Above, the liquid droplet guide parts became 110a . 110b of the injection valve 31 explained according to the present embodiment. The liquid drop guide parts 110a . 110b can be changed into different forms. In the following, variants of the liquid droplet guide parts will be explained.

(4.1 Variant 1)

9 and 10 are sketches that are a liquid drop guide part 120 according to variant 1 show. 9 shows the tip area of the injector 31 enlarged in section and in front view. 10 is a sketch showing how the urea water solution on the liquid drop guiding part 120 crystallized. While the in 2 shown liquid droplet guide parts 110a . 110b by expanding a part of the gasket 35 are formed, there is the liquid droplet guide member 120 according to variant 1 of a component other than the seal 35 which with the seal 35 connected is.

Such a liquid droplet guide member 120 is a rod-shaped liquid droplet guide member 120 that with the seal 35 connected is. An end of such a liquid droplet guide member 120 is in the direction of injector 31 bent, and close to the plate 37 arranged. The liquid drop guide part 120 is lower in the direction of gravity than the center of the plate 37 angordnet. The liquid drop guide part 120 according to variant 1 is also arranged so that it is not with the injection holes 37a coincides.

The type of connection of the liquid droplet guide part 120 with the seal 35 is not particularly limited. Thus, the liquid drop guiding part can 120 for example, by welding or by means of a heat-resistant adhesive with the seal 35 get connected. In 9 is only a liquid droplet guide part 120 provided, but there may also be more liquid droplet guide parts 120 be provided. The width of the liquid droplet guide parts 110a . 110b can be adjusted in a proper way.

Also in the liquid droplet guide part 120 the liquid drops move after stopping the injection control of urea water solution on the plate 37 arise over the liquid droplet guide member 120 , and become on the liquid drop guiding part 120 and crystallized at the seal. In this way, it is possible to prevent the urea water solution from crystallizing on the plate and the injection holes 37a clogged.

(4.2 Variant 2)

11 is a sketch showing a liquid drop guide part 130 according to variant 2 shows. 11 shows the tip area of the injector 31 enlarged in section and in front view. Such a liquid droplet guide member 130 essentially consists of a round disc, with an opening 130a with a diameter smaller than the diameter of the plate 37 is, is provided. The liquid drop guide part 130 is in the radially outer area with the seal 35 connected. The edge of the opening 130a is in the direction of the plate 37 bent and receding. The marginal edge of the opening of the seal 35 is close to the plate 37 arranged. The liquid drop guide part 130 is so arranged that this is not with the injection holes 37a coincides.

Also the type of connection of the liquid droplet guide part 130 according to variant 2 with the seal 35 is not particularly limited. Thus, the liquid drop guiding part can 130 by welding or by means of a heat-resistant adhesive with the seal 35 get connected. Also with the liquid drop guide part 130 According to variant 2, it is possible to prevent the urea water solution from crystallizing on the plate after stopping the spray control of urea water solution, and the injection holes 37a congested

(4.3, variant 3)

12 is a sketch showing a liquid drop guide part 140 according to variant 3 shows. 12 shows the tip area of the injector 31 enlarged in section and in front view. Such a liquid droplet guide member 140 consists of a rod-shaped component, which is attached to the plate 37 is attached, and in the from the plate 37 stretching away. The liquid drop guide part 140 can be perpendicular to the outer surface of the plate 37 be arranged, or arranged inclined vertically downwards.

Such a liquid droplet guide member 140 is on one of the injection holes 37a remote location to the plate 37 attached. It is preferable that the liquid drop guide part 140 in the direction of gravity lower than the middle of the plate 37 to the plate 37 to fix. The rod-shaped liquid droplet guide member 140 according to variant 3 does not need to be a single piece; It can also be several rod-shaped liquid droplet guide part 140 be provided.

Also the type of connection of the liquid droplet guide part 140 according to variant 3 with the plate 37 is not particularly limited. Thus, the liquid drop guiding part can 140 by welding or by means of a heat-resistant adhesive to the plate 37 get connected. Also with the liquid drop guide part 140 According to variant 3 can be prevented that the urea water solution after stopping the spray control of urea water solution on the plate 37 crystallized, and the injection holes 37a congested

(4.4, variant 4)

13 and 14 are sketches, the liquid droplet guide parts 150 . 160 according to variant 4 show. 13 and 14 show the tip area of the injector 31 enlarged in section and in front view. While the liquid droplet guide part 140 according to variant 3 from one of the plate 37 independent, rod-shaped component, and to the plate 37 is attached, have the liquid droplet guide parts 150 . 160 according to variant 4 projections, which by deforming the plate 37 were formed.

While that in 13 shown liquid droplet guide part 150 is a relatively high columnar protrusion, that is in 14 shown liquid droplet guide part 160 a relatively low, and relatively large projection. Such liquid droplet guide parts 150 . 160 For example, they can be formed by pressing.

Also such liquid droplet guide parts 150 . 160 is advantageously on one of the middle of the plate 37 attached remote location, and it is advantageous, the liquid droplet guide parts in the direction of gravity lower than the center of the plate 37 to arrange. The liquid droplet guide member consisting of a protrusion 150 respectively. 160 does not need to be a single piece; it is also possible to provide a plurality of liquid droplet guide parts. Also by the liquid droplet guide part 150 According to variant 4 can be prevented that the urea water solution after stopping the spray control of urea water solution on the plate 37 crystallized, and the injection holes 37a clogged.

(4.5th variant 5)

15 is a sketch showing a liquid drop guide part 170 according to variant 5 show5. 15 show5 the tip area of the injector 31 enlarged in section and in front view. While the liquid droplet guide parts 110a . 110b according to the above embodiment and the liquid droplet guide parts 120 . 130 according to variant 1 or 2, a part of the seal 35 are, or to the seal 35 are attached, and the liquid droplet guide parts 140 . 150 . 160 according to variant 3 or 4 to the plate 37 are fixed, or a part of the plate 37 form, is the liquid droplet guide member 170 according to variant 5 attached to the cooling housing.

The liquid drop guide part 170 consists of a rod-shaped component, one end of which with the cooling housing 39 while the other end is close to the plate 37 is arranged. Such a liquid droplet guide member 170 is arranged so that it does not coincide with the injection holes. It is preferable that the liquid drop guide part 170 in the direction of gravity lower than the middle of the plate 37 close to the plate 37 to arrange. The liquid drop guide part 170 does not need to be a single piece; It can also be provided several pieces.

In the example in 15 is the cooling housing 39 about a seal 35 attached, but the liquid drop guiding part 190 can, as in 16 shown, even without seal with the cooling housing 39 get connected. Also the type of connection of the liquid droplet guide parts 170 . 190 with the cooling housing 39 is not special limited. Thus, the liquid droplet guide parts 170 . 190 by welding or by means of a heat-resistant adhesive to the cooling housing 39 get connected.

Also with the liquid droplet guide parts 170 . 190 According to variant 5 can be prevented that the urea water solution after stopping the spray control of urea water solution on the plate 37 crystallized, and injection holes 37a congested

(4.6 variant 6)

17 shows a liquid droplet guide member 180 according to variant 6 in section. The liquid drop guide part 180 according to variant 6 is with the nozzle body 33 connected and attached. Such a liquid droplet guide member 180 can be used for example for a Reduktionsmittelzuführgerät, in which a flow control valve o.ä. is arranged to Regelg the spray rate of urea water solution outside the exhaust pipe, and the nozzle body 33 is inserted into the exhaust pipe.

The liquid drop guide part 180 according to variant 6 is at one end to the outer periphery of the nozzle body 33 connected, and the other end is close to the outer surface of the plate 37 arranged. Such a liquid droplet guide member 180 is arranged so that it does not coincide with the injection holes. It is preferable that the liquid drop guide part 180 in the direction of gravity lower than the middle of the plate 37 close to the plate 37 to arrange. Such a liquid droplet guide member 180 does not need to be a single piece; It can also be provided several pieces.

Also the type of connection of the liquid droplet guide part 180 according to variant 6 with the nozzle body 33 is not particularly limited. Thus, the liquid drop guiding part can 180 by welding or by means of a heat-resistant adhesive with the nozzle body 33 get connected. Also with the liquid drop guide part 180 According to variant 6 can be prevented that the urea water solution after stopping the spray control of urea water solution on the plate 37 crystallized, and the injection holes 37a congested

As discussed above, the reductant delivery device is 20 according to the present embodiment with liquid droplet guide parts 110a . 110b . 120 . 130 . 140 . 150 . 160 . 170 . 180 . 190 provided close to that in the tip region of the nozzle body 33 urea water solution injecting injector mounted plate 37 , or to this plate 37 subsequently, is arranged. This makes it possible for liquid drops that stop when controlling the injection of urea water solution on the outer surface of the plate 37 arise over the liquid droplet guide parts 110a . 110b . 120 . 130 . 140 . 150 . 160 . 170 . 180 . 190 flow, and in places, the injector 37a do not cover, crystallize. Therefore, the injection control of urea water solution at the next startup of the internal combustion engine 5 be started immediately.

In the above, advantageous embodiments of the present invention have been explained in detail with reference to the accompanying drawings. But the present invention is not limited to these examples. For a person skilled in the art who has general knowledge of the technical field to which the present invention pertains, it is obvious that various modifications or modifications will and should be made within the category of the technical ideas stated in the patent claims It is understood that these changes and modifications are, of course, within the technical scope of the present invention.

LIST OF REFERENCE NUMBERS

5

 internal combustion engine

10

 Urea SCR system

11

 exhaust pipe

12

 branch pipe

13

 reduction catalyst

20

 Reduktionsmittelzuführgerät

31

 Injector

33

 nozzle body

35

 poetry

37

 plate

37a

 Injection hole

39

 cooling housing

40

 pump module

41

 pump

43

 pressure sensor

50

 storage container

71

 Fließwegumschaltventil

100

 control unit

110a, 110b

 Liquid droplets guide parts

120, 130, 140, 150, 160, 170, 180, 190

 Liquid droplets guide parts

U

 Urea solution

C

 crystal

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• JP 2014-012992 [0005]

Claims (11)

 A reducing agent supply apparatus which sucks with a pump, which absorbs the reducing agent contained in the storage container and pressure, an injection nozzle which injects said pressure-promoted reducing agent into the exhaust passage of an internal combustion engine, and arranged from a nozzle body and at the tip of the nozzle body , having at least one injection hole provided plate, and a liquid droplet guide member, which is disposed in a region in which, when the tip of said nozzle body in the axial direction coincides with the said plate, and which is arranged close to said plate or on the said plate is connected.  A reducing agent supply apparatus according to claim 1, wherein said liquid drop guiding part is arranged in the direction of gravity at least lower than the center of said plate. A reducing agent supply apparatus according to claim 1 or 2, wherein said liquid drop guide member is disposed in an area where, when the tip of said nozzle body in the axial direction is seen, it does not coincide with said injection hole.  A reducing agent supply apparatus according to any one of claims 1 to 3, wherein a plurality of said liquid droplet guide members are provided.  A reducing agent supply apparatus according to any one of claims 1 to 3, wherein said liquid drop guiding member substantially comprises a circular disk provided with an opening having a diameter smaller than the diameter of said plate.  A reducing agent supply apparatus according to any one of claims 1 to 5, wherein the outer periphery of the tip of said injector is provided with a seal, and said liquid droplet guide member forms part of said seal.  A reducing agent supply apparatus according to any one of claims 1 to 5, wherein the outer periphery of the tip of said injection nozzle is provided with a seal, and said liquid drop guiding member is fixed to said gasket.  A reducing agent supply apparatus according to any one of claims 1 to 5, wherein said liquid drop guiding member is a projection formed on the plate.  A reducing agent supply apparatus according to any one of claims 1 to 5, wherein said liquid drop guiding member is fixed to the plate.  A reducing agent supply apparatus according to any one of claims 1 to 5, wherein said liquid drop guiding member is fixed to the nozzle body.  An injection nozzle for injecting the reducing agent into the exhaust passage and having a nozzle body, a plate disposed at the tip of said nozzle body and provided with at least one injection hole, and a liquid droplet guide portion disposed in a region, in which it is seen, the tip of said nozzle body in the axial direction, coincides with said plate, and is arranged close to said plate or connected to said plate is provided.

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