DE112017002822T5 - Integrated device, exhaust aftertreatment system and control method - Google Patents

Abstract

An integrated device (1) is provided which comprises a pump and a nozzle. The integrated device comprises: a pump assembly (18) and a nozzle assembly (19). The pump assembly (18) has a receptacle (322) for receiving the nozzle assembly (19), a pump assembly housing (180) and a pump (11). The pump assembly housing (180) has an inlet channel (15) and an outlet channel (16). The outlet channel (16) communicates with the nozzle assembly (19). The pump assembly (18) comprises: a shell (2); a motor coil (111) for driving the pump (11); a magnetic body (72); a first gear arrangement (74); and a second gear assembly (75). The first gear assembly (74) and the second gear assembly (75) mesh with each other. The nozzle assembly (19) includes a nozzle assembly housing (190) and a nozzle (12). The nozzle assembly (19) further includes a nozzle spool (121) for driving the nozzle (12). The integrated device (1) is further provided with a pressure sensor (172). The pressure sensor (172) does not have its own housing. The sheath (2) serves as a housing of the pressure sensor (172). The integrated device has a simple and compact structure and allows the realization of the reduction of the device. Furthermore, an exhaust aftertreatment system and a control method are disclosed.

Description

The present application claims priority to the Chinese patent application filed on Jun. 6, 2016, with the application number 201610392925.4 and the title of the invention, "Integrated Device, Exhaust Gas Aftertreatment System, and Control Method", the contents of which are incorporated herein by reference in their entirety.

Technical area

The present invention relates to an integrated device, an exhaust aftertreatment system and a control method that fall within the technical field of engine exhaust aftertreatment.

State of the art

Due to the increasingly stringent emission standards for vehicles with internal combustion engines is to reduce the emission of pollutants, such. As nitrogen oxides, conventionally selective catalytic reduction (SCR - Selective Catalytic Reduction) used as a post-treatment technology in the industry and urea solutions are injected into the exhaust gas upstream of the SCR. A urea solution is hydrolyzed and pyrolyzed to produce ammonia and reacts with nitrogen oxides to reduce pollutant concentration, etc.

At present, a commercially available urea injection system is usually an air assisted system or a non-air assisted system. Of course, both systems include a urea tank assembly, a pump supply unit connected to the urea tank assembly through a low-pressure pipe, a nozzle module connected to the pump supply unit through a high-pressure pipe, and a controller. The pump supply unit includes a urea pump, a pressure sensor, etc., and the nozzle module includes a urea nozzle, etc. The urea pump and the urea nozzle are spaced apart at a great distance and are interconnected by a urea tube. In addition, a conventional urea injection system includes a large number of components and is therefore difficult to install and expensive.

So urgently, a new technical solution must be provided.

Brief description of the present invention

An object of the present invention is to provide an integrated apparatus capable of realizing the downsizing of the apparatus, an exhaust aftertreatment system with the integrated apparatus, and a control method.

• eine integrierte Vorrichtung, die eine Pumpe und eine Düse umfasst, wobei die Pumpe zum Pumpen eines Fluidmediums zur Düse vorgesehen ist, die Düse zum Einspritzen des Fluidmediums in das Abgas des Motors vorgesehen ist, die integrierte Vorrichtung eine Pumpenanordnung und
• eine Düsenanordnung umfasst, wobei die Pumpenanordnung mit einem Aufnahmefach zur zumindest teilweisen Aufnahme der Düsenanordnung versehen ist; die Pumpenanordnung ein Pumpenanordnungsgehäuse umfasst und die Pumpe mit dem Pumpenanordnungsgehäuse zusammenpasst, das Pumpenanordnungsgehäuse einen Einlasskanal, der stromaufwärts der Pumpe positioniert ist und mit der Pumpe in Verbindung steht, und einen Auslasskanal, der stromabwärts der Pumpe positioniert ist und mit der Pumpe in Verbindung steht, umfasst, der Auslasskanal mit der Düsenanordnung in Verbindung steht, das Pumpenanordnungsgehäuse eine Ummantelung und ein erstes Gehäuse, das unterhalb der Ummantelung positioniert ist, umfasst, die Ummantelung mit einem Ummantelungshohlraum versehen ist und das erste Gehäuse mit einer Drucksensoraufnahmeöffnung versehen ist, die mit dem Aufnahmefach in Verbindung steht; die Pumpenanordnung eine Motorspule zum Antreiben der Pumpe, einen magnetischen Körper zum Zusammenwirken mit der Motorspule und eine erste Zahnradanordnung und eine zweite Zahnradanordnung, die miteinander kämmen, umfasst, die erste Zahnradanordnung eine erste Zahnradwelle und ein erstes Zahnrad umfasst, die zweite Zahnradanordnung eine zweite Zahnradwelle und ein zweites Zahnrad umfasst und das erste Zahnrad mit dem zweiten Zahnrad kämmt; die Düsenanordnung ein Düsenanordnungsgehäuse umfasst und
• die Düse mit dem Düsenanordnungsgehäuse zusammenpasst und die Düsenanordnung ferner eine Düsenspule zum Antreiben der Düse umfasst;
• die integrierte Vorrichtung ferner mit einem Drucksensor, der in der Drucksensoraufnahmeöffnung aufgenommen ist, versehen ist, der Drucksensor kein eigenes Gehäuse aufweist und die Ummantelung als Gehäuse für den Drucksensor dient.

In order to achieve the above object, the present invention employs the following technical solution:

• an integrated device comprising a pump and a nozzle, the pump being provided for pumping a fluid medium to the nozzle, the nozzle being provided for injecting the fluid medium into the exhaust gas of the engine, the integrated device comprising a pump assembly and
• a nozzle assembly comprises, wherein the pump assembly is provided with a receiving compartment for at least partially receiving the nozzle assembly; the pump assembly includes a pump assembly housing and the pump mates with the pump assembly housing, the pump assembly housing has an inlet channel positioned upstream of the pump and communicating with the pump, and an outlet channel positioned downstream of the pump and communicating with the pump; comprising, the outlet passage communicating with the nozzle assembly, the pump assembly housing comprises a casing and a first housing positioned below the casing, the casing is provided with a casing cavity, and the first casing is provided with a pressure sensor receiving opening communicating with the receptacle communicates; the pump assembly includes a motor coil for driving the pump, a magnetic body for cooperation with the motor coil, and a first gear assembly and a second gear assembly meshing with each other, the first gear assembly comprises a first gear shaft and a first gear, the second gear assembly comprises a second gear shaft and a second gear and the first gear meshes with the second gear; the nozzle assembly comprises a nozzle assembly housing and
• the nozzle mates with the nozzle assembly housing and the nozzle assembly further comprises a nozzle spool for driving the nozzle;
• the integrated device further comprising a pressure sensor mounted in the Pressure sensor receiving opening is added, is provided, the pressure sensor does not have its own housing and the sheath serves as a housing for the pressure sensor.

As an improved technical solution of the present invention, the pump is a urea pump, the nozzle is a urea nozzle and the fluid medium is a urea solution.

As an improved technical solution of the present invention, the pump is a fuel pump, the nozzle is a fuel nozzle and the fluid medium is a fuel.

As an improved technical solution of the present invention, the integrated device includes a controller connected to the motor coil and the nozzle coil, and the controller independently separately controls the urea pump and the urea nozzle.

As an improved technical solution of the present invention, the pressure sensor communicates with the exhaust passage and the integrated device further comprises an overflow element connected between the exhaust passage and the intake passage.

As an improved technical solution of the present invention, the pressure sensor comprises a base plate, a printed circuit board fixed to the base plate, a conductor wire connected to the printed circuit board, and a protective cover fixed to the printed circuit board, the base plate having a base A plate body portion and a convex portion extending downwardly from the plate body portion, a sealing ring is disposed on the convex portion, and the convex portion is provided with a through hole penetrating downwardly and extending upward through the plate body portion.

As an improved technical solution of the present invention, the circuit board is provided with a chip at the position corresponding to the passage opening, and the protective cover is attached to the periphery of the chip for protection of the chip.

As an improved technical solution of the present invention, the protective cover is provided with an opening communicating with the chip, and the opening communicates with the sheath cavity.

As an improved technical solution of the present invention, the pump assembly housing is provided with a connection plate assembly that mates with the first housing, the connection plate assembly includes a plate portion, and a metal cover fixed to the plate portion and protruding upward is the magnetic body in the metal cover and the motor coil is pushed onto the periphery of the metal cover.

As an improved technical solution of the present invention, the pump assembly further comprises an elastic body accommodated in the metal cover and positioned below the magnetic body, and the elastic body can be compressed to absorb the volumetric expansion caused by the urea freezing.

As an improved technical solution of the present invention, the plate portion is pressed down against the pressure sensor.

As an improved technical solution of the present invention, the pump assembly housing is provided with a gear groove for receiving the first gear and the second gear, wherein the first gear meshes with the second gear, one side of the gear groove is provided with a liquid inlet cavity communicating with the inlet port in Connection is made, and the other side of the gear groove is provided with a Flüssigkeitsauslasshohlraum, which communicates with the outlet channel.

As an improved technical solution of the present invention, the nozzle assembly comprises a magnetic portion for cooperation with the nozzle spool, a valve needle portion positioned below the magnetic portion, a spring acting between the magnetic portion and the valve needle portion, and a valve seat provided with fits the valve needle section.

As an improved technical solution of the present invention, the nozzle coil is positioned at the periphery of the magnetic portion, the valve needle portion is provided with a valve needle, and the valve seat is provided with an injection port that mates with the valve needle.

As an improved technical solution of the present invention, the valve seat comprises a swirl disk welded to the nozzle array housing, the injection port is disposed on the swirl disk, and the swirl disk is further provided with a plurality of swirl grooves communicating with the injection port.

As an improved technical solution of the present invention, the integrated device with a cooling arrangement for cooling the Provided urea nozzle and the cooling arrangement cools the urea nozzle through a cooling medium.

As an improved technical solution of the present invention, the controller is provided with a control board, the motor coil and the nozzle coil are electrically connected to the control board, the jacket is provided with a passage opening communicating with the case cavity, and a watertight fixed in the passage opening and breathable cover provided; If the control board is welded to a cable connector, the cable connector is exposed outside the enclosure.

As an improved technical solution of the present invention, the first housing comprises a first upper surface, a first lower surface and a first side surface, the first upper surface having a first annular groove, a first island portion surrounded by the first annular groove, and a first When the first seal ring is received in the first ring groove, the first seal ring is positioned below the metal cover, when the plate section is pressed down against the first seal ring, the first island section is a first positioning hole forming the first upper face and the first face penetrating the first lower surface, and providing a second positioning hole penetrating the first lower surface, and the urea pump comprises a first shaft sleeve received in the first positioning hole and a second shaft sleeve received in the second positioning hole, the first gear shaft i n the first shaft sleeve is inserted and the second gear shaft is inserted into the second shaft sleeve.

As an improved technical solution of the present invention, the first lower surface is provided with a first relief groove communicating with the first positioning hole and the second positioning hole.

As an improved technical solution of the present invention, the first island portion further includes a first distribution groove penetrating the first upper surface and communicating with the second positioning hole, and a first communication opening penetrating the first upper surface and communicating with the intake port ; the first housing is provided with a second connection opening penetrating the first lower surface and communicating with the liquid inlet cavity, and an outlet opening penetrating the first lower surface and communicating with the liquid outlet cavity.

As an improved technical solution of the present invention, the first housing is provided with an overflow receiving groove communicating with the discharge port, and the integrated device is provided with an overflow member installed in the spill receiving groove; When the pressure in the exhaust passage is greater than a predetermined value, the spill member is opened to return a portion of the urea solution into the intake passage.

As an improved technical solution of the present invention, the pump assembly housing includes a second housing positioned below the first housing and connected to the first housing, the second housing includes a second upper surface and a second lower surface, and the gear groove penetrates the second upper surface and the second lower surface.

As an improved technical solution of the present invention, the pump assembly housing includes a third housing positioned below the second housing and connected to the second housing, the third housing includes a body portion and a convex portion extending downwardly from the body portion the body portion is provided with a third upper surface, the third upper surface is provided with a third annular groove and a third island portion surrounded by the third annular groove, the third island portion having a third positioning hole and a fourth positioning hole forming the third upper one Penetrate surface, is provided, and the third positioning hole and the fourth positioning hole extend into the convex portion; The urea pump includes a third shaft sleeve received in the third positioning hole and a fourth shaft sleeve received in the fourth positioning hole, wherein the first gear shaft is inserted into the third shaft sleeve and the second gear shaft is inserted into the fourth shaft sleeve.

As an improved technical solution of the present invention, the third island portion is provided with a second distribution groove and a third distribution groove penetrating the third upper surface, the second distribution groove communicating with the third positioning hole, and the third distribution groove being with the fourth Positioning opening in connection.

As an improved technical solution of the present invention, the nozzle assembly housing includes a main body portion and an extension portion extending downwardly from the main body portion, the main body portion having a receptacle for receiving the urea nozzle and a groove for Receiving the convex portion provided and extends the receptacle down into the extension portion.

As an improved technical solution of the present invention, the nozzle assembly comprises a magnetic portion cooperating with the nozzle spool, a valve needle portion connected to the magnetic portion, and a spring acting on the valve needle portion; the extension portion is provided with a current collection cavity communicating with the receptacle, the portion of the magnetic portion protruding from the second upper surface being received in the receptacle.

As an improved technical solution of the present invention, the spring is installed in the magnetic portion and the valve needle portion, the valve needle portion is provided with a conical portion and a valve needle extending downwardly from the conical portion, the valve needle extends into the current collecting cavity wherein, the magnetic portion is provided with a first communication port communicating with the receptacle, the valve needle portion is provided with a second communication port communicating with the first communication port, and the conical portion is with a third communication port communicating with the communication port Communication of the second communication port with the current collecting cavity allowed provided.

As an improved technical solution of the present invention, the nozzle assembly includes a valve seat that mates with the valve needle, the valve seat includes a swirl disk welded to the extension portion, the swirl disk is an injection port that mates with the valve needle, and a plurality of swirl grooves. which communicate with the injection port, and the swirl grooves communicate with the current collecting cavity.

As an improved technical solution of the present invention, the nozzle assembly housing is provided with a first cooling passage, a second cooling passage spaced from the first cooling passage, and an end cover sealed at the periphery of the extension section, the nozzle arrangement housing forms a cooling annular groove is in communication with the first cooling passage and the second cooling passage between the end cover and the extension portion, the first cooling passage is connected to an intake port for injecting an engine coolant, and the second cooling passage is connected to an exhaust port for discharging an engine coolant.

• ein Abgasnachbehandlungssystem, das ein Abgasnachbehandlungseinspritzsystem und ein Abgasnachbehandlungsgehäusesystem umfasst, wobei das Einspritzsystem die integrierte Vorrichtung umfasst und das Gehäusesystem einen Träger umfasst, der stromabwärts der integrierten Vorrichtung positioniert ist.

The present invention further discloses the following technical solution:

• an exhaust aftertreatment system comprising an exhaust aftertreatment injection system and an exhaust after treatment housing system, the injection system comprising the integrated device and the housing system including a support positioned downstream of the integrated device.

• ein Steuerverfahren für eine integrierte Vorrichtung, wobei es sich bei der integrierten Vorrichtung um die zuvor erwähnte integrierte Vorrichtung handelt und das Steuerverfahren Folgendes umfasst:
  • dahingehendes Antreiben der Pumpe, das Fluidmedium durch den Einlasskanal in die Pumpe zu saugen;
  • nach der Druckbeaufschlagung durch die Pumpe, Leiten des Fluidmediums durch den Auslasskanal zu der Düse;
  • und wenn ein Einspritzzustand erreicht ist, Bestromen der Düsenspule und zumindest teilweises Öffnen der Düse zum Einspritzen des Fluidmediums in das Abgas des Motors, wobei
  • die Motorspule und die Düsenspule separat gesteuert werden.

The present invention further discloses the following technical solution:

• a control method for an integrated device, wherein the integrated device is the aforementioned integrated device, and the control method comprises:
  • causing the pump to suck the fluid medium through the inlet channel into the pump;
  • after being pressurized by the pump, directing the fluid medium through the outlet channel to the nozzle;
  • and when an injection state is reached, energizing the nozzle coil and at least partially opening the nozzle for injecting the fluid medium into the exhaust gas of the engine, wherein
  • the motor coil and the nozzle coil are controlled separately.

Compared with the prior art, an integrated device according to the present invention comprising a pump and a nozzle enables a very good integration of the pump and the nozzle, has a simple and compact structure and facilitates installation by the customer. On the basis of the integration of a urea pump and a urea nozzle in the integrated device, due to the improvement of the control precision, the ratio of urea injected into the exhaust gas to nitrogen oxides can be adjusted accordingly, thereby reducing the risk of crystallization caused by excessive urea injection. In addition, the pressure sensor does not have its own housing and a jacket is used. The size of the sensor can be reduced without affecting the function of the sensor and the downsizing of the integrated device can be realized.

list of figures

• 1 FIG. 12 is a schematic diagram of an exhaust aftertreatment system of the present invention used to treat engine exhaust. FIG.
• 2 shows a schematic diagram of the integrated device in 1 ,
• 3 shows a stereoscopic view of an integrated device according to an embodiment of the present invention.
• 4 shows a stereoscopic view of 3 from another angle.
• 5 shows a stereoscopic view of 3 from yet another angle.
• 6 shows a front view of 3 ,
• 7 shows a view of 3 from the right.
• 8th shows a view of 5 from underneath.
• 9 shows a plan view of 5 ,
• 10 Figure 4 shows a partial stereoscopic exploded view of an integrated device of the present invention in which the pump assembly is separated from the nozzle assembly.
• 11 shows a stereoscopic exploded partial view of the pump assembly in 10 in which the sheath, the motor coil and the waterproof and breathable cover are separated.
• 12 shows a stereoscopic view in which the sheath and the motor coil in 11 are installed together.
• 13 shows a stereoscopic exploded view of 12 ,
• 14 shows another stereoscopic exploded view of 11 in which the control board is disconnected.
• 15 shows a stereoscopic exploded view after removing the sheath and the control board in 14 in which the connection plate assembly is separated.
• 16 shows a stereoscopic view of the connection plate assembly in 15 ,
• 17 shows a stereoscopic exploded view of the connection plate assembly in 15 ,
• 18 shows another stereoscopic exploded view of 15 in which the magnetic body, the elastic body and the screws are separated.
• 19 shows another exploded view of 18 in which the first sealing ring, the temperature sensor and the pressure sensor are separated.
• 20 shows a stereoscopic exploded view of the magnetic body, the elastic body and the screws in 19 ,
• 21 shows a sectional view of 20 from a certain angle after assembly.
• 22 shows a stereoscopic view of the pressure sensor in 19 ,
• 23 shows a stereoscopic view of 22 from another angle.
• 24 shows a stereoscopic exploded view of 22 ,
• 25 shows a sectional view along the CC line in 22 ,
• 26 shows a stereoscopic exploded partial view after removing the first sealing ring, the temperature sensor and the pressure sensor in 19 in which the first housing is separated.
• 27 shows a stereoscopic exploded view of the first housing in 26 ,
• 28 shows a stereoscopic exploded view of 27 from another angle.
• 29 shows a stereoscopic view of a part of the first housing in 27 ,
• 30 shows a stereoscopic view of 29 from another angle.
• 31 shows a plan view of 30 ,
• 32 shows a sectional view along the DD line in 31 ,
• 33 shows a sectional view along the EE line in 31 ,
• 34 shows a sectional view along the FF line in 31 ,
• 35 shows a plan view of 29 ,
• 36 shows a sectional view along the GG line in 35 ,
• 37 shows a sectional view along the HH line in 35 ,
• 38 shows a sectional view along the II line in 35 ,
• 39 shows a stereoscopic view after removing the first housing in 26 ,
• 40 shows a stereoscopic exploded partial view of 39 in which the first gear arrangement and the second gear arrangement are separated.
• 41 shows a plan view of 39 ,
• 42 shows a stereoscopic exploded view after removing the first gear assembly and the second gear assembly in 40 ,
• 43 shows a stereoscopic view of the second housing in 42 ,
• 44 shows a stereoscopic view of 43 from another angle.
• 45 shows a stereoscopic view of the third housing assembly of 42 ,
• 46 shows a plan view of 45 ,
• 47 shows a sectional view along the JJ line in 46 ,
• 48 shows a sectional view along the KK line in 46 ,
• 49 shows a stereoscopic exploded partial view of a nozzle assembly of the present invention.
• 50 shows an exploded partial view of the urea nozzle in 49 ,
• 51 shows a stereoscopic view of the nozzle assembly housing in 49 ,
• 52 shows an exploded partial view of 51 ,
• 53 shows a plan view of a portion of the nozzle assembly housing in 52 ,
• 54 shows a sectional view along the LL line in 53 ,
• 55 shows a sectional view along the MM line in 54 ,
• 56 shows a sectional view along the NN line in 54 ,
• 57 shows a stereoscopic view of 53 from another angle.
• 58 Figure 4 shows a stereoscopic exploded view of an integrated device of the present invention.
• 59 shows a sectional view taken along the AA line in 9 ,
• 60 shows a sectional view along the OO line in 59 ,
• 61 shows a sectional view along the PP line in 59 ,
• 62 shows a sectional view along the QQ line in 60 ,
• 63 shows a sectional view along the RR line in 61 ,
• 64 shows a sectional view taken along the BB line in 9 ,
• 65 shows a sectional view along the SS line in 64 ,

Special embodiments

As shown in 1 For example, the present invention discloses an exhaust aftertreatment system 100 , which is used to treat the exhaust gas of the engine 10 , whereby the pollutant emissions are reduced to meet the requirements of emission standards, can be used. The exhaust aftertreatment system 100 includes an exhaust aftertreatment injection system 200 and an exhaust aftertreatment housing system 300 , where the injection system 200 an integrated device 1 for pumping a urea solution from the urea tank 201 (see arrow X) and injecting the urea solution into the exhaust gas of the engine 10 (For example, in the outlet pipe 106 or the enclosure system 300 ); the housing system 300 a mixing device 301 located downstream of the integrated device 1 is positioned, and a carrier 302 , which is downstream of the mixing device 301 is positioned. Of course, in some embodiments it is also possible not to provide a mixing device or to provide two or more mixing devices. The carrier 302 may be, for example, an SCR carrier.

The motor 10 is equipped with an engine coolant circulation circuit. As shown in 1 For example, in one embodiment of the present invention, the engine coolant circulating circuit includes a first circulation circuit 101 (which is shown by the wide arrow Y) and a second circulating circuit 102 (which is shown by the thin arrow Z), wherein the first orbit 101 configured to the integrated device 1 to cool, thereby reducing the risk that it will burn out due to the high temperature engine exhaust; the second circulating circuit 102 configured to the fuel tank 201 to heat, whereby the pyrolysis function is realized. It is understood that in the first orbit 101 the integrated device 1 with an inlet connection 103 for the flow of an engine coolant and an outlet port 104 is provided for the outflow of an engine coolant; in the second circulation circuit 102 a control valve 105 for pertinent opening or closing of the control valve 105 under suitable conditions, the control of the second circulating circuit 102 to realize is provided. The urea tank 201 is with a heating rod 202 provided to the effect with the second circulating circuit 102 connected to pyrolyze the urea solution using the temperature of the engine coolant.

The integrated device 1 The present invention will be described in more detail below.

As shown in 2 Integrates the integrated device 1 the present invention in principle the functions of the urea pump 11 and the urea nozzle 12 , At the urea pump 11 It may be, inter alia, a gear pump, a diaphragm pump, a piston pump or a vane pump. It is understood that the term "integrated", which is used here, means that the urea pump 11 and the urea nozzle 12 as a single device can be installed on an outlet pipe; Alternatively, there are the urea pump 11 and the urea nozzle 12 close together and are interconnected by a short connecting tube, which as a whole can be considered as a single device.

In addition, the exhaust aftertreatment system 100 of the present invention for independently controlling the urea pump 11 and the urea nozzle 12 further with a controller 13 Mistake. It is understood that the controller 13 with the integrated device 1 integrated or from the integrated device 1 can be provided separately. As shown in 2 is the controller 13 in the illustrated embodiment of the present invention in the integrated device 1 integrated to achieve a high degree of integration and improve the ease of installation for the customer.

The integrated device 1 is with a housing 14 for receiving the urea pump 11 and the urea nozzle 12 Mistake. In the 2 The embodiment shown is merely a rough representation of the housing 14 , For example, in one embodiment, the urea pump is shared 11 and the urea nozzle 12 the housing 14 , In another embodiment, the housing 14 in a first housing, with the urea pump 11 mates, and a second housing, with the urea nozzle 12 mates, subdivided, and the first housing and the second housing are installed together to form a whole body. The housing 14 is with an inlet channel 15 holding the urea tank 201 with the urea pump 11 connects, and an exhaust duct 16 who made the urea pump 11 with the urea nozzle 12 connects, provided. It is noted that the terms "inlet" in "inlet duct 15 "And" outlet "at" exhaust duct 16 "Used here on the urea pump 11 Respectively. In other words, upstream of the urea pump 11 the inlet and downstream of the urea pump 11 is the outlet. The outlet channel 16 stands with the urea nozzle 12 related to this, a urea solution to the urea nozzle 12 to pump. It is understood that the inlet duct 15 upstream of the urea pump 11 is positioned and is a low pressure channel; and the outlet channel 16 downstream of the urea pump 11 is positioned and is a high pressure channel.

In addition, the integrated device 1 with a temperature sensor 171 provided for the detection of a temperature. The temperature sensor 171 may be configured with the inlet duct 15 and / or the outlet channel 16 to communicate; Alternatively, the temperature sensor 171 for installation anywhere in the integrated device 1 be configured. One from the temperature sensor 171 detected signal is sent to the controller 13 Posted; the control 13 can the injection accuracy of the urea nozzle 12 by a control algorithm developed based on the input signal and other signals. The integrated device 1 is also with a pressure sensor 172 provided for detecting the pressure, and the pressure sensor 172 is to the effect with the exhaust duct 16 connected, the pressure in the high pressure passage at the outlet of the urea pump 11 to detect. Due to the integrated construction of the present invention, the inner channel is relatively short and it can be considered that the pressure sensor 172 near the urea nozzle 12 located. An advantage of this design is that of the pressure sensor 172 measured pressure close to the pressure in the urea nozzle 12 which ensures the accuracy of the data and the injection accuracy of the urea nozzle 12 be improved.

As shown in 2 is the integrated device 1 furthermore with an overflow element 173 provided that between the exhaust duct 16 and the inlet channel 15 connected is. In the overflow 173 It can be, among other things, an overflow valve, a safety valve or an electrically controlled valve. The function of the overflow element 173 is that the overflow 173 when the pressure in the high pressure passage is more than a predetermined value, is opened to discharge the urea solution in the high pressure passage into the low pressure passage, or directly into the urea tank 201 return, whereby the pressure regulation is realized.

To drive the urea pump 11 is the urea pump 11 with a motor coil 111 provided with the controller 13 communicates. To drive the urea nozzle 12 is the urea nozzle 12 with a nozzle coil 121 provided with the controller 13 communicates.

The control 13 stands with the temperature sensor 171 and the pressure sensor 172 to the effect in communication, temperature signals and pressure signals to the controller 13 to send. Of course, the controller 13 to achieve a precise control also receive other signals, such. B. signals from a CAN bus related to engine operating parameters. In addition, the controller 13 Furthermore, the speed of the urea pump 11 receive; Of course, the receipt of a speed signal by a corresponding speed sensor 175 (Hardware) or by a control algorithm (software). The control 13 independently controls the urea pump 11 or the urea nozzle 12 , An advantage of this control is that it can influence the operation of the urea pump for greater control accuracy 11 on the urea nozzle 12 can reduce.

In addition, the urea nozzle needs 12 in some cases, since the engine exhaust has a high temperature and the exhaust nozzle 12 is installed on the outlet pipe. The integrated device 1 is further provided for this purpose with a cooling arrangement, and the cooling arrangement cools the urea nozzle 12 with a cooling medium. The cooling medium can be inter alia air and / or an engine coolant and / or a lubricating oil and / or urea, etc. As shown in 2 For example, in the illustrated embodiment of the present invention, water cooling is employed, that is, use of an engine coolant to cool the urea nozzle 12 , In the case 14 is a cooling channel 141 provided through which an engine coolant can flow.

As shown in 2 the integrated device works 1 as follows:

The control 13 drives the urea pump 11 to operate on; in the urea tank 201 urea solution located through the inlet channel 15 into the urea pump 11 sucked; after pressurization, the urea solution is passed through the outlet channel 16 to the urea nozzle 12 transported, with the controller 13 required signals, such. As temperature, pressure and pump speed, procured and / or calculated. When an injection state is reached, the controller sends 13 a control signal to the urea nozzle 12 , such as B. the energization of the nozzle coil 121 , and realizes the urea injection by controlling the movement of the valve needle. The control 13 sends to the urea pump 11 a control signal for controlling its speed, whereby the system pressure is stabilized. In the illustrated embodiment of the present invention, the controller controls 13 the urea pump 11 or the urea nozzle 12 independently.

As shown in 3-65 includes the integrated device 1 in the illustrated embodiment of the present invention, a pump 18 , a nozzle arrangement 19 and a controller 13 , As shown in 10 is the nozzle assembly 19 at least in part in the pump assembly 18 introduced and by a number of mounting bolts 64 with it installed.

As shown in 3-10 includes the pump assembly 18 in the illustrated embodiment of the present invention, a pump assembly housing 180 and a urea pump 11 connected to the pump assembly housing 180 matches. The pump assembly housing 180 includes a sheath 2 , which is positioned at the upper part, and a first housing 3 , a second housing 4 and a third case 5 that are below the sheath 2 are positioned and stacked on top of each other. In the illustrated embodiment of the present invention, the first housing 3 , the second case 4 and the third housing 5 made of metallic materials.

As shown in 11 and 12 includes the sheath 2 a sheath cavity 21 to cover the controller 13 and at least part of the pump assembly 18 , a passage opening 22 that with the sheath cavity 21 is connected, a plurality of first attachment openings 23 , which are positioned in the periphery, and a waterproof and breathable cover 24 in the passage opening 22 is fixed. The control 13 is equipped with a chip and other electronic components that heat up in use and cause expansion of the ambient air. The present invention solves the problem of damage to the chip and / or electronic components due to air expansion by providing a watertight and breathable cover 24 which also has a sealing effect. In addition, the waterproof and breathable cover 24 the operating environment of the controller 13 which allows them to meet the working conditions. In the illustrated embodiment of the present invention is the sheath 2 to improve the heat dissipation performance made of a metallic material with good heat dissipation effect. In addition, the sheath can 2 further provided with a plurality of external heat sinks (not shown) to improve the heat dissipation effect.

As shown in 11 and 14 includes the controller 13 a control board 131 and a line connector 132 that with the control board 131 is welded. The cable connector 132 leads through the sheathing 2 so that it is exposed for connection to an external circuit. In the illustrated embodiment of the present invention, the control board is 131 ring-shaped and with a central opening 135 , which is positioned in the middle, provided. The pump arrangement 18 is also with several support columns 631 provided for supporting the control board 131 on the first housing 3 are attached.

As shown in 11 and 14-19 is the pump assembly housing 180 also with a connection plate arrangement 6 provided between the sheathing 2 and the first housing 3 is positioned. In particular, the connection plate assembly 6 with a plate section 61 and a metal cover 62 at the plate section 61 fixed and projecting upwards provided. The metal cover 62 passes through the central opening 135 the control board 131 up. As shown in 11 will be the control board 131 through the support columns 631 and the sheath 2 held together, and a gap is between the control board and the connection plate assembly 6 designed to better heat dissipation of the control board 131 and to ensure better prevention of disruptions.

As shown in 16 is the plate section 61 with a passage opening 614 , a first threaded opening 618 and a hole 615 , which runs through its upper and lower surface provided. As shown in 14 goes the pressure sensor 172 at least in part through the passage opening 614 through and the temperature sensor 171 at least partly goes through the hole 615 therethrough. The conductor wire 1721 of the pressure sensor 172 goes through the opening 614 through, the conductor wire 124 the nozzle assembly 19 goes through the first threaded opening 618 through, and the conductor wire 1711 of the temperature sensor 171 goes through the hole 615 through and is with the control board 131 electrically connected. In addition, the plate section 61 as shown in 15 with several mounting holes 611 provided by the screw 133 passes. As shown in 17 is the plate section 61 with an opening 617 that of the metal cover 62 corresponds, provided. In the illustrated embodiment of the present invention, the lower end of the metal cover 62 to the inner wall of the opening 617 welded.

In the illustrated embodiment of the present invention, the urea pump is 11 around a gear pump, which is a motor coil 111 , the metal cover 62 , an elastic body 71 and a magnetic body 72 in the metal cover 62 are positioned, a first sealing ring 73 that under the metal cover 62 is positioned, and a first gear arrangement 74 and a second gear arrangement 75 that mesh with each other includes.

Since a gear pump can provide a relatively high working pressure, it is for increasing the flow rate of the urea nozzle 12 relevant. In addition, the gear pump can also be switched, which is useful for pumping residual urea solution and reducing the risks of urea crystallization. As shown in 12 and 13 is the motor coil 111 with a holder 112 and a coil 113 around the bracket 112 is wound, provided. The holder 112 is with an opening 114 for receiving the metal cover 62 Mistake. In the illustrated embodiment of the present invention, the motor coil 111 in the sheath cavity 21 Press-fitted, so that the motor coil 111 without the use of any additional fixation elements (such as screws) in the shell cavity 21 can be integrated, reducing the number of parts. In addition, the urea pump includes 11 as shown in 20 and 21 also an outer sleeve 723 for receiving the magnetic body 72 , and the outer sleeve 723 is right in the metal cover 62 accommodated.

As shown in 59 is the motor coil 111 on the periphery of the metal cover 62 postponed. The plate section 61 presses to realize the seal the first sealing ring 73 down. In the illustrated embodiment of the present invention, the elastic body 71 at the lower end of the magnetic body 72 positioned, and the elastic body 71 and the magnetic body 72 be together from a metal frame 720 supported; For example, the magnetic body 72 and the elastic body 71 on the upper and the lower end of the metal frame 720 postponed. The metal frame 720 is with a partition plate 721 provided between the elastic body 71 and the magnetic body 72 is positioned. Except for the partition plate 721 is the metal frame 720 on the whole, a hollow cylinder, and the first gear arrangement 74 is at least partly in the metal frame 720 recorded (as in 59 will be shown). For better restriction of the elastic body 71 is an end of the metal frame 720 with a hook 724 provided, which against the elastic body 71 is pressed. The hook 724 is with a guide pin 725 provided, the pushing on of the elastic body 71 on the metal frame 720 facilitated. The elastic body 71 is with a radially extending mounting hole 711 provided, the metal frame 720 is with a fixation opening 726 that the mounting hole 711 corresponds, provided, and the upper end of the first gear assembly 74 is through a screw 722 in the mounting hole 711 and the fixation opening 726 is installed, radially to the metal frame 720 fixed. This arrangement can be the axial movement of the first gear arrangement 74 prevent and improve the running stability of the gear pump. It is well known that the volume of a urea solution expands upon freezing. In the present invention is an elastic body 71 intended. The elastic body 71 may be compressed to absorb the volumetric expansion, thereby avoiding damage to another component due to volumetric expansion.

As shown in 22-25 includes the pressure sensor 172 in the illustrated embodiment of the present invention, a base plate 176 , a circuit board 177 attached to the base plate 176 is fixed, a conductor wire 1721 that with the circuit board 177 connected, and a protective cover 178 on the circuit board 177 is attached. The base plate 176 is with a plate body 1761 and a convex section 1762 that is different from the plate body 1761 extends downwards, provided, and a sealing ring 1722 is at the convex section 1762 arranged. The convex section 1762 is with a passage opening 1763 , which penetrates down, provided, and the passage opening 1763 penetrates the plate section 1761 and the circuit board 177 up. The circuit board 177 is with a chip 1771 at the point of the passage opening 1763 corresponds, provided. The protective cover 178 is at the periphery of the chip 1771 to protect the chip 1771 attached. In the illustrated embodiment of the present invention, the cover 178 cuboid and the cover 178 is with an opening 1781 that with the chip 1771 communicates. As shown in 25 and 59 points the pressure sensor 172 in the present invention, unlike a pressure sensor of the prior art, no separate housing; instead, the sheath will 2 used as his housing. By this arrangement, the volume can be reduced, the installation can be facilitated and costs can be reduced. In the illustrated embodiment of the present invention, the pressure sensor is 172 around a differential pressure sensor, the differential pressure changes at the top and bottom of the chip 1771 converted into electrical signals. Since the skilled person is familiar with the operating principle of differential pressure sensors, it will not be described again exactly here.

As shown in 26-48 are the first case 3 , the second case 4 and the third housing 5 in the illustrated embodiment of the present invention machined workpieces and are from top to bottom by bolts 66 fixed together. The first case 3 includes a first upper surface 31 , a first lower surface 32 and a first side surface 33 , wherein the first upper surface 31 with a first annular groove 311 and a first island section 312 coming from the first ring groove 311 is surrounded, is provided. The first ring groove 311 becomes for receiving the first sealing ring 73 used. The first lower surface 32 is with a second annular groove 325 and a second island section 326 coming from the second ring groove 325 is surrounded provided. The second ring groove 325 becomes for receiving the second sealing ring 731 used (as shown in 64 ).

The first island section 312 is with a first positioning hole 3121 that the first upper surface 31 and the first lower surface 32 penetrates a second positioning hole 3122 that the first lower surface 32 penetrates, a first connection opening 3123 that the first upper surface 31 penetrates and with the inlet channel 15 in communication, and a first distribution groove 3124 that the first upper surface 31 penetrates and with the second positioning hole 3122 communicates. As shown in 27 . 28 and 59 is the urea pump 11 with a first shaft sleeve 76 that in the first positioning hole 3121 is received, and a second shaft sleeve 77 that in the second positioning hole 3122 is included, provided. In addition, the first housing includes 3 Furthermore, an internal thread opening 317 that of the screw 133 equivalent. When assembling the screw 133 after passing through the mounting hole 611 of the plate section 61 for fixing the connection plate arrangement 6 in the internal thread opening 317 tightened.

The first case 3 further includes a plurality of first mounting holes 318 for passing the bolts 66 , The first mounting holes 318 go through the first upper surface 31 and the first lower surface 32 therethrough. The first upper surface 31 is also with a pressure sensor receiving opening 313 on one side of the first island section 312 is positioned to receive the pressure sensor 172 and a temperature sensor receiving opening 314 for receiving the temperature sensor 171 Mistake. As shown in 59 exists between the sealing ring 1722 at the pressure sensor 172 and the inner wall of the pressure sensor receiving opening 313 a seal. The plate section 61 presses to achieve a fixation on the pressure sensor 172 , In addition, the first case 3 also with an outwardly convex mounting flange 315 provided, and the mounting flange 315 is with a second mounting hole 316 that of the first mounting hole 23 corresponds, provided. When assembling the bolts 63 successively through the second fastening opening 316 and the support columns 631 guided and in the internal thread of the first mounting hole 23 screwed. With this arrangement, the first housing 3 and the sheath 2 be fixed and the control board 131 can be clamped (see 59 ).

In addition, the first case 3 as shown in 30 with a liquid inlet channel 332 passing through the first side surface 33 runs, for connection to a urea connection 331 Mistake. The first case 3 is with a second connection opening 3127 provided the first lower surface 32 penetrates and with the liquid inlet channel 332 communicates. The first connection opening 3123 and the second connection opening 3127 are perpendicular to the liquid inlet channel 332 , The first positioning hole 3121 , the second positioning hole 3122 and the second connection opening 3127 penetrate the second island section 326 downward. The second island section 326 is also with an outlet opening 3126 provided the first lower surface 32 penetrates. The first lower surface 32 is with a first relief groove 321 provided with the first positioning hole 3121 and the second positioning hole 3122 to ensure pressure equalization. The first relief groove 321 is on the second island section 326 positioned. In addition, the first case 3 also with a storage compartment 322 that is the first lower surface 32 penetrates down to receive at least a portion of the nozzle assembly 19 Mistake. As shown in 33 . 34 and 36 is the storage compartment 322 with the pressure sensor receiving opening 313 in connection. The storage compartment 322 also stands with the outlet opening 3126 in connection. As shown in 32 and 33 is the outlet opening 3126 in the illustrated embodiment of the present invention obliquely and has approximately the shape of an inverted "V" in the first housing 3 on. The first case 3 is with a second threaded opening 323 provided, that of the first threaded opening 618 equivalent.

In addition, the first case 3 as shown in 38 . 64 and 65 also with a Überströmelementaufnahmenut 319 provided with the inlet duct 332 and the storage compartment 322 communicates. The Überströmelementaufnahmenut 319 penetrates to receive the overflow element 173 through the first side surface 33 outward. The overflow element 173 is in the illustrated embodiment of the present invention, a relief valve and its task is to ensure by pressure relief that the pressure in the high-pressure channel of the integrated device 1 within a safe area. For fixing the overflow element 173 is the first case 3 with a plug 5122 provided, which the overflow element 173 fixed. As shown in 65 is the overflow element 173 with a seepage opening 1731 always with the inlet duct 15 and the outlet channel 16 communicates. With this arrangement, on the one hand, the pressure fluctuation of the system can be reduced, especially when the nozzle assembly 19 Urea injects; On the other hand, the urea solution can be flowed, allowing for the heat dissipation of the motor coil 111 is useful.

As shown in 1 is the urea connection 331 with the urea tank 201 through the urea connection pipe 333 in connection. For better realization of the pyrolysis function, the exhaust aftertreatment system 100 also with a heater 334 for heating the urea connection pipe 333 be provided. As shown in 22 and 29 the liquid inlet channel extends 332 in the illustrated embodiment of the present invention horizontally in the first housing 3 , Of course, the liquid inlet channel 332 be arranged in other embodiments also at a certain angle.

As shown in 39-41 includes the first gear arrangement 74 a first gear shaft 741 and a first gear 742 at the first gear shaft 741 is fixed; includes the second gear arrangement 75 a second gear shaft 751 and a second gear 752 at the second gear shaft 751 is fixed, and combs the first gear 742 with the second gear 752 , As shown in 34 combs the first gear 742 in the illustrated embodiment of the present invention externally with the second gear 752 , In addition, the first gear shaft 741 a drive shaft, is the second gear shaft 751 a drive shaft and is the first gear shaft 741 higher than the second gear shaft 751 , The upper end of the first gear shaft 741 passes through the first shaft sleeve 76 and is at least partly in the metal frame 720 fixed. The upper end of the second gear shaft 751 is in the second shaft sleeve 77 positioned. Will the motor coil 111 energized, it works with the magnetic body 72 together and the electromagnetic force drives the first gear shaft 741 for rotation, whereby the first gear 742 and the second gear 752 be driven for rotation.

The second housing 4 is below the first housing 3 positioned and with the first housing 3 connected. In addition, multiple positioning pins are for better positioning 328 between the first housing 3 and the second housing 4 arranged. The second housing 4 includes a second upper surface 41 , a second lower surface 42 and a gear groove 43 passing through the second upper surface 41 and the second lower surface 42 runs, for receiving the first gear 742 and the second gear 752 , One side of the gear groove 43 is with a fluid inlet cavity 431 provided with the inlet duct 15 communicates, and the other side of the gear courage 43 is with a fluid outlet cavity 432 provided with the outlet channel 16 communicates. In particular, the liquid inlet cavity is 431 with the second connection opening 3127 in communication and is the upper end of the Flüssigkeitsauslasshohlraums 432 with the outlet opening 3126 in connection. In addition, the second upper surface 41 of the second housing 4 with a first receiving opening 411 provided through which the nozzle assembly 19 passes through, and the second lower surface 42 is with a second receiving opening 421 for positioning the nozzle assembly 19 Mistake. The second receiving opening 421 is larger than the first receiving opening to form stepped openings 411 , The nozzle arrangement 19 protrudes from the second upper surface 41 up in front and is in the receptacle 322 added. With this arrangement, the urea nozzle 12 a high pressure urea solution are supplied. In addition, the second upper surface 41 further with a third threaded opening 412 provided, that of the second threaded opening 323 equivalent. The first threaded opening 618 , the second threaded opening 323 and the third threaded opening 412 are for passing the conductor wire 124 the nozzle assembly 19 aligned with each other. The second housing 4 further includes a plurality of second mounting holes 418 on the first mounting holes 318 are aligned.

As shown in 26 and 45 - 48 is the third case 5 below the second housing 4 positioned and with the second housing 4 connected. The third case 5 includes a body portion 51 , a convex section 52 that is different from the body part 51 extends downwards, and a flange 53 that is different from the body part 51 extends to the outside. The flange 53 is with several third mounting holes 531 provided for passing the bolts 66 on the second mounting holes 418 are aligned. The body section 51 is with a third upper surface 511 Mistake; the third upper surface 511 is with a third ring groove 512 and a third island section 513 coming from the third ring groove 512 is surrounded provided. The third ring groove 512 becomes a third sealing ring 732 used (as in 64 will be shown). The third island section 513 is with a third positioning hole 5111 that the third upper surface 511 penetrates, and a fourth positioning hole 5112 that the third upper surface 511 penetrates, provided. The third case 5 is with a third shaft sleeve 78 that in the third positioning hole 5111 is housed, and a fourth shaft sleeve 79 that in the fourth positioning hole 5112 is housed, provided. The lower end of the first gear shaft 741 is in the third shaft sleeve 78 positioned, and the lower end of the second gear shaft 751 is in the fourth shaft sleeve 79 positioned.

In addition, the third island section 513 with a second distribution groove 5114 and a third distribution groove 5115 on the third upper surface 511 are arranged, provided, wherein the second distribution groove 5114 with the third positioning hole 5111 communicates and the third distribution groove 5115 with the fourth positioning hole 5112 communicates. As shown in 43 are the second distribution groove 5114 and the third distribution groove 5115 in the third housing 5 aslant. As shown in 48 is the lower end of the Flüssigkeitsauslasshohlraums 432 with the second distribution groove 5114 and the third distribution groove 5115 in connection.

During operation, a urea solution passes through the urea connection pipe 333 into the liquid inlet channel 332 ; a part of the urea solution passes through the first communication port 3123 in the metal cover 62 one and the other part of the urea solution passes through the second communication port 3127 into the liquid inlet cavity 431 one. The urea solution, which is in the metal cover 62 is located, seeping directly into the first positioning hole 3121 to the first shaft sleeve 76 to lubricate, and the second positioning hole 3122 along the first distribution groove 3124 to the second shaft sleeve 77 to lubricate. The into the liquid inlet cavity 431 entering urea solution is divided into two partial streams. A partial flow occurs after pressurization from the gear pump in the exhaust passage 16 one. The other partial flow passes through the second distribution groove 5114 and the third distribution groove 5115 for lubrication of the third shaft sleeve 78 and the fourth shaft sleeve 79 for improving the rotational stability of the gear pump and reducing its wear in the third positioning hole 5111 or the fourth positioning opening 5112 one. The in the exhaust duct 16 entering high-pressure urea solution occurs to the extent in the receptacle 322 along the outlet 3126 on, to the nozzle assembly 19 whereas some of the urea solution flows to the overflow element 173 flows. When the pressure is below a preset value of the overflow element 173 is, is the overflow 173 closed and is only through the seepage 1731 in connection; if the pressure is above the preset value of the overflow element 173 is located, the overflow opens 173 and a portion of the urea solution enters the fluid inlet passage to provide pressure relief 332 one.

It is understood that the inlet duct 15 in the illustrated embodiment of the present invention, the liquid inlet channel 332 , the second connection opening 3127 and the liquid inlet cavity 431 includes. Because the inlet duct 15 upstream of the urea pump 11 is positioned, it is referred to as a low pressure channel. The outlet channel 16 includes the liquid outlet cavity 432 , the outlet opening 3126 , the storage compartment 322 etc. As the exhaust duct 16 downstream of the urea pump 11 is positioned, it is referred to as a high pressure channel.

As shown in 49-58 includes the nozzle assembly 19 a nozzle assembly housing 190 and a urea nozzle 12 connected to the nozzle assembly housing 190 matches.

The nozzle assembly housing 190 includes a main body portion 91 , an extension section 92 coming from the main body section 91 extends downwards, and a mounting flange 93 coming from the main body section 91 extends to the outside. The mounting flange 93 is with several mounting holes 931 for fixing the integrated device 1 at the outlet pipe 106 or the enclosure system 300 Mistake. The main body section 91 is with a fourth upper surface 911 and a fourth side surface 912 Mistake. The fourth upper surface 911 is with a storage compartment 94 for receiving the urea nozzle 12 and a groove 95 for receiving the convex portion 52 Mistake. As shown in 55 extends the receptacle 94 down into the extension section 92 , The main body section 91 is also with a cylindrical section 917 , which is up in the storage compartment 94 protrudes, to support the urea nozzle 12 Mistake.

The nozzle assembly housing 190 is also with the cooling arrangement for cooling the urea nozzle 12 Mistake. In the illustrated embodiment of the present invention, the cooling arrangement is a water cooling arrangement. The cooling channel 141 in the nozzle assembly housing 190 is positioned, includes a first cooling channel 913 passing through the fourth side surface 912 runs, and a second cooling channel 914 leading to the first cooling channel 913 is spaced, wherein the first cooling channel 913 with the inlet connection 103 is connected and the second cooling connection 914 with the outlet port 104 connected is. The nozzle assembly housing 190 is with an end cover 96 provided at the periphery of the extension section 92 is sealed. In the illustrated embodiment of the present invention, the end cover 96 to the extension section 92 welded. With this arrangement, the nozzle assembly housing forms 190 a cooling ring groove 916 that the first cooling channel 914 and the second cooling channel 915 between the end cover 96 and the extension section 92 combines.

In the illustrated embodiment of the present invention, the mounting flange 93 integral with the main body portion 91 machined. Of course, the mounting flange 93 in other embodiments also of the main body portion 91 are manufactured separately and then they are welded.

As shown in 50 includes the urea nozzle 12 in the illustrated embodiment of the present invention, a nozzle coil 121 , a magnetic section 81 that with the nozzle coil 121 cooperates, a valve needle section 82 , which is below the magnetic section 81 is arranged a spring 83 that is between the magnetic section 81 and the valve needle section 82 acts, and a valve seat 84 that with the valve needle section 82 matches (see 5 ). The nozzle coil 121 is around the periphery of the magnetic section 81 wrapped around. The urea nozzle 12 further comprises a sleeve portion 122 placed on the periphery of the nozzle coil 121 pushed. The feather 83 is in the magnetic section 81 and the valve needle section 82 Installed. The valve needle section 82 is with a conical section 821 and a valve needle 822 extending from the conical section 821 extends downwards, provided. As shown in 52 includes the valve seat 84 a swirl disk 85 attached to the extension section 92 is welded. The swirl disk 85 is with an injection port 851 that with the valve needle 822 fits together, and several swirl grooves 852 that with the injection opening 851 communicate. As shown in 10 . 50 and 59 is a fourth sealing ring 812 for sealing the inner wall of the receiving compartment 322 on the upper end of the magnetic section 81 pushed; is a fifth sealing ring 813 for sealing the inner wall of the receiving compartment 94 on the lower end of the magnetic section 81 pushed. As shown in 59 supports the cylindrical section 917 the valve needle section 82 , so that the valve needle section 82 and the nozzle coil 121 essentially in the direction of movement of the valve needle 822 overlay and the impact of the nozzle coil 121 at the valve needle section 82 generated electromagnetic force can be increased, whereby the drive current is reduced, the energy consumption of the urea nozzle 12 is reduced and the heat generation is reduced. In addition, one is with the urea nozzle 12 matching seal 86 for adjusting the gap between the magnetic portion 81 and the valve needle section 82 in the storage compartment 94 intended. Of course, the stroke of the valve needle section is 82 closely related to the above-mentioned gap. By adjusting the gap with seals 86 different thickness, the stroke of the valve needle section 82 to improve the accuracy of the urea nozzle 12 be controlled exactly.

As shown in 59 is the extension section 92 with a current collecting cavity 921 provided, and the valve needle 822 extends into the current collecting cavity 921 , The magnetic section 81 is with a first communication opening 811 provided with the receiving compartment 322 communicates, the valve needle section 82 is with a second communication opening 823 provided with the first communication opening 811 communicates, and the conical section 821 is with a third communication opening 824 provided that allows the second combination opening 823 with the current collecting cavity 921 communicates. The twist groove 852 stands with the current collecting cavity 921 in connection. The lower part of the sleeve section 122 is in the storage compartment 94 recorded, and the part of the sleeve section 122 from the fourth upper surface 911 protrudes, is in the receptacle 322 added. The cooling ring groove 916 is at the periphery of the current collecting cavity 921 positioned.

It is understood that in other embodiments of the present invention, for example, an integrated device for injecting fuel into the exhaust gas of an engine to achieve regeneration of a Diesel Particulate Filter (DPF) downstream is used. In this application, the urea pump 11 be replaced by a fuel pump, the urea nozzle 12 can be replaced by a fuel nozzle and the urea solution can be replaced by a fuel. This variation will be readily apparent to one skilled in the art, and thus will not be described again in detail here.

For a better understanding of the present invention, the urea pump and the fuel pump are collectively referred to as the pump, the urea nozzle and the fuel nozzle are collectively referred to as the nozzle, and the urea solution and fuel are collectively referred to as the fluid medium.

Compared to the prior art, the integrated device is 1 of the present invention is an integrated construction in which a urea pipe used in the prior art for connecting a pump to a nozzle can be omitted or shortened, or the plug-ins between various sensors and the wiring harness in a pump supply unit of the prior art Technique can be omitted or no pyrolyzer is required, and thus is very reliable. The integrated device 1 The present invention has a compact structure and a small volume, and is suitable for installation in various types of vehicles. In addition, the fluid medium inner channel is in the integrated device 1 short of the present invention, the pressure drop is small and the dead volume between the pump and the nozzle is small; thus the efficiency is high. The temperature sensor 171 and the pressure sensor 172 are near the nozzle and the injection pressure accuracy is high. Moreover, the separate control of the pump and the nozzle avoids nozzle movement due to pumping, and thus the control accuracy is improved. Due to the improved injection accuracy of the nozzle can be ensured that the amount of urea injected into the exhaust gas and from the exhaust gas is proportional to the amount of nitrogen oxides; thus, the risk of crystallization caused by excessive injection of urea is reduced. The integrated device 1 of the present invention can apply water cooling, so that the urea residue in the integrated device 1 can not reach the crystallization point and there is no crystallization.

Although the present invention has been described above particularly with reference to preferred embodiments, it should be understood that the embodiments are not intended to limit the present invention and that those skilled in the art may make various modifications, substitutions and improvements without departing from the spirit and scope of the present invention present invention as defined by the claims to deviate.

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

• CN 201610392925 [0001]

Claims (31)

An integrated pump and nozzle apparatus, wherein the pump is for pumping a fluid medium to the nozzle and the nozzle is for injecting the fluid medium into the exhaust of the engine, characterized in that the integrated apparatus comprises a pump assembly and a nozzle assembly, the pump assembly is provided with a receptacle for at least partially receiving the nozzle assembly; the pump assembly includes a pump assembly housing and the pump mates with the pump assembly housing, the pump assembly housing has an inlet channel positioned upstream of the pump and communicating with the pump, and an outlet channel positioned downstream of the pump and communicating with the pump; comprising, the outlet channel communicating with the nozzle assembly, the pump assembly housing comprises a shell and a first housing positioned below the shell, the shell is provided with a shell cavity, and the first housing is provided with a pressure sensor receiving opening communicating with the receptacle communicates; the pump assembly includes a motor coil for driving the pump, a magnetic body for cooperation with the motor coil, and a first gear assembly and a second gear assembly meshing with each other, the first gear assembly comprises a first gear shaft and a first gear, the second gear assembly comprises a second gear shaft and a second gear and the first gear meshes with the second gear; the nozzle assembly includes a nozzle assembly housing and the nozzle mates with the nozzle assembly housing and the nozzle assembly further comprises a nozzle spool for driving the nozzle; the integrated device is further provided with a pressure sensor accommodated in the pressure sensor receiving opening, the pressure sensor does not have its own housing, and the casing serves as a housing for the pressure sensor. Integrated device according to Claim 1 , characterized in that the pump is a urea pump, the nozzle is a urea nozzle and the fluid medium is a urea solution. Integrated device according to Claim 1 , characterized in that the pump is a fuel pump, the nozzle is a fuel nozzle and the fluid medium is a fuel. Integrated device according to Claim 2 characterized in that the integrated device comprises a controller connected to the motor coil and the nozzle coil and the controller independently separately controls the urea pump and the urea nozzle. Integrated device according to Claim 2 characterized in that the pressure sensor is in communication with the exhaust passage and the integrated device further comprises an overflow member connected between the exhaust passage and the intake passage. Integrated device according to Claim 1 characterized in that the pressure sensor comprises a base plate, a circuit board fixed to the base plate, a conductor wire connected to the circuit board, and a protective cover attached to the circuit board, the base plate having a plate body portion and a convex portion extending downwardly from the plate body portion, a sealing ring is disposed on the convex portion, and the convex portion is provided with a through hole penetrating downwardly and passing upward through the plate body portion. Integrated device according to Claim 6 , characterized in that the printed circuit board is provided with a chip at the location corresponding to the passage opening and the protective cover is attached to the periphery of the chip for protection of the chip. Integrated device according to Claim 7 characterized in that the protective cover is provided with an opening communicating with the chip and the opening communicates with the sheath cavity. Integrated device according to Claim 2 characterized in that the pump assembly housing is provided with a connection plate assembly that mates with the first housing, the connection plate assembly includes a plate portion and a metal cover fixed to the plate portion and protruding upward, the magnetic body is received in the metal cover, and the motor coil is pushed onto the periphery of the metal cover. Integrated device according to Claim 9 characterized in that the pump assembly further comprises an elastic body received in the metal cover and positioned below the magnetic body, and the elastic body can be compressed to absorb the volumetric expansion caused by the urea freezing. Integrated device according to Claim 9 , characterized in that the plate portion is pressed down against the pressure sensor. Integrated device according to Claim 2 characterized in that the pump assembly housing is provided with a gear groove for receiving the first gear and the second gear, the first gear meshes with the second gear, one side of the gear groove is provided with a liquid inlet cavity communicating with the inlet port, and the other side of the gear groove is provided with a liquid outlet cavity communicating with the outlet channel. Integrated device according to Claim 2 characterized in that the nozzle assembly includes a magnetic portion for cooperation with the nozzle spool, a valve needle portion positioned below the magnetic portion, a spring that acts between the magnetic portion and the valve needle portion, and a valve seat that mates with the valve needle portion. includes. Integrated device according to Claim 13 characterized in that the nozzle spool is positioned at the periphery of the magnetic portion, the valve needle portion is provided with a valve needle, and the valve seat is provided with an injection port that mates with the valve needle. Integrated device according to Claim 14 characterized in that the valve seat comprises a swirl disk which is welded to the nozzle assembly housing, the injection port is disposed on the swirl disk, and the swirl disk is further provided with a plurality of swirl grooves communicating with the injection port. Integrated device according to Claim 2 , characterized in that the integrated device is provided with a cooling arrangement for cooling the urea nozzle and the cooling arrangement cools the urea nozzle by a cooling medium. Integrated device according to Claim 4 characterized in that the controller is provided with a control board, the motor coil and the nozzle coil are electrically connected to the control board, the casing is provided with a passage opening communicating with the casing cavity and a watertight and breathable cover fixed in the passage opening is; the control board is welded to a conduit connector and the conduit connector is exposed outside the enclosure. Integrated device according to Claim 9 characterized in that the first housing includes a first top surface, a first bottom surface, and a first side surface, the first top surface having a first annular groove, a first island portion surrounded by the first annular groove, and a first sealing ring, is housed in the first annular groove, the first sealing ring is positioned below the metal cover, the plate portion is pressed down against the first sealing ring, the first island portion having a first positioning opening, which penetrates the first upper surface and the first lower surface , and a second positioning hole penetrating the first lower surface, and the fuel pump comprises a first shaft sleeve received in the first positioning hole and a second shaft sleeve received in the second positioning hole, the first gear shaft inserted into the first shaft sleeve Hrt is and the second gear shaft is inserted into the second shaft sleeve. Integrated device according to Claim 18 characterized in that the first lower surface is provided with a first relief groove communicating with the first positioning hole and the second positioning hole. Integrated device according to Claim 18 characterized in that the first island portion further comprises a first distribution groove penetrating the first upper surface and communicating with the second positioning port, and a first communication opening penetrating the first upper surface and communicating with the intake port; the first housing is provided with a second connection opening penetrating the first lower surface and communicating with the liquid inlet cavity, and an outlet opening penetrating the first lower surface and communicating with the liquid inlet cavity. Integrated device according to Claim 20 characterized in that the first housing is provided with an overflow receiving groove communicating with the outlet opening, and the integrated device is provided with an overflow member installed in the spill receiving groove; when the pressure in the exhaust passage is greater than a predetermined value, the spill member is opened to recirculate a portion of the urea solution into the intake passage. Integrated device according to Claim 21 characterized in that the pump assembly housing includes a second housing positioned below the first housing and having the second housing includes a second upper surface and a second lower surface, and the gear groove penetrates the second upper surface and the second lower surface. Integrated device according to Claim 22 characterized in that the pump assembly housing comprises a third housing positioned below the second housing and connected to the second housing, the third housing comprises a body portion and a convex portion extending downwardly from the body portion, the body portion is provided with a third upper surface, the third upper surface is provided with a third annular groove and a third island portion, which is surrounded by the third annular groove, the third island portion having a third positioning hole and a fourth positioning hole, which penetrate the third upper surface , and the third positioning hole and the fourth positioning hole extend into the convex portion; the urea pump includes a third shaft sleeve received in the third positioning hole and a fourth shaft sleeve received in the fourth positioning hole, wherein the first gear shaft is inserted into the third shaft sleeve and the second gear shaft is inserted into the fourth shaft sleeve. Integrated device according to Claim 23 characterized in that the third island portion is provided with a second distribution groove and a third distribution groove penetrating the third upper surface, the second distribution groove communicating with the third positioning hole, and the third distribution groove communicating with the fourth positioning hole. Integrated device according to Claim 23 characterized in that the nozzle assembly housing includes a main body portion and an extension portion extending downwardly from the main body portion, the main body portion is provided with a receptacle for receiving the urea nozzle and a groove for receiving the convex portion, and the receptacle extends downward in extends the extension section. Integrated device according to Claim 25 characterized in that the nozzle assembly comprises a magnetic portion cooperating with the nozzle spool, a valve needle portion connected to the magnetic portion, and a spring acting on the valve needle portion; the extension portion is provided with a current collection cavity communicating with the receptacle, the portion of the magnetic portion protruding from the second upper surface being received in the receptacle. Integrated device according to Claim 26 characterized in that the spring is installed in the magnetic portion and the valve needle portion, the valve needle portion is provided with a conical portion and a valve needle extending downwardly from the conical portion, the valve needle extends into the current collecting cavity, the magnetic one Section is provided with a first communication opening communicating with the receiving compartment, the valve needle section having a second communication opening communicating with the first communication opening, and the conical section with a third communication opening providing communication of the second communication opening allowed with the current collecting cavity is provided. Integrated device according to Claim 27 characterized in that the nozzle assembly includes a valve seat that mates with the valve needle, the valve seat includes a swirl disk that is welded to the extension portion, the swirl disk having an injection port that mates with the valve needle, and a plurality of swirl grooves that connect to the injection port and the swirl grooves communicate with the current collecting cavity. Integrated device according to Claim 28 characterized in that the nozzle assembly housing is provided with a first cooling channel, a second cooling channel spaced from the first cooling channel, and an end cover sealed at the periphery of the extension section, the nozzle assembly housing forming a cooling annulus corresponding to the first Cooling passage and the second cooling passage between the end cover and the extension portion is in communication, the first cooling passage is connected to an inlet port for injecting an engine coolant and the second cooling passage is connected to an outlet port for discharging an engine coolant. An exhaust after-treatment system comprising an exhaust aftertreatment injection system and an exhaust after-treatment housing system, wherein the injection system comprises the integrated Device according to one of Claims 1 - 29 and the housing system includes a carrier positioned downstream of the integrated device. Control method for an integrated device, characterized in that the integrated device is the integrated device according to one of the Claims 1 - 29 and the method comprises: perturbing the pump to suck the fluid medium through the inlet channel into the pump; after being pressurized by the pump, directing the fluid medium through the outlet channel to the nozzle; and when an injection state is reached, energizing the nozzle coil and at least partially opening the nozzle for injecting the fluid medium into the exhaust gas of the engine, the engine coil and the nozzle spool being separately controlled.

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