Source: https://patents.google.com/patent/CN104334865A/en
Timestamp: 2020-03-31 10:44:13
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CN104334865A - Fuel injection valve and fuel injection device with same - Google Patents
Fuel injection valve and fuel injection device with same Download PDF
CN104334865A
CN104334865A CN201280073100.6A CN201280073100A CN104334865A CN 104334865 A CN104334865 A CN 104334865A CN 201280073100 A CN201280073100 A CN 201280073100A CN 104334865 A CN104334865 A CN 104334865A
CN201280073100.6A
2012-05-11 Application filed by 丰田自动车株式会社 filed Critical 丰田自动车株式会社
2012-05-11 Priority to PCT/JP2012/062208 priority Critical patent/WO2013168292A1/en
2015-02-04 Publication of CN104334865A publication Critical patent/CN104334865A/en
A fuel injection valve comprises: a needle valve having a seat section on the front end side thereof; a nozzle body having a seat surface on which the seat section is seated and having a nozzle hole located downstream of the seat surface; a pressure receiving section for receiving pressure within the combustion chamber of the engine; and a nozzle hole extension member provided with a movable section for changing the length of the nozzle hole by moving within the nozzle hole in the direction of the axis of the nozzle hole according to pressure to which the pressure receiving section is subjected. As a result of this configuration, when an increase in the spray angle is desired during injection in a compression stroke, the movable section is moved deep into the nozzle hole to reduce the length of the nozzle hole, thereby increasing the spray angle.
Fuelinjection nozzle and be equipped with the fuel injection system of this Fuelinjection nozzle
The present invention relates to Fuelinjection nozzle and be equipped with the fuel injection system of this Fuelinjection nozzle.
Past, the Fuelinjection nozzle that the spreading of spray of known injected fuel is variable.Attachment in order to avoid fuel to chamber wall, on piston-top surface, ites is desirable to spreading of spray to be adjusted to appropriate angle.Such as, in patent documentation 1, disclose a kind of fuel injection system, described fuel injection system, is configured with piezoelectric element in spray orifice, regulates spray orifice aperture or spray orifice length.By regulating spray orifice aperture or spray orifice length, adjustment spreading of spray.In addition, in patent documentation 2, disclose a kind of fuel injection nozzle, described fuel injection nozzle has coaxial dual needle roller, makes the first spray orifice and the second spray orifice opening and closing respectively.By making the lifting capacity of coaxial dual needle roller change, switching one-level and spraying or two-stage injection, whereby, can spreading of spray be changed.
Patent documentation 1: Japanese Unexamined Patent Publication 2001-220285 publication
Patent documentation 2: Japanese Unexamined Patent Publication 2009-275646 publication
But fuel injection system disclosed in described patent documentation 1, for executing alive distribution to piezoelectricity original paper, drive unit necessitates, and the system of also existing becomes complicated worry.In addition, also consider in high temperature environments, can piezoelectric element reliably work also can become problem.Fuel injection nozzle disclosed in described patent documentation 2, when making spreading of spray change, along with the change of orifice number, fuel flow rate can change.
Therefore, Fuelinjection nozzle disclosed in this specification and be equipped with the fuel injection system of this Fuelinjection nozzle to be changed to problem to make spreading of spray rightly.
In order to solve this problem, Fuelinjection nozzle disclosed in this specification, is equipped with: needle-valve, and described needle-valve has seat portion in forward end; Nozzle body, described nozzle body has described seat portion valve seat surface in place, and, in the downstream side of described valve seat surface, there is spray orifice; And spray orifice member for prolonging, described spray orifice member for prolonging is equipped with compression zone and movable part, described compression zone accepts the pressure in the firing chamber of motor, the pressure that described movable part and described compression zone accept correspondingly moves in described spray orifice along the axial direction of described spray orifice, makes the length change of spray orifice.
Fuelinjection nozzle, when its spray orifice length, spreading of spray diminishes, penetrating power grow.Such as, when intake stroke sprays, when fuel sprays, piston is positioned near BDC (lower dead center), in order to make spraying spread all over firing chamber distribution, obtaining uniform mixed gas, iting is desirable to reduce spreading of spray.On the other hand, when being sprayed formation stratified mixtures by compression stroke, or when forming diffusive combustion as diesel engine, when fuel sprays, piston is positioned near TDC (top dead center), and the distance of Fuelinjection nozzle and piston is short.Therefore, in order to liquid fuel is not adhered on piston, it is desirable to expand spreading of spray.Here, when carrying out compression stroke and spraying, the pressure exposed in the firing chamber of the front end of Fuelinjection nozzle uprises.Accepted the high pressure in firing chamber by compression zone, movable part moves in spray orifice, and spray orifice length shortens.When spray orifice length shortens, spreading of spray becomes large.Thus, liquid fuel can be suppressed to the attachment on piston.
Described compression zone can form gas compartment between this compression zone and the front end of described nozzle body.When the pressure in firing chamber is high, when surpassing the pressure in gas compartment, compression zone bends, and the upstream side of movable part to spray orifice can be pressed into.When movable part is pressed into by the upstream side to spray orifice, spray orifice length shortens.When pressure step-down in firing chamber, the gas in gas compartment can make compression zone and movable part return to original position.
Described movable part forms the cylindrical form being equipped with the axis consistent with the axial direction of described spray orifice, described compression zone is tabular body, the axis vertical take-off of described tabular body and described spray orifice, and, extended outside the radial direction of described nozzle body from the front-end edge of described movable part, its edge, periphery can be supported in described nozzle body.
Supported by the front end of nozzle body by the outer periphery of tabular body, for fulcrum, compression zone can be bent with this support, accompany therewith, the movable part of cylindrical form can be made to slide on the inner peripheral surface of spray orifice.
Between the inner peripheral surface and the outer circumferential face of described movable part of described spray orifice, under atmospheric pressure can gap be set.By the formation of under atmospheric pressure allowable clearance, the making of spray orifice and movable part becomes easy.On the other hand, in fact, when making fuel spray, by in-cylinder pressure, the ladder difference in spray orifice is alleviated.
Fuelinjection nozzle disclosed in this specification, can be equipped with jut in the continuous portion of described movable part and described compression zone, and described jut is outstanding to the direction residing for the piston that described motor is equipped with.The continuous portion of movable part and compression zone is positioned at the opening edge portion of spray orifice.When the opening edge portion of spray orifice becomes smooth curved shape (rounded shapes), also exist due to wall attachment effect, spraying can be expanded along the lower surface of compression zone, and the variation of the fuel of the peripheral part of spraying can become large worry.Therefore, by arranging jut, can wall attachment effect be suppressed, suppressing the variation of the fuel of the peripheral part of spraying.
Fuelinjection nozzle can be equipped with the swirling flow generating unit making the fuel swirl of spraying from described spray orifice.By making fuel swirl, can make to produce gas column in spray orifice, making the micro air bubble producing fuel between fuel and gas column.Micro air bubble from spray orifice spray after, crushed, by the spray particle diameter miniaturization of fuel.When spraying the fuel containing such micro air bubble, the attachment suppressing liquid fuel to chamber wall can also be sought, particularly, suppressing liquid fuel to the attachment of piston head.Thus it is effective for being equipped with spray orifice member for prolonging in the Fuelinjection nozzle being equipped with swirling flow generating unit.
The spray orifice member for prolonging that Fuelinjection nozzle disclosed in this specification is equipped with is movable.By making the action of spray orifice member for prolonging, the sediments being deposited in spray orifice periphery can be removed.In addition, when under the state in the action of spray orifice member for prolonging during burner oil, more effectively sediments can be removed.Therefore, compression stroke injection can be carried out termly, make the action of spray orifice member for prolonging energetically, carry out sediments cleaning.Specifically, a kind of fuel injection system can be made, described fuel injection system is equipped with the control device controlling the timing carrying out fuel injection from described Fuelinjection nozzle, described control device sprays resume based on fuel, when the compression stroke of carrying out within specified time limit is sprayed less than stipulated number, described Fuelinjection nozzle is made to carry out compression stroke injection.
According to the Fuelinjection nozzle of this specification, can spreading of spray be made rightly to change.
Fig. 1 is the explanatory drawing of a structure example of the engine system representing the fuel injection system having carried the Fuelinjection nozzle including embodiment 1.
Fig. 2 is the explanatory drawing of the major component representing the Fuelinjection nozzle of embodiment 1 with cross section.
Fig. 3 (A) represents the explanatory drawing that the state of spray orifice member for prolonging is housed at the front end of the Fuelinjection nozzle of embodiment 1, and Fig. 3 (B) is the explanatory drawing of the front end of the Fuelinjection nozzle representing the embodiment 1 being provided with spray orifice member for prolonging.
Fig. 4 is the perspective view of spray orifice member for prolonging.
Fig. 5 is the explanatory drawing of the state representing burner oil under the state that spray orifice length is short.
Fig. 6 is the chart that schematic diagram represents the relation of spray orifice length/spray orifice aperture and spreading of spray.
Fig. 7 is the flow chart of the example representing the control that the fuel injection system of embodiment 1 carries out.
Fig. 8 (A) is the explanatory drawing of the front end of the Fuelinjection nozzle representing embodiment 2, and Fig. 8 (B) is the explanatory drawing of the state representing that spray orifice member for prolonging moves, spray orifice length is short.
Fig. 9 is the sectional view of the spray orifice member for prolonging that the Fuelinjection nozzle of embodiment 2 is equipped with.
Figure 10 is the explanatory drawing of the front end of the Fuelinjection nozzle representing embodiment 3.
Figure 11 is the explanatory drawing of an example of the position relationship representing Fuelinjection nozzle and spark plug.
Below, with reference to accompanying drawing, embodiments of the present invention are described.But in the accompanying drawings, the size, ratio etc. of various piece actual conditions of getting along well consistently represent sometimes.In addition, in other instances, due to drawing, the description for thin portion is eliminated.
With reference to the accompanying drawings embodiments of the invention 1 are described.Fig. 1 is the figure of a structure example of the fuel injection system 1 having carried Fuelinjection nozzle 30 of the present invention.In addition, in FIG, the structure of a part for motor 1000 is only indicated.
Fuel injection system 1 shown in Fig. 1, is assembled in the motor 1000 as power source.Motor 1000 is equipped with the Engine ECU (Electronic Control Unit: electric control device) 10 of the motion generally controlling this motor.In fuel injection system 1, include the Fuelinjection nozzle 30 of burner oil in the firing chamber 11 of motor 1000.Engine ECU 10 has the function of control device.Engine ECU 10 is equipped with the ROM (Read Only Memory: ROM (read-only memory)) of the CPU (Central Process Unit: central processing unit (CPU)), storage program etc. that carry out calculation process and stores the RAM (Random Access Memory: random access memory) of data etc. or the computer of NVRAM (Non Volatile RAM: non-volatile random access memory).
Motor 1000 is motors mounted on a vehicle, is equipped with the piston 12 forming firing chamber 11.Piston 12 can slidably be coupled in the cylinder of motor 1000.Further, piston 12 is connected on the bent axle as output shaft component via connecting rod.
From the suction air that suction port 13 flows in firing chamber 11, the ascending motion of piston 12 is utilized to be compressed in firing chamber 11.The information of the position of Engine ECU 10 based on the piston 12 from crank angle sensor and the camshaft rotatable phase from intake cam angle transducer, determines fuel injection timing, signal is sent to Fuelinjection nozzle 30.Fuelinjection nozzle 30 according to the signal of Engine ECU 10, with indicated injection timing burner oil.The fuel atomization of being sprayed by Fuelinjection nozzle 30 also mixes with by the suction air compressed.Further, the fuel be mixed with suction air burns by being lighted a fire by spark plug 18, expands, piston 12 is declined in firing chamber 11.This descending motion is rotated by the axle being altered to bent axle via connecting rod, makes motor 1000 obtain power.
Firing chamber 11 is connected to suction port 13 and inlet air pathway 14, and described suction port 13 is communicated with firing chamber 11, and described inlet air pathway 14 is connected on suction port 13, and suction air is drawn oriented combustion chamber 11 from suction port 13.And then be connected to relief opening 15 and exhaust passageway 16 on the firing chamber 11 of each cylinder, described relief opening 15 is communicated with firing chamber 11, described exhaust passageway 16 is by the waste gas that produces the in a combustion chamber exterior guiding to motor 100.Inlet air pathway 14 is configured with tandem-driving bogie 22.
Inlet air pathway 14 is provided with Air flow meter, closure 17 and engine load sensor.Air mass flow takes into account the aperture that engine load sensor detects suction air quantity by inlet air pathway 14, closure 17 respectively, testing result is sent to Engine ECU 10.Engine ECU 10, based on the testing result sent, identifies suction port 13 and by the suction air quantity imported to firing chamber 11, by adjusting the aperture of closure 17, regulating and sucking air quantity.
Exhaust passageway 16 is provided with turbosupercharger 19.Turbosupercharger 19 utilizes the kinetic energy of the waste gas of circulation in exhaust passageway 16 that turbo machine is rotated, and compresses the suction air that have passed air-strainer and sends into interstage cooler.By the suction air that compresses after being cooled by interstage cooler, be temporarily stored in tandem-driving bogie 22, afterwards, be directed to inlet air pathway 14.In this case, motor 1000 is not limited to the motor with pressurized machine being equipped with turbosupercharger 19, also can be natural aspiration (Natural Aspiration) motor.
Piston 12 has cavity at its end face.The fuel sprayed from Fuelinjection nozzle 30, by from the direction of Fuelinjection nozzle 30 to its wall of Surface forming that the direction continuous print of spark plug 18 is smooth, is directed near spark plug 18 along wall configuration by cavity.In this case, piston 12 can be formed at the middle body of its end face with the recessed combustion chamber etc. of circular formation cavity, and the style according to motor 100 forms cavity with arbitrary position and shape.
Fuelinjection nozzle 30 is installed in the firing chamber 11 of suction port 13 bottom.Fuelinjection nozzle 30 based on the instruction of Engine ECU 10, by the fuel supplied by fuel flow path high pressure from petrolift, from being arranged on the spray orifice 33 of nozzle body 31 front end to firing chamber 11 inner direct.Injected fuel side in firing chamber 11 atomization and with suction air mix, the shape along cavity is directed near spark plug 18.The leaked fuel of Fuelinjection nozzle 30 is returned to fuel tank from relief valve by overflow pipe arrangement.
This Fuelinjection nozzle 30 is not limited to and is arranged on suction port 13 bottom, also can be arranged on the arbitrary position of firing chamber 11.Such as, also Fuelinjection nozzle 30 can be configured to spray from the central authorities upside of firing chamber 11.
In addition, motor 1000 can be petrol engine using gasoline as fuel, using light oil as the diesel engine of fuel, use any one in the flexible fuel engine of the fuel of gasoline and alcohol mixing with arbitrary ratio.In addition, in addition, also can be use the motor that can utilize the fuel of fuel injection valves inject etc.Motor 1000 also can construct the mixed power system combined with multiple motor.
Secondly, the structure for the Fuelinjection nozzle 30 as one embodiment of the present of invention is described in detail.Fig. 2 is the explanatory drawing of the major component representing the Fuelinjection nozzle 30 of embodiment 1 with cross section.Fig. 3 (A) represents that the front end at the Fuelinjection nozzle 30 of embodiment 1 is provided with the explanatory drawing of the state of spray orifice member for prolonging 50, and Fig. 3 (B) is the explanatory drawing of the front end of the Fuelinjection nozzle 30 representing the embodiment 1 being provided with spray orifice member for prolonging 50.
Fuelinjection nozzle 30 is equipped with nozzle body 31, pin guide 32 and needle-valve 33.
Nozzle body 31 is components of tubular, has valve seat surface 31a in inner side.The seat portion 33a that the needle-valve 33 described below is equipped with is located in valve seat surface 31a.Pressure chamber 34 is formed at the upstream side of valve seat surface 31a.In addition, nozzle body 31 is equipped with spray orifice 35 in the downstream side of valve seat surface 31a.The axle center AX1 of spray orifice 35 is consistent with the axle center of nozzle body 31.
Pin guide 32 is arranged in nozzle body 31.Pin guide 32 is components of tubular, and front end is provided with spiral chute 32a.Spiral chute 32a to be equivalent to make be imported in spray orifice 35 and the swirling flow generating unit of the fuel swirl of spraying from spray orifice 35.That is, by being formed at the fuel flow path 40 between the inner circle wall of nozzle body 31 and the terminal side outer circumferential face of pin guide 32, the fuel being once directed to pressure chamber 34 is imported to spiral chute 32a.Whereby, give fuel swirl composition, generate swirling flow.
Needle-valve 33 slidably can be installed on the inner circumferential wall 32b of pin guide 32.Needle-valve 33 is along axle center AX1 direction to-and-fro motion.The forward end of needle-valve 33 is provided with seat portion 33a.In place at valve seat surface 31a by this seat portion 33a, Fuelinjection nozzle 30 becomes closed condition.
With reference to Fig. 2, Fuelinjection nozzle 30 is equipped with driving mechanism 45.Driving mechanism 45 controls the sliding action of needle-valve 33.Driving mechanism 45 is in the past known mechanisms, is equipped with the parts adopting the actuator of piezoelectric element, electromagnet etc. or be suitable for needle-valve 33 action to the resilient member etc. that needle-valve 33 gives suitable pressure.
With reference to Fig. 3 (A), (B), Fuelinjection nozzle 30 is equipped with spray orifice member for prolonging 50 at the front end 31b of nozzle body 31.Fig. 4 is the perspective view of spray orifice member for prolonging 50.Spray orifice member for prolonging 50 is equipped with movable part 51 and compression zone 52.Movable part 51 has cylindrical form, and this cylindrical form has the axis consistent with the axis AX1 direction of spray orifice 35.Compression zone 52 is tabular body, is formed discoid, orthogonal with the axis AX1 of spray orifice 35, and extended from the front-end edge 51a of the movable part 51 of cylindrical form outside the radial direction of nozzle body 31, and its edge, periphery 52a is supported in nozzle body 31.Edge, the periphery 52a of compression zone 52 is by welding edge, the periphery 31b1 of the front end 31b of the nozzle body 31 that is fixed, is supported on.Whereby, compression zone 52 forms space 60 between itself and the front end 31b of nozzle body 31.By forming this space 60, allow the flexure of the compression zone 52 as tabular body.
Between the inner peripheral surface 35a and the outer circumferential face 51b of movable part 51 of spray orifice 35, under atmospheric pressure form gap 61.Like this, by the formation of under atmospheric pressure allowable clearance 61, in the operating accuracy this point that movable part 51 requires, the making of movable part 51 becomes easy.In addition, movable part 51 also becomes easy to the installation of spray orifice 35, and in addition, when making fuel spray actually, by in-cylinder pressure, the movable part 51 of cylindrical form is expanding, and the ladder difference in spray orifice 35 is alleviated.
The pattern being sprayed the fuel injection that 30 carry out by above-described fuel is described.The fuel injection system 1 of Fuelinjection nozzle 30 is equipped with, based on grasping with the numerical value of the engine warm state representated by the coolant water temperature of motor 1000, adjustment injected fuel pressure.By the fuel sprayed from Fuelinjection nozzle 30, owing to becoming swirling flow by spiral chute 32a, and facilitate pelletizing.The object of giving swirling flow is, can improve the good diffusion of fuel and the pelletizing of fuel.The micronized principle of fuel is as described below.In Fuelinjection nozzle 30, form the fireballing swirling flow of convolution, when this rotating flow is imported into spray orifice 35, produce negative pressure at the centre of gyration of this strong swirling flow.When producing negative pressure, the air of the outside of Fuelinjection nozzle 30 attracted in spray orifice 35.Whereby, in spray orifice 35, gas column is produced.The gas column of such generation and the interface of fuel generate bubble.The bubble generated is mixed into the ambient dynamic fuel at gas column, is mixed into stream as bubble, injected together with the flow in fuel moved at periphery effluent.Further, by bubbles burst, the pelletizing of fuel is reached.
Fuel injection system 1, by adjustment injected fuel pressure, can control the rupture time of particle size and the micro air bubble of spraying.Whereby, can according to the operating condition of motor 1000, suppress spraying droplets to the attachment on the wall of firing chamber 11, suppress the generation of oil dilution or PM (Particulate Matter: particulate matter), smog.Further, in firing chamber, form uniform mixed gas, HC (hydrocarbon), CO (carbon monoxide) can be reduced.In addition, due to as suitable fuel pressure, fuel pressure can be improved necessarily, so, the driving loss of petrolift can not be increased, can improve and improve oil consumption.
As shown in Fig. 3 (B), the spray orifice member for prolonging 50 that Fuelinjection nozzle 30 is equipped with, under atmospheric pressure state, forms space 60.When this state, movable part 51 becomes the state released from spray orifice 35, and spray orifice length becomes L1.When spray orifice length is L1, spreading of spray is θ 1.On the other hand, when pressing high state in cylinder, the compression zone 52 that spray orifice member for prolonging 50 is equipped with is subject to high in-cylinder pressure and bends.When compression zone 52 bends, compression zone 52 forward end bends to convex.Further, compression zone 52 makes the volume reducing in space 60, while be pressed into the side, depths (terminal side) of movable part 51 to spray orifice 35.Consequently, spray orifice length becomes L2.When spray orifice length is L2, spreading of spray is θ 2.Here, L1>L2, θ 1< θ 2.With spreading of spray, there is dependency relation with reference to Fig. 6, L/D (spray orifice length/spray orifice aperture).That is, when spray orifice aperture constant, spray orifice length, the value of L/D becomes large.When spray orifice length, when the value of L/D becomes large, spreading of spray diminishes.That is, by adjustment spray orifice length, spreading of spray can be adjusted.
The Fuelinjection nozzle 30 of embodiment 1, according to in-cylinder pressure, compression zone 52 and movable part 51 are relative to the change in location of spray orifice 35, and spray orifice length is adjusted.Compression zone 52 accumulates elastic force by flexure.
Here, such as, when carrying out intake stroke and spraying, when fuel sprays, piston is positioned near BDC (lower dead center), in order to make spraying spread all over firing chamber, obtains uniform mixed gas, ites is desirable to reduce spreading of spray.During intake stroke, compared with during compression stroke, in-cylinder pressure is low.When this state, compression zone 52 does not bend, and movable part 51 is held in place in the state of the forward end of spray orifice 35.Consequently, the state that spray orifice length is long is become.When spray orifice length, spreading of spray diminishes, penetrating power grow.
On the other hand, when carrying out compression stroke and spraying, from the view point of avoiding liquid fuel to piston-top surface attachment, wish angular width of spraying.More particularly, form stratified mixtures when being sprayed by compression stroke, or when carrying out diffusive combustion like that to diesel engine, when fuel sprays, piston is positioned near TDC (top dead center), and the distance of Fuelinjection nozzle and piston is short.Therefore, in order to liquid fuel is not adhered on piston, it is desirable to strengthen spreading of spray.When carrying out compression stroke and spraying, in-cylinder pressure raises.Consequently, movable part 51 is pressed in spray orifice 35, and spray orifice length shortens.As a result, spreading of spray becomes large.Like this, when compression stroke is sprayed, spreading of spray can be strengthened easily.
Below, this function of the compression zone 52 of movable part 51 in spray orifice 35 during movement that makes is described.When the pressure in firing chamber 11 is high, compression zone 52 bends, movable part 51 is pressed into by the upstream side to spray orifice 35.The compression zone 52 of deflected plays elastic force.Therefore, when pressure step-down in firing chamber 11, compression zone 52 makes oneself to return to original position by the elastic force that oneself plays, and accompanies therewith, makes movable part 51 return to original position.
As explained above, Fuelinjection nozzle 30 is according to in-cylinder pressure, and movable part 51 changes relative to the position of spray orifice 35, adjustment spray orifice length.Like this, movable part 51 can move in spray orifice 35.The mobile sediments that fuel injection system 1 can carry out make use of such movable part 51 is removed.Because spray orifice 35 is exposed to the firing chamber of high temperature, so, accumulative deposit thing sometimes in spray orifice 35.When sediment pile is in spray orifice 35, also exist by the worry that the flow of the fuel in spray orifice 35 reduces and generation spraying changes.Therefore, sprayed by the fuel carried out energetically under the state of movable part action, carry out sedimental removal.Below, the example carrying out the control of sediments removal is described with reference to the flow chart shown in Fig. 7.This control is carried out using ECU10 as main body.
First, in step S1, read compression stroke injecting times: Tc and the interval of terminating after previous compression stroke is sprayed: Tint.These values, spray resume as fuel and are often updated, be stored in ECU10.
In step S2, judge that whether Tc is at predetermined more than threshold value Tc0.Here, threshold value Tc0 is set to 10 times.When being judged as "Yes" in step s 2, enter step S3.On the other hand, when being judged to be "No" in step s 2, that is, when not carrying out the compression stroke injection of stipulated number within specified time limit, enter step S4.When being judged as "Yes" in step s 2, compression stroke is sprayed and is carried out continually.Due to burner oil under the state that compression stroke is injected in movable part 51 action, so sediments is easily removed.In more detail, in compression stroke, movable part 51 action, the sediments be deposited on the inner circumferential wall of spray orifice 35 and movable part 51 becomes and is easily stripped.When carrying out fuel when this state and spraying, sediments becomes and is more easily removed.Therefore, in step S3, compression stroke is sprayed mark and closes.In addition, to Tint accumulated counts, Tint+1 is updated to.In addition, the value of Tc is removed, makes Tc=0.
On the other hand, in step 4, judge that whether Tint is at predetermined more than threshold value Tint0.Here, threshold value Tint0 is set to 30,000 circulation.This 30,000 circulation be equivalent to by motor 1000 with 2,000rpm operate 30 minutes time period.When step S4 is judged as "Yes", enter step S5.When being judged as "No" in step s 4 which, enter step S3.Step S3 is entered when why being judged as "No" in step s 4 which, even if be based on when compression stroke injection does not reach threshold value Tc0 (=10 times), do not reaching 30, when 000 circulation, also can not carry out the judgement of sedimental removal.In step S5, compression stroke is sprayed mark and opens.In addition, Tint is removed, makes Tint=0.In addition, by Tc accumulated counts, Tc+1 is updated to.
In the step S6 that then step S3 and step S5 carries out, judge that compression stroke is sprayed mark and whether opened.When being judged as "Yes" in step s 6, enter step S7, carry out compression stroke injection.Whereby, because compression zone 52 bends, burner oil under the state in movable part 51 action, so sedimental removal becomes easy.At this moment, also a part for the fuel injection amount distributing to this circulation can be sprayed as compression stroke.Such as, also 80% of necessary for this circulation fuel injection amount can be sprayed as intake stroke, spray remaining 20% as compression stroke.When being judged as "No" in step s 6, enter step S8, carry out intake stroke injection.After step S7 or step S8, process returns.
In addition, even if due to when having carried out beyond compression stroke injection, sometimes also can bend by compression zone 52 because of the state of in-cylinder pressure, movable part 51 action, so, the effect of also wait in expectation sedimental stripping, removal.But, by making movable part 51 action as above-mentioned control energetically, can peel off, remove sediments.In addition, due to the temperature variation around the spray orifice that sprays along with compression stroke, sediments is removed, cleaning performance can improve further.
Secondly, with reference to Fig. 8 and Fig. 9, embodiment 2 is described.The difference of embodiment 2 and embodiment 1 is the structure of spray orifice member for prolonging.That is, embodiment 2 replaces the spray orifice member for prolonging 50 of embodiment 1, and is equipped with spray orifice member for prolonging 71.Because other structure of embodiment 2 does not have different from embodiment 1, so for common structure member, give identical reference character in the accompanying drawings, description is omitted.
Fig. 8 (A) is the explanatory drawing of the front end of the Fuelinjection nozzle 70 representing embodiment 2, and Fig. 8 (B) is the explanatory drawing of the state representing that spray orifice member for prolonging 71 moves, spray orifice length is short.Fig. 9 is the sectional view of the spray orifice member for prolonging 71 that the Fuelinjection nozzle 70 of embodiment 2 is equipped with.
Spray orifice member for prolonging 71 is divided into two parts, and is equipped with the movable part 72 and compression zone 73 that are formed separately, they is combined and forms described two-part.Movable part 72 has cylindrical form, turns back in its forward end edge, by being riveted on discoid compression zone 73, engages with compression zone 73.Like this, by riveted joint, in its continuous portion, both are joined together, thus, form jut 74 at the front end of movable part 72.Jut 74 is outstanding to the direction residing for the piston 12 that motor 1000 is equipped with.
Spray orifice member for prolonging 71, is joined together movable part 72 and compression zone 73 by riveted joint, thus improves rigidity.Whereby, the distortion of spray orifice member for prolonging 71 is suppressed.In addition, by thinning for spray orifice member for prolonging 71, consequently, movable part 72 can be reduced poor with the ladder of spray orifice 35.Consequently, the disorder of the flow in fuel in spray orifice 35 can be suppressed, the generation of the uniform micro air bubble caused by strong swirling flow can be promoted.In addition, by forming jut 74, the wall attachment effect of the opening edge portion at spray orifice 35 can be suppressed.That is, when the opening edge portion of spray orifice 35 becomes smooth curved shape (rounded shapes), due to wall attachment effect, spray along the lower surface of compression zone and expand, the variation that there is the fuel of the peripheral part in spraying becomes large worry.Therefore, by arranging jut 74, can wall attachment effect be suppressed, suppressing the variation of the fuel of the peripheral part of spraying.
Secondly, with reference to Figure 10, embodiment 3 is described.Embodiment 3 is using the example of the space 60 in embodiment 1 as gas compartment 80.Specifically, in embodiment 3, by narrow than embodiment 1 of the gap of the inner peripheral surface 35a of spray orifice 35 and the outer circumferential face 51b of movable part 51, space 60 and the outside area of embodiment 1 separated, makes it to play a part as gas compartment 80.Under the state that gas compartment 80 exists air in space, by improving its leak tightness, play a part buffer.As long as the constant one-tenth vacuum state of gas compartment 80.In the gas compartment 80 of embodiment 3, become the state being filled with air.In gas compartment 80, also can enclose other gas in addition to air.In addition, because other structure member does not have different from embodiment 1, so for common structure member, give identical reference character in the accompanying drawings, description is omitted.
In the action of spray orifice member for prolonging 50 in embodiment 3, except the elastic force of compression zone 52 illustrated in embodiment 1, the pressure in gas compartment 80 is also had to work.Specifically, under the state of the elastic force resistance in-cylinder pressure of the pressure in gas compartment 80 and compression zone 52, movable part 51 is maintained at the state of the forward end being positioned at spray orifice 35, and spray orifice length becomes long state.When spray orifice length, spreading of spray diminishes, penetrating power grow.When in-cylinder pressure exceedes the elastic force of pressure in gas compartment 80 and compression zone 52, compression zone 52 bends, and movable part 51 is pressed into by the upstream side to spray orifice 35.Thus spray orifice length shortens.Reduce at in-cylinder pressure, movable part 51 and compression zone 52 be when returning to original position, bent by compression zone 52 and pressure in the elastic force that plays and gas compartment 80 acts on compression zone 52, make movable part 51 and compression zone 52 return to original position.
Above-described embodiment.Only for implementing example of the present invention, the present invention not limit by them, these embodiments are carried out all distortion also within the scope of the invention, and then, obviously, from above-mentioned description, other various embodiment is possible within the scope of the invention.
Such as, as shown in figure 11, the position of spark plug 18 can be set to that igniting position when making compression stroke is near the spraying visible outline that spreading of spray becomes maximum.Such as, as shown in figure 11, spark plug 18 is arranged so that ignition location is in and carries out compression stroke injection, near the visible outline of spraying when becoming spreading of spray θ 2.Thus only when the compression stroke forming stratified mixtures is sprayed, spark plug is kept off in spraying.Consequently, the sooting of the spark plug 18 worried when carrying out layering running can be suppressed.
30,70 Fuelinjection nozzles
31 nozzle bodies
31a valve seat surface
32 pin guide
32a spiral chute
33 needle-valves
33a seat portion
35 spray orifices
40 fuel flow paths
50 spray orifice member for prolongings
51 movable parts
52 compression zones
80 gas compartments
AX1 axis
1. a Fuelinjection nozzle, is equipped with:
Needle-valve, described needle-valve has seat portion in forward end;
Nozzle body, described nozzle body has described seat portion valve seat surface in place, and, in the downstream side of described valve seat surface, there is spray orifice; And
Spray orifice member for prolonging, described spray orifice member for prolonging is equipped with compression zone and movable part, described compression zone accepts the pressure in the firing chamber of motor, the pressure that described movable part and described compression zone accept correspondingly moves in described spray orifice along the axial direction of described spray orifice, makes the length change of spray orifice.
2. Fuelinjection nozzle as claimed in claim 1, described compression zone forms gas compartment between this compression zone and the front end of described nozzle body.
3. Fuelinjection nozzle as claimed in claim 1 or 2, described movable part forms the cylindrical form being equipped with the axis consistent with the axial direction of described spray orifice, described compression zone is tabular body, the axis vertical take-off of described tabular body and described spray orifice, and, extended outside the radial direction of described nozzle body from the front-end edge of described movable part, its edge, periphery is supported in described nozzle body.
4. Fuelinjection nozzle as claimed any one in claims 1 to 3, between the inner peripheral surface and the outer circumferential face of described movable part of described spray orifice, under atmospheric pressure forms gap.
5. the Fuelinjection nozzle according to any one of Claims 1-4, is equipped with jut in the continuous portion of described movable part and described compression zone, and described jut is outstanding to the direction residing for the piston that described motor is equipped with.
6. the Fuelinjection nozzle according to any one of claim 1 to 5, is equipped with the swirling flow generating unit making the fuel swirl of spraying from described spray orifice.
7. a fuel injection system, is equipped with:
Fuelinjection nozzle according to any one of claim 1 to 5; And
Control the control device of the timing carrying out fuel injection from described Fuelinjection nozzle,
Described control device sprays resume based on fuel, when the compression stroke of carrying out within specified time limit is sprayed less than stipulated number, makes described Fuelinjection nozzle carry out compression stroke injection.
CN201280073100.6A 2012-05-11 2012-05-11 Fuel injection valve and fuel injection device with same CN104334865A (en)
PCT/JP2012/062208 WO2013168292A1 (en) 2012-05-11 2012-05-11 Fuel injection valve and fuel injection device with same
CN104334865A true CN104334865A (en) 2015-02-04
ID=49550373
CN201280073100.6A CN104334865A (en) 2012-05-11 2012-05-11 Fuel injection valve and fuel injection device with same
US (1) US20150090225A1 (en)
EP (1) EP2848799A4 (en)
JP (1) JP5949908B2 (en)
CN (1) CN104334865A (en)
WO (1) WO2013168292A1 (en)
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2012-05-11 JP JP2014514337A patent/JP5949908B2/en active Active
2012-05-11 EP EP12876307.5A patent/EP2848799A4/en not_active Withdrawn
2012-05-11 WO PCT/JP2012/062208 patent/WO2013168292A1/en active Application Filing
2012-05-11 CN CN201280073100.6A patent/CN104334865A/en not_active IP Right Cessation
2012-05-11 US US14/394,555 patent/US20150090225A1/en not_active Abandoned
JP5949908B2 (en) 2016-07-13
WO2013168292A1 (en) 2013-11-14
EP2848799A1 (en) 2015-03-18
US20150090225A1 (en) 2015-04-02
EP2848799A4 (en) 2015-08-19
JPWO2013168292A1 (en) 2015-12-24
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