CN101545429B - Electric control VE dispensing pump for directly measuring advance angle by inductance type transducer - Google Patents
Electric control VE dispensing pump for directly measuring advance angle by inductance type transducer Download PDFInfo
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- CN101545429B CN101545429B CN2009101117153A CN200910111715A CN101545429B CN 101545429 B CN101545429 B CN 101545429B CN 2009101117153 A CN2009101117153 A CN 2009101117153A CN 200910111715 A CN200910111715 A CN 200910111715A CN 101545429 B CN101545429 B CN 101545429B
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- proportioning pump
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- pump
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- 239000000446 fuel Substances 0.000 claims description 22
- 230000001939 inductive effect Effects 0.000 claims description 15
- XEEYBQQBJWHFJM-UHFFFAOYSA-N Iron Chemical group [Fe] XEEYBQQBJWHFJM-UHFFFAOYSA-N 0.000 claims description 11
- 229910000831 Steel Inorganic materials 0.000 claims description 4
- 230000033001 locomotion Effects 0.000 claims description 4
- 239000010959 steel Substances 0.000 claims description 4
- 238000012423 maintenance Methods 0.000 abstract description 4
- 238000005516 engineering process Methods 0.000 abstract description 3
- 239000003921 oil Substances 0.000 description 16
- 230000000630 rising effect Effects 0.000 description 7
- 230000005540 biological transmission Effects 0.000 description 4
- 239000010761 intermediate fuel oil Substances 0.000 description 4
- 238000002347 injection Methods 0.000 description 3
- 239000007924 injection Substances 0.000 description 3
- 238000007789 sealing Methods 0.000 description 3
- 230000000694 effects Effects 0.000 description 2
- 239000000295 fuel oil Substances 0.000 description 2
- 238000000034 method Methods 0.000 description 2
- 238000012546 transfer Methods 0.000 description 2
- 230000008878 coupling Effects 0.000 description 1
- 238000010168 coupling process Methods 0.000 description 1
- 238000005859 coupling reaction Methods 0.000 description 1
- 239000010727 cylinder oil Substances 0.000 description 1
- 230000007423 decrease Effects 0.000 description 1
- 238000011161 development Methods 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 238000007599 discharging Methods 0.000 description 1
- 238000005259 measurement Methods 0.000 description 1
- 238000012545 processing Methods 0.000 description 1
- 230000001105 regulatory effect Effects 0.000 description 1
- 239000007921 spray Substances 0.000 description 1
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- Fuel-Injection Apparatus (AREA)
- High-Pressure Fuel Injection Pump Control (AREA)
Abstract
The invention relates to an electric control VE dispensing pump for directly measuring an advance angle by an inductance type transducer, which comprises a VE dispensing pump with a mechanical governor and an inductance type advance angle sensor; and the inductance type advance angle sensor is arranged at the front end of a dispensing shell of the VE dispensing pump for directly measuring the start time for oil supply of a VE pump. The electric control VE dispensing pump increases the cam rise of the VE dispensing pump on the one hand, and improves oil supply pressure, and accurately controls the oil supply advance angle by electric control technology on the other hand; and the prior mechanical governor is adopted to control the oil supply quantity, and an EGR valve is matched for use, so that the discharge of a diesel engine achieves Europe 3 standard, and the electric control VE dispensing pump has simple structure, low price and convenient maintenance.
Description
Technical field
The present invention relates to a kind ofly control fuel delivery with mechanical governor, the automatically controlled VE proportioning pump of fuel supply advance angle is directly measured and controlled to inductive transducer.
Background technique
In order to make China's high-speed small-size diesel engine satisfy Europe 3 emission requests, adopting automatically controlled VE proportioning pump is to select preferably.Because China has produced VE proportioning pump more than ten years by batch, technology is ripe, and fittings supply and maintenance easily but still can't realize automatically controlledization of VE proportioning pump so far.
Summary of the invention
The object of the present invention is to provide a kind of automatically controlled VE proportioning pump of directly surveying advance angle with inductive pickup simple in structure, cheap, easy to maintenance.
Technological scheme of the present invention is following: it comprises VE proportioning pump, sensor, driving gear, high-speed electromagnetic valve, proportioning pump mounting plate, a TDCS TDC Sensor of directly surveying advance angle with inductance element of a band mechanical governor; It is characterized in that: the sensor of directly surveying advance angle with inductance element is installed in the front end that band mechanical governor VE proportioning pump distributes shell.
In order to measure the oil pump feed initial point, in the front portion of VE proportioning pump distribution shell, the barrel valve of a precision is installed directly, an end of barrel valve communicates with the proportioning pump plunger cavity, and the other end is equipped with the inductive transducer of measuring the barrel valve motion.When VE proportioning pump plunger moves upward, produce pressure at the plunger cavity intermediate fuel oil and make barrel valve rising 0.2-0.8 millimeter earlier, push up lid and produce high pressure again and be assigned in each cylinder; The motor message of barrel valve is just outputed among the ECU ECU by inductive transducer, calculates the declinate of engine tope center signal and these signals through computer; Then according to engine speed, temperature, parameters such as air pressure; Through high-speed electromagnetic valve control advance angle piston stroke; Thereby the slewing area of control roller base makes diesel engine reach best fuel supply advance angle, and its working principle is seen shown in Figure 1.Z is a cam angle among the figure, and K is the top dead center signal, and cam of injection pump whenever circles and produces a fixed signal relatively.P1 is the motor message of barrel valve; The cam of injection pump axle whenever circles; Produce four signals (four cylinder oil pumps); Angle T between the rising edge of barrel valve motion when measuring top dead center signal rising edge and a certain oil supply cylinder changes then like advance angle that signal can change to P2 from P1, as long as just can calculate fuel supply advance angle.
One aspect of the present invention increases VE proportioning pump cam lift; Improve charge oil pressure, control fuel supply advance angle accurately with electronic control technology on the other hand, the fuel supply rate curve that control is best; Adopt existing mechanical speed regulator control fuel delivery, cooperate the EGR valve to make diesel emission reach Europe 3 standards.Automatically controlled VE proportioning pump of the present invention is simple in structure, cheap, easy to maintenance.Can save huge development cost and time.
Below in conjunction with accompanying drawing structure of the present invention and working principle are further specified.
Description of drawings
Fig. 1 is automatically controlled VE proportioning pump advance angle principle of measurement figure of the present invention.
Fig. 2 is the automatically controlled VE proportioning pump structural drawing of band mechanical governor of the present invention.
Fig. 3 is the schematic diagram of automatically controlled VE proportioning pump advance angle control of the present invention.
VE proportioning pump, B inductance type advance angle sensor, C high-speed electromagnetic valve, D TDCS TDC Sensor, Z cam angle direction, K top dead center signal, P barrel valve motor message, the T fuel supply advance angle of A band mechanical governor among the figure; 1 transmission shaft; 2 oil transfer pumps; 3 roller base; 4 pins; 5 advancing device pistons; 6 rollers; 7 cam type surfaces; 8 cams; 9 piston springs; 10 sleeve oil outlets; 11 shell oil outlets; 12 control covers; 13 is fuel-displaced poor; 14 distribute sleeve; 15 outlet valves; 16 distribute plunger; 17 plunger cavities; 18 distribute shell; 19 distribute sleeve end face; 20 oil inlet holes; 21 spill ports; 22 hyperbaric chambers; 23 advance device springs; 24 low pressure chamber; Roller base sense of rotation during 25 injection advances; 26 cam rotation directions; 27 proportioning pump mounting plates; 28 transmitting gears; 29 magnet steel; 30 cylinder valve seats; 31 sensor overcoats; 32 barrel valves (label location is wrong among the figure); 33 cylinder valve gaps; 34 spring seats; 35 springs; 36 riveting points; 37 briquettings; 38 protecting jackets; 39 conical surfaces; Iron core in 40; 41 seal rings; 42 small sealing rings; 43 pads; 44 leads; 45 coils; 46 inner conical surfaces; 47 iron core sleeve; 48 Hall elements; 49 sensor outer housings; 50 setting sleeves; 51 screws; 52 clues.
Embodiment
Like Fig. 1, shown in 2, at distribution shell 18 front ends of mechanical speed governors VE proportioning pump A, inductance type advance angle sensor B is installed, advancing device piston 5 and high-speed electromagnetic valve C are equipped with in the oil pump bottom, and TDCS TDC Sensor D is installed on the proportioning pump mounting plate 27.Mechanical governor is used for regulating the oil pump feed amount in control control cover position.Fuel supply advance angle then passes through high-speed electromagnetic valve C by electronic control unit ECU, and by inductance type advance angle sensor B, TDCS TDC Sensor D the closed loop control signal is provided, and directly controls fuel feeding system advance angle.
Structure and the working principle of described top dead center signal emitter D are following: top dead center signal emitter D is the sensor that the Hall inductance element is housed.Hall inductance element 48 is installed in the sensor outer housing 49, and is fixed on the proportioning pump mounting plate 27 with setting sleeve 50 and screw 51, and the appropriate location on the driving gear 28 is equipped with a powerful magnet steel 29.When driving gear 28 rotates, can pass through clue 52 to control unit ECU output pulse signal during magnet steel 29 process Hall elements 48, thereby calculate the engine tope center position.Top dead center signal emitter D also can be directly installed on the suitable position of diesel engine cylinder block by the diesel engine requirement.
As shown in Figure 3, described inductance type advance angle sensor B is used for measuring fuel feeding zero hour.It is pressed on oil pump by sensor outer housing 31 with cylinder valve seat 30, barrel valve 32, cylinder valve gap 33 and distributes on the highi degree of accuracy end face 19 of sleeve.Cylinder valve seat 30 is a pair of precision pairs with barrel valve 32, gap 0.001-0.004 millimeter.Cylinder valve seat 30 bottom surfaces also are high precision plane, to guarantee the sealing in the plunger cavity 17.Be provided with spring 35 in the shell 31, spring 35 is pressed in spring seat 34 and barrel valve 32 on the cylinder valve seat 30, and spring seat 34 the other ends are conical surfaces, the inner conical surface 46 in leaving on the iron core 40 apart from the 0.5-08 millimeter.Sensor outer housing 31 right-hand members are provided with seal ring 41,42, to guarantee sealing.Inductive pickup is iron core 40 by the conical surface 39, interior iron core 40, the iron core sleeve 47 of spring seat 34 and in being contained in; Coil 45 between the iron core sleeve 47 is formed; Compact heap 37 is installed behind the inductive pickup,, inductive pickup is compressed in the riveted joint of end face 36 places of sensor outer housing 31.
When driving gear 51 drove oil pump drive spindle 1 rotation, transmission shaft 1 drove built-in oil transfer pump 2 and rotates, and fuel oil is pressurized to about 0.1~1Mpa.High pressure fuel leads in the hyperbaric chamber 22 of advancing device piston 5, as the power source of control advancing device piston 5 motions.Transmission shaft 1 also drives cam 8 simultaneously and rotates with plunger 16.When the protruding profile 7 on the cam 8 turn to roller base 3 in roller 6 contact, plunger 16 just rises with cam 8, and in plunger cavity 17, produces high pressure fuel.High-speed electromagnetic valve D is located between the oilhole 20 and 21 of advancing device piston 5, controls the break-make of this two oilhole.Oilhole 20 connects the hyperbaric chamber 22 of piston 5, and oilhole 21 connects piston 5 the other end low pressure chamber 24, and the return spring 23 of piston 5 is installed in the low pressure chamber 24.
High-speed electromagnetic valve D cuts off this two oilhole when rotating speed rises, and hyperbaric chamber 22 intermediate fuel oil pressure can increase, and hydraulic coupling overcomes the active force that acts on piston 5 upper springs 23, and piston 5 is rotated roller base 3 through pin 4 to the direction of arrow 25 indications.Cam is pressed the direction transmission of arrow 26; Be contained in the roller base 3 roller 6 in advance with cam 8 on protruding profile 7 contact; Feeding plunger 16 rises in advance; In plunger cavity 17, form pressure, the active force that forces barrel valve 32 to overcome spring 35 rises, until push up cover 33 till (stroke about 0.2~0.5mm).Pressure continues to rise in the plunger cavity 17, and opens outlet valve 15 through distributing chute 13 and oilhole 10,11, leads in the cylinder of diesel engine and goes.
When barrel valve 32 risings, the other end conical surface 39 of spring seat 34 makes the changes of magnetic field in the coil 45 produce pulse signal rapidly near the inner conical surfaces 46 of interior iron cores 40, is transferred to by clue 44 and carries out signal processing among the control unit ECU, measures fuel supply advance angle.If it is too big to calculate advance angle T; Then ECU instructs high-speed electromagnetic valve C to open oil duct at once; Fuel oil flows to the low pressure chamber 24 of piston 5 through oilhole 20,21 from the hyperbaric chamber 22 that shifts to an earlier date piston 5; Hyperbaric chamber 22 intermediate fuel oil pressure reduce, and return spring 23 is pushing away piston 5, drive the counter-rotation of roller base 3 to arrow 25 through pin 4.On the cam 8 the corner that contacts of protruding profile 7 and roller 6 postpone; Plunger 16 just postpones to rise with barrel valve 32; The signal delay that electromagnetic sensor sends passes among the ECU, and top dead center edge that the ECU measuring meter is calculated and barrel valve move, and angle T reduces between the signal of rising edge, the fuel feeding time-delay.Otherwise T is too little for fuel supply advance angle, and then ECU instructs high-speed electromagnetic valve C to close oil duct at once, and hyperbaric chamber 22 intermediate fuel oil pressure rise, and hydraulic pressure is pushing away piston 5, overcomes spring pressure and drives the direction rotation of roller base 3 to arrow 25 through pin 4.On the cam 8 protruding profile 7 and roller 6 contact corner in advance; Plunger 16 just rises with barrel valve 32 in advance; The signal that the electromagnetism inductive pickup sends passes among the ECU in advance; Top dead center edge that the ECU measuring meter is calculated and barrel valve move, and angle T strengthens between the signal of rising edge, and fuel supply advance angle increases.Fuel feeding finishes pressure decline in the back-plunger chamber 17, and barrel valve 32 is taken a seat under spring 35 effects, waits for the next fuel feeding cycle.
Because the control of control unit ECU makes the oil pump advance angle be controlled at the optimum state according to the diesel engine operating condition, thereby can improve diesel powered performance and exhaust index always.
The thickness of pad 43 can be used for adjusting the pretightening force of cylindrical spring 35; The rate of climb and the time of control barrel valve 32; Be used for adjusting the initial stage oil-supply speed of VE proportioning pump,, thereby reduce diesel engine noise and NOx discharging with the amount of fuel that sprays in the minimizing diesel engine delay period.The lift H of barrel valve 32 (fuel feeding pretravel) can adjust as requested.Oil pump whenever circles simultaneously, 4 times (4 cylinder diesel) of barrel valve 32 risings, but Input Control Element ECU is used for measuring the rotating speed of calculating diesel engine, plays the effect of multiple sensors.
Claims (5)
1. directly survey the automatically controlled VE proportioning pump of advance angle with inductive pickup for one kind, it comprises VE proportioning pump, sensor, driving gear, high-speed electromagnetic valve, proportioning pump mounting plate, a TDCS TDC Sensor of directly surveying advance angle with inductance element of a band mechanical governor; It is characterized in that: the sensor of directly surveying advance angle with inductance element is installed in the front end that band mechanical governor VE proportioning pump distributes shell.
2. the automatically controlled VE proportioning pump of directly surveying advance angle with inductive pickup according to claim 1; It is characterized in that: the described sensor of directly surveying advance angle with inductance element comprises: be provided with barrel valve, cylinder valve seat, cylinder valve gap, the spring seat of an end band conical surface, spring, briquetting, protecting jacket, interior iron core, seal ring, inductance coil, core retainer plate in sensor outer housing, the sensor outer housing; During oil pump feed; Barrel valve rises and drives the conical surface on the spring seat; Near the inner conical surface of iron core in the inductance coil, the magnetic field in the coil is changed, to control unit ECU output electrical signal; When fuel feeding finishes, force spring seat and barrel valve reposition by spring force.
3. the automatically controlled VE proportioning pump of directly surveying advance angle with inductive pickup according to claim 2; It is characterized in that: described barrel valve and cylinder valve seat are a pair of precision pairs; Gap 0.001-0.004 millimeter; Barrel valve to-and-fro motion in cylinder valve seat and cylinder valve gap, the stroke 0.2-0.8 millimeter of barrel valve, the interior iron core cylindrical and the sensor inwall of inductance coil are provided with rubber seal.
4. according to claim 1ly directly survey the automatically controlled VE proportioning pump of advance angle with inductive pickup, it is characterized in that: described TDCS TDC Sensor is the Hall inductive pickup, is installed on the proportioning pump mounting plate, perhaps is installed on the diesel engine cylinder block.
5. according to claim 1ly directly survey the automatically controlled VE proportioning pump of advance angle, it is characterized in that with inductive pickup: on the driving gear, with the corresponding position of TDCS TDC Sensor Hall inductance element on be provided with a magnet steel.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
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CN2009101117153A CN101545429B (en) | 2009-05-11 | 2009-05-11 | Electric control VE dispensing pump for directly measuring advance angle by inductance type transducer |
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CN2009101117153A CN101545429B (en) | 2009-05-11 | 2009-05-11 | Electric control VE dispensing pump for directly measuring advance angle by inductance type transducer |
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CN101545429A CN101545429A (en) | 2009-09-30 |
CN101545429B true CN101545429B (en) | 2012-01-11 |
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CN110671249B (en) * | 2019-09-25 | 2023-07-07 | 南京威孚金宁有限公司 | Distribution pump plunger with oil outlet valve and working method thereof |
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