DE102015213823A1 - suction - Google Patents

Abstract

The invention relates to a suction valve, in particular an electric suction valve, for a high-pressure pump with an inlet valve (22) and a movable armature (20) for actuating the suction valve (18), which cooperates with a spring (12) in a first state Opening the suction valve (18) causes, wherein the spring (12) has a progressive spring characteristic and such a pump.

Description

The invention relates to an electric suction valve, in particular an electric suction valve in a high pressure pump of a common rail diesel engine, and such a pump, which is designed in particular as a high-pressure pump. This high-pressure pump is, for example, set up for use in a common-rail diesel engine or a direct-injection gasoline engine.

State of the art

Suction valves are used in pumps for controlling an inflow of a liquid. If the suction valve is controlled by an electrical signal, this is referred to as an electric suction valve. In this usually an electromagnet is used, which cooperates with a coil to move an armature. The movement actuates the suction valve, d. H. this is open depending on the anchor position or open or closed or closed.

Such suction valves, in particular electric suction valves (eSV), are used, for example, in high-pressure pumps in common-rail injection systems. In such high-pressure pumps, the fuel supply takes place regularly via complex flow channels in the pump housing. The fuel is first passed through the pump housing before it passes through a suction valve in a pump working space of the high-pressure pump. Instead of the suction valve may be connected upstream of a metering unit, which controls the amount of fuel which is supplied to the pump working space.

In particular, in common-rail diesel engines electric suction valves are used for pressure control in the inlet of the high-pressure fuel system. The electric suction valve is open energized because it is pressed by a spring. In this case, the high-pressure pump can not deliver fuel into the rail pressure system, because the fuel is pushed back into the intake path. Currently used current controllers are usually two-position controller, which interrupt the circuit when the predetermined target current is reached. When the coil of the electric suction valve is energized, the coil current increases in the form of an e-function. If the current and thus the magnetic field is sufficiently large, the inlet valve closes. If this occurs in the compression phase of the high-pressure pump and the pressure in the pump chamber is greater than the pressure in the high-pressure accumulator (rail), then opens the hydraulic exhaust valve and the fuel is pumped from the pump room into the high-pressure accumulator.

A high-pressure pump for a fuel injection system is from the document WO 2014/102026 A1 known. This includes a cylinder head and a suction valve, which is integrated to supply the high-pressure pump with fuel in the cylinder head or attached to this. It is provided that a low-pressure port is provided directly on the cylinder head or on the suction valve, which is to be connected to a low-pressure fuel line of the fuel injection system.

Disclosure of the invention

Against this background, an electric suction valve according to claim 1 and a pump with the features of claim 8 are presented. Embodiments result from the dependent claims and the description.

It is herein a spring with progressive spring characteristic, which can also be referred to as a progressive spring used. The spring characteristic describes the dependence of the spring force F on the deflection s of the spring, the so-called spring travel. In a progressive characteristic, the ratio of spring force to deflection is not linear, but the spring force increases more with increasing deflection. The spring characteristic may, for example, take an exponential course.

• a. ein Federstahl mit variablem Drahtdurchmesser,
• b. kegelförmiger Aufbau,
• c. eine Tellerfeder mit progressiver Charakteristik, was wegen geringem Federweg vorteilhaft ist,
• d. eine gestufte Feder, weich bis zum "vollen Einfedern" von 1. Feder und dann hart mit 2. Feder. Es kommt nicht auf Linearität an, da das Saugventil immer voll ein- oder ausgeschaltet ist.

Possible realizations could be:

• a. a spring steel with variable wire diameter,
• b. conical structure,
• c. a plate spring with progressive characteristics, which is advantageous because of the limited travel,
• d. a stepped spring, soft to the "full compression" of 1. spring and then hard with 2. spring. It does not depend on linearity, as the suction valve is always fully on or off.

The presented suction valve makes it possible to achieve the lowest possible switching time of the valve for a precisely definable rail pressure build-up. Both the opening and closing times are very short.

The presented electric suction valve is characterized by the use of a progressive spring. The advantage is a faster opening and closing at the beginning of each switching operation. In addition, the anchor stops can be made softer, which avoids springing back of the valve.

In a progressive spring, the spring force F does not change linearly with the deflection s from the rest position. This means that in a suction valve, in particular an electric suction valve, when the spring is compressed to an ever greater extent. If the electric suction valve is de-energized, it will be by the spring kept open. At the beginning of the closing process when energizing the magnet, the valve undergoes a smaller spring force and thus by a higher force surplus of the magnet an increased acceleration than the attack in the upper seat. On the one hand, the closing speed is increased, on the other hand, the upper stop, since there is a lesser excess of force and a lower acceleration, be made softer, which allows the avoidance of a spring-back valve.

If the magnetic circuit is interrupted and the valve is opened again, the spring force is initially greatest when the spring is compressed and falls off towards the lower stop. This means that the spring expands faster at the beginning of the shift and the valve opens faster at the beginning. Also, the stop in the lower valve seat can be designed so softer and springing back of the valve can be reduced.

The electric suction valve of the type described above can basically be used in all pumps. For example, an application can be made in solenoid valve injectors, etc., wherever a spring, which defines a rest position, while an electrical actuator bridges the spring force to occupy the other rest position.

Further advantages and embodiments of the invention will become apparent from the description and the accompanying drawings.

It is understood that the features mentioned above and those yet to be explained below can be used not only in the particular combination indicated, but also in other combinations or in isolation, without departing from the scope of the present invention.

Brief description of the drawings

1 shows a high pressure pump with electric suction valve.

2 shows the functional principle of a high-pressure pump with electric suction valve.

3 shows in a graph the course of a spring force as a function of the deflection for a progressive spring compared to a linear spring.

Disclosure of the invention

Embodiments of the invention

The invention is schematically illustrated by means of embodiments in the drawings and will be described in detail below with reference to the drawings.

In 1 is shown in two perspectives a pump of the type described, in total with the reference numeral 10 is designated. This is designed in this illustration as a high-pressure pump. The illustration shows a spring 12 , which is designed as a progressive spring, ie as a spring with progressive spring characteristic. Furthermore, the illustration shows an electromagnet 14 that with a spool 16 interacts and a magnetic circuit of a suction valve 18 forms.

This suction valve 18 , which is designed as an electric suction valve in this embodiment, comprises the spring 12 , the electromagnet 14 , the sink 16 , an anchor 20 and an inlet valve 22 , which is designed here as a hydraulic inlet valve. By driving the electromagnet 14 will be over the coil 16 the anchor 20 moves, up and down in this illustration. This turns the inlet valve 22 operated, ie open or closed.

By energizing the armature or by its movement against the spring to the upper stop, the spring force, which keeps the actual valve open, suppressed. In 2 you can see that the spring is compressed when closing the valve. Hydraulic forces in the compression phase due to the piston movement and the flow through the valve seat now move the valve "behind the armature" to the closed position, whereby the pressure builds up in the valve chamber and the fuel delivery begins.

The opening of the valve after the fuel delivery is on the one hand by the spring, when not energized valve, and on the other hand by hydraulic forces during piston movement down ("suction phase") causes. The valve moves independently of the armature. However, the anchor must be at least at the bottom stop when the next compression phase begins. A repeatable fast switching on and off of the armature, especially at high speeds, is required for the good function of the suction valve or eSV.

Furthermore, the representation of the 1 an outlet valve 24 , which acts as a check valve and is designed as a hydraulic outlet valve, a pump chamber 26 , a pump piston 27 and a pump cam 28 with top dead center. The illustrated pump 10 thus includes the suction valve 18 , the exhaust valve 24 , the pump room 26 , the pump piston 27 and the pump cams 28 ,

2 illustrates the principle of operation of a high pressure pump with electric suction valve. The high-pressure pump is in total with the numeral 40 denotes a first state or operating state 40a , a second state 40b , a third state 40c and a fourth state 40d are reproduced. These states relate to states or operating states of the electric suction valve, the total with the reference numeral 42 is designated.

The illustration also shows a spring 44 , whose travel s with an arrow 46 is clarified. Furthermore, a hydraulic inlet valve 48 as a component of the electric suction valve 42 , a pump room 50 and a pump piston 52 shown. By actuating the electric suction valve 42 this is, in particular the hydraulic inlet valve 48 , open or closed. By energizing the coil of the electromagnet, the armature is pulled on or in the coil, whereby the valve closes. If the energization is terminated, the eSV is opened by the spring force. In the de-energized state, which is the first state 40a corresponds, is the electric suction valve 42 by spring force of the spring 44 kept open.

By controlling the electric suction valve 42 this can be opened, the illustrated fourth state 40d shows the fully opened state of the electric suction valve 42 When opening, the spring force of the spring must be 44 be overcome. During opening, the progressive spring characteristic of the spring then has an effect 44 out.

3 shows in a graph different curves of spring characteristics. It is on an abscissa 60 the deflection s and the spring travel of the spring and an ordinate 62 the spring force F applied.

The illustration shows a linear spring characteristic 64 and a progressive spring characteristic 66 and thus a spring characteristic with progressive course. It can be seen that the curve, which is the linear spring characteristic 64 represents, increases linearly. Ie. the curve increases linearly, the relationship between spring force F and deflection s is linear. The gradient of this curve is thus constant throughout the range, ie the first derivative of the curve, which is the linear spring characteristic 64 represents, is constant.

The curve representing the progressive spring characteristic 66 on the other hand, has an increasingly rising profile. The relationship between spring force F and deflection s is not linear. It should be noted that with deflection the deflection from the rest position, in this case, the compression of the spring is meant. The curve representing the progressive spring characteristic 66 represents, has in the area shown an increasing and thus not constant gradient. It can also be said that the first derivative of the curve, the progressive spring line 66 represents, is not constant or increasing.

With reference number 68 another spring characteristic of a progressive spring is shown. This shows a course with kink. It should be noted that the valve is typically operated in two-point operation.

In the embodiment shown, the progressive spring characteristic has an exponential course, i. H. a history that can be described by an e-function.

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

• WO 2014/102026 A1 [0005]

Claims (12)

Suction valve with an inlet valve ( 22 ) and a movable armature ( 20 ) for actuating the suction valve ( 18 ), with a spring ( 12 . 44 ), which in a first state ( 40a ) opening the suction valve ( 18 ), whereby the spring ( 12 . 44 ) a progressive spring characteristic ( 66 . 68 ) having. Suction valve according to claim 1, which is designed as an electric suction valve ( 42 ) is trained. Suction valve according to claim 2, comprising an electromagnet ( 14 ) and a coil ( 16 ). Suction valve according to one of claims 1 to 3, wherein the spring characteristic ( 66 ) has an exponential course. Suction valve according to one of claims 1 to 3, wherein the spring characteristic ( 68 ) has a course with kink. Suction valve according to one of claims 1 to 5, wherein the inlet valve ( 22 ) as a hydraulic inlet valve ( 48 ) is trained. Suction valve according to one of claims 1 to 6, wherein the spring ( 12 . 44 ) is designed as a helical spring. Pump with a suction valve ( 18 ) according to one of claims 1 to 7. Pump according to claim 8, which is a high pressure pump ( 40 ) is trained. Pump according to claim 8 or 9, comprising an outlet valve ( 24 ). Pump according to Claim 10, in which the outlet valve ( 24 ) is designed as a hydraulic outlet valve. Pump according to one of claims 8 to 11, which has a pumping space ( 26 . 50 ), a pump piston ( 27 ) and a pump cam ( 28 ) with upper pumping space.

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