DE19846182B4 - Exhaust gas recirculation valve, comprising a circuit arrangement for detecting the switching state of at least one pneumatic switching means - Google Patents

Abstract

Exhaust gas recirculation valve, containing a circuit arrangement for detecting the switching state a pneumatic switching means (26), wherein the pneumatic switching means (26) comprises a valve rod (20, 54, 20, 70) which is provided with a closing body (18) to open and closing the valve is connected, wherein the circuit arrangement a in dependence from a switching position of the valve rod (20, 54, 20, 70) actuated electrical Switching means (46), characterized in that an actuating element (52) of the electrical switching means (46) in a path of movement the valve rod (20, 54; 20, 70) lying space of an actuating force the valve rod (20, 54; 20, 70) can be exposed.

Description

The Invention relates to an exhaust gas recirculation valve, containing a circuit arrangement for detecting the switching state a pneumatic switching means according to the preamble of the claim 1.

Circuit arrangements of the aforementioned type are for example from the DE 3506180 A1 known. This document deals with a piston-cylinder arrangement in which the position of a cylinder piston is detected via sensors arranged radially on the outside of the cylinder. These sensors are in particular reed switches, which are switched by a permanent magnet arranged on the piston.

This known arrangement has the problem that it is only suitable for pneumatic switching elements, in which the movable element comprises a piston in which the permanent magnet can be arranged at a distance from the side wall of the cylinder, which is significantly smaller than the stroke of the movable element , If this is not possible, results in an arrangement as in the DE 3506180 A1 described the problem that the reed switch, which acts as an electrical switching element, practically constantly exposed to the influence of the magnet, no matter in which position the piston of the cylinder is located. As a result, the magnetic field acting on the switch changes only slowly in the course of the stroke, and the position of the piston at which the reed switch shifts fluctuates greatly depending on external influences.

From the US 4,694,812 is an exhaust gas recirculation valve of the type mentioned above with the features mentioned in the preamble of claim 1. The valve rod carries there at its end facing away from the closing body a magnetic core which is displaced upon movement of the valve rod in the interior of a converter which comprises a constant-current-fed primary winding and two axially spaced secondary windings. The evaluation of the caused by the movement of the valve rod change of the inductive coupling of the two secondary coils, however, requires a relatively complex circuit arrangement.

The US 5,027,781 discloses a similar exhaust gas recirculation valve in which, depending on the switching position of a valve stem in an EGR valve position sensor, a high level or low level voltage signal is generated for the onboard computer of the vehicle.

outgoing This is the object of the invention, the known exhaust gas recirculation valve to improve the monitoring of the pneumatic Switching means simplified by evaluation of movements of the valve stem becomes.

Advantages of invention

By the feature combination of the invention can the force of the valve stem or the movement of the valve stem premier Kraft be exploited to an actuator of the electric To actuate switching means, by a force from the valve stem or at the front end attached actuator on the actuator the switching means exercised and this is switched directly.

The inventive combination of features also an exhaust gas recirculation valve is provided with a circuit arrangement which is suitable for monitoring a pneumatic switching means, wherein the attachment of the electrical switching means in the in DE 3506180 A1 shown arrangement is not practicable, either because the movable member has no piston in which a magnet could be accommodated, because space conditions do not allow the attachment of the electrical switching element laterally from the movable element in sufficient proximity, or for whatever reason. The inventive arrangement of a portion of the electrical switching means in a lying in the direction of movement behind the movable element of the pneumatic switching means space also a compact construction of the entire arrangement is achieved.

These solution is particularly advantageous applicable to pneumatic switching means with a low lift, that is those where the stroke is similar big or smaller than the dimensions of the movable element transverse to the stroke direction are.

This For example, most pneumatic switching devices are where the movable element of a pneumatic medium exposed flexible diaphragm is driven.

Preferably, the lifting movement or the path on which this takes place, divided into three sections, wherein in a middle of these sections, the actuating force drives the actuating element of the electrical switching means to a coupled to the movement of the movable element of the pneumatic switching means movement between two end points, and wherein the actuator is stationary at one of the two ends points remains as the movable member moves in a respective end point corresponding to the two outer portions of the web. The subdivision of the entire web in the three sections can be fixed in the construction of the pneumatic switching means or adjustable on the finished composite switching means. Such an arrangement avoids that the actuator, when it has reached one of its two end points, obstructs the further movement of the pneumatic switching means.

According to one preferred embodiment of the invention is that of the movable Element of the pneumatic switching means on the actuator the actuating force applied to the electrical switching means is a magnetic force, wherein a magnet in particular on the movable element of the pneumatic Switching means can be mounted.

A effective transmission the magnetic actuation force is guaranteed when the magnet and the electrical switching means on one to the web of the movable element parallel axis, preferably the central axis are arranged of the pneumatic switching means.

One simple structure of the circuit arrangement results when the pneumatic Switching means is housed in a well-sealed housing and the electrical switching means outside on this case is arranged. In this case, the housing consists at least in the environment the electrical switching means of a permeable material for a magnetic field. Such a construction allows to seal the housing in Height of electrical connections to dispense with the electrical switching means.

According to one Variant of the invention is the actuating element of the electrical Switching means at an angle to the track displaced.

This is particularly useful if the operating force a mechanically transmitted Power is.

For transmission Such a force can be provided that the actuating element and the movable member at least on a portion of the web at an angle to the web extending contact surface touch, to transfer the power. This contact surface in particular, a cone-shaped area be on the movable element of the pneumatic switching means.

Around the mechanical actuating force to transfer to the electrical switching means is preferably an actuating pin of the movable member sealed from a housing of the brought out pneumatic switching means. That through this pin actuated Electrical switching means is expediently outside of the casing mounted, preferably it is by an attached cap on the casing held.

In Preferred embodiment of the invention is provided that at a Arrangement with several pneumatic switching means each of the pneumatic Switching means is associated with an electrical switching means, and the electrical switching means are connected in parallel. This can in a simple way even with several to be monitored pneumatic Switching means monitored the switching state of the pneumatic switching means to the effect be that at activity at least one of the pneumatic switching means a control signal is delivered to an evaluation circuit.

In Another preferred embodiment of the invention is provided, that everyone the electrical switching means a defined series resistor in series is switched, its size preferably accordingly a binary one Coding is set, wherein the series resistors dimensioned differently are. This makes it advantageously possible, even with several monitored pneumatic switching means based on the one generated electrical control signal to determine which or which of the pneumatic switching means changed their switching state to have. Thus, with simple evaluation, only one switching signal at the same time the switching position of several pneumatic switching means monitored in a simple manner become.

Further advantageous features of the invention will become apparent from the following Description of exemplary embodiments based on the accompanying drawings.

drawings

It demonstrate:

1 a sectional view through a circuit arrangement according to the invention;

2 a perspective view of a cap for fixing the electrical switching means on the housing of the pneumatic switching means;

3 a sectional view through a second circuit arrangement;

4 a side view of the arrangement 1 ;

5 and 6 Circuits for monitoring Chung the switching state of several pneumatic switching means and

7 a circuit for monitoring a plurality of pneumatic switching means.

description the embodiments

The invention will be described below using the example of an exhaust gas recirculation valve 10 having valve assembly 12 be explained, which is used for example in internal combustion engines of motor vehicles.

Structure and operation of exhaust gas recirculation valves are known, so that reference is made here only to the necessary components for the explanation of the circuit arrangement according to the invention. The exhaust gas recirculation valve 10 is in a suction channel 14 arranged, one in the intake 14 opening valve sleeve 16 by means of a closing body 18 is closable. The closing body 18 is with a valve stem 20 connected by an actuator 22 as a vacuum can 24 is formed on a path in the direction of an arrow 45 and is movable back. The vacuum box 24 forms a pneumatic switching means 26 , This is within a housing 28 a membrane 30 arranged one with the valve stem 20 rigidly connected diaphragm plate 32 having. The diaphragm plate 32 supports against the force of an elastic spring element 34 on a membrane lid 36 from. The membrane lid 36 forms a pressure-tight closure of the housing 28 , An interior 38 of the housing 28 is connectable via a non-illustrated connection with a vacuum source, while an interior 40 of the housing 28 with atmospheric pressure, that is, the atmosphere is acted upon.

The diaphragm plate 32 carries on its from the valve stem 20 opposite side in extension of the valve stem 20 an actuating pin 54 with a tapered distal tip 56 , valve rod 20 , Diaphragm plate 32 and actuating pin 54 Make a train together in the direction of the arrow 45 movable element.

The actuating pin 54 extends through one with a gasket 58 provided opening in the membrane lid 36 in a chamber, from one to the membrane lid 36 put on and locked at this cap 60 is formed.

This in 2 perspective view of cap shown inside 60 carries on one, from a flexible, with locking means 62 provided ridge-shaped edge 64 surrounded base plate 66 a longitudinally slotted shaft 68 , The length of the shaft is dimensioned so that it with a locked cap 60 the seal 58 between his face 69 and the bottom of a depression of the membrane lid 36 clamped holds.

On the base plate 66 is the electrical switching means 46 , here a micro-switch, mounted so that its actuator 52 in the cylindrical bore of the shaft 68 intervenes. Electrical connections 48 . 50 are through the bottom of the cap 60 led out (see 1 ).

The microswitch is located in the direction of the web virtually entirely behind the diaphragm plate 32 so that it the lateral dimensions of the entire arrangement of pneumatic 26 and electrical switching means 46 not enlarged.

The valve arrangement 12 has a second pneumatic switching means 42 , which in an analogous way to the switching means 26 also constructed as a vacuum box. By means of the second pneumatic switching means 42 can one in the intake 14 arranged flap 43 be actuated by means of a passage cross-section of the intake passage 14 is variable. As the construction of the pneumatic switching means 26 and 42 is identical, the further structure and the function is only based on the pneumatic switching means 26 explained.

For actuating the exhaust gas recirculation valve 10 becomes the interior 38 connected to the vacuum source, so that the interior 38 is evacuated. This will cause the membrane 30 against the force of the spring element 34 in the with the arrow 45 biased specified direction, so that the closing body 18 a sealing seat of the valve sleeve 16 opens.

By biasing the membrane 30 At the same time the moving element moves on its path from the in 1 shown position against the force of the spring element 34 in the direction of the membrane lid 36 , Only after the movable element has covered a first section of its path, the conical tip comes 56 in contact with the actuator 52 of the electrical switching means 46 and begins to move it in a direction perpendicular to the web. The tip glides 56 on the actuating element 52 along, and during the movement of the actuator 52 switches the switching means 46 , After the tip 56 the actuator 52 has passed behind, slides on a third portion of the web, the cylindrical outer surface of the actuating pin 54 on the actuator 52 along until a stop is reached, for example by the diaphragm plate 32 to a boundary in the interior 38 butt or the tip 56 the base plate 66 the cap 60 reached.

How to 1 easily recognizes, can through a suitable choice of the length of the actuating pin 56 and the positioning of the electrical switching means 46 whose switching point can be set anywhere on the path of the movable element. It can thus any degree of open position of the exhaust gas recirculation valve 10 be detected. when the actuating pin 54 is adjustable in length, for example by means of a thread, as well as a fine adjustment of the switching point on the fully assembled valve assembly is possible.

3 shows a second embodiment of a circuit arrangement according to the invention with a on an intake passage 14 arranged exhaust gas recirculation valve 10 , This arrangement is different from the one in 1 shown in the construction of the pneumatic and electrical switching means. The figure shows only the pneumatic switching means 26 in cross-section, the second, in 1 With 42 designated, which is identical, is in 3 omitted. The structure of the intake duct 14 , the exhaust gas recirculation valve 10 , the closing body 18 and the valve stem 20 is the same as with respect to 1 described embodiment. The vacuum box 24 includes one to the intake passage 14 molded chamber 40 under atmospheric pressure and a connectable to a vacuum source chamber 38 passing through a flexible membrane 30 are separated from each other gas-tight. A stiff membrane plate 32 is with the valve stem 20 screwed and distributed the power of one in the interior 80 arranged spring element 34 on the membrane 30 , At his the interior 38 facing surface carries the diaphragm plate 32 a magnet 70 from a rare earth alloy.

If the interior 38 is set under negative pressure, the spring element 34 through the one in the interior 40 prevailing atmospheric pressure, the closing body 18 rises from the seat of the exhaust gas recirculation valve 10 , and the magnet 70 pushes into one on the inside of the membrane lid 36 formed recess 72 and thus approaches the electrical switching means 46 which in this case is a reed switch.

The magnet 70 and the reed switch 46 Both are arranged on the central axis of the movable element, so that when approaching the magnet 70 at the reed switch that of this through the diaphragm cover 36 made of plastic perceived magnetic field increases rapidly and this can be switched reproducible. After the reed switch under the influence of the magnet 70 applied force has completed its switching movement, the movable element remains in the direction of the reed switch to continue to move until the magnet to the diaphragm cover 36 abuts.

This variant is particularly characterized by the fact that the interior 38 has no through holes except for the connection, not shown, for connection to a vacuum source, neither for an actuating pin nor for connected to the electrical switching element wires, and therefore in construction is simple and reliable tight.

4 shows the arrangement 1 seen in the by an arrow 44 designated direction. It illustrates the integration of the electrical con tact of the electrical switching means 46 in the entire terminal configuration of the valve assembly 12 , Known manner, the valve assembly has 12 a common connector 76 for connecting the pneumatic switching means 26 and 42 associated, designed as solenoid valves switching devices. By means of the solenoid valves is the interior 38 ( 1 ) Can be connected to the vacuum source so that it can be evacuated. The switching devices in this case is a connection contact 78 for the solenoid valve of the exhaust gas recirculation valve 10 , a connection contact 80 for the solenoid valve for actuating the flap 43 , and a terminal contact 82 assigned for a common ground line of the solenoid valves. The connector 76 has further connection contacts 84 respectively 86 on that with the to the electrical switching means 46 leading connecting lines 61 are contacted. The connection leads to a contact module 65 in which they contact the contacts 48 . 50 of the electrical switching means 46 are connected. This makes it possible in a simple manner, by means of a single connector plug 76 at the same time to connect the solenoid valves to a power supply and the switching means 46 to connect with an evaluation circuit, not shown in detail. The connection costs are reduced considerably. Is the other pneumatic switching means 42 the valve assembly 12 also assigned an electrical switching means, this is parallel to the exhaust gas recirculation valve 10 associated electrical switching means 46 switched, so that the connection cost does not increase.

In 5 For this purpose, a circuit diagram is shown. The connector 76 indicates the connection contacts 78 to 86 on. The connection contact 78 is with a solenoid valve 88 the pneumatic switching means 26 connected while the terminal contact 80 with a solenoid valve 90 the pneumatic switching means 42 connected is. The connection contact 82 is with a common ground line 92 the solenoid valves 88 and 90 connected. The connection contacts 84 and 86 are over the connecting lines 62 with the parallel electrical switching means of the two pneumatic switching means 26 respectively 42 connected.

About the evaluation circuit, not shown, the connection contacts 84 and 86 subjected to a measuring voltage. Now close one of the electrical switching means 46 or both switching means 46 due to the change in the switching state of the pneumatic switching means 26 respectively 42 - As explained with reference to the preceding Figu ren - are the terminal contacts 84 and 86 shorted so that a measuring current can flow. This is detected by means of the evaluation circuit, not shown, and provides a signal that one of the pneumatic switching means 26 or 42 is pressed.

In 6 is a modified circuit according to 4 shown, in which a connection cost is further reduced. Here it is provided that the terminal contact 84 a common supply voltage potential, both for the solenoid valves 88 and 90 as well as for the switching means 44 and 46 having. This allows the contact plug 76 four-pole, without the function of the solenoid valves 88 and 90 or the monitoring task of the switching means 46 is impaired. With regard to the function of the circuit arrangement according to 6 Reference is made to the description of the figure.

On the basis of in 7 the circuit arrangement shown, a variant is explained, with an exact closed position of a plurality of electrical switching means 46 and so forth, and thus actuation of a corresponding one of the number of switching means 46 associated pneumatic switching means 26 . 42 is possible.

In 7 It is believed that a variety of pneumatic switching means are simultaneously monitored in various system applications. For this purpose, each pneumatic switching means is an electrical switching means 46 assigned, it being assumed for the sake of simplicity that according to the actual numbers of the switching means 46 these are designated S ₁ , S ₂ , S ₃ to S _n . The switching means S ₁ to S _n are each connected in parallel and via the connecting lines 61 with the connection contacts 84 and 86 connected. At these lies the measuring voltage U _mess . Each of the switching means S ₁ to S _n is a series resistor R ₁ to R _{n connected} in series. This results in a total resistance R _g , if it is assumed that all switching means S ₁ to S _{n are} closed:

Where S _i can assume the value 0 with the switch open and the value 1 with the switch closed.

The size of the series resistors is given, for example, by the relationship R _i = R ₀ * 2 ^i-1 , where R _{0 is} a base resistance.

According to the closed switching means S ₁ to S _n , wherein here any combination is possible, that is, either only one of the switching means S ₁ to S _n or more, that is closed at least two of the switching means S ₁ to S _n , results the ability to accurately determine due to the known measuring voltage U _mess and the known, the individual switching means S ₁ to S _n series resistors, based on a flowing measuring current, which of the switch S ₁ to S _{n is} closed. As a result, it is possible with the evaluation circuit, which may be an integral part of a control unit of a motor vehicle, for example, to determine exactly which of the switching means S ₁ to S _n , that is, the electrical switching means 46 and thus the electrical switching means 46 associated pneumatic switching means 26 , is pressed and which is not. This evaluation can serve a fault diagnosis, with any errors, such as a non-triggering of a controlled pneumatic switching means, can be exactly assigned. For this purpose, in a computer unit, the information obtained from the evaluation of the closed switching means S ₁ to S _n , be compared with a further information, which due to a control of the pneumatic switching means 26 associated solenoid valves 88 . 90 and so on is derivable.

Instead of the current measurement at exactly predetermined measuring voltage U _mess , of course, an exact measuring current can of course also be specified and a measurement voltage U _mess resulting therefrom can be evaluated. In any case, a switching configuration of the switching means S ₁ to S _n can thus be determined unambiguously in a simple manner. Instead of the binary coding of the series resistors R ₁ to R _n , other, comprehensible and unambiguous codes are possible.

Claims (17)

Exhaust gas recirculation valve, comprising a circuit arrangement for detecting the switching state of a pneumatic switching means ( 26 ), wherein the pneumatic switching means ( 26 ) a valve rod ( 20 . 54 ; 20 . 70 ), which with a closing body ( 18 ) is connected to open and close the valve, wherein the circuit arrangement in dependence on a switching position of the valve rod ( 20 . 54 ; 20 . 70 ) actuated electrical switching means ( 46 ), characterized in that an actuating element ( 52 ) of the electrical switching means ( 46 ) in a movement path of the valve rod ( 20 . 54 ; 20 . 70 ) lying space of an actuating force through the valve rod ( 20 . 54 ; 20 . 70 ) is suspendable. Exhaust gas recirculation valve according to Claim 1, characterized in that the dimension of the valve rod ( 20 . 54 ; 20 . 70 ) perpendicular to the direction of movement of the valve rod ( 20 . 54 ; 20 . 70 ) greater than the path of movement of the valve rod ( 20 . 54 ; 20 . 70 ). Exhaust gas recirculation valve according to Claim 1 or 2, characterized in that the valve rod ( 20 . 54 ; 20 . 70 ) from a flexible membrane exposed to a pneumatic medium ( 30 ) is driven. Exhaust gas recirculation valve according to one of Claims 1 to 3, characterized in that the movement path of the valve rod ( 20 . 54 ; 20 . 70 ) comprises three sections, wherein in a middle of the sections, the actuating force of the actuating element ( 52 ) of the electrical switching means ( 46 ) to a to the movement of the valve rod ( 20 . 54 ; 20 . 70 ) of the pneumatic switching means ( 26 ) coupled movement between two end points, and wherein the actuating element ( 52 ) remains unmoved at one of the two end points while the valve stem of the pneumatic switching means ( 26 ) is moved in a corresponding one of the two outer portions of the movement path. Exhaust gas recirculation valve according to one of the claims 1 to 4, characterized in that the actuating force is a magnetic force is. Exhaust gas recirculation valve according to claim 5, characterized in that the valve rod ( 20 . 54 ; 20 . 70 ) of the pneumatic switching means ( 26 ) a magnet ( 70 ) contains. Exhaust gas recirculation valve according to Claim 6, characterized in that the magnet ( 70 ) and the electrical switching means ( 46 ) are arranged on an axis parallel to the path of the valve rod axis. Exhaust gas recirculation valve according to one of the preceding claims, characterized in that the electrical switching means ( 46 ) is a reed switch. Exhaust gas recirculation valve according to one of claims 5 to 8, characterized in that the pneumatic switching means ( 26 ) in a sealed housing ( 28 ) and that the electrical switching means ( 46 ) on the outside of the housing ( 28 ) is arranged. Exhaust gas recirculation valve according to one of claims 1 to 4, characterized in that the actuating element ( 52 ) of the electrical switching means ( 26 ) at an angle to the direction of movement of the valve rod ( 20 . 54 ; 20 . 70 ) is displaceable. Exhaust gas recirculation valve according to claim 10, characterized in that at least on a portion of the movement path of the valve rod ( 20 . 54 ; 20 . 70 ) the actuating element ( 52 ) and the valve rod ( 20 . 54 ) at one another to the direction of movement of the valve rod ( 20 . 54 ; 20 . 70 ) touch the inclined contact surface. Exhaust gas recirculation valve according to Claim 11, characterized in that the contact surface has a conical surface ( 56 ) on the movable element of the pneumatic switching means ( 26 ). Exhaust gas recirculation valve according to one of claims 10 to 12, characterized in that an actuating pin ( 54 ) of the valve rod ( 20 . 54 ) sealed from a housing ( 28 ) of the pneumatic switching means ( 26 ) is led out to transmit the operating force. Exhaust gas recirculation valve according to claim 13, characterized in that the electrical switching means ( 46 ) by an attached cap ( 60 ) on the housing ( 28 ) is held. Exhaust gas recirculation valve according to one of the preceding claims, characterized in that in an arrangement with a plurality of pneumatic switching means ( 26 . 42 ) each of the pneumatic switching means ( 26 . 42 ) an electrical switching means ( 46 ; S ₁ to S _n ), and that the electrical switching means ( 46 ; S ₁ to S _n ) are connected in parallel. Exhaust gas recirculation valve according to Claim 15, characterized in that each of the electrical switching means ( 46 ; S ₁ to S _n ) a defined series resistor (R ₁ to R _n ) is connected in series, wherein the series resistors (R ₁ to R _n ) are dimensioned differently. Exhaust gas recirculation valve according to claim 16, characterized in that the size of the series resistors (R ₁ to R _n ) is determined according to a binary coding.