DE19846182A1 - Electrical indicator for position of a pneumatic switch has a conical extension to a sliding bar which operates an electrical switch - Google Patents

Abstract

A pneumatic valve (12) has a sealing plunger (18) and rod (20) moving axially to open or close the valve. A membrane (30) and backing plate (32) carries an extension (54) to the rod which has a conical end section (56) which operates a switch (46) when extended as the valve opens.

Description

The invention relates to a circuit arrangement for Detection of the switching status of at least one comprising moving element on a track pneumatic switching means with one depending speed of a switching position of the movable ele actuated electrical switching means.

State of the art

Circuit arrangements of the generic type are known for example from DE 35 06 180 A1. This Scripture deals with a piston-cylinder arrangement, where the position of a cylinder piston over ra dial he arranged on the outside of the cylinder is caught. These sensors are ins special about reed switches, which are marked by a ben arranged permanent magnets who switched the.

This known arrangement has the problem that it is only suitable for pneumatic switching elements,  where the movable element is a piston summarizes in which the permanent magnet at a distance can be arranged to the side wall of the cylinder, which is significantly smaller than the stroke of the movable one Elements is. If this is not possible, the result is be with an arrangement as in DE 35 06 180 A1 wrote the problem that the reed switch that acts as an electrical switching element, practical is constantly exposed to the influence of the magnet, no matter in which position the piston of the Zylin who is located. As a result, that changes magnetic field acting slowly in the switch Course of the stroke movement, and the piston position, at that switches the reed switch fluctuates strongly in Dependence on external influences.

Advantages of the invention

With the circuit arrangement according to the invention the features mentioned in claim 1 is a Circuitry created for monitoring a pneumatic switching means is suitable for which the attachment of the electrical switching means not in the arrangement shown in DE 35 06 180 A1 is practical, be it because of the movable element does not have a piston in which a magnet is located could be brought, because the available space Attachment of the electrical switching element on the side  not sufficiently close to the movable element allow, or for whatever reason. By arranging a part according to the invention of the electrical switching device in one in motion direction behind the movable element of the pneumatic switchgear room is au also a compact structure of the entire arrangement achieved.

This solution can be used particularly advantageously for pneumatic switching devices with a short stroke, that means those where the stroke is similarly large or smaller than the dimensions of the movable Elements are transverse to the stroke direction.

For example, these are most pneumatic Switching means in which the movable element of a fle exposed to a pneumatic medium xiblen membrane is driven.

The lifting movement is preferably the course on which this takes place in three ab cuts divided, with the middle in the these sections the operating force that Actuator of the electrical switching means one to the movement of the movable element of the pneumatic switching means coupled movement driving between two endpoints, and where  the actuating element is stationary on one of the two Endpoints remain as the moving ele in one of the respective end points that of the two outer sections of the web. The subdivision of the entire train into the three ab cuts can be made in the construction of the pneu matical switching means fixed or also adjustable on the assembled switching device his. Such an arrangement avoids that the actuator when it is one of its has reached two endpoints, the further movement of the pneumatic switching means hindered.

According to a preferred embodiment of the invention is that of the moving element of the pneumatic Switching means on the actuating element of the elek trical switching means exerted actuating force a magnetic force, a magnet particularly on movable element of the pneumatic switching means can be mounted.

Effective transmission of magnetic actuation force is guaranteed if the magnet and the electrical switching means on one to the path of the movable element parallel axis, preferably the central axis of the pneumatic switching means are ordered.  

A simple structure of the circuit arrangement results when the pneumatic switching means in one tight housing is housed on all sides and that electrical switching means on the outside of this housing is arranged. At least the housing is there in the vicinity of the electrical switching means a material permeable to a magnetic field. Such a construction allows an ab Seal the housing at the level of electrical an to close the electrical switching means to breed.

According to a variant of the invention, the actuator is supply element of the electrical switching means under slidable at an angle to the track.

This is particularly useful if the Be actuating force a mechanically transmitted force is.

To transmit such a force can be provided be that the actuator and the be movable element at least on a section of the Web at a contact running obliquely to the web Touch the surface to transfer the power. This The contact surface can in particular be a conical one Surface on the moving element of the pneumatic Be switching means.  

To the mechanical actuation force on the elek Trical switching means to transmit is preferably se an actuating pin of the movable element sealed from a housing of the pneumatic Switching means led out. That through this Zap fen operated electrical switching means is appropriate Usually mounted on the outside of the housing, preferably it is wise due to an attached cap on the Housing held.

In a preferred embodiment of the invention seen that in an arrangement with several pneu matic switching means each of the pneumatic Switching means an electrical switching means assigned is net, and the electrical switching means in parallel are switched. This can be done in a simple manner even with several pneumatic ones to be monitored Switching means the switching state of the pneumatic Switching means are monitored so that at Actuation of at least one of the pneumatic Switching means a control signal to an evaluation circuit is supplied.

In a further preferred embodiment of the invention it is provided that each of the electrical switching medium a defined series resistor in series is switched, the size of which preferably corresponds is determined according to a binary coding, where  the series resistors are dimensioned differently are. This advantageously makes it possible, too with several monitored pneumatic switching based on the one generated electrical Control signal to determine which or which of the pneumatic switching means their switching changed state. So with easier Evaluation of only one switching signal at the same time Switch position of several pneumatic switching devices can be monitored in a simple manner.

Further advantageous features of the invention result from the following description of Ausfüh Example with the help of the associated drawings.

drawings

Show it:

Figure 1 is a sectional view through a circuit arrangement according to the invention.

2 is a perspective view of a cap for securing the electrical circuit means on the housing of the pneumatic switching means.

Fig. 3 is a sectional view through a second circuitry;

FIG. 4 shows a side view of the arrangement from FIG. 1;

Fig. 5 and 6, circuits for monitoring the switching state of a plurality of pneumatic switch means and

Fig. 7 shows a circuit for monitoring a lot of pneumatic switching means.

Description of the embodiments

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

The structure and mode of operation of exhaust gas recirculation valves are known, so that reference is only made to the components required for the explanation of the circuit arrangement according to the invention. The exhaust gas recirculation valve 10 is arranged in a suction channel 14, wherein an opening into the intake channel 14 valve sleeve 16 is closed by a closing body 18th The closing body 18 is connected to a valve rod 20 , which can be moved on a path in the direction of an arrow 45 and back by an actuating device 22 , which is designed as a vacuum box 24 . The vacuum box 24 forms a pneumatic switching means 26 . For this purpose, a membrane 30 is arranged within a housing 28, which has a diaphragm plate 32 rigidly connected to the valve rod 20 . The membrane plate 32 is supported against the force of an elastic spring element 34 on a membrane cover 36 . The membrane cover 36 forms a pressure-tight closure of the housing 28 . An interior 38 of the housing 28 is connected via a connection, not shown, to a sub-pressure source, while an interior 40 of the housing 28 with normal pressure, that is, the atmosphere is acted upon.

The diaphragm plate 32 carries on its tilstange from the side facing away from Ven 20 in extension of the valve rod 20 has an operating pin 54 with egg ner tapered distal tip 56th Valve rod 20 , diaphragm plate 32 and actuating pin 54 together form a moving element on a path in the direction of arrow 45 .

The actuating pin 54 extends through a gasket 58 provided with a hole in the diaphragm cover 36 in a chamber which is plugged by a membrane on the cover 36 and formed on this constant verra cap 60th

This in Fig. 2 Perspectively viewed from the inside shown cap 60 carries on a flexible, provided with locking means 62 web-like edge 64 surrounded base plate 66 a longitudinally slotted shaft 68th The length of the shaft is such that it holds the seal 58 between its end face 69 and the bottom of a recess in the membrane cover 36 when the cap 60 is engaged.

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

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

The valve assembly 12 has a second pneumatic switching means 42 , which is also built up in an analogous manner to the switching means 26 as a vacuum box. By means of the second pneumatic switching means 42 , a valve 43 arranged in the intake duct 14 can be actuated, by means of which a passage cross section of the intake duct 14 can be varied. Since the construction of the pneumatic switching means 26 and 42 is identical, the further construction and the function will only be explained on the basis of the pneumatic switching means 26 .

To actuate the exhaust gas recirculation valve 10 , the interior 38 is connected to the vacuum source, so that the interior 38 is evacuated. Here, the diaphragm 30 is biased against the force of the spring element 34 in the direction indicated by the arrow 45 , so that the closing body 18 opens a sealing seat of the valve sleeve 16 .

By prestressing the membrane 30 , the movable element simultaneously moves on its path out of the position shown in FIG. 1 against the force of the spring element 34 in the direction of the membrane cover 36 . Only after the movable element has laid a first section of its path back, does the conical tip 56 come into contact with the actuating element 52 of the electrical switching means 46 and begins to move it in a direction perpendicular to the path. Thereby moving the tip 56 to the actuating member 52 tet ent long, and during the movement of the Betätigungsele ments 52, the switching means switches 46th After the tip 56 has left the actuating element 52 behind, the cylindrical outer surface of the actuating pin 54 slides along the actuating element 52 on a third section of the track until a stop is reached, for example by the diaphragm plate 32 reaching a boundary in the inner space 38 bumps or the tip 56 reaches the base plate 66 of the cap 60 .

As can easily be seen in FIG. 1, the switching point can be set to an arbitrary position on the path of the movable element by a suitable choice of the length of the actuating pin 56 and the positioning of the electrical switching means 46 . It can thus be any degree of Of fenstellung the exhaust gas recirculation valve 10 detected. If the actuating pin 54 is adjustable in length, for example with the aid of a thread, a fine adjustment of the switching point on the fully assembled valve arrangement is also possible.

Fig. 3 shows a second embodiment of an inventive circuit arrangement with an arranged on an intake duct 14 exhaust gas recirculation valve 10th This arrangement differs from that shown in Fig. 1 in the structure of the pneumatic and electrical switching means. The figure shows only the pneumatic switching means 26 in cross section, the second, designated in Fig. 1 with 42 designated, which is identical, is omitted in Fig. 3. The construction of the intake duct 14 , the exhaust gas recirculation valve 10 , the closing body 18 and the valve rod 20 is the same as in the embodiment described with reference to FIG. 1. The vacuum box 24 comprises a molded on the Ansaugka channel 14 chamber 40 under atmospheric pressure and a connectable to a vacuum source chamber 38 which are gas-tightly separated by a flexible membrane 30 . A stiff membrane plate 32 is screwed to the valve rod 20 and distributes the force of a spring element 34 arranged in the interior 80 to the membrane 30 . On its surface facing the interior 38 , the membrane plate 32 carries a magnet 70 made of a rare earth alloy.

When the interior 38 is placed under negative pressure, the spring element 34 is pressed together by the atmospheric pressure prevailing in the interior space 40 , the closing body 18 rises from the seat of the exhaust gas recirculation valve 10 , and the magnet 70 urges into a formed on the inside of the diaphragm cover 36 Recess 72 and thus approaches the electrical switching means 46 , which is a reed switch in this case.

The magnet 70 and the reed switch 46 are both arranged on the central axis of the movable element, so that when the magnet 70 approaches the reed switch, the magnetic field perceived by this through the mem Brandeckel 36 made of plastic increases rapidly and this repro can be switched. After the reed switch has completed its switching movement under the influence of the force exerted by the magnet 70 , the movable element remains movable in the direction of the reed switch until the magnet abuts the diaphragm cover 36 .

This variant is particularly characterized in that the interior 38 has no through holes except for the connection, not shown, for connecting to a sub-pressure source, we who for an actuating pin still connected to the electrical switching element, and therefore simple and reliable in construction is tight.

FIG. 4 shows the arrangement from FIG. 1 seen in the direction indicated by an arrow 44 . It illustrates the integration of the electrical contacting of the electrical switching means 46 into the entire connection configuration of the valve arrangement 12 . As is known, the valve arrangement 12 has a common connector plug 76 for connecting the pneumatic switching means 26 and 42 , switching devices designed as solenoid valves. The interior 38 ( FIG. 1) can be connected to the vacuum source by means of the solenoid valves so that it can be evacuated. The switching devices here 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 connection contact 82 for a common ground line of the solenoid valves. The connector plug 76 has further contacts 84, respectively, 86 , which are in contact with the connecting cables 61 leading to the electrical switching means 46 . The connecting lines lead to a contact module 65 in which they are connected to the contacts 48 , 50 of the electrical switching means 46 . This makes it possible in a simple manner to simultaneously connect the solenoid valves with a voltage supply by means of a single connector plug 76 and to connect the switching means 46 to an evaluation circuit, not shown in detail. This considerably reduces the connection effort. If the further pneumatic switching means 42 of the valve arrangement 12 is also assigned an electrical switching means, this is parallel to the electrical switching means 46 assigned to the exhaust gas recirculation valve 10 , so that the connection effort does not increase.

In Fig. 5 a related circuit diagram is shown. The connector plug 76 has the connection contacts 78 to 86 . The connection contact 78 is connected to a solenoid valve 88 of the pneumatic switching means 26 , while the connection contact 80 is connected to a solenoid valve 90 of the pneumatic switching means 42 . The connection contact 82 is connected to a common ground line 92 of the solenoid valves 88 and 90 . The connecting contacts 84 and 86 are connected via the connecting lines 62 to the electrical switching means of the two pneumatic switching means 26 and 42 connected in parallel.

About the evaluation circuit, not shown, who applied the terminals 84 and 86 with a measurement voltage. Now closes one of the elec trical switching means 46 or both switching means 46 as a result of the change in the switching state of the pneumatic switching means 26 or 42 - as explained with reference to the preceding figures - the contacts 84 and 86 are short-circuited so that a measuring current can flow. This is detected by means of the evaluation circuit, not shown, and supplies a signal since that one of the pneumatic switching means 26 or 42 is actuated.

In Fig. 6, a modified circuit arrangement according to FIG. 4 is shown, in which a connection effort is further reduced. It is provided here that the connection contact 84 has a common supply voltage potential, both for the magnetic valves 88 and 90 and for the switching means 44 and 46 . As a result, the contact plug 76 can be four-pole without the function of the solenoid valves 88 and 90 or the monitoring task of the switching means 46 is affected. With regard to the function of the circuit arrangement according to FIG. 6, reference is made to the description of the figure.

An embodiment variant is explained on the basis of the circuit arrangement shown in FIG. 7, with which an exact closed position of a plurality of electrical switching means 46 and so on, and thus an actuation of a corresponding pneumatic switching means 26 , 42 assigned to the number of switching means 46 , is possible.

In Fig. 7 it is assumed that a variety of pneumatic switching means are monitored simultaneously in different system applications. For this purpose, each pneumatic switching means is assigned an electrical switching means 46 , for the sake of simplicity it is assumed that the actual numbers of switching means 46 are designated S ₁ , S ₂ , S ₃ to S _n accordingly. The switching means S ₁ to S _n are each connected in parallel and connected to the connecting contacts 84 and 86 via the connecting lines 61 . The measuring voltage U _{mess is applied} to them. A series resistor R ₁ to R _{n is connected} in series to each of the switching means S ₁ to S _n . 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 ₁ can assume the value 0 when the switch is open and the value 1 when the switch is 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 basic resistance.

Corresponding to the closed switching means S ₁ to S _n , any combination being possible here, that is, either only one of the switching means S ₁ to S _n or more, that is to say at least two of the switching means S ₁ to S _n closed, results the possibility, based on the known measuring voltage U _mess and the known series resistors assigned to the individual switching means S ₁ to S _n , to be determined exactly by means of a flowing measuring current, which the switch S ₁ to S _{n is} closed. May be thereby can be to the evaluation circuit, for example, an integral part of a control unit of a motor vehicle, ex nude determine which of the switching means S ₁ to S _n, that is, the electrical switching means 46 and so with the said electrical switch means 46 zugeord Neten pneumatic switching means 26 , is actuated and which is not. This evaluation can be used for error diagnosis, any errors, for example a non-triggering of a controlled pneumatic switching means, being precisely assignable. For this purpose, the information that is obtained from the evaluation of the closed switching means S ₁ to S _n can be compared in a computer unit with a further information that arises due to a control of the pneumatic switching means tel 26 associated solenoid valves 88 , 90 and so on can be derived.

Instead of measuring the current at a precisely specified measuring voltage U _mess , an exact measuring current can of course also be reversed and a resultant measuring voltage U _mess can be evaluated. In any case, a switching configuration of the switching means S ₁ to S _n can thus be clearly determined in a simple manner. Instead of the binary coding of the series resistors R ₁ to R _n , other, comprehensible and unambiguous codings are also possible.

Claims (17)

1. Circuit arrangement for detecting the Schaltzu state at least one on a track movable Lich element ( 20 , 32 , 54 ; 20 , 32 , 70 ) comprising pneumatic switching means ( 26 ) with an actuated in dependence on a switching position of the movable element electrical switching means ( 46 ), characterized in that an actuating element ( 52 ) of the electrical switching means ( 46 ) can be subjected to an actuating force by the movable element in a space lying in the direction of the path behind the movable element. 2. Circuit arrangement according to claim 1, characterized ge indicates the extent of the mobile Elements perpendicular to the path larger than the length the web is. 3. Circuit arrangement according to claim 1 or 2, characterized in that the movable element ( 20 , 32 , 54 ; 20 , 32 , 70 ) is driven by a flexible membrane exposed to a pneumatic medium ( 30 ). 4. Circuit arrangement according to one of claims 1 to 3, characterized in that the track comprises three sections, the middle of the sections from the actuating force, the actuating element ( 52 ) of the electrical switching means ( 46 ) to one of the movement of the movable element ( 20 , 32 , 54 ; 20 , 32 , 70 ) of the pneumatic switching means ( 26 ) drives coupled movement between two end points, and wherein the actuating element ( 52 ) remains motionless at one of the two end points while the movable element of the pneumatic switching means ( 26 ) moved in a corresponding one of the two outer sections of the web. 5. Circuit arrangement according to one of claims 1 to 4, characterized in that the actuation force is a magnetic force. 6. Circuit arrangement according to claim 5, characterized in that the movable element ( 20 , 32 , 70 ) of the pneumatic switching means ( 26 ) contains a magnet ( 70 ). 7. Circuit arrangement according to claim 6, characterized in that the magnet ( 70 ) and the electrical cal switching means ( 46 ) are arranged on an axis parallel to the path of the movable element be. 8. Circuit arrangement according to one of the preceding claims, characterized in that the electrical switching means ( 46 ) is a reed switch. 9. Circuit arrangement according to one of claims 5 to 8, characterized in that the pneumatic switching means ( 26 ) in a sealed housing ( 28 ) is housed un and that the electrical Schaltmit tel ( 46 ) is arranged on the outside of the housing ( 28 ). 10. Circuit arrangement according to one of claims 1 to 4, characterized in that the actuating element ( 52 ) of the electrical switching means ( 26 ) is displaceable at an angle to the track. 11. Circuit arrangement according to claim 10, characterized in that at least on a portion of the web, the actuating element ( 52 ) and the movable union element ( 20 , 32 , 54 ) touch each other on an inclined to the web contact surface. 12. Circuit arrangement according to claim 11, characterized in that the contact surface is a conical surface ( 56 ) on the movable element of the pneumatic switching means ( 26 ). 13. Circuit arrangement according to one of claims 10 to 12, characterized in that an actuation pin ( 54 ) of the movable element ( 20 , 32 , 54 ) is sealed out of a housing ( 28 ) of the pneumatic switching means ( 26 ) to the actuating force transferred to. 14. Circuit arrangement according to claim 13, characterized in that the electrical switching means ( 46 ) by an attached cap ( 60 ) on the Ge housing ( 28 ) is held. 15. Circuit arrangement according to one of the preceding claims, characterized in that with egg ner arrangement with a plurality of pneumatic switching means ( 26 , 42 ) each of the pneumatic switching means ( 26 , 42 ) is assigned an electrical switching means ( 46 ; S ₁ to S _n ) is, and that the electrical Schaltmit tel ( 46 ; S ₁ to S _n ) are connected in parallel. 16. Circuit arrangement 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, the prior resistors (R ₁ to R _n ) are dimensioned differently. 17. Circuit arrangement according to claim 16, characterized in that the size of the series resistors (R ₁ to R _n ) is determined in accordance with a binary coding.