SOLENOID VALVE SYSTEM AND METHOD OF OPERATING A SOLENOID VALVE SYSTEM

Abstract

Solenoid valve system having a solenoid valve and further having a controller, wherein the solenoid valve includes a valve housing through which a fluid channel passes, in which fluid channel a valve member for temporarily sealing a valve seat formed in the fluid channel is movably accommodated, and including a solenoid drive which has a magnetic circuit with a solenoid coil and a linear-movable armature which is coupled to the valve member, the controller provides a coil current to the solenoid coil and is connected to a sensor which provides a sensor signal which is dependent on a movement of the armature, the controller analyzes the sensor signal to determine a movement of the armature, wherein the controller provides a closed loop control for the coil current in the presence of the armature movement.

Claims

1. A solenoid valve system comprising a solenoid valve and further comprising a controller, the solenoid valve comprising a valve housing through which a fluid channel passes, in which fluid channel a valve member is movably accommodated for temporarily sealing a valve seat, which valve seat is formed in the fluid channel, the solenoid valve further comprising a solenoid drive which comprises a magnetic circuit with a solenoid coil and an armature, which armature is linearly movable between a first functional position and a second functional position and which armature is coupled to the valve member, wherein the controller provides a coil current to the solenoid coil and is connected to a sensor, which sensor provides a sensor signal which is dependent on a movement of the armature, wherein the controller analyzes the sensor signal to determine the movement of the armature and wherein the controller provides a closed loop control of the coil current after the movement of the armature has been determined.

2. The solenoid valve system according to claim 1, wherein the controller provides an open loop control or a closed loop control of a first coil current to cause an initiation of a movement on the armature and the controller provides a closed loop control of a second coil current after the detection of the movement of the armature, wherein an absolute value of the second coil current is smaller than a maximum amount of the first coil current.

3. The solenoid valve system according to claim 2, wherein the absolute value of the second coil current amounts at most 60 percent of the maximum amount of the first coil current.

4. The solenoid valve system according to claim 2, wherein the sensor is a current sensor and wherein the controller analyzes a current signal from the current sensor for detecting movement of the armature and for a closed loop control of the second coil current.

5. The solenoid valve system according to claim 2, wherein the controller provides the second coil current with a pulse width modulation in a frequency interval between 0 Hz and 100 kHz and/or with a constant magnitude.

6. A method for operating a solenoid valve system, in which a valve member is moved by an armature of a magnetic circuit, which is equipped with a solenoid coil, from a first functional position into a second functional position, comprising the steps: providing a first coil current from a controller to the solenoid coil for initiating a movement of the armature from the first functional position into the second functional position, determining a sensor signal dependent on the movement of the armature with a sensor and providing the sensor signal to the controller, detecting the movement of the armature coupled to the valve member on the basis of the sensor signal, closed loop control of a predetermined second coil current from the controller to the solenoid coil in a predetermined time interval after the detection of the movement of the armature coupled to the valve member.

7. The method according to claim 6, wherein the controller detects the coil current and wherein the detection of the movement of the armature coupled to the valve member is carried out on the basis of an inflection point in a time characteristic of the coil current.

8. The method according to claim 6, wherein the predetermined time interval is selected to be greater than a movement duration for the armature between the first functional position and the second functional position.

9. The method according to claim 6, wherein the closed loop current control for the second coil current is maintained after reaching the second functional position until a time at which a transfer of the armature and the valve member coupled thereto from the second functional position to the first functional position is carried out.

10. The method according to claim 6, wherein the controller performs a pulse width modulation for the coil current in a frequency interval between 0 Hz and 100 kHz.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0021] An advantageous embodiment of the invention is shown in the drawing. Here shows:

[0022] FIG. 1 a strictly schematic representation of a solenoid valve designed as a diaphragm valve,

[0023] FIG. 2 a strictly schematic representation of the essential functional components of the controller, and

[0024] FIG. 3 a strictly schematic representation of a current-time diagram.

DETAILED DESCRIPTION

[0025] A solenoid valve system 1 shown in FIG. 1 comprises a solenoid valve 2 and a controller 3 which is electrically connected to the solenoid valve 2. Purely by way of example, it is provided that the solenoid valve 2 is designed as a diaphragm valve, in which a flexible, in particular rubber-elastic, diaphragm 20 is accommodated in a sealing manner between a first valve housing part 18 and a second valve housing part 19 of a valve housing 17.

[0026] Purely by way of example, a first fluid connection 21 and a second fluid connection 22 are formed on the valve housing 17. By way of example, it is provided that the first fluid connection 21 opens into a fluid channel 23 which is formed in the form of a sleeve in some regions and, for its part, has an orifice 24 which opens into a valve chamber 25. In a purely exemplary manner, the orifice 24 is formed on an annular end face 26 of the fluid channel 23 and is also referred to as a valve seat. The valve chamber 25 extends coaxially with the fluid channel 23 and is fluidically connected to the second fluid port 22 via a fluid line 21.

[0027] The diaphragm 20, which is made of a rubber-elastic material, is arranged adjacent to the annular end face 26 of the fluid passage 23 in such a manner that it can be sealingly pressed onto the annular end face 26 by elastic deformation. In order to be able to cause this sealing effect, the solenoid valve 2 is provided with a solenoid drive 4. The solenoid drive 4 comprises a solenoid coil 5, a solenoid core 6, a movably mounted armature 7 and a yoke 8, which is designed with a rectangular profile in a purely exemplary manner Exemplarily, the solenoid coil 5 is formed as an arrangement of a plurality of wire windings, not shown, which in their entirety form a circular cylindrical sleeve extending coaxially to a longitudinal axis 9. Furthermore, both the magnetic core 6 and the armature 7 are each formed rotationally symmetrically with respect to the longitudinal axis 9 and are made of a magnetic flux conducting material. The magnetic core 6 is accommodated in a stationary manner in the solenoid coil 5, while the armature 7 is mounted in the solenoid coil 5 so as to be linearly movable along the longitudinal axis 9.

[0028] An end face 10 of the magnetic core 6 facing away from the armature 7, for example having a flat design, is in surface contact with the yoke 8 made of magnetic flux conducting material. The yoke 8 surrounds the solenoid coil 5, is formed with a rectangular profile in the plane of representation of FIG. 1 and is provided with a bore or recess 11 formed coaxially to the longitudinal axis 9, through which the armature 7 passes. In order to provide a preferred position for the armature 7, a spring 12, in particular a helical spring, is arranged between the armature 7 and the magnetic core 6, which spring 12 has an internal prestress and which presses a valve member 14, which is firmly connected to the armature 7 in a purely exemplary manner, onto the diaphragm 20 when the solenoid coil 5 is de-energized, so that the diaphragm 20 bears sealingly against the annular end face 26.

[0029] In this rest position, also referred to as the first functional position, of the solenoid valve 2, which can thus be described as normally closed, a fluidically communicating connection between the first fluid connection 21 and the second fluid connection 22 is interrupted.

[0030] In order to allow fluid flow from the first fluid port 21 to the second fluid port 22 or in the reverse direction, it is necessary to cancel the sealing effect between the diaphragm 20 and the annular end face 26 of the fluid channel 23 serving as the valve seat. For this purpose, it is necessary to transfer the armature 7 from the first functional position as shown in FIG. 1 to a second functional position (not shown),In the second functional position a distance between the armature 7 and the magnetic core 6 is reduced (compared with the first functional position) and the spring 12 is compressed. In order to cause this transfer of the armature 7, it is intended to provide a coil current from the controller 3 to the solenoid coil 5 in order to thereby cause a magnetic flux in the magnetic core 6, in the yoke 8 as well as in the armature 7. Since the magnetic flux must overcome an air gap 15 between the armature 7 and the magnetic core 6, an attractive force occurs between the armature 7 and the magnetic core 6. This attractive force can be used to cause an elastic deformation of the spring 12 and thus the approach of the armature 7 to the magnetic core 6 as well as the lifting of the diaphragm 20 from the circular ring-shaped end face 26.

[0031] For carrying out this approach process between armature 7 and magnetic core 6, the controller 3 is designed to provide a coil current to the solenoid coil 5 via connecting leads 28, 29.

[0032] A schematic design for the controller 3 can be seen in FIG. 2. It should be mentioned here that an electrical supply voltage Uv is only provided for the controller 3 between an input terminal 33 and an earth terminal 34 when control of the solenoid valve 2 is actually provided. In the remaining time it is not necessary to provide a supply voltage Uv to the controller 3.

[0033] By way of example, it is provided that downstream of the input connection 33 an input filter 35 is provided, the task of which is to attenuate or preferably completely eliminate interference radiation input which can act on the controller 3 from outside as well as interference radiation output which can be caused by the controller 3. Downstream of the input filter 35, a branch is provided to a final stage 36 and a voltage supply module 37, wherein the final stage 36 can have one or more electrically controllable switches, and wherein the voltage supply module 37 is designed to provide a stable supply voltage to a downstream microcontroller 38. The microcontroller 38 is electrically connected to the output stage 36 and provides drive signals, in particular pulse-width modulated drive signals, to the output stage 36 to enable current flow from the input terminal 33 to the solenoid coil 5, coupled to the output stage 36, of the solenoid valve not further shown in FIG. 2. The solenoid coil 5 is connected on the one hand to the output stage 36 and on the other hand via a measuring resistor 40 to the ground connection 34. This enables current to flow from the input terminal 33 through the output stage 36, the solenoid coil 5 and the measuring resistor 40 to the output terminal 34 in the presence of a suitable drive signal provided by the microcontroller 38.

[0034] A freewheeling diode 41 is arranged in parallel with the series connection of solenoid coil 5 and measuring resistor 40, which can dissipate the current occurring due to the reverse insulation of solenoid coil 2 when the power supply to solenoid coil 5 is turned off.

[0035] The measuring resistor 40 is electrically connected to the microcontroller 38 via measuring leads 42, 43 and is used to detect a current-dependent voltage drop, this voltage drop being determined by the microcontroller 38 and being able to be used as a measure of the current flow through the solenoid coil 5.

[0036] According to the representation of FIG. 3, in which a current-time diagram is shown in which the course of the supply voltage Uv is also drawn, the supply voltage Uv is provided at a time t0 and is switched off again at a time t7.

[0037] Shortly after the supply voltage Uv is provided, a drive signal is provided from the microcontroller 38 to the output stage 36 after an initialization of the microcontroller 38. This results in a release of a coil current by the output stage 36 at time t1, whereby this coil current is provided to the solenoid coil 5. Since the solenoid coil 5 opposes its self-induction to an externally imposed current flow, there is a linear increase in the coil current between time t1 and time t2 in the schematic and idealized representation of FIG. 3. At time t2, the magnetic flux in the air gap 15, as shown in FIG. 1, has increased to such an extent that the armature 7 overcomes the static friction with respect to the yoke 8 and the solenoid coil 5 as well as the restoring force of the spring 12 and starts to move in the direction of the magnetic core 6.

[0038] This movement of the armature 7 in the solenoid coil 5 causes an additional induction in the solenoid coil 5, which manifests itself in a current that is opposite to the current impressed on the solenoid coil 5. Accordingly, as shown in FIG. 3, there is a temporary reduction in the coil current from time t2 onwards, which also manifests itself in a decreasing voltage drop across the measuring resistor 40. This voltage drop is detected in the microcontroller 38 by comparing the currently measured voltage with voltages measured previously in time. For a time characteristic of the coil current provided to the solenoid coil 5, which is calculated on the basis of the voltage drop determined at the measuring resistor 40, there is thus a sign change for the slope of the current curve at time t2, whereby this sign change can be used as a trigger signal for the microcontroller 38 to provide current control (closed loop) for the solenoid valve 2 from time t5.

[0039] As can be seen from the schematic representation of FIG. 3, the coil current initially drops from time t2 due to the relative movement of the armature 7 with respect to the solenoid coil 5 until the armature 7 has reached the second functional position at time t3, in which, deviating from the purely exemplary representation of FIG. 1, there is a minimum air gap 15 between the armature 7 and the solenoid core 6. From time t3, the coil current in the solenoid coil 5 increases again due to the armature 7 now coming to a standstill again, until a maximum amount I1 max for the coil current I1 is reached at time t4.

[0040] In the event that the microcontroller 38 is unable to determine the voltage drop across the measuring resistor 40, or at least is unable to determine it reliably, a switchover from the first coil current I1 to a reduced and constant coil current 12, which is also referred to as the holding current, takes place at a time t6. This time t6 may be permanently programmed into the microcontroller 38 and is selected such that the armature 7 has reached the second functional position with a high degree of reliability.

[0041] If, on the other hand, it is the case that the microcontroller 38 can reliably determine the voltage drop across the measuring resistor 40 and thus the current flow through the solenoid coil 5, a switchover from the first coil current I1 to the reduced and constant second coil current 12 takes place at a time t5 which is significantly earlier in time than the time t6. Exemplarily, it is provided that between the time t2 and the time t5 there is a fixed time interval delta-t (=t5−t2), which is stored in the microcontroller 38. It is particularly advantageous if different time periods delta-t are stored in the microcontroller 38 for different solenoid valve types.

[0042] Exemplarily, it can be provided that the microcontroller 38 can make a determination of the connected solenoid valve type on the basis of the curve for the coil current I1 and can automatically make a selection of the time period delta-t for this case.