Abstract:
A drive for a control valve has a drive force unit, a yoke for connecting to a valve in a fixed manner, a drive spindle for transmitting the movement of the drive force unit to the valve and a sensor unit for detecting the position of the valve. The sensor unit includes a magnetic track with a reoccurring structure which is integrated into the drive spindle, a sensor which is connected to the yoke of the drive in the vicinity of the magnetic track, which is suitable for detecting the changing magnetic field lines and at least one permanent magnet in the area of the magnetic track and the sensor, whose magnetic field lines penetrate both the magnetic track and the sensor.

Description:
BACKGROUND OF THE INVENTION 
     The invention is directed to a drive of a control valve which includes a drive force unit, a yoke for the fixed connection to a valve, a drive spindle for the transmission of the motion of the drive force unit onto the valve and a sensor unit for acquiring the valve position. The sensor unit is integrated in the drive spindle and comprises a magnetic track having a periodic structure, a sensor connected to the yoke of the drive close to the magnetic track with the sensor being suitable for the acquisition of changing magnetic field lines, and at least one magnet in the region of the magnetic track and of the sensor with the magnet having magnetic field lines penetrating both the magnetic track and the sensor. 
     Such drives, for example, are operated pneumatically, hydraulically or electrically. The drive force unit converts electrical, thermal or mechanical energy into a motion of the drive spindle in order to generate a thrust or a rotation. The sensor unit for measuring the valve position is usually mechanically coupled to the drive spindle. The actual position of the valve can be monitored with the assistance of this sensor unit and can be controlled with a position controller that frequently contains the sensor unit. 
     Regardless of whether a non-contacting measuring principle such as, for example, a linear armature sensor, an optically incremental sensor or a contacting system such as, for example, conductive plastic is utilized in the sensor unit itself, the motion of the drive spindle is usually converted with a mechanical tap into a motion at a sensor of the sensor unit. The type of mechanical tap and the structure of the position controller for linear motions at drives is described in the standard DIN IEC 534 Part 6. In accord therewith, a connecting member for the return at the drive is provided at the working spindle, this comprising four M6 threaded holes—given rotatability of the connector member, two holes per side suffice—with a bearing area of at least 10 mm diameter for each threaded hole. The mounting material for coupling a position controller to the sensor is co-supplied by the manufacture of the position controller. It usually comprises a lever that is rotatably coupled to the sensor and a dog that is rigidly connected to the drive spindle and engages into the rotatable lever. The attachment of the sensor with the mounting material requires careful assembly and adjustment in order to avoid historesis and in order to correctly select the working range. 
     On the other hand, EP 0 870 932 A1 discloses a pneumatic or hydraulic cylinder with a cylinder tube, whereby at least one permanent magnet is arranged at a piston, and this magnet uses its magnetic field to actuate at least one signal generator at the outside of the cylinder tube. The signal generator is thereby secured so that it serves as a limit signal generator. The known fastening enables a comfortable displacement and adjustment of the signal generator in order to exactly set the switching points. The shape, nature and arrangement of the permanent magnet, however, is not disclosed. 
     U.S. Pat. No. 5,670,876 discloses a magnetic position sensor that comprises two magnetic sensors, whereby the one sensor acquires a non-variable flux, and the other sensor measures the modification of the magnetic resistance (“reluctance”) over the range of measurement. The variable magnetic resistance in that the part whose motion is to be acquired has a specific shape or is connected to an article with such a specific shape, so that the magnetic flux occurs by means of a continuous variation of, for example, the air gap length or the air gap width. The magnetic return has a characteristic shape therefor. 
     Another magnetic position sensor is disclosed by U.S. Pat. No. 5,359,288 for determining the position of shock absorbers. A Hall sensor thereby measures the strength of a magnetic field as a criterion of the position, and the magnetic region, that moves relative to the hole sensor, is composed of sub-regions having different magnetization, so that the resulting field strength at the Hall sensor continuously varies according to the position. 
     Magnetic field sensors, particularly magneto-resistive sensors, are likewise known that can be greatly miniaturized. Thus, DE 197 01 137 A1 discloses a length sensor chip whose plane resides opposite a scale plane. Magneto-strictive layer strips having barber pole structures are thereby arranged on the sensor chip in a specific way and fashion in order to be suitable for a high-resolution length measurement with high sensitivity given high resistance. 
     EP 0 618 373 A1 discloses a drive of the species with a device for determining the position of a magnetizable piston rod in a cylinder relative to a selected reference point. This device comprises a magnet for generating a magnetic field as well as a periodic arrangement of grooves on the piston rod that effect a modulation of the field generated by the magnet. This periodic modulation is sampled via two magnet resistors integrated in a bridge circuit and is electronically processed so that an analog position display is available in addition to the digital and a stroke speed can be read out. 
     In addition, CH 682 349 A5 discloses a magnetic measurement sensor for acquiring the position, speed and moving direction of a piston or cylinder that detects a flux density change of a magnetic field by means of a periodically profiled, magnetizable piston or cylinder rod. The magnetic flux density is thereby generated via a permanent magnet. 
     What is disadvantageous about the above devices is that the drive force units for actuators comprise no devices that undertake measures given a power outage in order to enable the continued defined and error-free operation of the actuator or, respectively, to move the actuator, for example in the form of a piston or cylinder rod, into a defined position. Thus, these devices are unsuitable for the control of control valves having high safety demands. 
     DE 196 21 087 A1 discloses an analog safety circuit for actuators based on RC or, respectively, RL elements that is essentially characterized by two characteristic times. These are thereby a matter of a first, short so-called hold time during which the actuator—given power outage—is moved into an undefined idle position and of a second, longer hold time during which the actuator is driven into a safe intermediate position in which it should dwell long enough for a service person or an automatic unit to undertake further measures for the protection of a system operated with actuators, particularly measures for further wind-down of the system. 
     This device also does not enable a defined continued operation of an actuator in the form of a drive in combination with a control valve given interruption of the mains power supply. Further, it can only be utilized for electrically operated actuators. 
     SUMMARY OF THE INVENTION 
     It is therefore an object of the present invention to develop the drive of the species such that the disadvantages of the prior art are overcome, in particular that a non-electrically operated drive that uses an incremental path sensor system is supplied for a control valve that enables the defined and safe continued operation of the control valve even after outage of an auxiliary energy, for example in the form of a mains power supply. 
     This object is inventively achieved with an improvement in a drive with a drive force unit, a yoke for the fixed connection to a valve, a drive spindle for the transmission of the motion of the drive force unit onto the valve and a sensor unit for acquiring the valve position, the sensor unit being integrated in the drive spindle and comprising a magnetic track having a periodic structure, a sensor connected to the yoke of the drive close to the magnetic track, the sensor being suitable for the acquisition of changing magnetic field lines, and at least one magnet in the region of the magnetic track and of the sensor, the magnet having magnetic field lines penetrating both the magnetic track and the sensor. The improvements are that the drive is coupled to a control valve, the magnet is a permanent magnet, the sensor can be supplied with energy via an auxiliary energy source, the sensor is connected to a unit for monitoring the electrical auxiliary energy source, the drive includes an energy store for supplying the sensor with electrical energy, the energy store is connected to the sensor at least during an outage of the electrical auxiliary energy, so that the energy store makes it possible to continue the position measurement of the valve position even when outage of the electrical auxiliary energy for at least a characteristic time. 
     The sensor is connected to a logic circuit which may be in a microprocessor of the sensor and which is connected to a timing unit and generates a signal for the drive unit after a predetermined time when the outage of the electrical auxiliary energy to force the drive spindle into a safe position. 
     The invention is thus based on the surprising perception that, by offering an energy store in combination with the drive of a control valve for a characteristic or predetermined time, a continued operation of this control valve is enabled by bridging a power outage for a short period of time. For example, with an outage of the auxiliary electrical energy, the control valve is only moved into a safe, defined position after a given, long-lasting outage. After a short-duration outage, the device can thus continue operating without interruption and need not be re-started, i.e. the original position need not be reset such as, for example, by registering initialization data, which in turn proves complex given precision processes upon employment of control valves and cost-intensive due to the time losses that are thereby incurred. All safety reservations in the employment of incremental path sensors in combination with control valves are thus overcome by the invention. 
    
    
     Further features and advantages of the invention derive from the following description wherein exemplary embodiments of the invention are explained in detail on the basis of schematic drawings. 
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a sectional view of a first embodiment of a drive of the invention; 
     FIG. 2 is a detailed sectional view of a drive spindle according to a second embodiment of the invention; 
     FIG. 3 is a detailed sectional view of a drive spindle according to a third embodiment of the invention; 
     FIG. 4 is a detailed sectional view of a drive spindle according to a fourth embodiment of the invention; 
     FIG. 5 is a sectional view of a fifth embodiment of an inventive drive; 
     FIG. 6 is a diagram showing the connection of the sensor to an energy store, the logic circuit, a monitoring unit, an electrical auxiliary energy source and a timing unit; and 
     FIG. 7 is a detailed sectional view of another embodiment of the drive spindle. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     FIG. 1 shows the preferred embodiment of a drive  10  of the invention. In accord therewith, a drive force unit  12  that generates a linear thrust motion acts via a drive spindle  18  on a valve  16 , and a yoke  14  serves for the fixed connection of the drive force unit  12  to the valve  16 . 
     A magnetic track  20  having a periodic structure is contained integrated in the drive spindle  18 , whereas the yoke  14  of the drive  10  comprises a sensor  22  close to the magnetic track  20 . The sensor  22  is suitable for the acquisition of changing magnetic field lines. The outside diameter of the drive spindle  18  is essentially constant over the entire extent thereof. A permanent magnet (not shown), whose magnetic field lines penetrate both the magnetic track  20  as well as the sensor  22 , is present in the region of the magnetic track and of the sensor  22 . The permanent magnet can be arranged both in the drive spindle  18  as well as close to the sensor  22 , for example on a side facing away from the magnetic track  20  (see the embodiment of FIG.  4 ). 
     Given the embodiment according to FIG. 2, the magnetic track  20  faces toward the sensor  22 . The drive spindle, further, is essentially composed of a non-magnetic, metallic rod whose metallic part is drawn down to a reduced diameter in a sub-region. The rod is extrusion coated with a plastic in this sub-region so that the outside diameter is constant over the entire extent of the drive spindle  18 . For manufacturing the magnetic track  20 , the plastic, which contains ferritic fillers, is magnetized with strong magnetic fields after the extrusion coating. It thereby suffices to produce the magnetic track  20  along a narrow strip lying opposite the sensor  22  instead of magnetizing the plastic over the entire circumference, so that the magnetic track  20  is itself durably magnetic and comprises a periodic structure having magnet poles  26  arranged at equidistant intervals. The sensor  22  comprises two magneto-resistive sensors  22   a ,  22   b  that are offset relative to one another in a direction of movement of the drive spindle  18 . Due to the arrangement of at least two sensors  22   a ,  22   b , the moving direction can also be determined. Further, the evaluation of two sensors  22   a ,  22   b  enables a suppression of noise quantities, since noise influences such as foreign magnetic fields or the distance dependency from the magnetic track  20  affect both sensors  22   a ,  22   b  in the same way. 
     It is provided in the embodiment according to FIG. 2 that the two magneto-resistive sensors  22   a ,  22   b  comprise a plurality of magneto-resistive regions connected in the form of a Wheatstone bridge circuit. The magneto-resistive regions in the various bridge branches of the Wheatstone bridge circuit are thereby turned in different directions, as known from the barber pole structure, so that the direction of current is slanted compared to the direction of motion of the drive spindle  18 . This type of sensor design enables an especially good resolution. The anisotropic magneto-resistive effect (AMR effect) is thereby utilized, in accord wherewith the resistance of a magneto-resistive layer is dependent on the angle between the current density and the magnetization. This type of position identification is a matter of an incremental path measuring system, i.e. the magnetic track acts as a scale that contains no absolute information about the position, so that the valve position is determined with a counter or, respectively, a memory. The precision can also be enhanced by interpolation, so that the resolution lies clearly below the cycle length of the magnetic track. 
     FIG. 3 shows a drive spindle  18  whose magnetic track  20  and whose sensor  22  correspond to the embodiment of FIG. 2; additionally, however, an envelope composed of a thin-wall, non-magnetic tube  30  is provided. This tube  30  can be composed of a rust-free steel or stainless steel and is either slipped over the rod or is placed around the drive spindle as a sheet and is welded along the joining edge with a seam. The advantage of a tube  30  as an envelope of the magnetic track  20  is in the smooth surface of the tube  30 . In particular, the transitions from the magnetic track  20  to the drive spindle  18  can be covered with tube and can thus be realized extremely smooth. The smoothness is important in order to keep the friction of the drive spindle  18  in seals and, thus, a wear of the seals low. 
     Another embodiment of a drive spindle  18  with a magnetic track  20  is shown in FIG.  4  and is fashioned so that the magnetic track  20  comprises soft-magnetic material  32  that is arranged at equidistant intervals in the moving direction of the drive spindle  18 . The interspaces between this periodic, soft-magnetic structure formed by the material  32  are filled with non-magnetic plastic  28  in order to achieve a smooth surface of the drive spindle  18 . The magnetic field in this version is generated by a permanent magnet  24  whose magnetic field lines penetrate both the magnetic track  20  as well as the sensor  22 . The permanent magnet  24  is connected to the sensor  22  or integrated therein at that side facing away from the magnetic track  20 . 
     In an alternative version (not shown), the drive spindle is formed by a soft-magnetic threaded rod or a toothed rod, so that the magnetic track is prescribed by the structure of notches formed by the threads or, respectively, teeth. 
     Another advantageous embodiment of the invention is shown in FIG.  5 . The drive force unit  12  is thereby a pneumatic drive that has a membrane  38  for charging with a pressure. The membrane  38  is rigidly connected via a membrane dish  52  and a screw  54  to a bipartite or two-part drive spindle  18   a ,  18   b , whereby the upper drive spindle  18   a  is secured to the membrane dish  52  by the screw  54  and the lower drive spindle  18   b  is connected to a valve (not shown). The output drive spindle  18   a  and the lower drive spindle  18   b  are coupled to one another via a coupling  44  and screws  46 ,  48 . The control pressure acts above the membrane  38  between a drive housing  50  and the membrane  38 . The drive  12  contains spring elements  40  that press the membrane  38  together with membrane dish  52  and the bipartite drive spindle  18   a ,  18   b  upward in FIG.  5 . Given an outage of the pneumatic control pressure, the drive spindle  18   a ,  18   b  in FIG. 5 moves upward into the drive  12 , so that the valve has a defined safety position. The yoke is likewise divided into two parts with an upper yoke  14   a  and a lower yoke  14   b  that are connected with a union nut  42 . 
     A sensor  22  is arranged close to the magnetic track  20 . The sensor  22  is secured to the upper yoke  14   a  and detects the variation of the magnetic field strength given motion of the drive spindle  18   a ,  18   b . The upper yoke  14   a  can be modified to form a closed housing by mounting a front and back cover (not shown in FIG.  5 ), and the closed housing surrounds the magnetic track and the sensor  22  on all sides. Seals  34 ,  36  are arranged at the top and bottom in the upper yoke  14   a , and are arranged around the upper drive spindle  18   a  to seal the enclosed space off from both the drive  12  as well as from the atmosphere. As a result thereof, the magnetic track and the sensor  22  are protected against contamination, particularly due to magnetic splinters or dust. The magnetic track  20  extends over the region of the upper yoke  14   a  and, to this extent, wipes the seals  34 ,  36  given movement of the upper drive spindle  18   a . Since the outside diameter of the upper drive spindle  18   a  is constant over its entire extent and is produced with a smooth surface, the presence of the magnetic track  20  does not lead to any increased wear at the seals  34 ,  36 . As a result thereof, it is possible to design the upper yoke  14   a  with minimal extent in moving direction of the upper drive spindle  18   a . If, namely, the surface in the transition of magnetic track/spindle were not smooth, then the upper yoke  14   a  would have to be designed so large that the seals  34 ,  36  during the valve stroke are not touched by the magnetic track  20 . The sensor  22  comprises a microprocessor and a memory unit (not shown) for acquiring and analyzing the change in the magnetic field lines. It is thereby preferred when the sensor  22  has an integrated circuit (not shown), so that the signal processing ensues as close as possible to the sensor  22  and has only slight dimensions. The output signal of the sensor  22  represents the valve position and is communicated to a position controller (not shown). 
     According to a further embodiment (see FIG.  7 ), the drive spindle comprises a hollow region, for example in the form of an axial bore  60 , into which a plastic-bonded magnet  61  is introduced. Advantageously, the magnetic track can thereby be generated by magnetization of a ferrite-filled plastic separate from the drive and subsequent introduction as a plastic-bonded magnet into the drive spindle. This reduces transitions on the surface of the drive spindle, so that seals are again not jeopardized by the magnetic track. 
     It is likewise advantageous when the drive spindle has a notch in its surface into which a plastic-bonded magnet terminating with the surface is placed. 
     According to the invention (see FIG.  6 ), a unit  70  for monitoring the electrical auxiliary energy of the electrical auxiliary energy source  71  is connected to the sensor  22 . In addition, a version is inventively provided that comprises an energy store  72  for supplying the sensor with electrical energy that is electrically connected to the sensor at least during an outage of the electrical auxiliary energy. This energy store  72  can be realized as a capacitor or as an accumulator or as a battery. The energy store  72  makes it possible to continue the position measurement of the valve position even given an outage of the electrical auxiliary energy, at least for a transition time. This is advantageous since, due to the incremental measuring principle, the sensor  22  cannot draw conclusions about the valve position only from the momentary physical signal. When the auxiliary energy returns before the energy store no longer supplies the sensor, then the drive together with valve can remain operating without interruption. The energy store  72  thus makes it possible to either completely bridge the time span of the outage of the electrical auxiliary energy or to move the valve into a safe position after a characteristic or predetermined time or dependent on the energy supply of the energy store  72 . 
     In another embodiment of the invention, the sensor  22  is connected to a logic circuit  75  or this is integrated in a microprocessor. This logic circuit  75  forces the drive spindle—given an outage of the electrical auxiliary energy—into a safety position in that it generates signals for the drive force unit. The safety position is the limit position of the valve, for example the position of “valve closed”. Alternatively, the logic circuit  75  is connected to a timer or timing unit  76 , which generates signals for the drive force unit given an outage of the electrical auxiliary voltage after a characteristic time has passed that force the drive spindle into a safety position. It can likewise be provided in one version that the logic circuit  75 , given an outage of the electrical auxiliary energy, generates a signal for the drive force unit that force the drive spindle into a safety position and subsequently generates the signals for the drive force unit given the return of the electrical auxiliary energy that move the drive spindle over the entire working range and accepts initialization data. It can also be inventively provided that the logic circuit  75 , given an outage of the electrical auxiliary energy, drives pneumatic blocking relays that hold a pneumatic drive force in position. 
     In order to realize a defined reference point for the valve position, a trigger different from the magnetic track is integrated in the drive spindle in an additional version (not shown) of the invention. The trigger triggers a characteristic signal in one position of the drive spindle. This is particularly meaningful when the limit safety position does not offer a mechanically defined stop. This trigger, for example, can be arranged lying opposite the magnetic track. It is also provided for this purpose that the yoke comprises an additional sensor for acquiring the position of the trigger. Given utilization of an above-described logic circuit that generates signals for the drive force unit given the outage of the electrical auxiliary energy that force the drive spindle into a safety position, so that signals for the drive force unit are generated subsequently when the electrical auxiliary energy returns that moves the drive spindle over the entire working range and picks up initialization data, this reference point can be realized both by mechanical limit position or can be defined with an additional sensor via an additional trigger as described above. The motion of the drive spindle over the entire working range assures that the path sensor also exhibits a correct reference point after outage of the auxiliary energy. By comparison to the original initialization data, further, conclusions can be drawn about possibly existing errors and an error message can be output as warranted. 
     The drive of the invention enables an especially simple coupling of the path sensor or the position controller to the drive spindle. It is not a mechanical connection and adjustment is thus not necessary, since the path sensor works in non-contacting fashion. The incremental basic principle is also advantageous since no mechanical balancing of the limit positions is needed. The magnetic track can be designed longer than the working region for compensating tolerances during assembly without the resolution within the working region being thereby reduced. A position controller with the inventive drive can be placed in operation in largely automated fashion, whereby errors are precluded and time and cost advantages simultaneously arise.