KR20130111397A - Pressure switching device with a magnet-switch and a device for diagnosing the magnet-switch - Google Patents

Abstract

PURPOSE: A pressure switching device including a magnetic switch and a magnetic switch diagnosing device is provided to easily change a switching state by changing a magnetic flow on a magnetic circuit. CONSTITUTION: A control member (5) changes the switching state of a magnetic switch. A pressure chamber is connected to an operation pressure source. A magnetic circuit is composed of the magnetic switch and at least one region which is permanently magnetized. An electric coil (10) is arranged on the magnetic circuit.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a pressure switching device having a magnetic switch and an apparatus for diagnosing a magnetic switch,

The present invention relates to a pressure switching device having a housing, a pressure chamber, a magnetic switch, and a pressure-dependent adjusting member for changing the switching state of the magnetic switch when a predetermined minimum pressure value is reached by acting on the magnetic switch will be. The pressure chamber may be connected to an operating pressure source by means of a connection and is limited by a movable adjusting member which is implemented in a pressure sealing manner and which is dependent on the applied operating pressure and in this case the value of the applied pressure corresponds to the adjusting member Corresponding to the adjustment distance.

DE 101 04 438 A1 discloses a safety circuit breaker with dual safety shut-off function driven by various physical parameters. A pressure sensitive area is formed by the connecting flange and the membrane contained within the connecting flange, and the compressive force is transmitted to the pressure pin in the pressure sensitive area. A fixing bolt is disposed in the same axial direction as the pressure pin, and an electromagnetic field generated in one coil acts on the fixing bolt. In the case of one fault, one slide is released through the fixing bolt by the excitation of the coil through a control device connected in front of which an arbitrary signal, preferably a temperature signal, is provided, The implemented electrical contacts are opened. Regardless, the slide is also released through the pressure pin in the event of unacceptable overpressure. The release operation of such a slide reduces the switching operating power applied to the electrical contacts in the case of normal operation.

The pressure switching device is responsive to pressure changes in the gaseous medium or liquid medium of the working pressure source, for example, as in a pipeline. In this case, the mechanical action of the medium on the membrane or piston which actuates the switching element upon pressure rise is often used. When the pressure is constant, the position of the membrane or the piston remains unchanged. Mechanically operated switching elements, such as, for example, microswitches, are used for various safety reasons, and such switching elements are also associated with wear, since they are associated with contact.

Alternatively, the use of non-worn switching elements such as inductive proximity switches, fork light barriers or magnetic switches is also known. The magnetic switch changes its switching state when there is an external magnetic field or when there is no external magnetic field. The switching element group also includes, for example, a reed-contact or Hall sensor. The hall sensor is a digital hall sensor that converts a signal of an analog hall sensor into a digital signal through a comparator. The digital signal may be a non-transition electrical switching contact and the non-transition electrical switching contact is closed or opened when there is sufficient magnetic field in accordance with the technical implementation.

In order to be able to "safely" stop pressure-affected pipelines, it is necessary to safely detect the pipeline pressure, ie to safely detect pressure drop conditions below the pre-provided minimum pressure value. The range of operating pressure values is preferably in the range of one bar or in the range of two bars, for example 20 bar. The minimum pressure value is preferably set to half of the operating pressure value according to the operation, for example, 10 bar.

The expression "safe" in connection with the above description means that the technical design of the elements necessary for the above purposes must meet safety technical relevant requirements. To actually meet the highest level of safety category, PL e according to EN ISO 1349-1; It is necessary to comply with SK4 in the previous standard EN 954-1 for SIL 3 according to EN 61508 or 62061 or in accordance with the latest Machinery Directive 2006/42 / EG. In this case, devices capable of diagnosing the function are also needed.

In order to meet such safety technical requirements, various redundancy principles are currently applied. This principle implies that for reasons of redundancy, two pressure switching devices can be used for pressure monitoring, so that if one pressure switching device fails, another additional pressure switching device is used . On the other hand, in order to avoid a systematic simultaneous failure in two pressure switching devices, the pressure switching devices must be manufactured by different manufacturers. At this time, it is considered that the probability of a double failure is very small when the configuration, structure, design and manufacture are different.

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide a pressure switching device with improved diagnostic capability.

This problem is solved by the objects of the independent claim. Preferred embodiments of the invention are described in the dependent claims.

The pressure switching device according to the present invention comprises at least one region permanently magnetized and a magnetic circuit consisting of magnetic switches. Wherein the adjusting action of the adjusting member causes a change in the magnetic flow in the magnetic circuit, so that the magnetic switch is actuated when it reaches a predetermined magnetic field strength value corresponding to the corresponding adjusting distance. The fact that the electric coil is disposed within the magnetic circuit results in a normal change in the switching state of the magnetic switch due to a flow change within the magnetic circuit resulting from the superimposed coil electromagnetic field .

The expression "change of switching state" in connection with the above description means the switching of the switching state and in particular the switching of the switching state which takes place between two possible switching states. The two switching states may be denoted as "ON" or "OFF", or as "OPERATION" or "NON-OPERATION" as "1" or "0".

Alternatively, the magnetic flux density value may be provided in advance instead of the magnetic field strength value. In this case, the physical variable "magnetic flux density (B)" or "magnetic induction" is calculated with the physical variable "magnetic field strength" through the magnetic permeability (μ) according to the mathematical relationship B = μH.

The essence of the present invention is that reliable functional testing of the magnetic switch of the pressure switching device is preferably possible under near real conditions. On the contrary, the rest of the components, especially the piston as a membrane or as a control member, are permanently designed and correspondingly less likely to fail. In this case, the functional test of the magnetic switch is carried out independently of the applied operating pressure, i.e. whether the operating pressure exceeds a predetermined minimum pressure value or is below a predetermined minimum pressure value, Regardless of whether it is at a set position of the pressure state or at a set position influenced by the pressure to some extent.

Accordingly, the above content is associated with the great advantage that the interconnection design associated with the safety of the second pressure switching device and the second pressure switching device can be omitted.

It is also advantageous that one magnetic circuit, including one electric coil and a permanently magnetized area, can be simply integrated within one pressure switching device.

The permanently pre-magnetized area is in the simplest case a permanent magnet, and the permanent magnet is inserted into the magnetic circuit in a suitable magnetization direction or inside the part of the magnetic field flow guide member. The permanently pre-magnetized area may be an electromagnet, the electromagnet being inserted in the magnetic circuit and permanently switched on during at least the operation of the pressure switching device.

In order to diagnose the magnetic switch, in the first step, a coil is triggered so that a magnetic field is generated in the magnetic switch area inside the magnetic circuit, and the magnetic field substantially corresponds to the magnetic field at each different setting position of the adjusting member. In the simplest case, a constant direct current is applied inside the coil. Then, when the magnetic switch changes its switching state, a normal replacement of the switching state is made. For example, after 0.5 seconds or 1 second, the coil is triggered by going to the second step, so that a magnetic field is generated again in the magnetic switch area inside the magnetic circuit, and the magnetic field substantially corresponds to the magnetic field of the previous setting position of the adjusting member . In the simplest case, the current excitation of the coil is again reduced or blocked. If the magnetic switch is then reversed back to its previous switching state, that is, to the pre-test switching state, a normal replacement of the switching state is performed again. Non-normal replacement of the switching state occurs even if the normal replacement of the switching state only takes place after an excessively long time, for example after 0.5 or 1 second. If two consecutive replacement operations of the switching state of the magnetic switch are normally performed within the framework of the test, the overall test of the magnetic switch is considered to be effective or successful.

The structure of the magnetic circuit including the adjusting member is such that magnetic flux inside the magnetic switch region gradually increases from the pressureless adjusting position to the adjusting position subjected to the pressure as the adjusting operation of the adjusting member increases, And in the opposite adjustment operation, respectively. Alternatively, the structure of the magnetic circuit including the adjusting member also allows the magnetic flow inside the magnetic switch region to move from the pressureless adjusting position to the adjusting position which is affected by the pressure as the adjusting operation of the adjusting member increases. It may be implemented to decrease gradually and to increase each in the reverse adjustment operation. Such a structural implementation can be achieved, for example, by suitably arranging the magnetic switches inside the magnetic circuit. The adjusting member and possibly the adjacent tappet can be arranged inside the magnetic circuit, so that the magnetic flow is displaced towards the magnetic switch or away from the magnetic switch.

According to one embodiment, an electrical coil may be connected to the triggering unit, the triggering unit excites the electrical coil with a current to cause the magnetic switch to change its current switching state, and then the triggering unit By again reducing the current excitation phenomenon, the magnetic switch eventually switches back to the current switching state again. For this purpose, the pressure switching device may have corresponding electrical terminals for connecting such external triggering units. The external triggering unit may be integrated inside the connected control device for the purpose of detecting the switching state of the pressure switching device. Alternatively, the triggering unit may be integrated within the pressure switch in the form of a small electronic circuit. In this case, the current supply can be made through a control device for detecting the switching state of the pressure switching device, for example.

According to one further embodiment, the triggering unit has an electrical output for outputting an error message. If the magnetic switch does not normally change its switching state at the time of testing, or if it does not normally switch back to the pre-test switching state, the triggering unit outputs an error message. The electrical output can be an unpotential electrical switching contact which can be read out for example via the control device mentioned in the preamble. Alternatively, the error message may be output or transmitted as a digital signal or as a bus signal in the frame of the bus connection of the pressure switching device.

According to one further embodiment, the triggering unit is designed to test a normal change of the switching state of the magnetic switch repeatedly, in particular periodically, e.g. every 30 seconds, hourly or daily, once or several times.

According to one further embodiment, the magnetic circuit has an air gap, and the gap length of the air gap can be changed by the adjusting means. The magnetoresistance inside the magnetic circuit is changed by the change of the air gap. As a result, the magnetic field intensity in the magnetic switch region also changes. The setting of the minimum pressure value for the pressure switching device is achieved in a simple manner since the magnetic switch corresponds to the pressure value to which the magnetic switch is again applied when a predetermined magnet field strength value corresponding to the corresponding adjustment distance is reached It becomes.

The magnetic switch is preferably a hall sensor, in particular a digital hall sensor or lead-contact.

Finally, the adjustment member may be subjected to compressive stress by a spring element to adjust the operating pressure range.

Such a pressure switching device can preferably be used for the purpose of particularly safely detecting a state in which the pressure has dropped below a minimum pressure value of a predetermined operating pressure source. The pressure switching device can be used particularly for the purpose of detecting a pressure drop state occurring in an operating pressure source formed as a pipeline.

The invention is described in detail below with reference to embodiments:
1 is a schematic view showing one embodiment of a pressure switching device according to the present invention in an unpressurized state, and
2 is a schematic view showing the embodiment according to FIG. 1 under the influence of pressure;

Fig. 1 shows one embodiment of a pressure switching device 1 according to the present invention in a pressureless operating condition. The membrane is used as the adjusting member 5. [ Alternatively, a piston or other suitable means, not shown in the figures, can also be used as the adjusting member 5. The pressure switching device 1 and most of the elements of the pressure switching device-except for the electric coil 10, the magnetic switch 7 and the components 12, 14 shown in the drawing-preferably the principal axis indicated by dotted lines. It was formed in a substantially rotational symmetry relative to.

A connecting part formed as part of the housing 2 of the pressure switching device 1 for connection to an operating pressure source is denoted by the reference numeral 21. The housing cover is denoted by reference numeral 22 and the external thread on the connecting portion 21 is denoted by reference numeral 23. The pressure chamber, which is embodied in a pressure-sealing manner and restricted in the form of a membrane by a movable adjustment member 5 that depends on the applied working pressure p, is indicated by reference numeral 3, in which case the value of the applied pressure Corresponds to the adjustment distance corresponding to the adjustment member 5. The inner space of the housing 2, which is separated from the pressure chamber 3 in accordance with the pressure and is actually in a pressure-free state, is indicated by reference numeral 4.

In this embodiment, the membrane 5 is adjacent to the tappet 11, so that the adjustment action of the membrane 5 is also transmitted to the tappet 11 at the time of the pressure change in the operating direction. The tappet 11 is also subjected to compressive stress by the spring element 8 to adjust the operating pressure range. In the case where the intrinsic stress of the bent membrane 5 shown in the figure must be sufficient, the spring element may be omitted. The spring element 8 is preferably housed within a spring cage 15 made of a non-magnetic material.

In the unpressurized state of the operating pressure source shown in the drawing, that is, in a state where the pressure p of the working pressure source is much lower than the predetermined or predetermined minimum pressure value of the pressure switching device 1 , The adjusting member 5 is in the left position.

According to the present invention, the pressure switching device 1 comprises a magnetic circuit MK consisting of at least one region 9 permanently pre-magnetized and a magnetic switch 7. In this embodiment, the permanently pre-magnetized area 9 is a permanent magnet fixedly received within the housing 2. Reference numeral M indicates an associated magnetization direction. In this embodiment, the magnetic circuit MK also comprises an adjusting member 5, in which case the adjusting member is a pressure plate or membrane made of a magnetic material such as, for example, magnetic steel. The magnetic circuit (MK) also includes a neighboring tappet (11) made from a magnetic material as well.

A gap SP is formed between the permanent magnet 9 and the tappet 11, which is gradually closed as the adjustment operation of the adjustment member 5 increases later. According to the present invention, such an adjustment operation also causes variation of the magnetic flow inside the magnetic circuit (MK), so that the magnetic switch (7) consequently reaches a predetermined magnetic field strength value corresponding to the corresponding adjustment distance The switching state of its own is changed. In this embodiment, the magnetic switch 7 is a digital hall sensor designed to detect a magnetic flow change and designed to output an over state or an under-state of a predetermined magnetic field strength value in the form of an electric signal.

In FIG. 1, the magnetic flow occurring inside the magnetic circuit MK is shown as a loop composed of small dots, which are formed at the north pole (right side of the permanent magnet 9) to form an adjustable air gap LS. Through the adjusting screw 13 as adjusting means, via the plate 12 and the screw bolt 14, and further through the housing part 21, the membrane 5 and the adjacent tappet 11 And finally through the gap SP to the south pole (right) of the permanent magnet 9. All of the specific parts described above were made from magnetic materials. Particularly, due to the high magnetic resistance of the gap SP, the magnetic flow generated in the magnetic circuit MK has a relatively small flow velocity value, and the flow velocity value is symbolically represented by small points .

According to the present invention, since the electric coils are arranged inside the magnetic circuit (MK), the magnetic flux density inside the magnetic circuit (MK) caused by the superposed electromagnetic coil field A normal change of the switching state of the switch 7 can be tested. In this embodiment, a portion of the magnetic plate 12 passes through a coil 10 formed into a cylindrical shape. The coil 10 has a soft magnetic magnetic core to reinforce the coil electromagnetic field. Furthermore, the magnetic switch 7 is arranged inside the coil 10 on the plate 12, as a result of which the magnetic switch 7 originates from the permanent magnet 9 to provide the magnetic circuit MK. The magnetic field strength of the passing magnetic field and the magnetic field strength of the coil electromagnetic field overlapping the magnetic field strength can be detected. It can be mentioned that the magnetic switch 7 may be arranged at another place of the magnetic circuit MK, for example, in the screw bolt 14. [

In order to test the function of the magnetic switch 7, a magnetic field leading to the inside of the magnetic switch 7 area is raised by applying a direct current in a suitable current direction, The switching state is changed. The switching state corresponds to a state of being affected by the pressure according to Fig. If the magnetic switch 7 is again replaced with the previous switching state after the current excitation state is extinguished, the diagnostic process of the magnetic switch 7 is terminated, and the function of the magnetic switch is confirmed.

2 shows a pressure switching device 1 according to the present invention in the case where the pressure p of the working pressure source has a pressure value exceeding a predetermined or predetermined minimum pressure value of the pressure switching device 1 Giving.

The adjusting power S for acting on the adjusting member 5 appears by the applied operating pressure p and the adjusting power acts against the spring power F of the spring element 8. [ When the adjustment power S is larger than the spring power F, the adjustment member 5 and the tappet 11 are moved to the right in the operation direction together. At this time, the gap SP formed between the tappet 11 and the permanent magnet 9 is closed. The magnetic flux is increased due to the decrease of the magnetoresistance inside the magnetic circuit M caused by the closing operation. This situation is symbolically marked by large points. The raised magnetic field strength causes a situation in which the electric field intensity value detected by the magnetic switch 7 exceeds a predetermined minimum magnetic field strength value. At this time, the magnetic switch 7 replaces its switching state.

In order to be able to test the function of the magnetic switch 7 under the influence of the pressure as described above, the coil 10 is excited with the current polarity opposite to the direct current, and the resulting counter electromagnetic The magnetic field leading to the inside of the area of the magnetic switch 7 is lowered or compensated for by the magnetic switch 7 so that the magnetic switch 7 changes its switching state. The switching state corresponds to the pressureless state according to Fig. If the magnetic switch 7 is again replaced with the previous switching state after the current excitation state is extinguished, the diagnostic process of the magnetic switch 7 is terminated, and the function of the magnetic switch is confirmed.

As the two figures show, the length of the air gap LS can be adjusted via mechanical adjusting means 13 in the form of adjusting screws, symbolically indicated by double arrows. In this case, a minimum pressure value for the switching operation of the pressure switching device 1 can be set by a suitable tool such as an internal hexagonal wrench. A lock nut for protecting the rotation is denoted by reference numeral 16.

1: pressure switching device 2: housing
3: pressure chamber 4: internal space, pressureless space
5: adjusting member, membrane 6: sealing means, O-ring
7: Magnetic switch, lead-relay, Hall sensor
8: Spring element, cylinder spring, compression spring
9: permanently magnetized area, permanent magnet
10: coil 11: tappet
12: plate, steel plate 13: adjusting screw, adjusting means
14: Screw, threaded bolt 15: Spring cage, bushing
16: safety means, nut, lock nut 21: housing portion, connection portion
22: housing part, cover 23: external thread
M: magnetization, magnetic moment F: spring power
p: pressure, working pressure S: adjustment power
SP: gap LS: adjustable air gap

Claims (7)

And a pressure-dependency adjusting member for changing the switching state of the magnetic switch (7) when a predetermined minimum pressure value is reached by acting on the housing (2), the pressure chamber (3), the magnetic switch (1) having a pressure chamber (5)
The pressure chamber 3 can be connected to an operating pressure source by means of a connection 21 and is limited by a movable adjustment member 15 which is implemented in a pressure sealing manner and which depends on the neighboring operating pressure p, And the neighboring pressure value corresponds to the adjusting distance corresponding to the adjusting member 5,
Characterized in that the pressure switching device comprises a magnetic circuit (MK) consisting of at least one region (9) permanently magnetized and a magnetic switch (7)
The adjusting operation of the adjusting member 5 causes a change in magnetic flow in the magnetic circuit, so that the magnetic switch 7 has reached a predetermined magnetic field strength value corresponding to the corresponding adjusting distance. Change their switching state, and
The arrangement of the electric coils 10 within the magnetic circuit MK results in a change in flow inside the magnetic circuit MK caused by the superposed electromagnetic coil field, A normal change of the switching state of the switch can be tested,
Pressure switching device. The method of claim 1,
The electric coil 10 may be connected to or may be connected to a triggering unit, wherein the triggering unit is adapted to switch the electric coil 10 by a current so that the magnetic switch 7 changes its current switching state , And then the triggering unit again reduces the current excitation phenomenon, resulting in the magnetic switch (7) being switched back to the current switching state again.
Pressure switching device. 3. The method of claim 2,
The triggering unit has an electrical output for outputting an error message and if the magnetic switch 7 does not normally replace its switching state at the time of testing or if it does not normally reverse back to its pre-test switching state Characterized in that the triggering unit outputs an error message.
Pressure switching device. The method according to claim 2 or 3,
The triggering unit is characterized in that it is designed to repeatedly, in particular periodically, test the normal change of the switching state of the magnetic switch 7,
Pressure switching device. The method according to any one of claims 1 to 4,
The magnetic circuit has an air gap LS, characterized in that the gap length of the air gap can be changed by the adjusting means 13,
Pressure switching device. 6. The method according to any one of claims 1 to 5,
Characterized in that the magnetic switch (7) is a lead-contact or hall sensor.
Pressure switching device. 7. The method according to any one of claims 1 to 6,
Characterized in that said adjusting member (5) is subjected to compressive stress by a spring element (8)
Pressure switching device.

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