FR2678236A1 - Method for automatic control and slaving of the magnetic immunisation of a naval vessel - Google Patents

Abstract

A method for automatically monitoring and controlling, by means of a modelling system, the degaussing of a naval vessel having degaussing circuits. The method comprises the steps of: determining a danger zone in relation to which a magnetic risk is to be estimated (2); determining the spatial coordinates of said zone relative to a naval vessel reference point (12); and using an on-board modelling system providing a real-time estimate of the vessel's magnetic risk according to the vessel's position relative to said zone (a,b,c).

Description

 Self-monitoring and slaving method of the magnetic immunization of a naval vessel.

 The present invention relates to a method of self-monitoring and slaving of the magnetic immunization of a naval vessel provided with magnetic immunization circuits.

 It is known that ferromagnetic parts present in naval vessels make them detectable by means of detection of their "magnetic signature" which can, for example, be integrated in mines, in other naval vessels or even in aircraft.

 Thus, some mines, said to have magnetic influence, include sensors capable of detecting any variation in their magnetic environment caused by a naval vessel, allowing them to destroy or damage this vessel. Some aircraft are also fitted with sensors of this type enabling them to detect the naval vessel in order to destroy it. The risk generated by the possibility of detection by an aircraft of the magnetic signature of a naval vessel is called the risk M.AD. (Magnetic Anomaly Detection).

 The magnetic signature of a building is constituted by its permanent magnetization and by its induced magnetization.

 The permanent magnetization of a structure is due to the ferromagnetic materials constituting it. This is substantially constant, fluctuates only over time and is linked to the nature of the material used.

 The induced magnetization, on the other hand, is essentially variable. In the case of a ship, it depends on its orientation in the land field, its course and its inclination due to roll and pitch.

 The magnetic signature of the ship therefore makes it possible to locate it, to follow it, and possibly to guide or ignite devices intended to destroy it.

 R is therefore very important to minimize or even cancel this "magnetic signature" to prevent its detection by magnetic method.

 This operation, called "magnetic immunization", is carried out, in a known manner, by creating in the volume of the building a magnetic field which compensates for that of the building, in order to cancel its magnetic signature. For this, the building is provided with a set of circuits called "immunization loops" which are traversed by electric currents.

 The dimensions, the arrangement of the loops and the currents flowing therein are determined to best minimize the "magnetic signature" of the building, whatever its orientation in the Earth's magnetic field, that is to say whatever its heading. and its inclination due to roll and pitch. These immunization loops are distributed in three directions corresponding to the roll, yaw and pitch axes, conventionally called "l, M, A" or even "L, V, r '(Longitudinal, Vertical, Transversal).

 The currents in the immunization loops are adjusted using values obtained by passing the naval vessel through a measuring station. This station may be placed at the bottom of the sea (at a depth generally varying from 8 m to 30 m) and made up of a line of magnetometers with regard to the risk caused by mines or other naval vessels, or be made up of magnetometers on board an aircraft for the MAD risk The readings obtained thanks to these magnetometers make it possible to obtain on land a setting of the value of the currents to be circulated in the immunization circuits whatever the heading of the vessel, in a plane at the depth or at the altitude of danger.

 After adjustment, the building goes on a mission without knowing precisely the map of the magnetic field it creates in the volume that surrounds it and for different heights of water. Indeed, such knowledge would imply the transmission, from a land station, of too large a number of data.

However, depending on the requirements of its mission, during which the naval vessel may be required to locate a suspicious object or the presence of an aircraft likely to locate it, this vessel must be able to know its exact magnetic signature and the associated risk to this one, at a point or on a given area. Indeed, it may be necessary to modify in intensity the currents flowing in the immunization circuits and to control the results of these modifications on the magnetic signature. However, there are currently no methods making it possible to predict in real time the magnetic signature of a naval vessel in a defined danger zone and to deduce its risk with respect to an underwater magnetic detection. or aerial.

 In addition, if as a result of an incident, the electric current flowing in a given circuit cannot be maintained at its set value, the building must be able to estimate for itself the consequences of this failure on its vulnerability and remedy it immediately by a new adjustment of the currents in the immunization circuits.

 An object of the present invention is to provide a method enabling a naval vessel to predict in real time its magnetic signature in a danger zone in order to allow it to very quickly deduce its risk with respect to a detection system. magnetic located in the risk zone.

 Another object of the present invention is to provide a method allowing the naval vessel to assess its magnetic signature even in the event of an anomaly detected in the immunization circuits, and thus to independently assess its vulnerability, possibly by redefining automatically the best combination of currents taking into account the new constraints generated by the detected fault (s).

 Another objective of the invention is to provide a method allowing the naval ship to test in simulation the modifications of the currents in the immunization circuits in order to better control the impact of the latter on its magnetic signature, then if necessary to modify his real signature.

According to the invention, the method of self-monitoring and slaving of the magnetic immunization of a naval vessel provided with magnetic immunization circuits by means of a modeling system according to the invention comprises the steps consisting in:
- determine a danger zone in relation to which we want to assess the
magnetic risk;
- determine the spatial coordinates of said area in relation to a
reference mark of the naval vessel;
- use an on-board modeling system providing the risk
magnetic of the building according to the position of the building relative
to said area
In the present description, the term "modeling system" means any system making it possible to model a naval vessel or one of these "circuit effects", circuit effect being the difference of the magnetic fields created by a circuit of immunization, measured with the circuit supplied on the one hand and the circuit not supplied on the other.

According to a preferred variant, the method according to the invention comprises the steps consisting in:
- read in real time the values of the currents in the immunization circuits
naval building;
- define a type of risk and a danger threshold in order to characterize the
danger zone;
- read the on-board representative models of the magnetizations and effects of
naval ship circuits;
- predict in real time the magnetic field created by the naval vessel
in said danger zone;
- assess, according to the prediction obtained, the vulnerability of the building and
modify or not the values of the circulating currents in the circuits
building immunization.

According to a particularly advantageous variant of the invention, the self-monitoring and servo-control method further comprises the steps consisting in:
- detect any anomalies concerning the current values
immunization;
- predict the magnetic field by the ship building taking into account
any anomalies detected in the immunization circuits;
- possibly modify the currents in the immunization circuits by
according to the anomalies detected.

 This variant allows the naval vessel to independently estimate the consequences caused on its magnetic signature by an anomaly in a given circuit and to remedy it immediately by a new adjustment of the currents in the immunization circuits.

 According to an advantageous variant, the method according to the invention comprises an additional step consisting in testing in simulation the modifications of the currents in the immunization circuits, so as to control the validity of the information provided by the modeling system.

After simulation test and although a human intervention can be envisaged to carry out the stage of modification, in real time, of the values of the currents circulating in the immunization circuits of the building according to the information provided by the modeling system , the modification of these values is advantageously carried out automatically
According to a preferred embodiment of the method, it comprises a periodic updating of the on-board models thanks to magnetic sensors installed on board the naval vessel.

 According to another interesting variant, the method comprises a phase consisting in permanently updating the on-board models thanks to magnetic sensors installed on board the naval vessel.

 In order to optimize the use of the information provided by the modeling system, the method according to the invention can include a step consisting in using this information on a console or on a tactical table.

The operator can thus quickly modify the definition of the danger zone himself, for example switching from a mine risk to a MAD risk, assessing its vulnerability and ordering, if necessary, a temporary or permanent modification of the currents in the circuits. 'immunization.

The invention as well as the advantages which it presents will be more easily understood thanks to the nonlimiting example of embodiment of the invention which will follow with reference to the drawings in which:
- Figure 1 shows the three directions of arrangement of the loops
immunization in a ship;
- Figure 2 shows a flowchart of a process according to
the invention.

 According to FIG. 1, the building 21 comprises ferromagnetic structures surrounded by immunization loops 22, 23, 24. These loops are arranged in three separate planes. A loop 22 serves to compensate for the longitudinal magnetization and is commonly called a loop, another loop 23 serves to compensate for the vertical magnetization and is noted lS "and the third loop 24 which has the function of compensating for the transverse magnetization is noted ' T. Loops 22 and 23 are presented in perspective.

 A loop is characterized by its coordinates (x, y, z) relative to a given point, by its dimensions, by its resistance, by its shape, by the maximum current that can cross it, and by the number of available turns.

 Of course, the arrangement of FIG. 1 is only indicative, the immunization of all the ferromagnetic structures included in a ship implying the arrangement of numerous loops in the different planes around the structures to be compensated.

 According to FIG. 2, a step prior to the method of controlling and controlling the magnetic immunisatson of a naval vessel consists of an operation comprising two steps. The first of these stages a consists in measuring the magnetic field of the ship on station at sea. This stage consists in making traverse to the naval vessel twice the same course above networks of magnetic sensors according to opposite headings. The permanent magnetization linked to the building rotates with it, while the induced magnetization does not rotate. To know the induced magnetization it suffices to subtract the measurement results from the two opposite directions.

 The second step b consists in defining the representative models of the magnetizations of the naval ship and its loop effects. For example, it is possible to model the naval vessel or one of these "circuit effects" by a set of N ellipsoids.

The magnetic field derives from a magnetic potential V; the components hr hy, hz of the magnetic field are respectively equal to
1 dV 1 dV 1 dV 0 dx '0 dy 0 dz p0 being the permeability.

For an ellipsoidal model the potential is given nar:

The limit e is given by z
X Y Z
a + eb + ec + e each ellipsoid being defined by 9 data: the position of the center x, y, z, the projections of the magnetizations on the 3 axes M%, Mz, and the dimensions a, b, c.

 For a building with M immunization circuits, this is perfectly defined using (M + 4) models, i.e. 9 N (M + 4) given. The number 4 corresponds to the 4 models for the cut circuits and relating to the permanent magnetization and to the induced magnetizations along the 3 axes.

 The process of self-monitoring and control of the immunization consists, after having transferred all of the models, c, on board the naval vessel, to characterize a danger zone 2, by defining the type of risk 10 and the thresholds of dangers 11 so as to arrive at a precise definition of the danger zone 12. Steps 10 and it can be replaced by a step 19 for reading in real time the parameters relating to the danger zone (depth, target, etc.). The method then consists in reading the on-board representative models of the magnetizations and effects of circuits of the naval vessel 3, these models being updated 8 by means of sensors installed on board, but in predicting in real time the magnetic field created by the naval vessel in the defined danger zone 4, to exploit the results graphically 5 finally to interpret the vulnerability of the building and to decide whether or not to modify the values of the currents flowing in the building's immunization circuits 6 ,.

In addition, the method according to the invention comprises an additional step
7 consisting in detecting any anomalies concerning the values of the immunization currents flowing in the immunization circuits.

 As such, the real-time reading of the immunization currents flowing in the circuits 1 is followed by a step making it possible to detect any anomalies concerning the values of the immunization currents and to predict the magnetic field created by taking into account these possible anomalies. This step is divided into a step of detecting the anomaly 13 followed, if an anomaly is detected, by a step of predicting the magnetic field produced in the immunization loops by taking into account the detected anomaly 14 and then of a step of calculating the optimum currents 15 followed by a validation 16 leading to the modification of these currents during a step 17.

 The step of reading in real time the currents flowing in the immunization circuits 1 followed by the step of detecting anomalies making it possible to modify these currents 7 results in knowing the currents in the immunization loops 18.

 It will be taken into account that in other embodiments the two preceding steps I and 7 can be substituted by manual entry of the values of the currents flowing in the circuits.

 Thanks to the process according to the invention, the building has all the means necessary to calculate the magnetic field created at a point with any coordinates (x, y, z) in the frame centered on the building.

Indeed this field can be described as the sum of contributions
- of the building without the immunization circuits, obtained from the models
permanent and induced magnetizations, the local magnetic field and the
course of the ship known elsewhere,
- immunization circuits, obtained from models of the effects of
immunization circuits and measurement of the currents Ii in the circuits
immunization (lsisM); the magnetizations M, My, M are multiplied by
the ratio Ii / IiO where Ii represents the current used to measure the effect of
circuit on station.

 The coordinates (x, y, z) are defined by a hazard analysis. The parameter z is either the depth (mine risk) or the assumed altitude of the aircraft relative to the building (MAD risk). The x, y coordinates of the points for which the field is calculated define the length and width of the area that you want to cover.

 Once the components hx, h "hz have been calculated at several points on the plane corresponding to the danger zone, the module is calculated for example, which is compared to a predefined limit value (threshold) not to be exceeded. If there is overshoot , the captain orders a maneuver to move the building. The field is then recalculated to check if the building is still vulnerable. The captain can also order a calculation of the magnetic field with new current values in the circuits and modify these currents if the building has become non-vulnerable again.

 Apart from any immediate danger, if there is an anomaly detected, the system allows the building to almost instantly assess the consequence of this anomaly on its vulnerability and redefine the best combination of currents to minimize its signature.

 Advantageously, the danger zone and the values of the magnetic field are displayed on a console or a tactical table to aid in the decision.

Claims (8)

1. A method of self-monitoring and slaving of the magnetic immunization of a naval vessel provided with magnetic immunization circuits by means of a modeling system characterized in that it comprises the steps consisting in:  - determine a danger zone in relation to which we want to assess the  magnetic risk;  - determine the spatial coordinates of said area in relation to a  reference mark of the naval vessel;  - use an on-board modeling system providing in real time the  magnetic risk of the building depending on the position of the building by  relative to said area; 2. Self-checking and servo-control method according to claim 1, characterized in that it comprises the steps consisting in:  - read in real time the values of the currents in the immunization circuits  naval building;  - define a type of risk and a danger threshold in order to characterize the  danger zone;  - read the on-board representative models of the magnetizations and effects of  naval ship circuits;  - predict in real time the magnetic field created by the naval vessel  in said danger zone;  - assess, according to the prediction obtained, the vulnerability of the building and  modify or not the values of the circulating currents in the circuits  building immunization. 3. A method of self-monitoring and control according to one of claims 1 or 2 characterized in that it further comprises the steps consisting in:  - detect any anomalies concerning the current values  immunizations;  - predict the magnetic field by the ship building taking into account  any anomalies detected in the immunization circuits;  - possibly modify the currents in the immunization circuits by  according to the anomalies detected. 4. A method of self-monitoring and control according to one of claims 1 to 3 characterized in that it comprises an additional step consisting in testing in simulation the modifications of the currents in the immunization circuits. 5. Self-checking method according to one of claims 1 or 4 characterized in that the final step of modifying the values of the currents in the immunization circuits of the naval vessel is carried out automatically according to the prediction of the magnetic signature obtained . 6. A method of self-monitoring and control according to one of claims 1 to 5 characterized in that it further consists in periodically updating the on-board models using magnetic sensors installed on board the naval vessel. 7. A control and servo-control method according to any one of claims 1 to 5, characterized in that it also consists in permanently updating the on-board models thanks to magnetic sensors installed on board the naval vessel. 8. Control and servo-control method according to one of claims 1 to 7 characterized in that it consists in exploiting the information on a console or on a tactical table.