FR2899387A1 - Radio antenna device for surface ship, has antenna with cable extending between support and float, where device is adapted so that cable is suspended over major portion of length of cable above stretch of water when float is towed by ship - Google Patents

Abstract

The device (1) has an antenna (3) attached to an antenna support (4), where the support is attached to a surface ship (2). The antenna has a flexible cable (6a) e.g. single-strand cable, extending between the support and a float (5), where the device is adapted so that the cable is suspended over a major portion of a length (8a) of the cable above and at a distance from a stretch of water when the float is placed on the surface of the stretch of water and towed by the ship.

Description

The present invention relates generally to the field of antennas

  and antenna devices used on surface vessels.

  More particularly, the invention relates to a radio antenna device for a surface vessel comprising: - an antenna; an antenna support to which said antenna is fixed, this support being adapted to be fixed to said vessel. We can associate for example a whip antenna with a tuning box: in this case a whip usually between 6 and 12 m high equipped with a tuning box can cover the HF band. This solution has a relatively small footprint allows to tune the antenna on a narrow portion of the HF band. The use of frequency evasion type waveform requires the use of high cost specific tuning boxes. This type of antenna has a radiation pattern that is strongly affected by the presence of the superstructures of the ship.

  It is also possible to use a broadband antenna composed of a ribbon antenna for the lower part of the strip (typically 2 - 8 MHz) as described in patent document US3803615 and a triple whip or a vertical bicon for the the upper part of the HF band (typically 8 MHz), the assembly being associated with a duplexer, allowing the combination of these two antennas to be seen by the transmission system as a single air. The disadvantage of this type of solution lies mainly in the size of the HF web that must be deployed over the bridge over a significant length (10 to 25 m).

  It is also possible to use a single or twin whip antenna equipped with a damping device making it possible to have a broadband antenna at the cost of a significant loss of output at the bottom of the band.

  For the three solutions mentioned above, one of the main drawbacks lies in the need to deploy the radiating elements of the antenna on the deck of the ship or on the superstructures of the ship, which limits the distance between the various equipment installed on board. and consequently the decoupling between the said elements.

  The deployment of antennas such as high frequency antennas aboard the surface ships therefore faces the problems of the necessary dimensions of the antennas, which, in order to ensure satisfactory performance, must have a length approaching 1% wavelength. frequencies considered. In practice, for low frequencies, antennas have, for reasons of space, less than 1% wavelength: at 2 MHz the wavelength? = 150 m is an ideal antenna of length%, / 4 = 37.5 m.

  Given the space available on the ship it is extremely difficult to deploy antennas of such a large size. As a result, the actual length of an antenna is often less than the optimal theoretical size it should have for optimal performance at certain frequencies. In this context, the present invention aims to provide a surface vessel antenna device for deploying an antenna without posing congestion problem at the deck of the vessel or its structures. To this end, the antenna device of the invention, moreover complies with the definition, gives the preamble defined essentially characterized in that it floats and in that the antenna comprises flexible cable extending between the support the float , the device being adapted from that when the float is placed on the surface of a body of water and towed by a surface vessel carrying the antenna support, said antenna cable extending between the float and the support is then suspended over a major portion of cable length, above and away from the water, thus allowing the aerial deployment of an antenna cable.

  The antenna cable is provided to allow transmission and / or reception of radio signals included in bandwidths of generic means than previously, is at least comprises antenna at a frequency and a frequency (MF) up to at high frequency bandwidths such as 30 MHz frequencies. For a frequency of 2 MHz the antenna length will preferably be 35 m, corresponding to a quarter of the wavelength at 2 MHz, a quarter of 150 m. The invention makes it possible to deploy, overhead, above the water surface and outside the ship, thus outside the strongest zones of electromagnetic disturbances generated by the ship, an antenna length that can be adapted specifically to the types of frequencies to be used. capture and / or transmit. The float allows on the one hand to exert a tension force of the cable to maintain it stretched above the body of water. The float also allows identification of the end of the cable to avoid damage during maneuvering / crossing other vessels. Thanks to the present invention a ship can use one or more antennas whose size is greater than the antennas that can be placed on board, on the deck or on the superstructure of the ship. In addition, the fact that the antenna is away from the ship allows a reception / emission limiting functional electromagnetic compatibility phenomena. In addition, the deployment of the antenna outside the vessel's vertical space requirement and by its structures / equipment makes it possible to obtain a more regular radiation pattern with respect to the aerial antennas installed on the bridge, whose Radiation diagrams are largely distorted by the presence of super structures.

  The invention allows an improved antenna performance, a release of space at the superstructure of the ship and thus an improvement in the safety of people accessing the deck of the ship.

  Preferably, the device of the invention comprises a frequency generator electrically connected to the antenna cable and / or an electronic reception module connected to the antenna cable. Other characteristics and advantages of the invention will emerge clearly from the description which is given hereinafter, by way of indication and in no way limiting, with reference to the appended drawings, in which: FIG. 1 represents an assembly formed by an equipped vessel the antenna device of the invention with a single antenna cable, the ship being viewed in rear perspective; Figure 2a shows a side view of the assembly of Figure 1 with the ship underway and the antenna cable stretched above the body of water; Figure 2b shows a top view of all of Figures 1 and 2a; FIG. 3 represents a detailed side view of the float of the device of the invention, according to a first embodiment of the float with electrical insulation of the antenna cable;

  FIG. 4a shows a detailed side view of the float of the device of the invention, according to a second embodiment of the float with a grounding of the cable; Figure 4b shows an embodiment of the float equipped with a cable trestle for the grounding of the antenna cable; FIG. 5a shows a side view float according to a third alternative embodiment of the float with a ballast and a grounding of the cable through an electrical resistor; FIG. 5b shows an embodiment of the float equipped with a trolley cable for grounding the antenna cable and an electrical resistor disposed in the float and electrically interconnecting the trunk and antenna cables; FIG. 6 represents the assembly comprising a ship in top view equipped with the device of the invention, this device comprising two disjointed antenna cables, each of these cables being kept apart from the other cable by a sling specific to each cable ; Figure 7 shows the assembly of Figure 6 with the ship in rear perspective, and the slings directly attached to the ship structure; FIG. 8 shows the assembly of FIG. 6 with the ship in rear perspective, in which each sling is not fastened directly to the ship's structure, as is the case in FIGS. 6 and 7, but in FIG. end of poles; FIG. 9 represents an assembly comprising a ship seen in rear perspective and equipped with the device of the invention with a single antenna cable, a pole and a sling connecting one end of the pole to a point of the antenna cable, the boom being placed on a side edge of the ship so as to deport the cable with respect to the wake of the ship.

  As previously announced, the invention relates to a radio antenna device 1 for a surface vessel 2 shown in FIGS. 1 to 9. This device comprises: an antenna 3; an antenna support 4 to which said antenna 3 is fixed, this support 4 being adapted to be fixed to said vessel; - a float 5.

  The antenna 3 comprises at least one flexible cable 6a, 6b extending between the antenna support 4 which is fixed on the ship and the float 5. In the embodiment of Figures 1, 2a, 2b and 9 the antenna has a single antenna cable.

  In another embodiment shown in Figures 6, 7, 8, the antenna is formed by two cables disjoined from each other over a major part of their respective lengths.

  The device 1 is provided so that when the float 5 is placed on the surface of a body of water 7 and towed by the surface vessel 2, or the antenna cable (s) 6a, 6b is / are then stretched (s) between the float 5 and the support 4 and is / are suspended (s) on a major part of the length of the cable or cables 8a, 8b, in this case here, over the entire length of the cables, and / or be above and at a distance from the body of water 7.

  For this, the float 5 comprises a variable drag force generation device adapted to generate a tension force of the antenna cable (s) between the support 4 and the float 5, this voltage force is variable at least as a function of the relative towing speed of the float 5 with respect to the water plane 7, so as to obtain a tension force of the cable 6a at a relatively low towing speed greater than a tension force of the cable at a relatively high speed of towing. The drag force generation device is provided to increase the drag force at low speed so that the at least one cable is suspended above the water plane, between the float and the support, as soon as the speed of the drag ship exceeds 4 nautical knots.

  For example, the drag force generating device can be obtained by profiling the float so that at low towing speed, it is pushed deeper into the water than at high speed. Thus the draft of the float is much larger at low speed, which increases the drag force generated and therefore the tension force exerted on the cable or cables of the antenna. In order to promote a strong drag force at low speed, it is possible to make the float in the form of a floating anchor having a drag coefficient decreasing with increasing speed.

  The device is adapted so that when the float 5 is towed by the ship 2 beyond a predetermined relative speed with respect to the water plane 7, the at least one antenna cable 6a, 6b is then suspended above of the body of water 7 over its entire length 8a, 8b located between the float 5 and the antenna support 4. On all of Figures 1 to 9, the cable or cables are shown stretched, while the ship tows the float above the predetermined relative speed.

  The antenna cable may be a single-strand or multi-strand cable and is electrically conductive to enable the pick up and transmission of radio waves.

  In the embodiment of FIGS. 6, 7, 8 the device 1 comprises two antenna cables 6a, 6b that are distinct from each other, each of these antenna cables having one of its ends connected to the vessel 2 in at least one feed point 9a, 9b. The feed points may be specific to each cable and distant from each other or alternatively be interconnected. In all cases the device is adapted so that at least when the float 5 is towed by the ship 2, the two antenna cables 6a, 6b are spaced apart from each other over a major part of their respective lengths. 8a, 8b.

  Here, the cables 6a and 6b are connected only to each other at their ends and are disjoint and distant between these ends which widens the bandwidth of the antenna.

  Preferably the device comprises at least one antenna feed point 9a, 9b located on the ship 2 and at one end of said at least one antenna cable 6a, 6b. In the embodiments shown in Figures 6 to 8, the antenna feed points are merged. The device may also comprise at least one sling 10a, 10b of dielectric material adapted to connect an intermediate point 11a, 11b of said antenna cable to a slinging point 12a, 12b, said intermediate point 11a, 11b being located between ends said antenna cable 6a, 6b and said slinging point 12a, 12b being located on the ship 2 and away from said feed point 9a, 9b of said at least one antenna cable 6a, 6b. In the embodiment of Figures 7 and 8, the device comprises two slings 10a and 10b, each of these slings having one end attached to only one of the two cables and another end attached to a slinging point formed on the ship. Each of the slings is tensioned so as to spread the cables apart from each other when the ship is traveling by dragging the float 5 and the antenna cables 6a, 6b. In the embodiment of Figure 9 which has only one antenna cable 6a, a single sling is used to deport the antenna cable to an edge of the ship. In addition to allowing the guide or the antenna cables, or slings can reduce the force actually applied to a cable at its power point which reduces the risk of cable breakage at this point.

  In a complementary embodiment shown in Figures 8 and 9, the device comprises at least one pole 13a, 13b (as many poles as slings) of a dielectric material having a base fixedly fixed to the ship 2 and extending to the outside of the ship 2, this pole 13a, 13b having an end remote from its base and constituting said point of linkage 12a, 12b of said at least one antenna cable 6a, 6b. Thus, in the embodiments of Figures 8 and 9 each antenna cable is guided by a sling and each sling is attached to the end of a pole itself assembled to the ship. The poles make it possible to ensure that the sling (s) and the antenna cable (s) are always spaced from the hull so as to prevent them from falling vertically to the edge of the shell, thus reducing the risk of snagging of the hulls. cables. In order to prevent the cable from plunging into the water when the vessel no longer drag the float, said at least one antenna cable 6a, 6b has floating means 14 adapted to give it a positive buoyancy.

  Said at least one antenna cable 6a, 6b also has an electrically insulating cladding 14 over most of its length 8a, 8b.

  Preferably, the insulating cladding is in a light material (that is to say with a density lower than that of water) and thus fulfills both an electrical insulation function of the antenna cable and a flotation function positive of the cable.

  Advantageously, as shown in FIG. 2, the device comprises an impedance matching device 15 electrically connected to said at least one antenna 3, this antenna being adapted to operate in reception and in radio wave transmission.

  Advantageously, the float 5 has a shape and a distribution of masses such that when the float 5 is placed on the surface of a body of water 7, it naturally moves in a stable position in which the float and the position said plane always distance D between the center of gravity of the body of water is constant regardless of the float when it is placed on the surface of water. Thus the float is adapted to position itself in a predefined stable position independently of placed at the moment of relative to the water and this the position in which it is launched.

  In an embodiment shown in FIG. 3, the float 5 is made of electrically insulating material and the cable which is mechanically connected to the float is also electrically isolated from the body of water via the float. Preferably, the cable will be sheathed and electrically insulated along its entire length to avoid electromagnetic disturbances related to the water body.

  Alternatively, one can look to electrically connect the cable to the water. In this embodiment, the device comprises an electrical ground contact 16 for electrically connecting said antenna cable 6a, 6b to the water plane 7. This contact can be located at said float 5 as shown in FIGS. 4a and 5a. or offset from the float as shown in Figures 4b and 5b where the ground contact extends away from the float. In the case of FIGS. 4a and 5a, the electrical ground contact 16 is disposed on a lower face of the float, which is always oriented towards the bottom of the body of water and is therefore always in contact with the water, thus allowing establishing the mass contact when said float is positioned on the water.

  In this embodiment the cable is electrically connected to the body of water via the electrical contact 16. This embodiment is particularly suitable for use of the device in seawater where the conductivity is important.

  It is also possible to make the ground contact 16 by connecting the antenna cable to a peripheral ring formed around the float, this ring having the advantage of being in contact with the water, even when the float starts to rotate. makes currents exerted around the buoy. Preferably, in order to limit the risk of rotation of the float 5 along an axis close to the antenna cable 6a, and in order to avoid deterioration of the antenna cable, the float is made to have a symmetry of revolution with preferentially a distribution also. symmetrical masses according to the axis of revolution of the float 5. In an embodiment of the float that can be combined with any of the previously described float embodiments, it is possible to arrange to have an electrically conductive cable and not isolated extending to the rear of the float (Figures 4b and 5b). This cable 16 is electrically connected to the antenna cable 6a which is then placed at the front of the float. The advantage of a cable trestle 16 is that it always remains in contact with the water and this even if the float 5 comes off the surface 7 of water for example under the effect of a wave or high trolling speed. This embodiment guarantees a grounding even in case of bad sea. FIG. 4b shows an embodiment where the trunk cable 16 is a direct extension of the antenna cable, the insulated antenna cable by a sheath. stopping at its junction with the float.

  FIG. 5b shows an embodiment of the float 5 according to the invention in which the trunk cable 16 is electrically connected to the antenna cable 6a by an electrical resistor 17.

  The use of an electrical resistor 17 disposed at said float 5 and connected in series between said antenna cable 6a, 6b and said electrical ground contact 16 (ground wire ring device or other mass) can create a load cushioning. In a preferred embodiment shown in Figure 2, the device comprises mechanical means such as one or more winch (s) 18 for adjusting the length of said at least one cable 6a, 6b extending between the antenna support 4 and said float 5 thus allowing adjustment of the radio bandwidth of the antenna and / or for retracting the antenna. It can be ensured that the support of the device of the invention is formed by one or more winch (s) which is or are fixed (s) on the ship. This or these winches allow a winding of the cable and thus facilitate both the launching of the antenna shaped cable (s) and storage. The winch may for this include a drum rotatably mounted motorized about an axis and the antenna wrapping around the drum. This embodiment makes it possible to adjust the size of the antenna to adapt it to the frequency ranges to which it must be applied and thus to improve its efficiency. For this, an electronic cable length control device can be directly connected to the radio receiver / transmitter on which the antenna is connected.

Claims (13)

  1) Radio antenna device (1) for surface vessel (2) comprising. an antenna (3); an antenna support (4) to which said antenna (3) is fixed, this support (4) being adapted to be fixed to said vessel (2); characterized in that it comprises a float (5) and in that the antenna (3) comprises at least one flexible cable (6a, 6b) extending between the antenna support (4) and the float (5). ), the device (1) being adapted so that when the float (5) is placed on the surface of a body of water (7) and towed by a surface vessel (2) carrying the antenna support (4), said antenna cable (6a, 6b) extending between the float (5) and the support (4) is then suspended over a major portion of length (8a, 8b) of the cable (6a, 6b ), above and away from the body of water (7), thus allowing the aerial deployment of an antenna cable (6a, 6b).   2) Device according to claim 1, characterized in that the float (5) comprises a variable drag force generation device adapted to generate a tension force of the antenna cable between the support (4) and the float (5). ), this tensioning force being variable at least as a function of the relative towing speed of the float (5) with respect to the water plane (7) so as to obtain a cable tension force at a relatively low towing speed greater than a cable tension force at relatively high towing speed.   3) Device (1) according to any one of claims 1 or 2, characterized in that it is adapted so that when the float (5) is towed by the vessel (2) beyond a predetermined relative speed with respect to the body of water (7), said at least one antenna cable (6a, 6b) is then suspended above the body of water along its entire length (8a, 8b) situated between the float (5) and the antenna support (4).   4) Device (1) according to any one of the preceding claims, characterized in that it comprises two antenna cables (6a, 6b) separate from each other, each of these antenna cables being adapted to have one of its ends connected to the ship (2) at a feed point (9a, 9b) specific to each cable, the feed points of the cables being distant from each other, the device being further adapted so that at least when the float (5) is towed by the ship (2), the two antenna cables (6a, 6b) are spaced apart from each other over a major part of their lengths respective ones (8a, 8b).   5) Device according to any one of claims 1 to 4, characterized in that said device comprises at least one antenna feed point (9a, 9b) located on the ship (2) and at one end of said at least one an antenna cable (6a, 6b) and a sling (10a, 10b) of dielectric material adapted to connect an intermediate point (11a, 11b) of said antenna cable to a slinging point (12a, 12b), said intermediate point (11a, 11b) being located between ends of said antenna cable (6a, 6b) and said slinging point (12a, 12b) being located on the ship (2) and away from said feeding point ( 9a, 9b) of said at least one antenna cable (6a, 6b).   6) Device according to the preceding claim, characterized in that it comprises a pole (13a, 13b) of a dielectric material having a base fixedly mounted on the ship (2) and extending outwardly of the ship (2) , said pole (13a, 13b) having an end remote from its base and constituting said slinging point (12a, 12b) of said at least one antenna cable (6a, 6b).   7) Device according to any one of the preceding claims, characterized in that said at least one antenna cable (6a, 6b) has floating means (14) adapted to confer positive buoyancy to said cable.   8) Device according to any one of the preceding claims, characterized in that said at least one antenna cable (6a, 6b) has an electrically insulating cladding (14) over most of its length (8a, 8b) .30   9) Device according to any one of the preceding claims, characterized in that it comprises an impedance matching device (15) electrically connected to said at least one antenna (3), this antenna being adapted to operate in reception and in radio wave transmission.   10) Device according to any one of the preceding claims, characterized in that it comprises an electrical ground contact (16) disposed at said float (5), the contact (16) being adapted to electrically connect said cable (6a). , 6b) antenna to the water body (7), when said float is positioned on the body of water.   11) Device according to claim 10, characterized in that an electrical resistor (17) is disposed at said float (5) and connected in series between said antenna cable (6a, 6b) and said electrical ground contact (5). 16).   12) Device according to any one of claims 10 and 11, characterized in that said electrical earth contact (16) comprises at least one electrically conductive cable and cable (16) not electrically isolated.   13) Device according to any one of the preceding claims, characterized in that it comprises mechanical means such as a winch (18) for adjusting the length of said at least one cable (6a, 6b) extending between the support antenna (4) and said float (5) thus allowing adjustment of the radio bandwidth of the antenna and / or retracting the antenna.