EP0524045B1 - Antenna for decametric waves with reduced wind load - Google Patents

Description

The present invention relates to antennas with HF dipole arrays and relates more particularly to the problem of their resistance to wind. This problem arises particularly, but not only, with rotating curtain antennas; this is why the solution to this problem will be studied, in the following, with such antennas. The adaptation of the solution to fixed antennas, such as antennas where the where the dipole arrays are stretched between fixed masts, generally vertical, will also be mentioned. In all these antennas the dipoles of the same network are arranged substantially in the same plane, which makes it possible to speak indifferently of a network or curtain of dipoles.

HF antennas, with dipole arrays, are antennas that are several tens of meters high and several tens of meters wide; some reach and even exceed one hundred meters in height and one hundred meters in span. The known antennas have rectangular vertical arrays made of dipoles regularly distributed in superimposed lines and in columns, and a network of antenna dipoles is presented substantially like a rectangle or a square. Associated with this network is a reflector generally made up of parallel wires and this reflector which, too, is substantially like a rectangle or a square of dimensions substantially greater than those of the network, is arranged parallel to the network of dipoles. Given the dimensions of an HF antenna it is difficult and therefore very expensive to ensure good rigidity at the antenna; when this rigidity is not correctly ensured, this results, in strong winds, in a significant modification, of its adaptation characteristics; this modification can make that the broadcast is disrupted or even that it must be stopped.

The object of the present invention is to avoid or at least reduce these drawbacks.

This is obtained in particular by giving the dipoles, in the curtain, a distribution different from that according to the prior art, that is to say different from a rectangle or a square.

According to the invention an HF antenna is proposed comprising a vertical reflector and a vertical curtain designed to work in a given frequency range, the curtain being made of radiating dipoles distributed in groups on n different levels, with at least n integer equal to 2, characterized in that, for reasons of wind resistance, the number of dipoles of the group located at the highest level is at least one unit less than that of the group located at the lowest level and in this that, between any two of the groups, the upper group has a number of dipoles at most equal to that of the lower group.

• les figures 1 et 2, respectivement des vues de face et de côté d'une antenne selon l'art connu,
• les figures 3 et 4, deux vues de face relatives respectivement à deux antennes selon l'invention.

The present invention will be better understood and other characteristics will appear from the following description and the figures relating thereto which represent:

• FIGS. 1 and 2, respectively front and side views of an antenna according to the prior art,
• Figures 3 and 4, two front views respectively relating to two antennas according to the invention.

In the various figures, the corresponding elements are designated by the same references.

Figures 1 and 2 show a rotary antenna, double, for HF, 82 meters high and 76 meters wide, which includes a support and two antennas proper: a low range antenna working in the radio bands from 6 to 11 MHz and a high range antenna working in the radio bands from 11 to 26 MHz.

The support includes a hollow base, in masonry, forming a room L inside which are placed transmitters and a mechanical assembly with a motor shaft which rotates a crown C arranged on the roof of the room. This crown is integral with the lower end of a vertical mast M on which are fixed four horizontal beams P1 to P4 arranged in the same vertical plane; forty beams such as b1 to b4 and B1 to B6 are joined at their first end to one of the beams. Rigid bars constituting crutches, such as T1 and T2, or spacers, such as T3 are mounted at the ends of the beams P1 to P4, and are arranged substantially in the plane of these beams; the two spacers such as T3, allow the beam P2 to support the beam P1. Guy lines, such as H1 and H2, connect the beams to the mast at an oblique angle. The mast has three parts: a vertical cylindrical barrel with circular cross section, M1, surmounted by a vertical lattice beam, M2, itself surmounted by an assembly M3 formed by two bars welded to the rune of their ends to form an acute angle with point facing upwards.

The low range antenna is an antenna of the HR 4/4 / 0.5 type, that is to say that it comprises a curtain of horizontal dipoles, H, with reflector, R, with 4 half-wave dipoles folded per line and 4 per column in the curtain and with a height of the first line of dipoles from the ground equal to 0.5 times the average operating wavelength of this antenna. The dipole curtain of the low range antenna thus consists of 16 dipoles d1 to d16 fixed on the free ends of 16 of the 40 beams, like the beams b1 to b4; these dipoles are arranged in the same vertical plane parallel to the vertical plane of the beams P1 to P4. It should be noted that in FIG. 1, as in fact in FIGS. 3 and 4, the different dipoles are represented from the front by thick lines in their rigid part and by parallel fine lines in their wire part. It is between the vertical plane of the dipoles d1 to d16 and the vertical plane of the beams or, more exactly, in the plane of the front faces of the beams P1 to P4 that a third plane is arranged. vertical, parallel to the first two, made of a layer of horizontal wires and constituting the reflector Rb of the low range antenna; the horizontal wires of this reflector are held by an edge cable C1 which passes through the top of the mast M and through the free ends of the bars constituting crutches such as T1 and T2; the spacing between the horizontal wires of the reflector Rb is kept using vertical cables such as K1, on which the horizontal wires are fixed at regular intervals, The reflector Rb of the low range antenna was not drawn in whole in FIG. 1, so as to make it possible to see the high range antenna which is placed behind it, and, in FIG. 2, it has been represented schematically by a dashed line which symbolizes its trace in the plane of the figure.

The high range antenna is an antenna of the HR 4/6 / 0.75 type, that is to say that it comprises a curtain of horizontal dipoles, H, with reflector, R, with 4 half-wave dipoles folded per line and 6 per column in the curtain and with a height of the first line of dipoles from the ground equal to 0.75 times the average operating wavelength of this antenna. The dipole curtain of the high range antenna therefore consists of 24 dipoles, D1 to D24, fixed on the free ends of 24 of the 40 beams, like the beams B1 to B6; these dipoles are arranged in the same vertical plane parallel to the vertical plane of the beams P1 to P4. As for the reflector, Rh, of the high range antenna it is made of a vertical sheet of horizontal wires arranged in the plane of the rear faces of the beams P1 to P4, between the reflector Rb and the dipole curtain of the range antenna high; the horizontal wires of the reflector Rh are held in a frame delimited by the upper beam P1, by border cables such as C2, held at their lower end by two crutches such as T4 secured to one of their ends of the lower beam P4; the spacing between the horizontal wires of the Rh reflector is kept using vertical cables such as K2, on which the horizontal wires are fixed at regular intervals. Like the reflector Rb, the reflector Rh has not been shown in its entirety in FIG. 1 in order to reveal the dipole curtain of the high range antenna which is behind it, and, in FIG. 2, it has been represented schematically by a dashed line which symbolizes its trace in the plane of the figure.

Because of the geometrical dimensions of the antenna according to FIGS. 1 and 2 and therefore of the surfaces that constitute the two dipole curtains and the two reflectors, the wind generates in the structure of the antenna significant forces which must be transmitted to the ground. Now the dynamic wind pressure increases with height, that is to say that the preponderant forces are generated by the wind in the upper parts of the antenna structure and the effect is further amplified by the fact that the arm of lever relative to the ground is obviously the longest in the upper parts. In addition, the upper parts of the antenna greatly increase the periods of oscillation of the structure, but the longer the period, the more the dynamic effect of the wind is. amplified. This led to thinking of modifying the antenna of FIGS. 1 and 2, in its upper parts.

Figures 3 and 4 are two embodiments of antennas obtained by modifications of the upper parts of the antenna according to Figures 1 and 2. These modifications have brought a significantly lower cost of the antenna in particular because the mast M and the hollow base L not having to undergo such great efforts, are less costly to produce.

• la longueur de la poutre supérieure P1 a été réduite de près des deux tiers,
• les deux entretoises telles que T3 ont été remplacées par deux poutrelles obliques, telles que J, qui s'appuient sur le mât et soutiennent la poutre P1
• la surface du réflecteur gamme basse, Rb, a été fortement réduite par suppression de ses coins supérieurs, la fixation des fils de ce réflecteur restant assurée de la même façon mais avec de nouvelles béquilles, telles que T5 à T6, aux extrémités des poutres P1 et P2
• la surface du réflecteur gamme haute, Rh, a été légèrement réduite du fait d'une modification, dans ses deux coins supérieurs, de son système de fixation : prolongation vers le haut des câbles de bordure tels que C2, en raison de la réduction de longueur de la poutre P1.

The antenna according to FIG. 3 corresponds to the antenna according to FIGS. 1 and 2 in which the dipoles d1 and d4 of the low range antenna have been removed and, consequently,

• the length of the upper beam P1 has been reduced by almost two thirds,
• the two spacers such as T3 have been replaced by two oblique beams, such as J, which rest on the mast and support the beam P1
• the surface of the low range reflector, Rb, has been greatly reduced by removing its upper corners, the fixing of the wires of this reflector remaining ensured in the same way but with new crutches, such as T5 to T6, at the ends of the beams P1 and P2
• the surface of the high range reflector, Rh, has been slightly reduced due to a modification, in its two upper corners, of its fixing system: upward extension of the edge cables such as C2, due to the reduction in length of beam P1.

• pas de modification des performances de l'antenne gamme haute
• réduction de l'ordre de 0,5 dB du gain de l'antenne gamme basse
• pointage en site relevé de 0,8 degré pour l'antenne gamme basse ; ceci peut être réduit en fournissant plus de puissance aux dipôles supérieurs
• réduction de poids d'environ 15% sur la partie de l'antenne située au dessus de la base L.

The comparison of the antenna according to FIG. 3 to the antenna according to FIGS. 1 and 2 gives the following results:

• no change in the performance of the high range antenna
• 0.5 dB reduction in low range antenna gain
• site pointing raised by 0.8 degrees for the low range antenna; this can be reduced by providing more power to the upper dipoles
• weight reduction of around 15% on the part of the antenna located above the base L.

The antenna according to FIG. 4 corresponds to the antenna according to FIGS. 1 and 2 in which the dipoles d1, d4, d5, d8 of the low range antenna and the dipoles D1, D4, D5, D8 of l have been deleted. '' high range antenna. These deletions allowed a reduction of almost two thirds of the length of the beams P1 and P2 and a reduction in the surfaces of the reflectors Rb and Rh by a suppression of their upper corners; and it should be noted that this suppression is significantly greater than in the case of the antenna according to FIG. 3.

• réduction de l'ordre de 1 à 1,5 dB , selon la fréquence, du gain de l'antenne gamme basse dont l'angle de site est relevé de 1 à 1,5 degrés, selon la fréquence,
• réduction de l'ordre de 0,8 à 1 dB, selon la fréquence, du gain de l'antenne gamme haute dont l'angle de site est relevé de 1 degré,

et il est à noter que, là encore, la modification de l'angle de pointage peut être réduite en fournissant plus de puissance aux dipôles supérieurs, c'est-à-dire aux dipôles des lignes comportant moins de dipôles que la ligne la plus basse du réseau considéré.The comparison of the antenna according to FIG. 4 to the antenna according to FIGS. 1 and 2 gives the following results

• reduction of the order of 1 to 1.5 dB, depending on the frequency, of the gain of the low range antenna whose elevation angle is increased from 1 to 1.5 degrees, depending on the frequency,
• reduction of the order of 0.8 to 1 dB, depending on the frequency, of the gain of the high range antenna whose elevation angle is increased by 1 degree,

and it should be noted that, here again, the modification of the pointing angle can be reduced by providing more power to the upper dipoles, that is to say to the dipoles of the lines comprising fewer dipoles than the most low of the network considered.

The present invention is not limited to the examples described, this is how it applies very generally to fixed or rotary antennas, in HF, comprising at least one vertical curtain of dipoles distributed in groups over different levels with fewer dipoles at the higher level than at the lowest level and, between any two of the levels, a number of dipoles in the upper group at most equal to that in the lower group. The number of dipoles in some of the groups can also be odd and even in the others, in which case, without it being an obligation, the symmetry of the curtain can be preserved by shifting the dipoles of the even groups with respect to the dipoles of the odd groups, that is to say by not keeping the arrangement in column between the dipoles of the different levels.

The invention has been described with folded half-wave dipoles, it also applies to cases where the dipoles are of different types and in particular to cases where the dipoles are, for example, whole-wave dipoles.

Claims (6)

1. Decametric-wave antenna comprising a vertical reflector (Rb) and a vertical curtain which are designed to work in a given range of frequencies, the curtain being formed by radiating dipoles (d2, d3, d5-d16; d2, d3, d6, d7, d9-d16) distributed in groups on n different levels, where n is an integer at least equal to 2, characterized in that, for reasons of wind resistance, the number of dipoles of the group (d2, d3) located at the highest level is smaller by at least one unit than the number of dipoles of the group (d13-d16) located at the lowest level and in that, between any two of the groups, the higher group has a number of dipoles at most equal to that of the lower group.
2. Antenna according to Claim 1, characterized in that it comprises a rotating vertical mast (M) and in that the reflector (Rb) and the curtain (d2, d3, d15-d16; d2, d3, d6, d7, d9-d16) are fixedly joined to the mast.
3. Antenna according to Claim 2, characterized in that it comprises another vertical curtain of dipoles (D1-D24; D2, D3, D6, D7, D9-D24), positioned parallel to the reflector (Rb), on the other side of the reflector in relation to the curtain designed to work in the given range of frequencies, fixedly joined to the mast and designed to work in a range of frequencies above the given range.
4. Antenna according to Claim 3, characterized in that the other curtain is a rectangular curtain (D1-D24) with overall dimensions smaller than the dimensions of the curtain designed to work in the given range of frequencies.
5. Antenna according to Claim 3, characterized in that the dipoles of the other curtain (D2, D3, D6, D7, D9-D24) are distributed in groups on m different levels, where m is an integer at least equal to 2, in that the number of dipoles of the group (D2, D3) located at the highest level is smaller by at least one unit than the number of dipoles of the group (D21-D24) located at the lowest level and in that, between any two of the groups, the higher group has a number of dipoles at most equal to that of the lower group.
6. Antenna according to Claim 1, characterized in that the power is distributed over the dipoles in such a way that, between two groups with different numbers of dipoles, it is the dipoles of the group with the smaller number of dipoles that receive the most power.

Images