CZ220492A3 - decametric wave aerial - Google Patents

Abstract

The invention relates to antennas for decimetric waves including at least one vertical array of dipoles (d2, d3, d5-d16) distributed in groups on various levels. The substantially rectangular form of the dipole array of known antennas is abandoned in favour of a form which is narrower in the top part of the array, by virtue of a reduced number of dipoles in the groups of the top part (d2-d3) by comparison with that in the groups of the bottom part (d5-d8; d9-d12; d13-d16); the reflector (Rb) associated with the array has correspondingly a surface of smaller width in its top part than in its bottom part. The performance thereof is only slightly affected and the structure is considerably lighter in weight. Application, in particular, to rotary antennas. <IMAGE>

Description

-111504 PRAGUE 1, Zitna 2S

ANTENNA FOR DEWETER WAVES!

'i

Technical Field ¹ _ </ - __

The invention relates to an antenna for decameter waves with a vertical reflector and a vertical dipole network for operation at a given frequency scale, which network consists of radiant dipoles divided into groups at n different levels, where n is an integer at least equal to 2. the problem of wind resistance of the aforementioned type.

BACKGROUND OF THE INVENTION

The problem of wind resistance of antennas relates in particular, but not exclusively, to rotating mesh antennas. Therefore, further solutions to the problem will be studied with these antennas. Adaptation of the problem solution for fixed antennas with dipole networks placed between fixed, generally vertical masts will also be discussed. For all these antennas, the dipoles of one and the same network are located substantially in the same network

V V f plane, which allows the use of the dipole net expression *

Antennas for decameter waves with dipole networks are antennas having a height of several tens of meters and a span of several tens of meters. Some have reached and even exceed a height of 100 meters and spans of stb ~ meters. The prior art antennas have vertical rectangular dipole nets regularly spaced in stacked lines and in columns, and the antenna dipole nets have the shape of a rectangle or square. To this net is connected a reflector generally formed by parallel wires and also having the shape of a rectangle or square with dimensions slightly larger than and with the dimensions of the dipole net. Given the dimensions of the antenna for decameter waves, it is difficult and therefore very costly to ensure the proper rigidity of the antenna. If this rigidity is not properly ensured, strong winds cause a significant change in antenna adjustment characteristics. This change can cause or even suppress radiation,

It is an object of the present invention to avoid or at least reduce the above-mentioned drawbacks of the prior art.

SUMMARY OF THE INVENTION

The problem is achieved in particular by having the dipoles in the network having a distribution different from the prior art, that is to say, from a rectangle or a square.

. . The invention solves the problem by providing an antenna for decameter waves with a vertical reflector and a vertical network of dipoles for operation in a given

- a frequency scale, which network consists of radiant dipoles divided into groups at n n different levels, where n is an integer at least equal to 2, the nature of which is that, for reasons of wind resistance, the number of dipoles in the highest level is less than one than the number of dipoles of the group placed on

- the lowest level and between any two groups the upper group has a number of dipoles not more than the number of dipoles of the lower group,

According to a preferred embodiment of the present invention, the antenna comprises a rotatable vertical mast with which the reflector and dipole network are rigidly connected.

According to another preferred embodiment of the present invention, the second vertical network of dipoles located parallel to the reflector on the other side of the reflector relative to the network for operation at a given frequency scale, rigidly connected to the mast and for operation at a frequency scale higher than that scale.

According to another preferred embodiment of the present invention, is;

the second network is a rectangular network of dipoles smaller in size than that of the network for operation at a given frequency scale.

According to another preferred embodiment of the present invention, the dipoles of the second network are divided into groups at m of different levels where m is an integer at least equal to 2, wherein the number of dipoles of the group, u-

WS still standing at the highest level is smaller by at least one than the number of dipoles * groups located at the lowest level, and between the kterými- ^υ koli two groups has an upper group, the number of dipoles at most equal to the number of dipoles of the lower group.

·' her

According to another preferred embodiment of the present invention, the power is divided into dipoles such that between the two groups with different number of dipoles the highest power is obtained by the dipoles of the group with the least number of dipoles.

BRIEF DESCRIPTION OF THE DRAWINGS

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a front elevation and Fig. 2 is a side elevational view of an antenna of the prior art; Fig. 1 is a front elevation of a first embodiment of an antenna according to the present invention; Examples of embodiments of the invention in

Figures 1 and 2 show a double rotating antenna for decameter waves with a height of 82 m and a span of 76 m, comprising, a carrier and two own antennas, namely one antenna for low-scale operation

-1Working in radio bands from 6 to 11 MHz and one high-scale antenna operating in radio bands from 11 to 26 Ι.ΊΗΖ.

The carrier comprises a hollow masonry foundation forming the building L, within which are located the transmitters and the mechanical assembly with the motor, which rotates the ring C mounted on the roof of the building L. The ring C is rigidly connected to the lower end of the vertical mast M to which four horizontal beams Π to P4 located in the same vertical plane. Forty arms B1 to bi4 and EL. to B6 are attached to one of the horizontal beams with their first end. PI to Ρ4 »

The ends of girders .vodorovných P4jsou attached to a rigid bar forming the support as Tl and T2 or Tl as struts and are located in a plane horizontal beams G to P! ₀ two struts 4 as T3 allow possession of a horizontal beam PI horizontal beam P2. The stiffeners such as H1 and H2 connect the horizontal beams P1 to P4 in an oblique direction to the mast M. The mast M has three parts: the first part M1. which is cylindrical and has a circular cross-section: the second one. Part. M2,. . which is formed as a truss, and a third part M3 consisting of two rods positioned at sharp, angle and welded at the upper ends.

The low scale antenna is an HR 4/4 / 0.5 antenna, that is to say that; copper είΐ H of horizontal dipoles, reflector R with four half-wave curved ´ dipoles for one line and four, for one grid of the net and with the height of the first line of the dipoles relative to the ground

half-wavelength of the mean wavelength of the effect of this antenna. The dipole network of the low-scale antenna is thus formed by 1b dipoles d1 to d16 mounted at the free ends 16 of the 40 arms such as arms b1 to b4. These ¹ dipoles are located in one plane vertical and parallel to the vertical plane of the horizontal beams F1 to »4. It should be noted that in Figures 1 and 3 and 4 the various dipoles are indicated by thick lines in their rigid part and thin parallel lines in their wire part. Between the vertical plane of the dipoles d1 to d16 and the vertical plane of the horizontal beams g to p4, or more precisely in the plane of the front surfaces of the horizontal beams p1 to p4, is a third plane parallel to the two first planes. The horizontal wires of this reflector Rb are held by an edge cable C1 which is connected to the top of the mast M and to the free ends of the bars forming supports such as T1 and T2. The horizontal wires of the reflector Rb are provided with vertical distances

-4 cables like Kl, on which horizontal wires are fixed at regular distances. The low-scale antenna reflector Rb is not shown in full in FIG. 1 to show the high-scale antenna located behind the reflector Rb, and in FIG. 2 has been shown schematically with broken lines symbolically showing its position in the drawing.

The high-scale antenna is an HR 4/6 / 0.75 antenna, that is my horizontal dipole network H, a reflector R with four half-wave curved dipoles for one line and six for one column in the network and with the height of the first dipole line with respect to the soil equal to 0.75 wavelength, the mean wavelength of the effect of this antenna. The dipole network of the high-scale antenna consists of 24 dipoles D1 to D24 mounted at the free ends of 24 out of 40 arms such as arms B1 to B6. These dipoles are located in one plane vertical and parallel to the vertical plane of the horizontal beams Ř1 to P £ _{e The} reflector Rh of the high-scale antenna is designed as a vertical horizontal wire net placed in the plane of horizontal backs, H to H between reflector Rb and high scale antennas. The horizontal wires of the reflector Rh are held in a frame formed by the upper horizontal beam P1, the edge cables such as C2 fastened with a small diameter of the door and a support like T4 'fixed at one end to the lower horizontal arm P4. The distances between the horizontal wires of the reflector Rh are maintained by vertical cables such as K2, on which the horizontal wires are fixed at regular distances. Similarly to the reflector Rh, the reflector Rh is not fully illustrated in FIG. 1 so that the high-scale antenna located behind it is visible, and in FIG. 2 has been shown schematically by a dashed line showing symbolically its position in the drawing.

Due to the geometric dimensions of the antenna according to FIGS. 1 and 2 and the surfaces formed by both dipole networks and both reflectors, the wind generates considerable forces in the antenna structure to be transmitted towards the soil. Dynamic pressure. The wind increases with <height, that is, the predominant forces are exerted by the wind in the high regions of the antenna design and the effect is further amplified by the fact that the lever arm relative to the ground is probably the longest in the high regions. In addition, the high portions of the antenna increase the vibration periods of the system very strongly, because the larger the period, the more the dynamic wind effect is amplified. This has led to considerations of reshaping the antenna of FIGS. 1 and 2 in its upper regions.

Figs. 3 and 4 show two examples of an antenna embodiment of the present invention by modifying the top of the antenna shown in Fig. 1a. These modifications have caused the antenna cost to be slightly lower since the mast M and the building L are less stressed and thus cheaper to implement.

The antenna of Fig. 3 corresponds to the antenna of Figs. 1 and 2, in which the dipoles d1 and d4 of the low-scale antenna were omitted, resulting in a reduction of the length of the upper horizontal beam Pl'asi to 2/3 of the original length. replaced by two inclined arms like J, which are supported by the mast and support the horizontal beam P1, the surface of the low-scale reflector Rb has been substantially reduced by omitting its upper corners, retaining the reflector wires Rb in the same way, at the ends of the horizontal beams P1 and P2 _{t, the} surface of the reflector Rh for the 'high scale' has been somewhat reduced due to a change in its fastening system at its two upper corners, namely elongation of the edge cables like C2 upwards Pl.

Comparison of the antenna of Fig. 3 with the antenna of Figs. 1 and 2 gives the following results:

- no change in the behavior of the high-scale antenna.

reducing the hardness for low; scale: of the order of 0, -5 dB-- - ~ —.....

location increased by 0.8 degrees for a low-scale antenna, which can be reduced by delivering more power to the upper dipoles.

- a reduction in the weight of the components above Building L by about 15% «.

The antenna of FIG. 4 corresponds to that of FIGS. 1 and 2 in which the dipoles d1.d4.d5.d8 of the low scale antenna and the dipoles D1.D4.D5.R8 of the high scale antenna have been omitted. This made it possible to reduce the length of the horizontal beams P1 and P2 to about 2/3 of the original length and to reduce the surfaces of the reflectors Rb and Rh by omitting their upper corners. It should be noted that this omission is more significant than the antenna of FIG.

Comparison of the antenna of FIG. 4 with that of FIGS. 1 and 2 gives the following results:.

- Low-gain antenna gain by 1 to 1.5 dB depending on frequency, and an increase in location angle by 1 to 1.5 degrees depending on frequency

reducing the gain of the high-scale antenna by 0.8 to 1 dB depending on the frequency and increasing the location angle by 1 degree depending on the frequency.

It should also be noted that the change in the locating angle can be reduced by supplying more power to the upper dipoles, i.e. to the dipoles belonging to lines having a lower number of dipoles than the lowest link of the respective dipole network.

The present invention is not limited to the examples described. It can be used in a very general way for fixed or rotating decamer wave antennas containing at least one vertical dipole network divided into groups at different levels with fewer dipoles at the highest level than at the lowest level _o Between any two levels the number of dipoles in the upper group is at most / f equal to the number of dipoles in the lower group. Thus, the number of dipoles may be odd in some groups and even in others. In this case, without necessity, the symmetry of the network can be maintained by deflecting the dipoles of the even-numbered dipoles relative to the odd-numbered dipoles of the dipole groups, i.e. the column arrangement between the dipoles of different levels is not maintained.

The invention has been described with half-guilty and curved dipoles, but it can also be used with dipoles of different types, and especially in cases where the dipoles are, for example, whole-wave dipoles.

-f>. $ • í «Λ $

Claims (6)

TIGJ4-PHAHALŽRR25 -7- / / WJW 7 /.^// PATENT 'CLAIMS An antenna, for decameter waves with a vertical reflector and a vertical dipole network for operation at a given frequency scale, which network consists of radiant dipoles divided into groups at n different levels, where n is an integer at least equal to 2, characterized in that z For reasons of wind resistance, the number of dipoles (d2, d5) of the n-wall group at the highest level is at least one less than the number of dipoles (dl3-dl) of the group located at the lowest level. lower group dipoles. Antenna according to claim 1, characterized in that it comprises a rotatable φ vertical mast (M) with which the reflector (Rb) and the dipole network (d2, d3, dl5-dl6; d2, d3, d6, d7, d9) are connected. -d16) rigidly connected. The third antenna according to claim 2, characterized in that it comprises a second upright web dipoles (D24íD2 Dl, D3, ^D6:, D7, D9, D24) positioned parallel to the reflector (Rb), 'on the other side reflector "(b) with respect ,, to the network. for operation at a given frequency scale, rigidly connected. with mast (Μ) and for operation-on the scale-frequencies higher than given. scale. in * Antenna according to claim 3, characterized in that the second network is a rectangular and a plurality of dipoles (D1-D24) with dimensions smaller than the network dimensions for operation at a given frequency scale. ~ Antenna according to claim 3, characterized in that the dipoles (D2, D3, D6-, jD7, D9-D24) of the second network are divided into groups at m different levels, where m is an integer at least equal to 2, wherein the number of dipoles (D2, D3) of the group placed at the highest level is less by at least one than the number of dipoles (D21-D24) of the group placed at the lowest level, and wherein between any two groups the upper group has a number of dipoles at most equal to the number of dipoles of the lower group. Antenna according to claim 1, characterized in that the power is divided into dipoles so that between two groups with different numbers of dipoles φ f the highest power receives the dipoles of the group with the least number of dipoles. octC (γ-7), FIGd FIG2 U_ FIG.4 AND*