SE429374B - FESTE - Google Patents

Description

Sšë flfi ššd-ë 2 The stand is placed on a surface and after a companies rough setting, a series of small adjustments are made to the azimuth and elevation angles, which adjustments affect the others, in order to achieve a satisfactory focus.

Another known mount for satellite dishes is ~ grasps an angled mast on which the antenna is fixed mounted. The mast tube is mounted vertically and the antenna is rotated so that it points in the azimuth direction towards the satellite. The the angled portion now has such a predetermined slope re- lative vertical that the antenna is assumed to point approximately in the correct direction of elevation. A device for setting , ning of the direction of elevation exists.

The first of the above-mentioned known brackets is suitable only for mounting on rooftops. The bracket cannot be mounted on one vertical wall, a chimney or on an existing mast pipe.

The second of the above brackets is mounted in the same way as conventional mast pipes and can thus be mounted on t. ~ x. a house gable. A disadvantage of this bracket, however, is that The angle of inclination is determined by the angularly bent mast tube and that thus pipes with different elevation angles in principle must manufactured for localities located at different latitudes.

The present invention aims to provide a bracket of the type initially described, which avoids the limitations of the known brackets, are easy to install in buildings and building details, such as gables, chimneys, masts, mast pipe foundations, etc. and which are adjustable in azimuth and the elevation directions, the latter settings take place largely independently of each other. Those for the invention The distinctive features are set out in the appended claims.

By setting the azimuth and elevation direction ~ They can be made almost completely independent of each other it is possible to quickly make an accurate targeting of snozasà-4 meant. Since the element is roughly set, it is possible to perform the alignment of the element towards the fixed point with only an azimuth angle fine adjustment and an elevation angle setting. The order in which the last two mentioned directions are, is important. If you start with the azimuth angle fine adjustment and then perform the elevation the angle setting, no more settings need be taken without the element now points right towards the fixed point. If one, on the other hand, starts with the elevation angle setting ocn then perform the azimuth angle fine adjustment, normally one must additional readjustment is made of the elevation angle before the element points right towards the fixed point.

During the azimuth angle fine adjustment and during the elevation The setting means are the setting means by means of which the settings are executed independently, ie. the set the position is not disturbed e.g. due to a gust of wind or on due to the installer releasing the antenna with both hands or the antenna mount and instead e.g. calibrates one signal strength instrument with the aid of the antenna alignment implemented. The entire installation and setting process thereby becoming fast, easy and accurate.

The invention will be described in more detail below in connection to the accompanying drawings, in which Figure 1 is a perspective view shows a bracket according to the invention, figures 2-4 in the side view shows different assemblies of the bracket according to the invention, Figure 5 in plan view from above, on an enlarged scale and in different proportions relative to Figure 1 show a part of the bracket single beam, figure 6 in plan view from above and on the same scale as figure 5 shows a plate rotatable around the beam in figure 5, Figure 7 is a side view along the line VII-VII in Figure 3, Figure 8 in perspective view shows a detail of the azimuth angle fine adjustment seen obliquely from below, figure 9 in perspective view shows same detail as figure 8 but seen obliquely from above mounted pivot pin, figure 10 in perspective view shows the angle adjusting means, figure ll in plan sectional view 8ÜG28584 + shows a detail of the elevation angle adjusting means in Fig. 10, Fig. 12 is a diagram showing the path along it which an imaginary central beam from the center of the element touches in the room at the setting towards the fixed point if the the muting angle fine adjustment is accompanied by the elevation angle and Figure 13 is a graph showing the trajectory of the with which an imaginary central ray from the center of the element moves in the room at the setting towards the fixed point about you start by setting the elevation angle.

Figure 1 shows an element in the form of a satellite dish 1 with a microwave head 2. The antenna is connected to the bracket with help of an annular holder 3. In the illustrated embodiment of The invention is the bracket mounted on a substantially vertical mast pipe 4. The bracket comprises a shaft, which in this embodiment form of the invention is a sleeve 5, which is threaded over mast pipe 4. A stop not shown, e.g. a piece of pipe can be anchored in the mast 4 to support the sleeve on the mast until the sleeve is locked to the mast tube 4 using the following described locking means. Figure 2 shows how a bracket, which is mounted on a mast pipe according to the invention, mounted on the roof of a house. At A is the mast pipe 4 fixedly mounted on a stand, which is screwed on on the roof. At B, the mast pipe goes through the roof and is anchored at a truss. At C, the mast pipe 4 passes through the roof and is anchored to a rafters. In cases B and C, the mast pipe in a conventional manner sealed to the roof with the aid of a s.k. takstos (not shown). In Fig. 2, the shaft is in the form of a sleeve, which is threaded on the mast pipe in accordance with Fig. 1. I Figure 3 shows the bracket attached to a chimney with help of straps, which are fastened around the chimney. In each band sit- a conventional holder. The shaft of the bracket is attached here at the holder by means of conventional U-bolts D. Through to loosen these U-bolts D, the azimuth direction of the bracket can be is adjusted, after which the U-bolts are tightened. The shaft needs in this embodiment may not necessarily be a sleeve, but may e.g.

^ H * f fl ß H »-_ Vvnwuk ' be a massive rod. Figure 4 shows how the bracket can be set fixed to a wall using conventional brackets and U ~ bultar. By loosening the U-bolts can coarse alignment in the azimuth direction.

Figure 1 shows the other main details in the bracket according to the invention. ningen. A beam 6 is fixedly attached to, e.g. {welded on, a holder 7 which in turn is fixedly attached to, e.g. sweaty sat on, the sleeve 5. The longitudinal axis of the beam is substantially angular. straight against the longitudinal axis of the sleeve. As shown in Figure 5, the sleeve is 5 placed asymmetrically along the beam to make room for rovågshuvudet 2 (cf. fig. 1). In case the antenna is missing microwave head, the sleeve is suitably arranged symmetrically, i.e. in the middle of the beam 6. By turning the sleeve 5 around the mast pipe 4 roughly align the antenna in the azimuth direction. Rough setting- one thus occurs over a range from 0-3600. The sleeve is locked in the coarse-set azimuth angle (which is calculated in proportion to a fixed direction, e.g. north) by means of two locking screws 8 and 9 placed at the top and bottom of the sleeve, respectively. Where- je locking screw is threaded in each nut, which is welded on the sleeve surface of the sleeve and which passes through an opening not shown in the wall of the sleeve, which opening is opposite the nut.

A plate 10, e.g. L-profile beam, is articulated supported by ken 6 at a pivot 11 (cf. fig. 6) in the form of a wide plate welded bolt, which extends upwards through a counter- standing opening 12 (fig. 5) in the beam 6. The plate 10 hangs thus in the beam 6 by means of a nut (not shown) and is rotatable relative to the beam. At each end of the plate 10 is a nut 13 and 14, respectively (Fig. 6) welded to the nut longitudinal axes lying in the horizontal plane. Nuts pla- is such that an imaginary line 15, which coincides with the longitudinal axes of the nuts intersect the longitudinal axis of the pivot 11, i.e. rotation center for the azimuth angle fine adjustment. each the nut is intended to have its pivot pin threaded therein 16.

The longitudinal axes of the pivot pins are thus in the interface between 539532338-11 plate shelter and beam 6- Two opposite mounting brackets 17 (Fig. 1 and Fig. 9) are fixedly connected, e.g. screwed if holder and are rotatably mounted on the pivot pins 16, each of which through the satellite dish is thus rotatably connected to bracket and can rotate about the shaft 15 for adjusting elevation angle and, as mentioned above, around the essential vertical pivot pin ll for fine adjustment of the azimuth the angle. The relative rotational movement between the plate and the beam is provided with an azimuth angle fine adjustment means 18 in the form of an adjusting screw 19 (cf. Figs. 8 and 9), extending between the plate and the beam and which are connected to the plate 10 and to the beam 6 in each of the pin 20 and 21, respectively. The guide pin 21 is articulated in an enlarged portion 22 on the beam 6 and the adjusting screw is threaded in an opening (not shown), which extends radially across the guide pin 21. The front tip of the adjusting The screw 19 has no thread but is smooth and extends smoothly. through a similarly radial, continuous, not shown opening in the guide pin 20. The front tip is rotatable in this opening but is anchored to axial movement relative to the pivot 20 by means of a tilt joint (not shown) or by means on either side of this applied lock washers, scissor pins or the like (not shown). The guide pin 20 is rotatably arranged in a bore in a tongue 23 projecting from the nut 13. In the setting the opposite end of the screw is a flat adjustment knob 24. Off The above shows that the azimuth angle fine adjustment device is self-locking (self-inhibiting).

Instead of the shown means 19-24 for providing relative movement between the sheet 6 and the plate 10 can e.g. one at both ends articulated fastening screw is used. Even one rotatable cam disc, e.g. eccentrics can be used to achieve come this movement, whereby in the latter case the beam and the plate are biased towards each other, e.g. using a coil spring. 8OÛ2838- fi 7 The fine-tuned azimuth angle is locked by means of two bolt joints (Figs. 5 and 6) arranged on each side of the rotating I tappen ll. Each bolted joint passes through an opening 25 in the plate. 10 and a sector-shaped opening 26 in the beam 6. Sectors the center of the nose passes through the pivot pin ll. Of Figures 8 and 9 it can be seen that each bolt joint comprises a bolt 27 and a lock nut 28. During the azimuth fine adjustment, the nuts are loosened said and after finishing the fine tuning, they are tightened, whereby the upper surface of the plate 10 is locked against the lower surface of the beam 6.

An elevation angle adjuster 29 (Figs. 1 and 10) extends between the antenna 1 and the sleeve 5 and is articulated associated with each of these entities; at the sleeve by means of a hinge pin 30 and at the antenna by means of a ball joint 31. the adjusting means is embodied in the form of an adjusting screw 32 which is threaded in the pivot pin 30 rotatable in a bearing sleeve 33.

The bearing sleeve 33 is rigidly connected, e.g. welded, in the sleeve 5.

The guide pin 30, shown in detail in Fig. 11, consists of a threaded one pin with an extended head 34. A bore 35 runs transversely through the extended head 34 and in this bore the screw thread 32. Opposite the bore 35 are elongate through-openings 36 received in the mantle surface of the bearing sleeve 33 so that the adjusting screw is rotatable a distance around the longitudinal axis of the ger sleeve. The guide pin 30 can be locked against rotation relatively the bearing sleeve 33 by means of a nut 37, which is threaded ad at the end of the pivot pin 30.

The ball joint 31 (Fig. 10) comprises a ball 38, which is fixedly tied, for example, screwed, into the front tip of the adjusting The ball 38 is clamped between two plates 39, 40, each provided with conical or spherical depressions. in which the ball rests. The plate 40 which may be an integral integrated part of the satellite dish is attached to the holder 3, for example by screwing. The plate 40 can also be an integrated one part of the holder 3. By means of a locking screw 41, which passes through the tan 39 with winch and threaded in the lower plate only 40, the position of the ball 38 can be locked between the plates 39, 40.

When setting the elevation angle, first loosen the nut 37 and then loosen the ball joint by means of the locking screw 41.

The adjusting screw 32 is then rotated by turning a handle Ä2 attached to the end until maximum signal strength obtained from the antenna. Then the ball joint 31 and last are locked lock the pivot pin with the nut 37.

Only axial forces act on the ball joint, ie. forces rich in the axial direction of the adjusting screw. No lateral forces act on the ball joint, because all such forces occupied by the transverse beam 6. The ball joint is necessary for to record the motion around the axis AZf, described below (and the angle change of the adjusting screw.

Instead of the elevation angle member 29 shown above, the can use a water screw, which is hingedly attached to the antenna respectively the shaft.

As a length-changing element corresponding to the setting screw 32, you can also use two opposite ones rods, tubes, etc. provided with through holes, which are inserted opposite each other, after which a locking member, e.g. sprint, bult- storage etc. is introduced through the two opposite each other the holes and fixes the set elevation direction.

From the above description it is clear that coarse the position of the azimuth angle takes place around an axis, denoted with AZg in Figure 1, which coincides with the longitudinal axis of the sleeve 5, while the fine-tuning of the azimuth angle takes place around another axis, denoted by Azf in Figure 1, which passes through the pivot pen ll and ball joint 31. By the shaft 15, around which the the unit is rotated at the setting of the elevation angle, through the pivot pin 11 and by the shaft 15 lying in the interface between the beam 10 and the plate 6, an imaginary central comes beam emanating from the antenna, that when operating the the vation setting means point to a point in space as then moves along a vertical line. This means that the setting 8 {ï (u ' 'vvuiçvíl 1-51 9 the azimuth and elevation directions are to a large extent independent of each other. This is clearly illustrated in the bands with Figures 12 and 13, showing the path envisaged central beam from the antenna travels in the room from a point X, which corresponds to the point where you end up when the tin is roughly set in the azimuth and elevation directions, to a point 0, which corresponds to the fixed point in the room (= space) to which the antenna is to be directed. Azimuth angle the fine adjusting means has in the initial position the beam 6 arranged parallel to the plate 10, i.e. the angle of rotation between lan these devices are zero. When rotating the plate 10, lative beam 6, i.e. at the azimuth angle fine adjustment the imaginary central ray it with dashed lines mar- shaped satellite dish in the room.

According to Figure 12, an azimuth angle fine adjustment is first made from point X until the antenna points directly below the fixed one point 0 (which is indicated by the maximum signal strength measured on a field strength meter), the central one the beam follows the path marked by the arrow 43. Thereafter, the elevation angle setting is teased from the tip of the arrow 43 up towards the fixed point 0, the central beam follows the path marked by the arrow 44 (when the maximum signal strength is obtained, point O has been found). Should now shoulder or the sleeve 5 must not be arranged absolutely vertically but inclined an angle (towards the vertical, the central beam would at the latter setting moves along the dashed line the line in Figure 12, which dashed line likewise forms angle xi to the vertical (marked with a dotted line).

If, when aligning the antenna from point X to point ten 0 instead starts with the elevation angle setting from point X up to the height of point 0, the central the beam describes the path marked by the arrow 45 and then makes the azimuth angle fine adjustment, whereby the central beam follows the path marked by the arrow 46, an ele- angle of error A, which must be corrected with a renewed one

Claims (9)

10 'elevation angle adjustment, from the tip of the arrow 46 to the point 0, the central beam following the path marked by the lilac 47. Thus, in this case, apart from the coarse setting of the elevation and azimuth angles, three settings are required against only two if one proceeds in the manner illustrated in Figure 12. The above-described embodiment of the invention can be modified and varied in many ways within the scope of the basic idea of the invention. l. Bracket for an element (l), which is to be given a fixed alignment. The bracket is intended to be attached to a building, building detail, foundation, etc. The characteristic of the bracket is a shaft (5), which is arranged partly rotatable in and partly substantially vertical to a holder (4), which in turn is mounted at the building or equivalent, thereby forming an azimuth angle coarse adjusting means. An azimuth angle fine adjustment means (18) comprises on the one hand a plate (10) which is rotatably mounted on a transverse beam (6) fixedly mounted on the shaft (5) and which rotates around one between the beam and the plate. arranged pivot pin (ll) and partly a member (l9-24) fi is pivoting of the plate relative to the beam around the pivot pin. The element (1) is rotatably mounted to the plate by means of two pivot pins (16), the longitudinal axes of which coincide with the longitudinal axis of the x-cut pin (11). A longitudinally variable elevation angle adjusting means (29), which in a manner known per se extends between a point on the element (II) and one on the shaft (5), is hingedly attached to each of these points. The articulation point at the element allows rotation of the element in the azimuth and elevation directions, whereby when operating the azimuth angle adjustment means (6, 10, ll) the element (l) rotates about an imaginary axis (Azf) passing through the pivot (ll) and elevation angle adjuster joint- CD CD CD 5) LJ QQ šü I -P * ll point at the element. Bracket according to claim 1, in which the longitudinal axes of the pivot pins lie in the interface between the plate (10) and the beam (6). Bracket according to claim 1 or 2, in which the shaft is a sleeve (5). Bracket according to claim 1, in which the means (19-24) in the azimuth angle fine adjustment means (18) comprise a length-changing means, e.g. a fine-tuning screw (19), which extends between the plate (10) and the beam (6) and which is hingedly fixed both in the plate and in the beam. Bracket according to claim 1, in which the elevation angle adjusting means comprises an adjusting screw (32). Bracket according to claim 1, in which a locking device for locking the bracket with elements attached thereto in the fine-tuned azimuth position, in 'nefaïtar' two mmstable fi æ bolt joints (27, 28), each extending between the plate and the beam through each sector-shaped , through opening (26), which sector has the pivot pin (II) as its center. Fastener according to claim 3, in which the adjusting screw (32) of the elevation angle adjusting member is hingedly supported on the sleeve by means of a hinge pin (30) or a ball joint. Bracket according to claim 7, in which the adjusting screw (32) at its end facing the antenna is fixedly connected to a ball joint (31) intended to be fixed in the element at said point. Bracket according to claim 1 or 3, in which the azimuth angle groove adjusting means comprises at least one locking screw (8,9) extending through the sleeve wall or at least one U-bolt (D) which releasably clamps the shaft against the holder.