DE29720123U1 - Fastening device for a satellite receiving antenna, with an adjusting mechanism for different satellite positions, which enables universal alignment and simplifies operation - Google Patents

Description

Mounting device for a satellite receiving antenna with an adjustment mechanism for different satellite positions which enables a universal alignment and the
Operation made easier.

Description:

In single reception systems for receiving multiple satellites, it is common to make the parabolic antenna rotatable. The declination angle can be partially compensated by a medium elevation angle if the satellite positions are not too far apart.

The declination setting changes the tracking movement of the polar mount from a circular movement (at the equator, receiving system viewed from the side) to
a flat ellipse (the flatter the further the location is from the equator). Since the satellites to be received are up to 50° to the east and west and thus the resulting

Deviation is not very large, this may be partly due to the size and sensitivity
and the elevation angle of the parabolic antenna, if the individual
Satellite positions are not too far apart.

When installing a parabolic antenna, it is particularly important that the antenna mast to which it is to be attached is exactly vertical. Even small deviations lead to significant errors in the tracking by the polar mount.

For manual adjustment, the known construction with the patent number DE 195 33 396 is a suitable option, but it requires a left or right variant, depending on which side the adjustment mechanism is operated from.

Furthermore, the adjustment lever on the side only allows a limited reception range and can affect the swivel range of the parabolic antenna for certain satellite positions and are therefore not accessible.

The invention is therefore based on the task of creating a universally adjustable holding and positioning device with which it is possible for a larger area (e.g. Europe) to align commercially available antennas to all accessible satellite positions by simply swiveling around a fixed axis. The swiveling movement is carried out by hand. It is therefore advantageous if the locking boom is adjustable around the horizontal axis so that it can be fixed within reach and does not restrict the parabolic antenna when swiveling around the horizontal axis.

This task is solved by the features specified in the characterizing part of claim 1. In order to obtain a sufficiently free adjustment range for the outer satellite positions, it is therefore necessary to create a device that allows the locking arm to be aligned and fixed in a favorable position.

The locking arm is mounted directly around a support tube. This can be moved around the axis of the support tube and is secured in a favorable position using adjusting screws. A cylinder is attached to the fastening of the locking arm or connecting bar around the support tube as a rotating extension of the support tube, which can also be pivoted around its vertical axis. An adjusting lever is attached to this cylinder, the locking lug of which rests on the locking blade of the arm. The adjusting mechanism is either integrated in the support tube or is subsequently screwed onto the support tube.
The cylinder is used to attach the satellite dish. The lever attached to the cylinder is used to adjust the satellite positions and is at the same angle as the

Connecting bar to which the locking blade is attached. With a swivel movement, the parabolic antenna is now brought into the actual horizontal satellite positions.

The invention is based on the idea of creating a fastening device

- which moves a parabolic antenna into the various receivable satellite positions by simply turning a lever,

- which simplifies the basic alignment by making the setting position easier to reach and does not limit the swivel range of the parabolic antenna,

- which does not require a right or left variant and is therefore universally applicable.

The invention is explained in more detail below with reference to Figs. 1 and 2.

Fig.1

A support tube 1 is fixed to a wall or similar using appropriate screw connections. A base bracket 7.1 with the connecting bar 7 is attached to the support tube 1, which can be moved around the horizontal axis of the support tube until a favorable position for adjusting the lever 3 is reached. In this position, the base bracket 7.1 is fixed to the connecting bar 7 using clamping screws 7.2. A cylinder 2 is mounted with two fastening screws 2.1 and 2.2 so that it can move around its vertical axis via a threaded pin 2.3, which is firmly screwed into the base bracket 7.1. The lever 3 is attached to the bottom of the cylinder 2. This lever 3 rests on a locking plate 5 with a certain pressure. For this purpose, the locking lug 4 is attached to the lever 3, which engages in the locking positions 6. These locking positions 6 correspond to the horizontal angles of the individual satellite positions, which run around the axis of the cylinder 2. The locking plate 5 is held in the outer positions by the connecting bar 7. The locking plate 5 is connected to the cylinder 1 by the fixed connecting bar 7 and the lever of the cylinder. This creates the counter pressure for the lever 3, which holds it in the individual locking positions 6. The parabolic mirror is screwed onto the cylinder 2.

Fig.2

The base bracket 7.1 is attached to a support tube 1 using screw connections 7.3. The base bracket 7.1 is fixed using clamping screws 7.2 so that the lever 3 can be easily adjusted. The base bracket 7.1 has a laterally fixed web 7, which holds the locking blade 5 with its notches 6 at its end. The cylinder 2 is mounted with two fastening screws 2.1 and 2.2 so that it can move around its vertical axis via a threaded pin 2.3, which is firmly screwed into the base bracket 7.1. The lever 3 is attached to the bottom of the cylinder 2. This lever 3 rests on a locking blade 5 with a certain pressure. For this purpose, the locking lug 4 is attached to the lever 3, which engages in the locking positions 6. These locking points 6 correspond to the horizontal angles of the individual satellite positions, which run around the axis of the cylinder 2. The locking blade 5 is held in the outer positions by the connecting bridge 7. The locking blade 5 is connected to the cylinder 1 by the fixed connecting bridge 7 and the lever of the cylinder. This creates the counter pressure for the lever 3, which holds it in the individual locking points 6. The parabolic mirror is screwed onto the cylinder 2.

Claims (3)

Protection claims: 1. Fastening device for a satellite receiving antenna with an adjustment mechanism 5 for different satellite positions, characterized in that - a base bracket (7.1) that can be rotated around the vertical axis is attached to a support tube (1). The base bracket (7.1) is fixed in a convenient, functional position using the clamping screws (7.2). A connecting bar (7) that is firmly attached to the 10 Base bracket (7.1) is attached, holds at its outer end the locking blade (5) with the locking points (6). A threaded pin (2.3) is screwed in above the base holder (7.1), which also holds a cylinder (2) that can rotate around the vertical axis using the fastening screws (2.1) and (2.2). A lever (3) is attached to the base of the cylinder (2), which, with its locking lug (4) attached to the outer end, 15 rests on the locking plate (5). The inherent tension of the lever (3) causes the The locking lug (4) is sufficiently fixed in the locking points (6). The parabolic antenna is attached to the cylinder (2), - the cylinder (2) is used to adjust the horizontal angle, - the locking blade (5) has several locking points (6) corresponding to the satellite positions to be set. 2. Fastening device according to claim 1, characterized in that the 25 The steering mechanism can be subsequently attached to a support tube using the screw connections (7.3). 3. Fastening device according to claim 1 and 2, characterized in that the locking positions (6) are exchangeable for a locking blade with further locking positions for the 30 Adjusting the satellite reception antenna to additional satellite positions.