DE195466C - - Google Patents

Description

IMPERIAL

PATENT OFFICE.

PATENT LETTERING

-M 195466.- CLASS 42 c. GROUP

Field meter. Patented in the German Empire on August 22, 1906.

The subject of the invention is a field theodolite, which with compact design and easy portability a useful measuring instrument for the azimuth and the Represents zenith angles as well as for orientation with reference to the magnetic north pole.

When reconnoitering in the field, the officers must take azimuth and zenith angle measurements perform, for which you need a very precise instrument, which of is easy to carry with a rider. The device described below has the purpose of fulfilling these conditions and, among other things, allowing yourself to orientate exactly via the magnetic north pole or to carry out distance measurements.

The theodolite is shown in detail in the drawings, namely: FIG. 1 is a side view, FIG. 2 is a longitudinal section along AA in FIGS. 3 and 4, FIG. 3 is a horizontal section along BB in FIG. 2, FIG. 4 is a plan view; Figures 5 and 6 show the device on a tripod.

The device consists of the main

after a housing a, which consists of several closely spaced chambers for receiving the visor and orientation elements, and which is traversed by an axis b , about which it can be rotated in a plane perpendicular to that. In order to avoid backlash, is in the axis a in two by a spring χ aneinandergepreßte sprockets s and t is divided toothing 45

cut, which engages a screw c , the axis g of which is perpendicular to the direction of the axis b and is also stored in the housing α.

The toothed half s is rotated by the spring χ with respect to the toothed half f in such a way that the backlash that could occur is avoided. The spring χ is supported for this purpose on a ring ί ¹ which, like the ring gear s, is drawn onto a core b ^l connected to b . The ring s sits loosely on the core, while the ring ί ^{1 is} firmly wedged on by means of a cotter pin i ^2. From this it follows that the thread of the wheel c, which is in engagement with a tooth of the system t, s , is always pressed tightly between the two half-teeth of t and of s , which, as a result of the spring χ, constantly tend towards each other at an angle approach.

If you hold the axis b z. B. by means of an external ball- and-socket tripod head <P and turns the screw c directly or by means of a button h, which sits on a wall of the housing and is firmly connected to a drive i , which engages in a drive 0 wedged on the axis g, This causes a rotation of the housing α about the axis b , and the angle through which it is rotated can be determined by means of the pitch circles e and f , which are located on the axis b and the spindle g of the screw.

Part of the housing α forms a chamber parallel to the spindle g for accommodating

55

60

supply · a declination needle k. This chamber, on the end faces of which a magnifying glass I and a matted glass pane m provided with a mark is attached, serves as the axis of rotation for a strongly magnifying and short prism telescope with a micrometer on the inside and arranged in the chamber η.

From this construction it follows that. that this

ίο telescope u ^{l is} entrained in the rotary movements of the housing α about the axis b , and that it can also perform a rotation in a plane perpendicular to the axis of rotation of the mentioned housing, sliding past a division Jr attached to the housing α, which the The size of its inclination towards the horizon is permitted. ,>. _ii?

The device is supported by two Libel-.

len κ and \. and, completes a bussole r housed in a chamber ν of the housing which is covered with a hinged lid n>.
The theodolite just described can be used to:

i. to measure the horizontal angle between the two planes . in ; objects located at different heights;

2. the horizontal angle between the directional plane of an object and the measure the vertical plane passing through the theodolite and the magnetic north pole;

3. around the above or below the horizon of one of the theodolites and measure angles formed at any point ending line;

4. by using two theodolites and a suitable auxiliary circle to den Measure the distance of a distant point.

After the theodolite on the tripod ρ

(Fig. 5) is placed, the axis b in particular is set vertically by turning the ball joint by setting the air bubble of the circular level η in the middle of the latter. If the handle h is rotated, the telescope u ¹ rotates with the housing a around the vertical axis. It is aimed at a first object and the telescope is tilted about its axis of rotation in order to point it at the object either above or below the horizon. The angle that the axis of the telescope forms with the horizontal can then be seen on the vertical division y .

If the telescope is aimed at an object, the divisions of the upper disk e and the side disk f determine this direction from the zero point of the divisions by a certain number.

The upper disc is z. B. divided into 60 parts of six degrees, each of which has 100 units applies and which with o, 100, 20Ö. . . 5900 are designated. The side panel is in 100 parts divided, which have the designations o, 1, 2 ... 99.

If pointer 1 of the upper disk is between 4200 and 4300, pointer 2 of side disc on 75, the direction of the telescope is determined by the number 4275.

As soon as the lateral disk f is rotated by a graduation, the telescope u ¹ rotates about the axis i, and then the new direction is given by the number 4276 or 4274, depending on the direction of the rotation. Since, moreover, the unit of measurement is the Veooo part of the circle, the arc which a point on the axis of the telescope M ¹ describes to get from the starting point of the directions to the graduation 4275 is ^4S75 / oooo of the circle. The angle of rotation of the telescope was measured in this way. This process can be repeated one after the other for all points located around the vertical axis of the theodolite, the direction can be determined for each of these and the angles between these directional lines can be measured.

Of these points it may be of interest to determine which one is in the direction of the magnetic north pole; the theodolite is then rotated until the magnetic needle k comes into equilibrium with respect to a mark attached to the matt glass pane m. It is then directed to the north and the telescope u ¹ , which is attached 90 ° to the right of the needle axis, is directed to the east.

On the other hand, since the dials e, f with gentle friction on the axes b and g. are movable, the instrument can be marked zero at this moment and all subsequent adjustments of the telescope are then measured from a fixed starting point obtained by orienting the instrument to the magnetic north pole.

If the theodolite is as shown in Fig. 6, its axis of rotation b has become horizontal, the housing a moves in a vertical plane and its rotation as well as that of the telescope are always read on the divided disks e, f. Since the side surface f to the disc which is now above, a spirit level \ which is attached parallel to the axis of the telescope, we have a means, the axis of the telescope horizontally to adjust. Then the pointers 1 and 2 are set to zero.If the telescope u ¹ is tilted upwards or downwards, the angle by which:

it was turned out of the horizontal, read from the graduation y.

Claims (1)

Patent claim: Feldmeßinstrument, characterized in that in a chamber (u) enclosed sighting device ^ ^«1 J (Prism telescope u. The like.) To the (b, c) is fixed to the for accommodating the moving device serving chamber connected, the orientation members (compass needle) containing Chamber (j) is rotatable for the purpose of compact design. For this purpose ι sheet of drawings.