CS251585B1 - Supporting centering device for optical predominance of geodetic points - Google Patents

Abstract

This device allows geodetic points to be measured simply and with high accuracy. The supporting centering device consists of a fixing clamp to which a tubular bearing is attached with a rotatably mounted lower cylindrical part of the outer sleeve, which is locked by a first locking screw. The upper part of the outer sleeve is perpendicular to the lower part and an inner sleeve with an extendable arm passes through it, the positions of which are secured by the second, third and fourth locking screws. At one end of the extendable arm, a fine feed screw is axially mounted, and at the other end, a base plate with a hollow fixing screw for fixing the measuring element is rotatably attached by means of a pin. A fifth locking screw passes through the cutout of the base plate. In the extendable arm, there is a thrust screw against the edge of the base plate, which is in contact with the edge by means of a pressure spring, connected with one end to the extendable arm and the other to the base plate. The device can be used for marking out and checking measurements of buildings, measuring steel structures, or surveying and documenting existing buildings.

Description

The invention relates to a support centering device for optical weighing of points, which allows coordinate connection of geodetic points in higher floors of buildings with respect to the starting points at the level of the foundations or the ground level. external terrain.

Until now, the optical surveying through building openings, mechanical projection of the plumb line, or polygonization of stairwells has been used to connect geodetic points on the upper floors of buildings. The first method is only applicable if suitable apertures in the ceiling are available and cannot be used for surveying finished objects or for external rebounding. The second method is used only for lower accuracy and low heights, because the external appearance is adversely affected influences such as wind. The last method is very laborious and poorly accurate due to the unfavorable configuration and shape of the polygon programs, short and steep intentions.

The above-mentioned drawbacks are eliminated by the new support device according to the invention, consisting of a gripping part formed by a fastening clamp and an arm with a base plate for fastening the measuring element. In essence, a tubular bearing is attached to the support portion of the fastening clamp, in which the lower cylindrical portion of the outer sleeve is rotatably mounted, against which the first detent screw is located in the tubular bearing. This lower cylindrical portion of the outer casing merges into an upper portion whose longitudinal axis is perpendicular to the longitudinal axis of the lower cylindrical portion and is provided with second and third locking screws. The arm is formed by an inner housing slidably mounted in the upper portion of the outer housing and is provided with a fourth locking screw at one end. In the inner housing there is a slide-out arm, at one end of which a fine displacement screw is located in its longitudinal axis and at the other end a pivot plate with a hollow fastening screw is fastened by means of a pin for fastening the measuring element. A cutout is formed on the edge of the base plate, outside the pivot, through which the fifth arresting screw is guided vertically and connected to the extension arm by its thread. Perpendicular to the axis of the fifth arresting screw, a thrust screw is placed in the extension arm opposite the edge of the base plate, which is in contact with this edge via a spring. The spring is connected at one end to the extension arm and the other end to the base plate.

An advantage of the centering device for optical weighing of geodetic points according to the invention is that it enables to utilize high precision of the method of optical weighing due to the possibility of attaching a standard tripod with a replaceable pin. Using the device, it is possible to attach points outside the object to be weighed, very easily and quickly and with high connection accuracy without height limitations. The connection of each floor is independent of the starting points. This sliding device by the rigidity of its construction, connected directly to the building object, eliminates disturbing external influences, such as wind. In addition, it enables indirect measurement of the connection distance with higher accuracy, as the standard tripod can be inserted eg with a horizontal or vertical base lath for measuring distances. The support centering device according to the invention is structurally simple, requires only low production costs and is very easy to operate.

An exemplary embodiment of a measuring element carrier for optical weighing of geodetic points is schematically shown in Fig. 1, which is a vertical longitudinal section of the carrier, and Fig. 2, which is a plan view of the carrier.

The carrier consists of a fastening clip 2 / second outer casing, the inner casing 3, the telescopic arm and the base plate £ 2 · Fixing clamp 2 comprises ^a supporting portion, connected with the tube 15 bearing the lower cylindrical portion of the outer sleeve 2 »which actually consists of a sleeve inner housing 2 · the inner casing 2 is mounted telescopic arm 2 · θ telescopic arm 4 by means of the pivot 2 rotatably connected to the base plate 5 for fixing the measuring element 13 by means of a hollow fastening screw 2 · Fine cross feed base plates 2 ³ and allow a push bolt 10 which is located in the withdrawable arm 2 against the edge of the base plates 2 ^{and 3} in this edge in abutment by a compression spring 11. the suspension centering device has a first locking screw 12 in a sleeve bearing 15 which is locked in rotation of the outer sleeve 2, outer sleeve 2 has the second and third arresting screws 16, 16 for coarse arrest longitudinal feed. The extension arm 2 is provided on one side with a screw 2 for fine feed. This screw B is in the longitudinal axis of the extension arm. The inner sleeve 2 has a fourth arresting bolt 17. The fifth arresting bolt 12 extends through a recess 18 ground 18, which is formed outside of the stud 9 in the base plate 5. This fifth arresting bolt 18 is threadedly connected to the extension arm.

The supporting centering device operates by attaching it, for example, to a window sill or other building structure by means of a fastening clamp. A measuring element 13, for example a standard tripod of a geodetic device, is fastened to the base plate 5 by means of a hollow fastening screw 6. After all the locking screws 12, 14, 16 and 17 have been loosened, the center of the hollow fastening screw 4 is guided roughly by rotating and extending the outer sleeve 2, inner sleeve 3 and extension arm 4 approximately into the vertical. Fine fine adjustment to the vertical is done by alternating rotation of the fine feed screw 8 and the thrust screw 10. Finally, the fifth locking screw 12 is tightened.

The functional range of the device is approximately 10 to 60 cm from the outer face of the building and is governed by the length of the extension arm 4.

The device is intended for use in setting out and control measurements of buildings. It can also be used for measurement of steel structures or for surveying and documentation of existing objects.

Claims (1)

Supporting center for optical interconnection of geodetic points, consisting of a gripping part consisting of a fastening clamp and an arm with a base plate for fastening the measuring element, characterized in that a tubular bearing (15) is attached to the supporting part of the fastening clamp (1). a lower cylindrical portion of the outer casing (2) is rotatably mounted, against which a first locking screw (14) is located in the tubular bearing (15) and this lower cylindrical portion of the outer casing (2) passes into an upper portion whose longitudinal axis is perpendicular to the longitudinal the axis of the lower cylindrical portion a is provided with second and third locking screws (7, 16) and the arm is formed by an inner sleeve (3) slidably mounted in the upper part of the outer housing (2) and provided with a fourth locking screw (17) at one end; in this inner housing (3) there is a retractable arm (4), at one end of which is in its longitudinal axis um a fine displacement screw (8) is mounted and at the other end a base plate (5) is rotatably mounted by a pin (9) with a hollow fastening screw (6) for fastening the measuring element (13) to the outside of the base plate (5) outside a notch (18) is formed, through which the fifth arresting screw (12) is guided vertically, which is threadedly connected to the extension arm (4) and is perpendicular to the axis of the fifth arresting screw (12) in the extension arm (4). a pressure screw (10) is placed against the edge of the base plate (5), which is in contact with this edge via a spring (11), one end connected to the extension arm (4) and the other end with the base plate (5).