DE4121816A1 - Inclination meter consisting of rectangular triangle and pendulum pointer - has rods attached to pendulum with threaded adjustments wt. and pointer segments - Google Patents

Abstract

The inclination meter consists in its basic form of a rectangular triangle with a scale ring (4) and a gravity pendulum pointer (8) with an angular measurement range of 180 deg. Two coaxial threaded rods (10) are attached to the pendulum at approx. the height of and perpendicular to the axle. Each rod carries an internally threaded self-locking adjustment wt. (12, 13) and its free end carries a pointer segment (14, 15) contactlessly opposing the scale ring. Each pointer segment has an index marker (16, 17) and a vernier (18, 19). The pendulum also has a spirit level. ADVANTAGE - Enables angle of line to be measured w.r.t. another line, i.e. reference line, without knowledge of reference line.

Description

The invention relates to an inclinometer according to the Preamble of claim 1.

DE-GM 86 04 512.1 shows an inclinometer for simple, safe and quick reading of angular degrees, consisting of a triangle with the same shape in its basic form Leg lengths and a pendulum pointer, which is an angular degree Measuring range of 180 ° degrees, the bearing place for the pendulum pointer in the dimensional center of the Baseline opposite hypotenuse is arranged, wherein the center of the bearing point also the center of the radius for the circular arc-shaped opening is the 180 ° angle has, whereby a symmetrical angular degree measurement is possible becomes. Since the pendulum pointer always points to the center of the earth, can hereby the angular deviation of a straight line compared to the Hori zontal or vertical can be measured. This solution fails however, if the slope is, for example, a straight line another line is to be measured.

Accordingly, the invention is based on the object Generic inclinometer in such a way that the Angular position of a straight line in relation to another straight line, the Reference line, can be measured.

This task is with a / m generic inclinometer solved by the characterizing features of claim 1. Here is particularly advantageous that the angular position of the reference device which need not be known.  

Advantageous developments of the invention are in the subclaims specified.

The invention is shown in the drawing and below explained in more detail. Show it

Fig. 1 an inclinometer

Fig. 2 shows the section II according to Fig. 1,

Fig. 3 is an inclinometer with an additional pivot axis,

Fig. 4 is a view IV of Fig. 3,

Fig. 5 is a prism bearing,

Fig. 6 shows the section VI-VI of Fig. 5,

Fig. 7 shows an axle with toe bearing,

Fig. 8 is an axis with ball bearings,

Fig. 9 is an axis of a magnetic storage,

Fig. 10 is a clamping device with a knurled nut,

Fig. 11 shows the view XI of FIG. 10,

Fig. 12 is a clamping device with a V-spring,

Fig. 13 is a clamping device with a rotary wedge,

Fig. 14, the view XIV in Fig. 13,

Fig. 15 shows the section XV-XV of Fig. 14 and

Fig. 16 illustrates an embodiment with an eddy current damping.

Figs. 1 and 2 show an inclinometer 1, in wesentli surfaces consisting of a base body 2 in the form of an angle three-sided polygon from the usual 30 ° -60 ° -90 ° configuration. The outer edges of the base body 2 are stiffened by a type of T-profile. In the interior of the base body there is a circular opening 3 into which a scale ring 4 with a graduation is inserted so as to be rotatable and pivotable. In the lower area of the scale ring 4 , a bearing holder 5 or 6 is attached on both sides thereof, which has at its upper end a bearing bore in alignment with the other bearing holder 5 , 6 with the common axis 7 . A heavy-duty pendulum 8 is pivotally mounted about this axis. The lower end of the pendulum is formed by a cheek 9 , which is provided with a corresponding weight and always shows in the position of use of the inclination meter towards the center of the earth. At the gravity pen del 8 two aligned threaded rods 10 and 11 are attached at the level of the axis 7 , the axis of which intersects the axis 7 perpendicularly. In the leveled state of gravity pendulum 8 , the threaded rods 10 and 11 are exactly horizontal. An adjusting weight 12 , 13 provided with an internal thread is screwed onto each of the threaded rods 10 , 11 . Self-locking is provided so that the nuts can be adjusted precisely by hand, but that an unwanted adjustment of the weights 12 , 13 cannot occur. The free ends of the threaded rods 10 , 11 are each provided with a pointer segment 14 , 15 , which is opposite the scale ring 4 without contact and has an index mark 16 , 17 and a vernier 18 , 19 . On the vertical axis of the gravity pendulum 8 at its upper end is located a vial 20, whereby the vertical position of the pendulum 8 can be checked. In the upper left and lower right quadrant of the coordinate cross formed by the axes AA and BB, a circumferential groove 21 , 22 is incorporated into the surface of the base body 2 lying against the scale ring 4 . A radial thread for a stud screw is arranged in the plane of symmetry of the scale ring 4 at the level of the respective 0-degree mark.

In the bottom right quadrant of the coordinate cross formed by the axes AA and BB is a concentric around the scale ring 4 extending arcuate through opening 23 is arranged. In the wall located between the groove 22 and the breakthrough 23, a gap is incorporated symmetrically to the central plane, which extends over the entire length of the wall. The screws screwed into the radial thread are denoted by 24 and 25 and each have a tip at their outwardly pointing ends. In addition, the stud 25 is integrally formed a cylindrical shaft 26 at the top. The studs 24 , 25 are set so that their tips protrude as deeply as possible into the grooves 21 , 22 , but without touching the material of the base body. The shaft 26 penetrates the aforementioned gap and protrudes as deeply as possible into the Breakthrough 23 without, however, touching the material of the opposite surface. The scale ring 4 is thus rotatably arranged within the plane of the base body 2 in a range of 90 degrees. In the Darge presented position of the base body, its long side b horizon tal is aligned, so that the index marks 16 and 17 due to the pendulum 8 show exactly on the two 0-degree markings of the scale ring 4 . If the scale ring 4 is rotated 90 ° relative to the basic body by 2 , the short side a of the basic body 2 can be placed on an object in order to check its horizontal alignment. It is ensured by the grooves 21 , 22 that the scale ring 4 can only be rotated in the range of 90 ° mentioned. In addition, the scale ring 4 can also be pivoted out about the axis BB defined by the two stud bolts 24 , 25 from the plane of the base body 2 and adjusted parallel to the side c to the zero degree mark. To fix the scale ring 4 with respect to the base body 2 , a device, not shown here, is provided, which acts on the shaft 26 .

FIGS. 3 and 4 show an embodiment of the invention, which consists in principle of the above-mentioned elements 1 to 26, but except for a modified scale ring 4 a two pin screws 24 a and 25 has a an additional pivot ring 27. Here the studs 24 a and 25 a are arranged radially on the axis AA and adjusted again so that their tips protrude into corresponding recesses in the swivel ring 27 , so that the scale ring 4 a is rotatably mounted about the axis AA relative to the swivel ring 27 . The swivel ring 27 in turn also has two studs 28 and 29 provided with tips, whereby the swivel axis BB of the swivel ring 27 is defined relative to the base body 2 . So that the scale ring 4 is fully gimbaled relative to the base body 2 . The area of the base body 2 which surrounds the swivel ring 27 is in principle designed in accordance with FIG. 1: Here, too, a groove 30 and 31 and an arcuate opening 32 are provided in the corresponding quadrant. The wall between the groove 31 and the opening 32 is broken through in the area of the plane of symmetry over the entire length of the wall. As a result, the swivel ring 27 can be rotated through 90 ° degrees within the plane of the base body 2 . With regard to a device to be attached to fixing the swivel ring 27 , the stud 29 is also provided with a cylindrical shaft 33 which projects into the opening 32 .

Different solutions are conceivable for mounting the gravity pendulum 8 . Thus, FIGS. 5 and 6 a delay Prismenla. Here, a prism 34 with a triangular cross section rests in the bearing bores 35 of the bearing holders 5 and 6 . As shown in FIG. 6, the area of the prism 34 lying between the bearing holders 5 and 6 is pulled down slightly. This prevents axial displacement of the prism. The heavy power pendulum 8 is rigidly connected to the prism 43 in a suitable manner.

Fig. 6 shows a top bearing for the gravity pendulum. 8 Here, a shaft 36 provided with tips at its ends is mounted between two axially adjustable hollow cones 37 , 38 . The hollow cone 37 , 38 are rotationally symmetrical in the ends of two adjusting screws 39 , 40 incorporated. To accommodate the adjusting screw ben 39 , 40 , the bearing holders 5 , 6 have two internal threads aligned with one another. The set screws 39 , 40 are set to minimal play between the hollow cones 37 , 38 and the tips and secured in a known manner.

Fig. 8 shows a solution, wherein a shaft 41 of the gravity pendulum 8 is mounted in two roller bearings 42 , 43 . Here, the bearing holders 5 , 6 are each provided with a cap 44 , 45 into which the roller bearings are fitted. In the embodiment shown, two deep groove ball bearings 42 , 43 are provided as roller bearings. This example version of the bearing is very resilient despite low friction.

Fig. 9 shows another embodiment of the bearing for the gravity pendulum 8 , which consists in that a shaft 46 is kept floating by magnetic forces. The shaft 46 itself is designed as a rod-shaped permanent magnet. The ends of the shaft 46 which form the two poles of the magnet have conical taperings of approximately 90 ° degrees. The opposite poles to the shaft 46 are formed by two cap magnets 47 and 48 . These are arranged on the bearing holders 5 , 6 and each have a hollow cone which is adapted to the tapering of the shaft 46 . The cap magnets 47 , 48 are polarized perpendicular to their wall thickness, in such a way that the surface of the hollow cone of one cap magnet 47 , 48 is north-pole magnetic and the surface of the hollow cone of the other cap magnet 47 , 48 is south-pole magnetic. The shaft 46 is enclosed between the Kappenmagne ten such that each end of the shaft 46 is associated with a cap magnet of the same magnetic polarity. As a result, there is a magnetic repulsive force between the respective end of the shaft 46 and the relevant cap magnet, which keeps the shaft 46 in suspension. The shaft 46 due to the conical shape of the cap magnets 47, 48 and of the ends of the shaft 46 is centered in the radial direction, these automatically both in the axial. This solution works practically without friction and therefore enables measurement results of very high accuracy.

FIGS. 10 and 11 show a device for fixing the pivot ring 27, consisting essentially of a sliding stone 49, a knurled nut 50 and a curved spring ticket be 51st A threaded shaft 52 is formed on the sliding block 49 and extends upward in the figure. The sliding block 49 is provided with a transverse bore 53 and has a head 54 below the basic body 2 . The sliding block 49 has the oval shape shown in FIG. 11 and is fitted into the groove 32 . The shaft 33 protrudes as deeply as possible into the transverse bore 53 , but without being clamped when the knurled nut 50 is tightened. If the knurled nut 50 is loosened, the sliding block 49 can be moved within the groove 32 . The shaft 33 is mitgenom men, so that the pivoting ring 27 is rotated within the base body 2 with the axis BB around the center of the pivot ring 27th If a certain position of the swivel ring 27 relative to the base body 2 is reached, the knurled nut 50 is tightened. This now prevents displacement of the sliding block 49 , but at the same time the pivot ring 27 can still be pivoted about the axis BB relative to the surface of the base body 2 .

Fig. 12 shows another embodiment of a Festsetzeinrich processing for the shaft 33. This practically consists of only one part, namely a V-shaped spring 55 , in Chen wesentli formed from a yoke 56 and two legs 57 , 58 , each having a handle 59 and 60 at their free ends. In its lower area in the picture, the V-spring 55 has a transverse bore which again receives the shaft 33 . The V-spring 55 is shown in the clamped state. This results from the fact that the legs 57 , 58 firmly attach to the material of the base body 2 by their own spring force. As a result, the V-spring 55 is fixed with the shaft 33 in the groove, so that the swivel ring 27 cannot be rotated about its axis. To release the clamp, the handles 59 , 60 are pressed by hand in the direction of the arrows 61 , 62 . This releases the clamp and the swivel ring 27 can be rotated.

Figs. 13, 14 and 15 show a further embodiment of a clamping device for the shaft 33. This also consists of only one part, namely the rotating wedge 63 . This has a bore 64 in its center, which receives the shaft 33 . The rotary wedge 63 penetrates the groove 32 and is shown in its solved position. In this position there is a clearance fit between the rotary wedge 63 and the groove 32 . To clamp the rotary wedge 63 is rotated around the shaft 33 . 32 being wider areas in the groove of the rotary contact wedge 63 having an oversized relative to the groove 32nd As a result, the rotary wedge 63 is clamped in the groove 32 and the position of the axis BB is fixed in the plane of the base body 2 . The devices shown in FIGS. 10 to 15 for fixing the swivel ring 27 can also be used correspondingly for the scale ring 4 .

Fig. 16 shows an example embodiment of the invention with an eddy current damping. The representation corresponds practically to the section IV-IV of FIG. 3, but here the vortex current damping is integrated. This arrangement consists, for example, of the aforementioned elements 2 to 23 and also has a permanent magnet 65 which cooperates with the edge of the cheek 9 of the gravity pendulum 8 . This is horseshoe-shaped and arranged between the two bearing brackets 5 and 6 so that its poles engage around the edge of the cheek 9 of the gravity pendulum 8 without contact. In this case, the cheek 9 itself consists of an electrically highly conductive material, for example of aluminum or copper. The permanent magnet 65 is designed as an arcuate profile and is inserted between the bearing holders 5 and 6 . This solution dampens the pendulum movement of the gravity pendulum 8 . The consequence of this is that the annoying oscillation is avoided and the reading position of the gravity pendulum 8 is reached more quickly.

Claims (13)

1. Inclinometer for reading angular degrees, consisting of a triangle in its basic form with a scale and a pendulum pointer, which enables an angular measuring range of 180 ° degrees, characterized in that the scale is designed as a scale ring ( 4 ) and the pendulum pointer a gravity pendulum ( 8 ), which is approximately at the level of the axis ( 7 ) two aligned threaded rods gene ( 10 , 11 ), the axis of which crosses the axis ( 7 ) vertically, with each of the threaded rods ( 10 , 11 ) with an internally threaded actuating weight ( 12 , 13 ) is screwed on in a self-locking manner, the free ends of the threaded rods ( 10 , 11 ) each being provided with a pointer segment ( 14 , 15 ) which lies opposite the scale ring ( 4 ) without contact and an index mark ( 16 , 17 ) and a vernier ( 18 , 19 ) and the gravity pendulum ( 8 ) is also provided with a spirit level ( 20 ). 2. inclinometer according to claim 1, characterized in that the scale ring ( 4 ) within the plane of the base body ( 2 ) is rotatably arranged in a range of approximately 90 ° degrees. 3. inclinometer according to claim 1 or 2, characterized in that the scale ring ( 4 ) about the by the two studs ( 24 , 25 ) defined axis (BB) from the plane of the base body ( 2 ) is pivotally arranged. 4. inclinometer according to one of claims 1 to 3, characterized in that the scale ring ( 4 a) about the axis (AA) relative to the pivot ring ( 27 ) is rotatably mounted, which in turn also has two studs provided with tips ( 28 ) and 29 has, whereby the Schwenkach se (BB) of the swivel ring ( 27 ) relative to the base body ( 2 ) is defined. 5. inclinometer according to one of claims 1 to 4, characterized in that for the storage of the gravity pendulum ( 8 ) a prism bearing is provided which in wesent union from two bearing holders ( 5 , 6 ) with bearing bores ( 35 ) and a triangular in cross section Prism ( 34 ) exists. 6. Inclinometer according to one of claims 1 to 5, characterized in that for supporting the gravity pendulum ( 8 ) a tip bearing is provided such that a shaft provided with tips ( 36 ) at its ends between two axially adjustable hollow cones ( 37 , 38th ) is included. 7. Inclinometer according to one of claims 1 to 6, characterized in that the shaft ( 41 ) of the heavy-duty pendulum ( 8 ) is mounted in two roller bearings ( 42 , 43 ). 8. Inclinometer according to one of claims 1 to 7, characterized in that the shaft ( 46 ) for mounting the gravity pendulum ( 8 ) is formed as a rod-shaped permanent magnet, the tapered pole ends between two polarized to repulsion cap magnets ( 47 , 48 ) is included. 9. Inclinometer according to one of claims 1 to 8, characterized in that for fixing the swivel ring ( 27 ) or the scale ring ( 4 ) by means of a knurled nut ( 50 ) and a molded threaded shaft ( 52 ) clampable sliding block ( 49 ) is provided with a transverse bore ( 53 ) for receiving the shaft ( 33 ). 10. Inclinometer according to one of claims 1 to 9, characterized in that a V-shaped spring ( 55 ) is provided for fixing the swivel ring ( 27 ) or the scale ring ( 4 ), which at the free ends of the legs ( 57 , 58 ) has grips ( 59 , 60 ). 11. Inclinometer according to one of claims 1 to 10, characterized in that a pivot wedge ( 63 ) which can be pivoted about the shaft ( 33 ) is provided for fixing the swivel ring ( 27 ) or the scale ring ( 4 ). 12. Inclinometer according to one of claims 1 to 11, characterized in that a permanent magnet ( 65 ) is provided for eddy current damping, which cooperates with the edge of the cheek ( 9 ) of the gravity pendulum ( 8 ). 13. Inclinometer according to one of claims 1 to 12, characterized in that the permanent magnet ( 65 ) is horseshoe-shaped and engages around the edge of the cheek ( 9 ) of the heavy-duty pendulum ( 8 ) without contact.