DE3035600A1 - Optical measurement of models for isometric representation - using directional units sliding vertically on horizontally movable columns - Google Patents

Abstract

An arrangement for optical measurement of models for generation of isometric representations consists of two directional units vertically adjustable on columns and horizontally adjustable as guides. At least one unit swivels in the vertical plane. A measurement system determines the coordinate distances covered. The arrangement measures spatial points accurately and is simply constructed. It provides supplementary measurements without correction computations. The horizontal guides for the columns (8,9) are removable strips (1,2) attached to a table (5) carrying the model being measured. The directional units (10,11) are moved on the column by hand. The measurement system is a digitally indicating distance measurement arrangement (15,30 to 35) with a selectable null position and providing direct readout of the spatial coordinates of points on the model.

Description

Device for the optical measurement of models

The invention relates to a device for the optical measurement of Models according to the preamble of claim 1.

A method for the optical that can be carried out with very simple means Measurement of Konstruk Lions models for the preparation of isometric drawings consists in the use of scales with which the respective model points are three-dimensional measured and used to produce the drawings. This because of the great simplicity and in the absence of other inexpensive facilities today The widely used method is, however, with the error of great inaccuracy tainted because the yardsticks are not held exactly at right angles by hand when measuring and not all fashion points can be achieved with them.

There is therefore a device for eliminating the measurement error in question developed (DE-PS 1 548 278). However, this known device is extraordinary expensive to purchase because it requires a data processing device for storing and processing the respectively measured coordinate points and a This device is downstream of the drawing machine, which is based on the rates won automatically creates the relevant isometric drawing. It stands to reason that a data processing device and an automatic drawing machine require a very substantial investment. Another significant disadvantage this known device is that to determine the pillars and the motor-driven spindles are used on these direction finding units be, which also a not inconsiderable effort in manufacturing and Material costs. Furthermore, the lead screws are coupled with tachometers whose values are passed on to a counter, the zero point is the Spindles or the coordinate zero point cannot be changed when the device is set up fixed, which means that an aligned and measured model is in its position may not be changed during the entire measurement; otherwise is an error correction calculation with regard to all previously obtained measurement data is required.

The object of the invention is to create a device for the optical measurement of models or the like according to the preamble of Claim 1, which allows precise measurement of spatial points and in structure is significantly simplified and subsequent measurements without correction calculations enables.

The solution to this problem is in the characterizing part of claim 1 specified.

The device according to the invention allows precise measurement the relevant spatial points on a construction model or the like, since the apparatus Method is applied. However, the device according to the invention is in contrast in relation to the previously known device constructed much more simply because a data processing device with downstream drawing machine is not required and the device is also otherwise simpler in structure. Accordingly, the material expenditure for Making isometric drawings of models or the like considerably lowered, which in particular the preparation of such drawings of smaller Models is economical. Another advantage is that the model basically does not need to be aligned on its support surface, since that used Distance measuring system makes it possible to locate a desired point or several points to be selected as the zero point on the model because the DeBsysbxwr can be adjusted accordingly. The routes traveled can then be read immediately. Subsequent Measurements on the model can therefore be carried out quickly, easily and without correction calculations. Another advantage is that the device can be used on marking tables, which are usually available anyway, can be screwed on, so that their table surface serves as a horizontal reference plane. The device can be dismantled after use and stored or kept, so that the scribing table without impairment its function can continue to be used. In addition, the device is fast and easy to use, as e.g. those guided on the strip arrangements columns be moved horizontally by hand and are designed to run smoothly for this purpose.

In a further development of the invention, a preferred embodiment is in claim 2 Proposed to achieve the smoothness of the columns. According to claim 3 is a fine adjustment for the columns is also provided; this can also be done for the DF units come into consideration.

The invention is described below with reference to one in the accompanying drawings illustrated embodiment explained in more detail.

They show: FIG. 1 a very simplified schematic representation of the embodiment in perspective, Figure 2 is a partial section along the line II-II in Figure 1 on an enlarged scale, Figure 3 on the same scale a section according to the line 111-111 in Figure 2, Figure 4, the detail IV in Figure 3 in section, FIG. 5 shows a partial plan view according to arrow V in FIG. 1.

Figure 6 and 7 sectional views according to the lines VI-Vlbzw. VII-VII in Figures 5 and 6.

According to Figure 1, the device comprises two strip assemblies 1 and 2, which are detachable to one another at right angles to the side on a conventional scribing table 3 are screwed so that they are in horizontal Direction parallel are apsgeoriented to the table plane, so that they are the X and Z coordinates of a spatial Form X-coordinate system. Each strip arrangement has as a supporting element for Pillars still to be explained at least one strip 4 resp.

5, on which the columns for the purpose of optical measurement of a the model standing on the scribing table (not shown) can be easily moved by hand can. While the rough adjustment of the columns is made by hand, it is closed whose fine adjustment is each a further bar indicated by dash-dotted lines in the figure 6 or 7 releasably attached to the table 3, with each of which a setting wheel works together, as will be explained later.

Each horizontal bar arrangement 1, 2 is a vertical column or column construction 8 and 9, respectively, and each column or the like carries a known optical direction finding unit 10 or 11 to a desired point on the model to be able to target. The DF units can be swiveled in the vertical plane, to reach unfavorable points on the model even better. The pivoting just mentioned the DF units is known and for the purpose of a clear presentation of the embodiment not shown in detail.

Figure 1 further shows that of each column base and of at least one DF unit measuring lines 12, 13 and 14 to a display device 15th guide which parts are part of a distance measuring system known per se, with which the traveled routes are recorded very precisely, e.g. to a hundredth of a millimeter can be, the respective routes on the display panel 16 of the device 15 can be read directly and unencrypted digitally and thus for Preparation of a drawing by hand are available immediately. The device 15 has Furthermore, an operating keyboard 17 to it after alignment of the columns and bearing units to a desired point on the model, e.g. to zero or to one to be able to set a certain numerical value, which is then reduced to zero. The device 15 is preferably operated with mains energy.

In Figures 2 and 3 is the leadership of the columns on their bar arrangements, can be seen here in the example of pillar 9, cenau. The one screwed onto the scribing table 3 load-bearing bar 5 is on its top and bottom narrow sides with each a V-shaped groove 5a, 5b is provided. The column foot 9a has four bearing shoes 18 on, of which two each of the two narrow sides of the bar 5 are opposite and also V-shaped, but are grooved in reverse to the grooves 5a, 5b (Figure 2). This results in a prismatic guide in which a large number of bearing balls 19 is or are arranged so that a smooth and precise shift the column 9 on its strip arrangement 2 is possible.

The strips 4 and 5 of each strip arrangement 1 and 2, respectively, have a length which corresponds essentially to the corresponding side length of the marking table 3, and accordingly the grooves 5a and 5b are correspondingly long. For training the adjustability of the bearing balls 19 in their groove guides of the parts 5 and 18, in order to reduce the size of the game that has possibly become too large, are known constructions used. In Figure 2 it can be seen that this is achieved with screws 20, which are screwed to a crossbar 21, which in turn corresponds to the lower column shoes 18 are in connection.

The already mentioned strips 6 and 7, which are part of the fine adjustment devices can, for example, consist of an angle profile and are made using auxiliary angle pieces 22 attached to the side of the scribing table 3 below the strips 4 and 5. The top Areas of these strips 6, 7 serve as an adjustment track on which an adjustment wheel frictionally unrolls. In Figure 2, the adjustment track is designated with 7a, on which the dial 23 rolls, which may for example consist of a rubber material. That Adjusting wheel 23 is initially rotatably mounted on a lever 24, which in turn is hinged to the column base 9a. As can be seen better from Figure 3, is between the lever 24 and the column foot a torsion spring 25 is provided, which the setting wheel 23 presses against the single track 7a. To adjust the setting wheel 23, what on can best be seen from Figure 4, is the Lever 24 with a Bearing bush 26 welded, in which a small shaft 27 is freely rotatable one end of which has the dial 23 in a form-fitting connection, while the other end has a hand-operated control wheel 28. It will be understood that when the control wheel 28 is rotated, it will move simultaneously the setting wheel 23 rotates and thus rolls on the setting track 7a of the bar 7, whereby the column 9 can be adjusted very finely along the bar 5. Of the Pillar base has an opening 29 of the required size through which the socket 26 extends.

For the fine adjustment of the column 8 is an identical training is provided. Alternatively, however, it is also possible that instead of the flat adjustment path 7a and the setting wheel 23 cooperating with it also have a toothed system can be provided in the form of a rack and a gear, so that a form-fitting There is a connection between the setting track and the setting wheel.

The distance measuring system already mentioned exists in addition to the device 15 and the measuring lines 12, 13 and 14 from two measuring rails 30 and 31, which are also laterally on the scribing table 3 and preferably below the columns 8 and 9 supporting Bars 4 and 5 are arranged. Furthermore, scanning and transmitter units 32 and 33 provided on the foot area of columns 8 and 9 arranged are and cooperate with the measuring rails 30 and 31 in such a way that when moving of the columns corresponding pulses are forwarded to the device 15, to whose Display 16 shows the corresponding distances. At least one of the DF units 10, 11 is also equipped with a scanning and encoder unit 34, which cooperates with a corresponding measuring rail 35 (Figure 5) of the associated column, around the measured distance units in the vertical, i.e. in the direction of the Y coordinate, forward to the device 15. As the distance measuring system is known in its structure no further explanation is required.

The height adjustment of the bearing units will now be briefly explained (Fig. 5). Each bearing unit can be easily moved by hand on its column in the vertical direction 10, 11 is balanced by a counterweight. This is at the top of each column a deflection wheel 36 freely rotatably mounted, over which a rope 37 runs, which on the one hand engages on the associated direction finding unit and on the other hand on a weight 38 which is provided within the hollow main stand 39 of the column 9. the Pillar 9 exists for the purpose of maintaining the vertical management level and achieving a great rigidity, for example, from the already mentioned stand 39 and a parallel arranged for this thinner stand 40, both at their upper end by a connecting piece 41 are attached to each other. The already mentioned pulley is then located above it 36.

To achieve easy movement of the bearing unit 11 without play a roller bearing construction that can be adjusted and readjusted is provided on column 9, which is shown in FIGS. 6 and 7. It consists of one of the housing 50 Bearing unit ~ carriage 44 held by adjusting screws 48 with lock nuts 49 Rolling bearings 46 which are fixed via axle bolts 47 and spacer rings 45.

The roller bearings 46, e.g. one at each end of the car, are on the other hand supported on the stand 39 of the column 9 and are thereon rolling smoothly and without play moveable.

The other column 8, together with its bearing unit 10, is as above described designed to their bearing unit in the same way easily in vertical Adjusting direction and being able to lead. Alternatively, other adjustment mechanisms can also be used can be selected, and additional fine adjustments can also be provided.

As already mentioned and indicated schematically in Figure 1, the DF units in addition to those resulting from the description above Possibilities of movement can still be pivoted in the vertical plane. This is beneficial in the event that a desired model point is not aimed in the horizontal direction can be.

The optical devices 42, 43 of the direction finding units 10, 11 can from simple. Sighting devices exist. To be favoured Sighting devices, on the other side a plate with a sight hole and on the model side a crosshair exhibit. Expensive optical lens systems are therefore not required.

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Claims (5)

Claims Q Device for optically measuring models for the purpose of producing isometric drawings, consisting of two each on a column vertically adjustable guided bearing units, made of horizontal guides for the two accordingly adjustable columns to the bearing units according to the right-angled To be able to move the coordinate system along the coordinates X, Y, Z, with at least a direction finding unit is pivotable in the vertical plane, and from a measuring system for determining the respective traveled coordinate data routes, characterized in that that the horizontal guides for the columns on a model to be measured supporting table (3) horizontally and detachably attachable strip arrangements (1, 2) exist that the columns (E, 9) on the bar arrangements (1 or 2) and the bearing units (10,11) can be moved by hand on the pillars and that the aforementioned, with the two Columns and in operative connection with at least one of the pivotable direction finder units standing measuring system from a digitally displaying distance measuring system (15, 30 to 35) with selectable zero point for immediate reading of the spatial coordinates of the relevant Model point exists 2. Device according to claim 1, characterized in that that each strip arrangement (1, 2) at least one extending over its entire length and each column (8, 9) at least in its foot region engaging the strip arrangement a prism formation (5a, 5b) for receiving: bearing balls provided for adjustment (19) for play-free and smooth mounting of the columns on their bar arrangements having. 3. Apparatus according to claim 1 or 2, characterized in that each strip arrangement (1, 2) an adjustment track (7a) extending over its entire length includes, on which a manually rotatable dial (23) of the columns frictionally or rolls in a form-fitting manner to provide fine adjustment. 4. Device according to at least one of claims 1 to 3, characterized aekennzeich net that each direction finding unit (10, 11) by an adjustable roller bearing device (44 to 49) free of play and easy to move in their column (8 or 9) and with a counterbalance made of a guided inside each column and a rope (37), which runs over a pulley (36) at the Cberende of the columns, with the associated Bearing unit connected counterweight (38) is provided. 5. Device according to at least one of claims 1 to 4, characterized characterized in that the direction finding units (10,11) simple sighting devices from the eye side provided plate with visor thread and crosshairs provided on the mibll side.