DE300752C - - Google Patents

Description

When measuring stereograms, Thompson and Orel used the comparator cranks to move the drawing rulers, which are rotated by hand. This facility works as long as only a few Rulers have to be moved and we take the stereo normal case of the simplest terrain recording have in front of us. The problem gives way

to the map order from / this by terrain difficulties nich _f i often given case, so must in order to meet the mathematical conditions of the respective position of the optical axes, such as z. B. in topographical recordings from the aircraft to meet, several rulers are moved, in such a way that z. B. a second ruler only comes into its correct position through one or more first rulers that have already been moved.

In solving this problem, the simple crank transmission in stitches and can no longer be used, as the ruler to be moved secondarily is only indirect mechanical dependency on the slide crank.

In the patent 285716 »Device for the mechanical application of comparator measurements by means of guide marks and automatic rulers «, a device is already provided to facilitate the movement of those who are drawing Provides rulers through electrical currents. In this patent the rulers are on placed contact-making carriage devices. It roll off the comparator drums Tapes that lead contact marks and bring them into the position, which the mathematical calculations is equivalent to. By pushing the contact devices on the carriage the guide marks pinned on the tapes are closed or the streams opened. If these institutions are pursued further, the idea that they used earlier is obvious Manual spindle rotation and fine adjustment achieved by the to accomplish electrical power. So now the automatic stop or continue turning the spindle is done within sufficient accuracy, the following device is which is the subject of the additional patent.

In Fig. Ι the task to be solved is schematic shown. The ruler 5-6 will revolve around pivot point 2, which is at a distance 2-7 equals the simple or a multiple of Focal length of the lens protrudes from the edge of the comparator 5-7, move after the Slide has been moved from its normal position 1-7 to 4-5. Be'i the earlier one Apparatus was used for this, the drum 8, which directly on the carriage

of the comparator worked, shifted it by the distance X = 1-4 and thereby brought the ruler 3-7 into position 5-6.

The invention now relates to the next device, which is shown schematically in FIG is shown.

The ruler 2-1 r, which is drawn in its zero position, rotates around the pivot 2. At a distance a = ■ - 2-12 = f or .ίο η ■ f , the X or Y guide rail is attached perpendicular to this, and it contains the screw spindle 3-6, which has the Z mark 12 (40 in Fig. 5) either by unwinding tapes from the X-drum of the comparator or by

»5 the known transmission devices to the one read under the microscope X values shifts corresponding point.

FIG. 9 shows the transmission device, starting from the crank of the comparator. The shaft 8 converts the linear path of the slide into the rotary movement. The gear wheel 78 meshes with the bevel gear 79, which rotates about the axis So, and thereby transmits this movement to the bevel gear 81, on which the contact-making jaw 40 slides back and forth. The ratio of the two diameters of the wheels. 78 and 81 is due to the distance a = 2-12 in FIG.

As a result of the rotation of the comparator crank, the contact device now comes to rest from its zero position (x = y = 0) after position 15. The line 12-15 now corresponds to the selected multiple of the trigonometric tangent of the angle of view on the plate, because

By moving the contact 12 (Fig. 2), the switched off in its zero position Circuit closed. The consequence of this is that the screw spindle 13-14, which the nut joint (9) for the primarily to be moved ruler 15-9 (= 2-11 in zero position) for the secondary ruler 9-10 leads, rotates until through the contact ball at 15 the power switches off again.

This solves two tasks. The one given on the photographic plate

Angle of view tg a _n = ~ j ~ is in the linear dimension 15-12 by developing the tangent values

tg a _n -

η ■ Ct _n

converted. Also have

we project this distance 12-15. on any third level, the vertical panel track of which represents the spindle 13-14 the distance 9-11 (Fig. 2) is determined.

Conversely, we can also use the lever arm 2-11 any distance on the screw spindle run and slide by direct connection with the comparator (Fig. 3, 24-25) read off the position of the microscope axis or set an image point.

Serve to represent the micrometric run achieved by electrical currents 3, which shows the path of the current, the on and off switching and blocking devices demonstrate. Furthermore, FIGS. 4 and 5 contain two cross-sectional views of the. Lever contact devices.

The feeler lever contact should be discussed first.

In Fig. 3 and 4 the same is shown in plan. When the comparator slide crank is rotated, a jaw 40, which carries the adjustable contact pin 15, runs on the thread of the screw spindle. Fig. 10 shows the cross section through the jaw 40, which completely fills the interior of the tube for the safety of the guide. Depending on the focal length ratio, the transmission ratio in FIG. 9 is regulated here, because the coordinate sizes X and Y must develop on the same scale on the spindle of the guide rail.

A guide jaw slides in the dovetail-like groove of the direction ruler 2-11 (Fig. 5) 16. A spring housing 23 is firmly connected to the latter.

In Fig. 4 you can see the circular scale 26, which is set up for three fields for the positive current field 49, for the negative current field 59 and for the very narrowly delimited current-free field 34 (21-22 drawn needle position).

The guide jaw 16 (FIG. 5) slides up and down during movement in the slots 2-11 away. At the same time, as shown in FIG. 5, through a jaw guide 77 that is connected to it Spring housing 23 is guided in the slot axis Fig. 4 "of the guide rule 3-6. The contact pin 19, which is pressed by the spring 18 (Figs. 4 and 5) has an eyelet at 20 in which engages a dial pointer 21-22 rotatable about the axis 21. Depending on the counter pressure, which the contact pin 15 is able to exert on the spring 18 is this sensing lever come to stand in the positive 49, negative 59 or current-free field 34. .

To make the contact point as independent as possible from. the variations of the range of the To get a current-closing spark, the direct pressure contact 15-19 would be used as a current short avoided and a feeler lever contact with arms that are as unequal as possible was used in its place.

The pressure fluctuations that cause only imperceptible adjustment errors in the direction 15-19 would immediately come into play through this ratio on the circular scale, and it can thus the current-free field 34, the

actual axis position of the direction rulers can be limited with increased accuracy.

Thus a fluctuation in this position of the pointer within the permissible error limit is avoided, another spring housing 48 is attached in the axis of the pointer, the contains an adjustable counter pin with a plate-shaped surface end 25 under spring pressure. As well as the spring 18 a higher pressure than

to how by adjusting the counter pins 25 and 15 is provided, exerts on the needle, snaps the same out of its zero position, in order to reduce the counterpressure to the same level by moving the rule forwards or backwards Bring greatness.

In order to facilitate the transition into a current field, electrical engineering has a Set of tools created. First and foremost are the starting resistors shown here To name 73.

In Fig. 3 and 4 are the dependent on the position of the pointer movement processes, the forward and backward movement and the rest position of the direction ruler explained. It let the jaw 40 migrate in the direction 3-6. The spring 18 can its compressive force on the exercise shorter lever arm of the pointer 21-22 in the eyelet 20, the contact of the contact balls 15, 19 is released, and the pointer comes to 49 in the plus field. Well will a circuit free, which the direction ruler 2-11 (Fig. 2), d. H. the Associated Contact ball 19, in turn, the ball 15 (Fig. 3, 4, 5) automatically approaches the overpressure in the spring 18 has disappeared and has thus reached the new rest position will.

In 'our case (Fig. 3) the current from the parallel connection terminal 27 goes to in The dashed path in the drawing into the iron magnet pair 28, pulls it around the pin 29 rotatable and bent lever 30-31, which secures the coupling sleeve 74 thereby turns off, comes into the iron core pair 32 and brings by attraction of the by 35 rotatable and kinked engaging lever 33-34 the coupling sleeve 36 for engagement in the crooked teeth of the reading running back gear 17. Since the coupling sleeve on the one that is firmly seated on shaft 13-14 Nuföi moves, the screw spindle takes part in the rotation.

The current is then via 37, 41 or with a branch via 37 'through the pole terminals 38, 39 through the electric motor 62, goes through the line button 41 and 42 in. the pair of electromagnets 43 and 45, energizes the same, then goes over the line points 47 to 49 to the current connection point in the positive Fields of the scale 26. From here the current path then leads through the pointer through the Axis of rotation 21 '(Fig. 4) to the parallel connection terminal back into the light guide.

At the other end 14 of the screw spindle (Fig. 3) are two ratchet wheels 51 and 52 with opposite teeth attached. Depending on which shaft is now turning, the one pawl 50 to inhibit each 53, while the second is always on the rotating one The teeth grind.

In the present case, the pair of magnets 43 pulls the pawl 50, the end of the lever is thus pressed into the teeth 75. By the pair of magnets 45 is on the opposite Teeth grinding pawl 53 pulled out of the teeth at 75, so that the rotation of the spindle is only in the opposite direction of the clockwise can go. >

When increasing the spindle in the sense of the 8p Clockwise, the stream takes the following strongly drawn-out path. From the parallel connection terminal 27 (Fig. 3) it goes through the pair of magnets 54, disengages the levers 33, 34 'for safety, pulls through the pair of magnets 60 the lever 30-29-31 and thereby moves the coupling sleeve 74 into the oblique teeth of the intermediate gear 17, then goes via 55, 56 either by the electric motor 62 or immediately via 55, 57, 58 into the pair of magnets 46, the pawl 50 disengages and presses through the attraction in the pair of magnets 44 the lever 53 on the teeth, so that the Can only turn the spindle clockwise.

From the magnet 44 it then goes into the negative field 59 of the scale 26, comes again at point 59 by the pointer at 21, finally at the parallel connection terminal of the light line.

By moving forwards or backwards of the jaw joint 9 on the spindle 13-14, the ruler 2-11 is moved forward so that the contact buttons 15 and 19 w, again for touch come at the point where the contact 15 connects the button 19 with the same Force like the spring 18 (see Fig. 4) pressed against it. As a result, the pointer 20-22 becomes the in 3 and 4 take the zero position shown and again on the currentless Parts 34 of the scale 26 come to a standstill, will remain there as a result of the blocking device 48, until the pressure of the spring 18 changes recently.

At the moment when the feeler lever contact 21-22 hits the current-free field 34 (FIG. 4) of the scale 26, both the two release devices 74 and 36 switch off and the pawls 50-53 switch on _;

The current flow is in this case with lines, which are interrupted by circles are drawn. From the light line 27, the current goes into the electromagnet

pairs 28 and 54, advances by attraction of the two release levers rotatable by 29 and 35, the two release sleeves 74 and 36 at the same time off, goes through the motor 62 via the line 63, 64 in the electromagnet pairs 43 and 44, This pulls the two pawls, which can be rotated by 50 and 53, at the same time and inhibits them thereby any forward and backward movement of the two ratchet wheels 51 and 52. Then goes This current continues over 65 through the grinding magnets 66-67, which are on a 'metallic Abrasive path 76 immediately adhere as a result of their excitement and any further movement of the Inhibit rulers 2-11. From there the current goes to the pin 25 in the spring housing 48, enters the pointer 22-21 through the plate-shaped end of the same 25 to likewise return to the light guide through the parallel switching terminal 31. The spindle 13-14 is now held and can no longer turn. Likewise comes the whole Ruler mechanism, the primary ruler 2-9 or 11 and the secondary ruler 9-10 for Standstills.

In order to achieve the micrometric shift within the sufficient precision line thickness of the drawing - 0.15 mm - with certainty, we use the following dimensions as a basis. The diameter of the screw spindle is 30 mm. Here the depth of the screw run, the cut spiral groove, is 1.5 mm. Let the increase be 20 mm and the diameter of the ratchet wheels d = 20 cm. The teeth ζ require 3 mm, so that we get 210 teeth with a circumference of the ratchet wheel u _r - 628 mm. The circumference of the screw spindle u _s is 94.2 mm. Now the shift when turning the ratchet wheel by one tooth (w = i ° 43 '11 ") shift v = -

3-2 ■ 3? '4__ 60

= ro, imm.

3.14 x 628 628
Since a line thickness of 0.15 mm has to be regarded as sufficiently accurate when mapping, a tooth can even be skipped during the escapement without reducing the steep slope of 2 cm.

This locking process can be secured by a number of technical devices, z. B. by resistances, by 'electromagnetically operated band brakes, by weakening of the magnetic field, by regulating the friction in the bearings and finally by the speed of the driving shaft and the choice of gear ratio.

In the drawing (Fig. 3) a small servo motor 62 is switched into the power, which in this simplest case runs backwards when the current changes and through the additional gear 17 acts on the spindle to be driven.

In FIG. 6, instead of the direct power transmission by a motor, which develops an initial speed that is too high, especially at the beginning of the movement, a belt or cable transmission is selected. Pulleys 69 and 70 run on the driving shaft 68. This rotation is transmitted to the idle pulleys 71 and 72 by means of belts or cords. Another arrangement of the engagement and disengagement clutch is shown in FIGS. 8a and 8b. T) The driving shaft 68 carries an open and a crossed belt for forward or reverse travel. Two disks 86 and 87, which consist of wire bundles and are separated by the insulating plate 88, sit firmly on the driven shaft 13-14. Depending on its direction, a current enters the iron wire bundle disk 87 or 86 through the brushes, attracts the loosely running disk 71 or 72 due to the electromagnetic excitation and causes the spindle 13-14 to run forwards or backwards through this magnetic coupling. In Fig. 8b, the electromagnetic clutch device is also provided on the driving shaft, so that in this latter case only the two work-performing wheels turn on the shafts. In the event that the locking device should not find space at the end of the spindle 13-14, the same can also be attached at right angles below the same and developed in the width direction.

For this purpose, as Fig. 11 shows, the end of the screw spindle 13-14 built into a housing 8 and ends in the Bevel gear 82. This engages in a bevel gear 84 mounted vertically in the housing. At the axis of the same 85 is then attached to the entire locking mechanism.

This arrangement saves space and makes the apparatus more compensatory.

Claims (5)

Patent Claims: ■ i. Ruler device for electromechanical Transfer of photogrammetrically given lengths to any inclined straight track according to patent 285716, thereby characterized in that by the rotational movements of the comparator cranks in one ■ perpendicular to the direction ruler - at single or multiple intervals of Focal length - attached guide rail (3-6) a mark (jaws 40) arranged is, and that the direction ruler carries a feeler lever contact (20-22) that opens or closes electrical currents, soft the straight track shown as screw spindle (13-14) by switching on of driving power shafts rotate in such a way that the carried along by a hub (9) End of the direction ruler (2-11) the length of the projection on the inclined straight line determines the photogrammetric length automatically during the feeler lever contact measures. 2. Apparatus according to claim i, characterized in that the current-closing Feeler lever contact as. Pointer levers (20-21-22) with unequal arm lengths is formed and as a result the contact of the contact balls in proportion adjusts itself to the housing spring in the currentless field (34) of the circular scale, in which position a counteracting suspension (48, keeps it free from vibrations. 3. Apparatus according to claim 1 and 2, characterized in that open through and closing of currents relays on bent lever arms (30-29-31 and 33-35-34) act which on and off devices and at the same time, on the same Axis seated locking devices (51, 52) according to the position of the sensing lever put into action or suspend that within any accuracy limits the micrometer movement and consequently the ruler shift automatically before 25. is going. 4. Apparatus according to claim 1 to 3, characterized in that one end a second ruler to be moved secondarily with the primarily moved direction ruler are connected by the hub (9) running on the screw, spindle can, so that it covers the same path with the same 'moment of force and with a similar coupling of the other end a new track line with different mathematical conditions mechanically shown. 5. Device according to claim 1 to 4 dagekmarks, because of several such unit rulers the most varied photogrammetric applicators that meet all possible axis positions, can be put together. For this purpose ι sheet of drawings.