FR2805648A1 - Parallax instrument for teaching purposes, comprises circular sector plate graduated in degrees which rotates about horizontal axis and has optical sight rotatable about an axis orthogonal to plate - Google Patents

Abstract

A plate (11) shaped as a sector of a circle is graduated in degrees and may be rotated about an horizontal rod (50) with a knurled screw fixing (15). An optical sight (60) in a cradle (21) may be rotated parallel to the plate about an axis (Z) which is orthogonal to the plate and at the centre of the circle. The optical sight assembly includes a measuring arm (23,24) and a vernier scale (25) to read the plate graduations.

Description

The present invention relates to an experimentation device for educational purposes intended to perform parallax measurements.

We know that parallax is defined as the angle at which we see an object or a frontal distance from a determined point. In astronomy, the value of the parallax of a star reveals the distance of this star. We are also interested in parallaxes in the field of photometry, metrology, photography, or even psychophysiology.

Parallax measurements are therefore of great interest to high school students, and it is interesting to facilitate the implementation of parallax measurement experiments, these experiments having to be as demonstrative as possible, with satisfactory measurement accuracy.

The state of the art is illustrated by extremely ordinary devices, using a protractor and a rope, the protractor being moved on a support plane against a fixed ruler, and the rope connecting the center of the protractor to the object observed, so to measure the angle corresponding to a given linear displacement reporter. A trigonometric calculation then easily gives the distance from the object to the rule by simple triangulation. However, such a device remains extremely rudimentary, and of mediocre precision. In addition, it becomes impractical if the object is at a relatively large distance from the observer and / or if the measurements are taken outdoors.

There is therefore a need for an experimentation device for educational purposes which enables precise parallax measurements to be made.

The object of the invention is therefore to produce an experimentation device for educational purposes intended to be carried out with parallax measurements, which is both precise and simple to implement, and which is suitable for both indoor and outdoor experiments. 'outdoors. problem is solved in accordance with the invention thanks to an experimentation device comprising a plate in a sector of a circle, the periphery of which carries angular graduations, said plate being fixed on an associated support; a rotary assembly mounted on the plate being able to rotate on an axis perpendicular to the plane of said plate and passing through the center of the outline of circular plate, said rotating assembly having on the one hand a cradle intended to receive a sighting system such that the axis of said sighting system is parallel to the plane of the plate and intersects the axis of rotation of the rotary assembly, and on the other hand a radial arm ending in a vernier which is arranged to remain adjacent and coplanar with the edge device of the plate during the rotation of said rotating assembly.

The rotating arm with its vernier allows measurements to be made by direct reading in a very precise manner, and this under very varied experimental conditions, both indoors and outdoors.

Preferably, the rotary assembly is clipped onto the plate at the level of the axis of rotation of that '.

In a first embodiment, the cradle of the rotating assembly is wedged on an axis distinct from the axis of rotation, but parallel to the latter.

We can in this case provide that the plate is surmounted by a target support, said support being wedged on the axis of rotation of the movable assembly. In particular, the target support has at least one receiving slot extending in a transverse plane passing through the axis of rotation.

According to another embodiment, the cradle of the rotating assembly is wedged on the axis of rotation of said rotating assembly.

We can then provide that the cradle has at least one receiving slot extending in a transverse plane passing through the axis of rotation, said cradle then also forming target support.

The sighting system mounted on a cradle may be a crosshair sight, or an optical scope, or even a laser pencil.

More preferably, the arm of the rotating assembly comprises an elongated plate connecting to a terminal circular bezel centered on the peripheral edge of the plate, said bezel carrying the vernier. Preferably then, the vernier is fixed to the circular bezel by snap-fastening.

Advantageously also, the vernier includes an angular stop for the position 0 and / or the position 90 cooperating with an associated part of the edge of the plate. In particular, provision may be made for the plate to have an angular range close to 110.

Advantageously finally, the plate includes means for fixing to a rail or to a tripod.

Other characteristics and advantages of the invention will appear more clearly in the light of the description which follows and of the appended drawings, relating to a particular embodiment, with reference to figures where - Figure 1 illustrates in perspective an experimentation device in accordance with the invention, this device being mounted on a horizontal rail; - Figures 2 and 3 are end and top views of the aforementioned device, to better distinguish the arrangement of the rotating assembly with cradle lens holder and vernier holder arm; - Figure 4, and the associated half-section of Figure 5 illustrate in perspective the rotating assembly of the above device, without the vernier mounted at the end of the radial arm; - Figure 6 is a perspective view of the vernier, and Figure 7 is a top view of the vernier and the adjacent area of the plate, with a cutaway to better distinguish the stop system which is here provided for the angle 90; Figures 8 and 9 illustrate in perspective, respectively in the disassembled state and in the assembled state, a reticle telescope equipping the aforementioned device; FIG. 10 is a perspective view of the above-mentioned device on which the reticle telescope has been replaced by a vertical target, said device then being mounted on a tripod; - Figure 11 is an associated end view of the device of Figure 10; Figure 12 is a perspective view illustrating a variant of the experimentation device according to the invention, in which the cradle is wedged on the axis of rotation of the assembly rotating said cradle in this case carrying an optical telescope; - Figure 13 is an end view of the previous device; - Figures 14 and 15, which are to be compared to the aforementioned figures and 11, illustrate, respectively in perspective and at the end, the experimentation device of Figures 12 and 13 in which the optical scope has been replaced with a vertical target; - Figure 16 is a schematic top view illustrating the implementation of the device according to the invention for indoor measurement, said device being mounted on a horizontal rail; - Figure 17 illustrates in the same way, but in perspective, the implementation of an experiment carried out outdoors, using two devices according to the one just described.

We will now describe in more detail, with reference to Figures 1 to 3, the main components of an experimentation device for educational purposes according to 1 invention.

The experimentation device, denoted 10, firstly comprises a plate 11 in a sector of a circle, the periphery of which carries angular graduations denoted 12, going here from -10 to +100. This therefore corresponds to a range of 110, but it goes without saying that the precise value of range may be modified as the case may be, without however going below the value of 90. The plate 11 has a circular contour whose center is noted 0.

circular edge, noted 13, has a profile with a peripheral rib.

In this case, the plate 11 is fixed on an associated support 50, which is a horizontal rail, preferably graduated over at least part of its length. For this purpose, there are provided, below the plate 11, stirrups 14 serving for the passage of the rail 50, the blocking of the plate in the desired axial position being effected by tightening a knurled screw 15. The plate 11 also has a reference edge at a facet 16, which makes it possible to pinpoint the distance of movement of the plate 11 on its rail 50. It will also be noted the presence of a metal insert 15 ′ in the vicinity of the center of the plate 11, said insert used to mount the plate another type of support, bearing on a lower base 19 (visible in Figure 2), such as a tripod 51 such mounting is illustrated in Figures 10 and 11 which will be described later) .

The experimentation device 10 further comprises a rotating assembly denoted 20 which is mounted on the stage 11 while being able to rotate around an axis denoted Z, which is perpendicular to the plane of said stage and passes through the center 0 of the outline of circular stage . Provision may be made for the rotary assembly 20 to be clipped onto the plate 11 at the axis of rotation thereof. This will be better understood by referring to FIGS. 4 and 5, which show the rotating assembly 20, and in particular hooking teeth 27 used for the snap-fastening of 1 rotating assembly 20 on the plate 11.

The rotating assembly 20 firstly has a cradle 21 which is intended to receive an aiming system so that the axis X of said aiming system is parallel to the plane of the plate 11 and intersects the axis Z of rotation of the rotating assembly 20. In this case, the cradle of the rotating assembly 20 is wedged on an axis denoted Y, which is distinct from the axis of rotation Z, while being parallel thereto. The sighting system here is a simple sight with two reticles, the structure of which will be better understood by referring to FIGS. 8 and 9. There are in fact two sub-assemblies capable of snapping into each other when they are brought together coaxially, each of these sub-assemblies having a bottom formed by a washer 60.1 forming a reticle by means of adapted holes (in this case a central circular hole, and four radial holes at right angles).

It goes without saying that the reticle sight 60 can be replaced by an optical scope or even by a laser pencil.

As will be seen below, it may prove advantageous to use the experimentation device according to the invention outdoors, the device being placed on a tripod and used in duplicate. In this case, it is advantageous to be able to place a target on a device, the other being equipped with an aiming system which can be pointed at the center of the target. As a result, it is advantageous to provide a means allowing a target to be quickly mounted on the rotating assembly of the device, in particular to replace the aiming system, this assembly having however to be carried out with care for the target being exactly aligned with respect to the axes. remarkable features.

In this case, provision has been made for the rotating assembly 20 to be equipped with a target support which is wedged with the axis of rotation Z of said assembly. The target support has a receiving slot 30 extending in a transverse plane passing through the axis of rotation Z, said receiving slot being delimited by the vertical edges of an element 28 in the form of a cylindrical sector, and a tab central maintenance 29. As is better visible in Figures and 5, the central retaining tab 29 has a protrusion 29.1 which ensures tightening and possibly also allows embedding in an associated bore of the target.

Figures 10 and 11, there is thus illustrated the mounting of a target 65 in the form of a circular disc, said target being placed in its receiving slot 30, being held by the elastic tab 29 against the edges of the curved element 28. It is easy to understand that the substitution of the sighting system by the target and vice versa is extremely easy to achieve. It should be noted that the horizontal axis of the target 65 is coincident with the axis X of the cradle receiving space, that is to say the axis of the sighting system when the latter is put in place. on said cradle 21. It will also be noted that the axis of rotation Z of the rotating assembly 20 passes in the plane of the target once the latter has been put in place. In FIGS. 10 and 11, the plate 11 is fixed to a tripod. This is particularly suitable for experiments carried out outdoors, as will be described later.

The cradle for receiving the sighting system can be arranged differently, and another variant will be described with reference to FIGS. 12 to 15.

In these figures, it can be seen that the rotating assembly 20 has a cradle 21 'which is wedged on the rotation axis Z of the rotating assembly 20. An optical telescope 61 is placed on the cradle 21', with its axis X which is not only parallel to the plane of the plate 11, but also intersects the axis of rotation Z at the center of the cradle 21 '. Here again, provision has been made for the possibility of substituting a target for the optical telescope 61. To this end, provision is made for the cradle 21 'to have at least one reception slot 30' extending in a transverse plane passing through the axis. of rotation Z, said cradle then forming target support. In this case, such a slot 30 'has been provided on the outer face of each branch of the cradle 21', at a transverse median plane of said cradle. FIGS. 14 and 15 thus illustrate the positioning of a target 66, replacing the optical telescope 61. However, it can be seen that the target 66 has here a particular geometry, with two lateral branches coming to straddle the cradle 21 ', of so that the internal edges of said branches pass into the aforesaid slots 30 '. Once the target 66 has been put in place, by being pushed in until it comes into abutment against the support cradle 21 ', the center of the target 66 is located on the axis X of the space for receiving the cradle 21', which was before the axis of the optical scope 61 previously put in place, and the axis Z of rotation of the rotating assembly 20 passes in the plane of said target 66.

In all cases, whatever the type of cradle 21 or 21 ′ used, the rotating assembly 20 also has a radial arm terminated by a vernier 25 is arranged to remain adjacent and coplanar with the peripheral edge 13 of the plate 11 during of the rotation of said rotating assembly. A distinction is thus made, for the two variants described above, of a plate assembly 22 adjacent to the cradle 21 or 21 ′, which is extended by a radial arm constituted by an elongated plate 23 connecting to a terminal circular bezel 24 centered on the peripheral edge 13 of the plate 11, said bezel carrying the vernier noted 25.

As can be seen more clearly in FIG. 3, the vernier 25, substantially in the shape of a half moon, has an upper screen-printed face with graduations ranging from 0 to 10, for an offset of one tenth of a graduation with respect to the graduations 12 of the plate 11. Conventionally, such a vernier then allows a reading to the nearest 10th of a degree when the angular position of the radial arm is modified from the initial reference position set to 0, or 90 here.

The vernier 25 is preferably fixed to the circular bezel 24 by snap-fastening. FIGS. 4 and 5 show for this purpose snap-fastening tabs 26 projecting internally from the circular bezel 24, these tabs passing through circumferential openings 25.1 of the vernier 25, better visible in FIGS. 6 and 7. Once the vernier 25 snapped onto the underside of circular bezel 24, the screen-printed semicircle of vernier appears perfectly in the center of the circular bezel.

It can also be seen that vernier 25 has two support facets 25.2 which slide against the circular edge of the plate 11. One of these support edges 25.2 is extended by an elastic tongue 25.3 which ends in a tooth latching 25.4. As is better visible in Figure 7, thanks to a cutaway of part of the thickness of the plate 11, we see that the tooth 25.4 is received in an associated notch 18 of the plate 11 to constitute an angular stop for position 90. This avoids awkward manipulation which would free the rotating assembly from its support plane insofar as the radial arm rests directly on the upper face of the plate 11. An angular stopper has also been provided for position 0, in the form of 'a projecting rim 17 terminating the quadrant beyond the position - 10, this rim 17 cooperating with the edge of the vernier 25, the contact being made when the axis X corresponds to an angular position fixed on the direction 0.

will now describe the implementation of the experimentation device which has just been described, with reference to the schematic views of FIGS. 16 and 17.

, ce qui permet de calculer la distance D qui correspond alors à la formule D = d.tan

On est ainsi parvenu à réaliser un dispositif d'expérimentation permettant d'effectuer des mesures précises de parallaxe, ou tout en étant aisé à mettre en oeuvre, et ce aussi bien en extérieur qu'en intérieur. FIG. 16, this is an experiment carried out indoors, with a single experimentation device 10 mounted on a horizontal rail 50. We then proceed in two successive stages - in a), the device 10 is put in place in front of an object 70 comprising a marker 71 (for example a vertical line); in this position, the viewfinder 60 is in position 90 of the plate 11, and the reference facet 16 is at 0 of the graduation carried on the rail 50; - In b), the device has been moved by a distance d, which is measured with precision by the reference facet 16. We then rotate the rotating assembly so that the viewfinder 60 points exactly in the direction of the reference 71 : this corresponds to an angle e_ of rotation, which then easily makes it possible to deduce the distance D separating the object 70 from the axis Z using the formula D =. cotanx. In Figure 17, this is an outdoor experiment. In this case, there is no support rail, so that the two experimentation devices used are mounted on a tripod 51. We then proceed in several successive steps - in a), we position a first device on its tripod 51 in such a way that the optical telescope points to the reference 71, the X axis of this telescope being set to the position 0 of the plate 11; - In b), the optical telescope 61 has been replaced with a target 66, and the rotating assembly of this first device has been rotated by 90, and a second experimentation device is then positioned, at a distance d measured from the first , so that the optical telescope 61 carried by this second device points to the center of the target 66 carried by the first device: a right angle has then been defined which serves as a reference for the following measurement; - in c), the rotating assembly of the second device is rotated to bring the axis X of the optical telescope 61 the reference 71: this has caused a rotation of an angle

, which makes it possible to calculate the distance D which then corresponds to the formula D = d.tan

It has thus been possible to produce an experimentation device making it possible to carry out precise parallax measurements, or while being easy to carry out, both outside and inside.

The invention is not limited to the embodiments which have just been described, but on the contrary encompasses any variant incorporating, with equivalent means, the essential characteristics set out above.

Claims (13)

<U> CLAIMS </U> 1.Experimentation device for educational purposes intended to perform parallax measurements, characterized in that it comprises - a plate (11) in a circle sector, the periphery of which carries angular graduations (12), said plate being fixed on a associated support (50,51); - a rotating assembly (20) mounted on the plate (11) being able to rotate about an axis (Z) perpendicular to the plane of said plate and passing through the center (0) of the outline of circular plate, said rotating assembly having d 'firstly a cradle (21,21') intended to receive an aiming system (60,61) in such a way that the axis (X) of said aiming system is parallel to the plane of the plate (11) and intersects the axis (Z) of rotation of the rotating assembly, and on the other hand a radial arm (23,24) ending in a vernier (25) which is arranged to remain adjacent and coplanar with the peripheral edge of the plate (11 ) during the rotation of said rotating assembly. 2. Device according to claim 1, characterized in that the rotary assembly (20) is clipped onto the plate (11) at the level of the axis of rotation (Z) thereof. 3. Device according to claim 1 or claim 2, characterized in that the cradle (21) of the rotating assembly (20) is wedged on an axis (Y) distinct from the axis of rotation (Z), but parallel to this one. 4. Device according to claim 3, characterized in that the rotating assembly (20) is further equipped with a target support (28,29), said support being wedged on the axis of rotation (Z) of said assembly . 5. Device according to claim 4, characterized in that the target support (28,29) has at least one receiving slot (30) extending in a transverse plane passing through the axis of rotation (Z). 6. Device according to claim 1 or claim 2, characterized in that the cradle (21 ') of the rotating assembly (20) is wedged on the axis of rotation (Z) of said rotating assembly. 7. Device according to claim 6, characterized in that the cradle (21 ') has at least one receiving slot (30') extending in a transverse plane passing through the axis of rotation (Z), said cradle forming then also target support. 8. Device according to one of claims 1 to 7, characterized in that the sighting system mounted on the cradle (21,21 ') is a reticle sight (60), an optical scope (61), or even a laser pencil. 9. Device according to one of claims 1 8, characterized in that the radial arm of the rotating assembly is an elongated plate (23) connecting to a terminal circular bezel (24) centered on the peripheral edge (13) of the plate (11), said bezel carrying the vernier (25). 10. Device according to claim 9, characterized in that the vernier (25) is fixed to the circular bezel (24) by snap-fastening. 11. Device according to claim 9 claim 10, characterized in that the vernier (25) includes angular stop for position 0 and / or position 90 cooperating with an associated part of the edge of the plate (13). 12. Device according to claim 11, characterized in that the plate (11) has an angular range close to 110. 13. Device according to one of claims 1 to 12, characterized in that the plate (11) includes means (14,15,19,15 ') for fixing to a rail (50) or to a tripod (51) .