ES2283201B1 - LARGAVISTAS WITH FOCAL DISTANCE MULTIPLIER. - Google Patents

Abstract

The Larvists with focal length multiplier, are similar devices to the known ¿Binoculars¿, which have a system of mirrors, located in the corners of some square tubes, which serve to multiply the focal distance that the light that enters through the lens, until focal distances similar to those of the telescopes of the astronomical observatories are achieved, so that it can considerably approach the focused objects, and especially the stars, even though they are, - by their dimensions -, a home object.

Description

Longview with distance multiplier focal.

Object of the invention

The main objective of the present invention is to bring objects in sight as much as possible achieve, fully exploiting all the possibilities of the optics. For this purpose, a multiplier system of focal length formed by mirrors that are located in the corners of some square tubes.

Background of the invention

In addition to the well-known Astronomical Telescopes , and Binoculars for private use, there are homemade Telescopes for fans of astronomical observation. These telescopes achieve approximate focal distances of one or two meters in tubes that have, between the lens of light entry, and the viewfinder, that same distance, or half, that is doubled by the inside of the tube by placing the viewfinder near the entrance of the lens and bouncing the light in a tilted mirror to said viewfinder from the other end of the tube. As an alternative, an object is presented that would be among the three types of existing objects whose mission is also to bring the image of the objects closer together. This object has the advantages of the three existing objects and none of its disadvantages. On the one hand it has the dimensions of homemade binoculars , and at the same time, it has the benefits of an Astronomical Telescope while the focal length that it can achieve is similar to that of these, so that it can convert the hobby, from which use, by profession. To achieve it, you only have to place mirrors that channel the light, from the input lens, to the viewfinder in square tubes. One of the variants shown in the drawings owes more to my previous patent, entitled: Focal length multiplier for telescope , than to the system presented today, but it is also a similar object in terms of the objectives to be achieved as an object homemade, which can also work as a professional telescope. It has a system whose shape is different, to the extent that, instead of gridding the tubes, it keeps them elongated and connected to each other at the ends. Moreover, the system is the same as it is also about increasing the focal length as much as possible to bring as close as possible to the farthest objects in the Galaxy.

Description of the invention

The Largvists with focal length multiplier , are an alternative to the Binoculars and the homemade Telescopes that can allow to make the hobby of astronomy almost a profession while, an object of the dimensions of some homemade Binoculars, can achieve similar focal distances to those of the Astronomical Telescopes of today, and thus bring, in sight, objects that are extremely distant, in the Galaxy. The object is formed by a lens (2) for the entry of the light, (1), -or two, depending on the model-, which channels it to square tubes (6), which have other tubes inside ( 7), also square. Among them there are small tubes or holes, which allow light to be transferred from the small, internal square tubes, to the large and external square tubes. In each corner of each tube there is a flat mirror, (5), inclined 45 °, which deflects the light towards the other mirrors of the other corners. In figure 1 we can see a gap between the inner square tube and the outer square tube through which a ray of light passes. This means that the light, (1), which has entered through the lens, (2), is first directed towards the inner square tubes and runs them, from the center, to the ends. Once there, the light jumps through a gap towards the outer square tubes and travels all the space that exists, from the ends, to the viewers (10). This is observed, in diagram, in figure n ° 2. In figure n ° 3 we can observe one of the square tubes; both the outer and inner square tubes are the same. Figure 3 clearly shows the way in which the light (1) arrives - in this case from the left -, to any one of the square tubes, it crosses it, and then goes to the one next to it. This is achieved by a double mirror (8) found in the lower front part of the drawing. To one of those mirrors, -to the mirror on the left-, comes the light from the tube on the left, and to the mirror on the right, comes the light from the tube itself, from the other end of the bottom, and this is the mirror of the right the one that drives the light that has just arrived, to the next square tube to the right of the drawing in the figure. Figure 4 offers a diagram of the path of light from the moment it reaches the lens (2) until it reaches the viewfinders (10), first traveling through the inner tubes -from the center to the ends-, to pass, once at the ends, to the exterior, approaching them again to the center where it is directed towards the viewfinders. Another possible way to delimit the path of light as soon as it reaches the lens, is to make the ray of light deviate, from the inside, -from the first mirror of the first square tube in its path-, towards an extreme. Then it will return through the outer tubes and fork towards the viewfinders. This form is more effective than the previous one in that it increases twice the focal length. A variable device, -not drawn in the figures-, could switch the first mirror with which the light beam comes in contact so that it orients in one direction or another, that is, towards the end of the system, or towards the other corners of your own square. The advantage that this would have is that the Largavistas could serve, in addition to serving to observe the stars, also to observe the short distances and function as binoculars for home use, thus being able to focus on the nearest objects.

Figures 7 and 8 show us another system of Largavistas , which owes more to the operation of the registration of my previous Patent, entitled: Focal length multiplier for telescope , than this one in terms of the most apparent form, although in terms of The logic of the focal length multiplier system is the same issue. In this other system, the tubes (6) with the mirrors are not square but longitudinal, and are connected to each other by the ends. This is practically the only difference.

Figures 5 and 6 describe a variant for the Professional Astronomical Telescope similar to that of the Largavistas that is presented today in terms of the square tubes of the focal length multiplier. As seen in them, in the upper part is the main tube -mobile in all directions-, which comes the light (1) of the stars. At the other end of this tube there is a pivot (3) that allows the tube (2) to move up and down. When the light reaches that end of the pivot, a mirror in a recess (4) causes the light to descend to the immediate lower floor of the horizontal and square tube (6) which is the first of a long series of floors (6), so many as desired or permitted by the dimensions of the observatory. Inside these square tubes there are also other equal and smaller square tubes, such as those described above for the home Largavistas. The viewfinders (10) on the left, one on each floor, -figure n ° 5-, have a spring that allows the mirror, just before the viewfinders, to move, and instead of deflecting the light towards another mirror on the lower floor, I can let it pass to the viewfinder. This has the advantage of being able to choose a specific focal length, which is needed at all times, which is less than that allowed by the entire system. An Astronomical Telescope of these characteristics that had dimensions of 10 meters high, four meters wide and long, could reach a focal length of about 7,200 meters if it is taken into account that at least three columns of tubes could be placed inscribed squares. And, you could put some more because the tubes do not need too much width to channel the light. This would increase the focal length much more. In any case, 7,200 meters, compared to the 20 or 30 meters of focal length achieved by the current Astronomical Telescopes, is a considerable difference. Date of the invention: 12-13.X.05.

Description of the drawings

Figure n ° 1: Side view of the Largavistas with focal length multiplier in vertical square tubes, in which shows the path of light through the outer tubes and interiors

Figure 2: Front view of the Largavistas with focal length multiplier in square tubes in which It shows the light path between tube and square tube.

Figure n ° 3: Top view of the Largavistas with focal length multiplier in square tubes and detail of one of the square tubes that is a perspective view of one of the tubes in which it shows how a couple of mirrors channel the light that reaches them inside the tube square and then divert it to the tube at its side.

Figure 4: Top view in which it is shown how is the light path since it enters the viewfinder, it forks and travels the lower square tubes heading towards the two ends of the longview, and then goes, through the tubes outer squares, towards the central area where the viewfinders or eyepieces

Figure n ° 5: Telescope side view astronomical with focal length multiplier in square tubes horizontal.

Figure 6: Top view of the Telescope astronomical with focal length multiplier in tubes squares.

Figure 7: Top view of the Largavistas with focal length multiplier in elongated tubes.

Figure n ° 8: Front view of the Largavistas with focal length multiplier in elongated tubes.

Figures 1-3

one).

Light of the stars

2).

Lens in the receiver tube mobile

3).

Pivot

4).

Pipeline hollow light

5).

Flat mirrors

6).

External pipes for channeling the light: square or elongated

7).

Internal square tubes

8).

Double mirror

9).

Tube fixed clamping mobile receiver tube

10).

Viewers

Description of a preferred embodiment

The Larvists with focal length multiplier , are characterized by their specific function of bringing the most distant objects into view as if they were binoculars or a telescope for home use. Add to this function benefits that allow its operation to also approach a professional use of the object, while it can achieve focal distances similar to those of astronomical observatories. It consists of the Largavistas -figure n ° 1-, in a mobile tube (2) -which can only move forward and backward, from and to another fixed tube (9) to the object housing-, which has a receiving lens (2) to which comes the light reflected from the objects. Next, the light will reach square tubes (7) that are inside other square tubes (6), - larger than the previous ones -, in which they are inscribed. In each corner of each square tube - be it the large exterior, or the small interior - there is a flat mirror, inclined 45 °, which channels the light to the other immediate corner of the square. But, in one of those corners the mirror is double (8). This allows, on the one hand, - see Figure 3-, to receive the light that comes from the square tube on your left and circulate it through the square of the tube, bouncing from mirror to mirror until you reach the point of departure from that tube, that is, to the corner where the light had reached said square, but, upon reaching this corner, the light does not impact the entrance mirror, (8), but, as there is two mirrors, it has another exit mirror, (8), which allows channeling the light to the mirror of the square tube on its right. This allows the light to travel, from mirror to mirror, all square tubes, both interior and exterior of the system, until reaching the viewfinders (10), having traveled a considerable focal length. The system allows the light that reaches the first inner square tube (7) to deflect towards one end and travel through all the internal tubes (7) and then all the external tubes (6) before reaching the viewfinders (10); Or, you can start your journey from the center to the ends and return through the outer tubes, back towards the center, until you find the viewfinders. A spring, not drawn in the figures, can switch the position of the first mirror that receives the light, so that it deflects it, either towards the corners of its own square, or towards the square of one end of the Largavistas. For this, an opening at the same height in all the squares and a moving mirror would suffice. In the variant, figures 7 and 8, there is a Largavistas that instead of having the square tubes, has them longitudinal and connected to each other by small holes in the ends of the tubes (6). The other variant - Figures 5 and 6-, presents the same previous system of square tubes in a
Professional astronomical telescope of greater dimensions. The system is the same as the previous one. Only the horizontal position of the squares of the tubes changes in it, while in the previous Largavistas the squares of the tubes are in an upright position. Also the main tube with the receiving lens (2) of the light (1) differs from the Largavistas in that, although it is also mobile like it, it can rotate up and down, and from right to left, without moving The whole system, while the previous one can only move forward and backward. This system is capable of being applied, with the appropriate modifications, to a Microscope, being able, perhaps, to be a powerful tool that allows us to get closer to the most hidden nature of atoms.

Claims (3)

1. Larvise with a focal length multiplier, characterized by its specific function of bringing the most distant objects into view as if they were binoculars or a home-use Telescope, but with features close to those of a professional Astronomical Telescope . It consists of the Largavistas in a mobile tube (2), which is located inside another tube (9), -fixed to the object housing-, and which has a receiving lens. Next, there are square tubes (7) that are inside other tubes, also square (6), -and, larger than the previous ones-, in which they are registered. In each corner of each square tube, be it the large exterior, or the small interior, there is a flat mirror, inclined 45 °. But, in one of those corners, the mirror is double (8) and, -the one on the right-, is also inclined 45 ° towards the square tube on the right, while the one on the left is inclined 45 ° towards the left, oriented towards the square tube that is before him, on his left. There are also viewfinders (10) on the back of the system. A spring can switch the position of the first mirror that receives the light, orienting it towards a mirror at one end of the system, or towards the corners of the square tube itself. For this, an opening at the same height in all the squares, and a moving mirror is enough. 2. Larvise with focal length multiplier, according to claim one, characterized by presenting a variant with respect to the previous system in a Largavistas, which instead of having the square tubes, has them longitudinal and connected to each other by small gaps in the tube ends (6). 3. Larvise with focal length multiplier, according to claim one, characterized by presenting another variant with the same previous system of square tubes, but now, located in a larger professional Astronomical Telescope. Only the horizontal position of the squares of the tubes that would thus form a column changes in the variant, while in the previous Largavistas the squares of the tubes are in an upright position, forming a lying column. Also the main tube (2), with the light receiving lens (1), differs from the Largavistas in that it is mobile in all directions.