SE522396C2 - Light or sound reinforcing reflector device - Google Patents

Abstract

A device (10) in order to reflect a bunch of rays (30) towards a receiver (R). The system consists of two concave reflectors (12, 16). The invention describes also a system which deflects a bunch of rays towards a receiver by means of two convex refractors. According to the invention it is suggested that the reflectors (12, 16) are single-curved and have inter-crossing, especially right-angled crossing bending axis (14, 18). According to the invention it is suggested that the refractors (31, 32) are single-curved convex and have inter-crossing, especially right-angled crossing bending axis (14, 18).

Description

20 25 30 522 3962 «u | =. Summary of the Invention According to a consideration of the invention, the reactors are single curved and have mutually crossed curved axes.

According to another consideration of the invention, the refractors are single curved and have mutually crossed curvature axes.

Preferably, the curvature axes are perpendicularly crossed.

According to one embodiment of the invention, at least one of the reactors is circularly cylindrically curved.

According to another embodiment of the invention, at least one of the reactors is circularly cylindrically designed.

According to yet another form of emission, a reactor or reactor element is placed between the receiver and the reactors, designed to compensate for distortion or distortion of the beam of the beam caused by the reactors.

According to a further embodiment, at least one of the reactors is composed of your elements. The elements can then be arranged in a plane, essentially according to Fresnel's principle.

The device may typically be incorporated in an apparatus for treating electromagnetic beams, such as a telescope, binoculars, a camera or the like, but also in a magnifying apparatus, such as a microscope or the like.

However, even in the case of the desiccation example, the reactor can be incorporated into an apparatus for treating mechanical beams / waves, such as a sound dryer or the like.

As a telescope or binoculars, the invention has 2 single-curved concave (cylindrical) rectifiers in particular. 2 2 3 9 6 3 vertical joint, secondary fl ectom consists of a planar re fl rectifying surface soin bends to be given focus that is linear in horizontal direction, the linear focus intersects each other in 90 degrees, primary fl ect reacts the object's rays towards secondary fl ectom which is well in focus from focus the secondary flector is positioned so that its focus is combined with the focus from the primary flector, the linear focus of the primary and secondary skerectors takes place at the same point, two linear foci have now formed focus at one point, the secondary flector is displaced laterally prim from the primary attector. with a focus on the center of the primary fl ectom.

A system of lenses can be placed around the focus to adjust the reproduced image for distortion, aberration, zooming, etc.

The rectum can advantageously be somewhat cylindrically parabolic.

A shield against extraneous light can be placed between the focus and the secondary fl ectom.

Technical description A flat reflecting surface single bend concave to give a vertical linear focus. This primary vector reflects incoming light from a distant object to the secondary vector. The secondary ectometer also consists of a flat reflecting surface. This surface curves single concavely, giving a horizontal linear focus. The secondary ktector is well placed in focus from the primary ectom.

The secondary flector is placed fi opposite, offset laterally in front of the primary .ector.

The secondary flector is positioned so that its focus is combined with the focus from the primary Re The ectectors can be parabolic to provide a uniform focus. The rays from the primary mirrors have different lengths from the right and left sides of the primary mirror. A stronger curvature towards one side of the primary mirror compensates for this. All rays can thus be collected in a linear focus. Lenses around focus can otherwise adjust for uniform focus.

Focus is conveniently placed next to the primary ,ector, the center in height to avoid correction as above. 10 15 20 25 30 A protection is placed between the secondary reflector and the focus, the protection prevents unintentional incident light. No protection is required before the secondary flector.

Secondary ectom can be semi-transparent. The system can be symmetrically designed; the primary stårector is in the middle of the secondary flector. As a result, the beams on the left and right sides will not have different distances to travel. No lens to correct focus will be needed. Focus is preferably directed towards the center of the primary mirror.

In the version with refraldors, these are simply curved convex to give a linear focus.

The primary refractor stands in the middle of the secondary refractor. Through the primary refractor, incoming light is refracted to provide a vertical focus. The secondary refractor is well within the linear focus of the primary ct alctorris.

In the secondary refractor, the light is refracted to give a horizontal focus.

The two refractors have a common focus. The two linear focuses have formed a focal point in accordance with the invention.

In accordance with the design, in one embodiment a reactor and a reactor can be combined to form a focus.

Advantages A large telescope can be designed at a lower cost. The telescope can be designed considerably larger than with advanced technology. Today, large mirrors must be ground out of a piece of solid glass, which is problematic and costly. The largest today grounded is about 8 meters in diameter.

The Hubble Space Telescope is about 2.5 meters in diameter. According to the present invention, telescopes can be constructed, for example, of a large and tower metal or ceramic disc, polished or coated with a reflecting surface.

A larger telescope can advantageously be constructed with a number of smaller reactors placed in a grid pattern to cover a surface that is optimal for the purpose, this magnetic construction would allow the construction of a very large telescope.

In the case of a larger telescope with the reactors displaced laterally, a system for continuous laser shielding can be placed in focus for each individual reactor. A laser can be placed in linear focus on the respective reectors. Lasem scans the surface of the reactor to measure any 10 20 25 30 522 3965 irregularities. A system of centrally controlled reactor holders continuously adjusts the image area for best image reproduction. Through this method, a ground-based telescope can compensate for atmospheric disturbances, etc.

The system can also be used to advantage for binoculars, cameras, camcorders. The system allows a lens to be made very large at a small cost. The system can also be used to amplify sound waves, such as directional microphones. The system can also be used in reverse; to enlarge a light or sound image. In this way, it can be used to magnify a light image in, for example, a microscope, magnifying glass or monitors. Even sound can be magnified from a smaller area to be spread evenly over a larger area. The system replaces the dish for receiving electromagnetic radiation in a wide range of wavelengths. The system can also be designed as simple and inexpensive solar collectors.

A pair of binoculars is advantageously manufactured with a sernitrarisparent secondary fl ector. The sector is placed in the primary sector. The light passes through the secondary fl ectom. The reactors are designed to be symmetrically single curved and give focus at the same point. Light from a distant object passes through the secondary ectector, is reflected in the primary ectector, is reflected there in the sectarian ectom and is concentrated in focus. In this way, a camera can be equipped with a large lens at a small cost.

A camera is advantageously also manufactured with re akt actuators.

The advantages become obvious when you consider that a presentation on a screen or otherwise in a photo is invariably square in design. A larger part of the aperture of the lens will hereby be used for image production. A camera would not need to be larger than the front area of the lens.

Lens material is saved.

Figure description Fig. 1 Perspective view of the two rectifiers of the invention with drawn radiation.

Perspective view of the two rectifiers with drawn radiation. (Primary primary ,ector, (2) secondary flector, (3) focus, (A, B, C, D) radiating and (A1, A2, B1, B2) reflected rays.

Fig. 2 (6) shows the occupied image area of the telescope. 20 25 30 522 3696 Shows the linear focus of the primary primary (4) and (i) in Fig. 3 (ALBI, C1, D1) l) reflected rays.

Fig. 4 Shows (2) the linear focus of the secondary (ector (5) and (A2, B2, C2, D2) reflected rays.

Fig. 5 Top view. (1) primary ectoma reflects (A, B) incoming radiation to (2) secondary ectoma whose curvature is not visible above the river.

The common focus (3) of the reactors has gathered all the radiation.

Fig. 6 Side view. The single curvature of the primary primary is not visible from the side, (A1, C1) reflected rays are horizontally parallel to (2) the secondary curve whose single curvature can be seen from the side.

The radiation is refracted in the secondary flectom to (A2, C2) rays that accumulate in a focal point next to the primary flector.

(A, C) Incident radiation.

Fig. 7 Top view. A variant of Fig. 5. (1) primary flector, (2) secondary ochector and (3) focus.

Fig. 8 Schematic side view of an embodiment of the invention in the form of a telescope.

Fig. 9 Schernatic side view of an outdoor form of the invention in the form of a telescope.

Fig 10 View from above. The formation consisting of two refractors, the primary refractor single-curved convex, the secondary fi-actor single-curved convex.

Fig 1 1 Side view. The invention consisting of two re-actors.

Fig. 12 Perspective view. The invention consisting of two reactors.

Detailed description Fig. 1 Perspective view of the two rectifiers with drawn radiation. (1) primary mirror reflects (Al, B1, Cl, D1) rays towards (2) secondary mirror (2) which reflects (A2, B2, C2, D2) rays towards (3) focus.

Fig. 2 The perspective view shows how the concave single-curved (D-primary fl vector reflects (A, B, C, D) incoming radiation towards (2) the secondary fl-vector. which are horizontally parallel but are given a refraction to accumulate linearly vertically through (3) focus.The concave single-curved (2) secondary fl ectom refracts incoming (A l, B l, C l, D l) rays, the radiation is reflected to 20 25 Fig. 4 Fig. 5 522 39§ (A2, B2, C2, D2) rays which pass through the (Bsekundärlre flektor lcrö kuninng sam. U lasmi (3) focus.

I: nu n 0 Perspective view. Shows the linear focus of the (Dprirnear flector (4) and (A1, B1, C1, D1) reflected rays. The rays are parallel horizontally and are refracted to linear focus vertically by the single curved reflecting surface.

Perspective view. Displays (2) the linear of the secondary (ector (5). focus and its (A2, B2, C2, D2) reflected rays. The beams are parallel in the vertical direction and are refracted to a linear focus in the horizontal direction.

Re fl ectom is single curved concave and linear in horizontal view from above. (The primary ochector and (AB) incoming radiation give (Al, B1) mirror radiation to (2) the secondary vars vector whose curvature is not visible from above.

The common focus (3) of the reactors has gathered all the radiation. (l) primary kt ectom can be made slightly single-curved parabolic to compensate for an oxygen netrie in refraction - The beam B1 has a longer path to (2) secondary fl ector than the beam A1.

Side view. The single curvature of the primary primary ectector is not visible from the side, (Al, C1) reflected rays are horizontally parallel to (2) the secondary ectector whose single curvature can be seen from the side. (3) focus.

The radiation is refracted in secondary fl ectomers to (A2, C2) rays that accumulate in a focal point. (A, C) incident radiation.

View from above. A variant of Fig. 5. (2) the secondary ärector is semi-transparent and transmits radiation to (Dprimnear ktectom (A, B, E) incoming radiation is re-reflected in (1) the primary fl ector, forms (A 1, B l, E Dre fl ectant radiation towards the central placed (2) secondary ectomers that provide reactions (A2, B2, E2) to common (3) focus Incoming (E) beam passes through (2) secondary flector 10 15 20 25 30 Fig 8 Fig 9 Fig 10 Fig 11 Fig 522 39 A schematic side view of an embodiment of the receiver in (R) a receiver looks through (20) the eyepiece. side view (12A) center A (10) device for angularly changing a beam (16) the secondary re vector reflects (30) the beam towards (20) eyepieces.

Schernatic side view of an embodiment of the invention in the form of a telescope. (40) the telescope receives a (30) beam of radiation reflected by a split (l 2 ') primary mirror and its peripheral (12A) parts, mounted in one (13) plane.

A (16) lateral reflector directs (30) the beam towards (R) a receiver.

View from above. The formation consisting of two reactors, the primary actuator (31) single-curved convex, the secondary fi-actuator (32) single-curved convex.

Near the fi actuator (31) can be seen breaking a beam of radiation (30) towards the focus (3) vertically- gives a vertical focus. The secondary refractor (32), on the other hand, breaks a beam of radiation (30) towards the focus (3) horizontally and gives a horizontal focus. (shown in fi gurll).

Side view. The invention consists of two refractors, the first refractor (3 l) single-curved convex, the secondary refraction door (32) single-curved convex.

The primary refractor (31) breaks a beam of radiation (30) towards the focus (3) vertically, which cannot be seen in the side view. The secondary fi actuator (32) refracts a beam of radiation (30) towards the focus (3) horizontally.

Perspective view. The invention consists of two refralctors, the primary ctlector (31) single-curved convex, the secondary fiactor (32) single-curved convex.

The primary refractor (31) can be seen breaking a beam of radiation (30) towards the focus (3) vertically. The secondary refractor (32), on the other hand, refracts a beam of radiation (30) towards the focus (3) horizontally.

Claims (14)

10 20 25 30 522 396 9 v u v | ø »| now Patent Claim Device (10) for angularly changing a beam (30) to a receiver (R) by means of two optical elements (12, 16, 31, 32), characterized in that the elements (12, 16, 31, 32) are single curved and have mutually crossed curved axes (14 and 18, respectively). Device (10) according to claim 1, characterized in that the axes of curvature (14, 18) are rectangularly crossed. Device (10) according to claim 1 or 2, characterized in that at least one of the elements (12, 16, 31, 32) is circularly cylindrically curved. Device (10) according to any one of the preceding claims, characterized by a reactor or reactor element (20) located between the receiver (R) and the reactor (12, 16) designed to compensate for caused by the reactors (12, 16) distortion of the beam (30). Device (10) according to any one of the preceding claims, characterized in that at least one of the reactors (12) is composed of element elements (12A; 12B). Device (10) according to any one of the preceding claims, characterized in that the elements (12B) are arranged in a plane (13), substantially according to Fresnel's principle. Device (10) according to any one of the preceding claims, characterized in that it is incorporated in an apparatus (40) for processing electromagnetic beams. Device (10) according to claim 7, characterized in that the apparatus is a telescope, binoculars, a camera or the like. characterized The device according to claim 7, in that the apparatus is a magnifying apparatus, such as a microscope or the like. Device according to one of Claims 1 to 6, characterized in that it is incorporated in an apparatus for treating mechanical beams / waves. 10 522 396 10 - | a - | e. 11. Device according to claim 10, characterized in that the apparatus is an acoustic amplifier or the like. The device according to any one of the preceding claims, characterized in that the apparatus is a lighting apparatus or the like. The device according to any one of the preceding claims, characterized in that the angular change is effected by refractors (31, 32). The device according to any one of the preceding claims, characterized in that at least one reactor part (12, 16) can be combined with a reactor part (31,32).