SI25145A - Telescopic device for picture apparatus mounting on telescope or measurement system - Google Patents

Abstract

The telescopic attachment for mounting an imaging device on a binocular or measuring system of the present invention relates to a novel product for the purpose of aiming the target, determining the frame, using a rifle shotgun or other measuring system. The user observes the target through the camera (E) screen (K) located on the base plate (4) and fixed so that the connection is fixed after shooting. The base part of the telescopic attachment (1) is attached to the rifle of the rifle or other measuring means, through the nut (2) and the adjusting sleeve (3) so that the entire system can withstand the impact of the rifle charge without having to move the joint. With the additional attachment of the rim of the binoculars (Dl) to the cone of the telescope attachment (1.3), the centered attachment of the telescopic attachment (9) to the rifle (D) is achieved. By rotating the telescopic nozzle (9) with the screwdriver (9.1), we enable the longitudinal slider (8) to adjust the correct focal length of the camera (K) along the plug (8.1). The slider of the longitudinal slider (8.1) provides the horizontal position of the camera (K) with respect to the binocular (D).

Description

Telescopic mount for mounting an imaging apparatus to binoculars or a measuring system

F41A 15/00 (2006.01)

G03B 17/48 (2006.01)

F41C 27/00 (2006.01)

F41G 1/38 (2006/01)

G03B 29/00 (2006.01)

G03B 17/56 (2006.01)

The subject of the invention is a technical system that allows very rigid installation and at the same time telescopic adjustment of focal length, camera, camera or telephone with integrated camera K, binoculars or binoculars of the measuring system or any other measuring system D, which can be mounted on: rifles, pistols , a crossbow, bow or other weapon or similar device with which we aim, through binoculars or similar system, to optically aim at a specific point, or just to observe, photograph, record a particular frame. The purpose of this technical system is for the user to observe the measurement or the target through the screen of the camera-phone E or similar. User through camera, camera, or telephone with integrated camera or K camera, via screen E connected to the lens of the camera, telephone, camera centered on binocular D through the base plate 4, which is an integral part of the weapon or measuring device device, observes the binoculars, which is magnified in this way on the screen E and is much easier to see or center.

The described system is intended to facilitate the aiming (targeting) of firearms, or other devices with which the user wants to aim at a specific point, or just to observe, document a certain frame. The present invention also provides accurate aiming or an excellent view for persons with partially impaired vision, the elderly, since the frame observed is enlarged to the screen size of the camera E, the camera or the phone with the built-in camera-camera K. In this way, the user can optically determine target as the scale is magnified, illuminated — due to the camera-phone system and can be viewed from a greater distance by the user. Compared to the use of binoculars D, without the system described above, the user must point his eye at the binoculars and adjust his binoculars, firearms, etc., according to the observed measurement. This task is difficult for older users with certain optical eye defects.

The problem solved by the described invention is that the user, even with some degree of damage to the eyes, can perfectly observe or intend to the desired destination, because the system, through the camera K, allows significantly higher resolution of the bullet - magnification of the bullet visible on the screen E Camera K. Another feature of the present invention is that the observed frame can be recorded and archived through camera K. The third and most important function of the present invention, which places it above the patented inventions in this field, which are listed below, is that cameras, cameras or phones with a built-in K camera can be mounted on different binoculars D, which means very rigid, that the limb-impulse force caused by the shot does not require the recalibration of the system, which is not the case with the known solutions described by the patents listed below, where, after each shot, a recalibration of the system, camera, camera or telephone is required with built-in camera.

Similar systems are already known as public goods or patents.

A similar technical invention of looking through binoculars is already a fairly old state of the art, as evidenced by Patent US2,933,992 of 26/04. 1960, Patents US4,290,219 of 22/09/1981, Patent US4,815,822 of 28/03/1989, Patent US6,019,326 of 01/02/2000, Patent US7,614,805 B2 of 10/11/2009, Patent US7,739,822B1 of 07/22/2010, Patents US5,026,158 of 6/25/1991. Patent: U.S. Patent Numbers 8,793,917B2 - (Date: 05/08/2014),

Patent: U.S. Patent Numbers 9,151,571B2 - (Date: 03/25/2011), Patent: U.S. Pat. Patent Numbers 20140305024 - (Date: 06/18/2014), PatenfcU.S. Patent Numbers 20130111798Date: 10.06.2011), Patent: WO2012134507 - (Date: 06/16/2011)

All of the above inventions - patents are used as a basis for looking through binoculars or bullets through a camera, or some other system, for ease of resolution for the user, or for the purpose of documenting optical frames. All of the above patented inventions use as their basis the principle of looking through a measure through an additional system, which may be a camera, a camera, other binoculars, etc., and in their upgrading they use various technical inventions of mounting cameras, cameras, phones with built-in cameras, etc., and differentiate and determine only in the various technical inventions mountings, fittings, etc. of these systems, while the technical invention looks through binoculars with a camera, a camera, a telephone with a built-in camera, etc., already known prior art, patented in 1960 by Patent PatentUS2,933,992 of: 26.04. 1960.

The technical differences between the additional adapters for mounting to the measuring systems covered by the above-mentioned patented inventions in comparison with the technical embodiments - the solutions of additional adapters for mounting to the measuring systems covered by the present patent application are the following:

All of the systems covered by the patented inventions mentioned above use simple technical solutions for attaching binoculars to the systems, namely: through clamps, through screws, via bushing with screws, via connecting split bushing.

The foregoing patented inventions utilize primitive and technically simple attachments of the camera-phone, the camera to the carrier system, which are made in a variety of simple rather than rigid ways, including by elastic-eraser mounting.

The invention is explained in more detail below with a description of the case and the accompanying drawings showing:

Figure 1: Side view of mounting the system with a phone-camera with binoculars, which is an integral part of the rifle from the rear.

Figure 2: Side view of mounting the system with a phone-camera on the riflescope, which is an integral part of the rifle, from the front.

Figure 3: Side view of the system mounting, without the carrier plate for the camera-mounted binoculars, which is an integral part of the rifle from the rear.

Figure 4: Cross-sectional side view of the system - composite bushings where the mechanics of mounting binoculars are visible.

Figure 5: Cross-section of the system without a mounting plate for telephones and without binoculars showing the mounting method of the binoculars, which may be an integral part of the rifle. The mechanics of telescopic focal length adjustment are also visible.

Figure 6: Side view of a tensile bush, which can be of different sizes of inner diameter to match different sizes of outer diameters of binoculars.

Figure 7: Side view of the system, with partial cross sections, without mounting plate and without binoculars, with partial cross sections at pin locations 8.1, guide groove 1.4 and helix-guide groove 9.1, showing the mechanics of telescopic focal length adjustment.

The present invention presented by this patent application uses a binocular D mounting system via an adjustable clamping sleeve 3, similar to the known systems for attaching tools to milling and other machine tools. A similar attachment is also used for t.i. hiking poles, which can be shortened, extended, via so-called. elastic tensile bushings. The present invention provides a technical solution for attaching a telescopic mount to a binoculars or similar measuring device of cylindrical shape. The mounting procedure is as follows:

Depending on the diameter of the binoculars D or the measuring device, we select a suitable adjusting sleeve 3 which has an inner diameter equal to or slightly larger than the outer diameter of the binoculars or measuring device to which we attach the telescopic extension 1

Unscrew the telescopic attachment 1 apart by unscrewing the nut 2 from the base of the telescopic attachment 1. Insert the selected adjustable sleeve 3, which is generally made of an elastic polymer, into the unscrewed nut 2. All other parts of the telescopic attachment 1 are generally made of aluminum alloy so that they are sufficiently rigid and light enough to be mounted on a weapon or other device. Figures 1 and 5 illustrate this.

Since the adapter sleeve 3 is symmetrical, the orientation of the insertion into the nut 2 is arbitrary. When the adjusting sleeve 3 lies in the nut 2 with its cone 3.1, it rests on the inner cone 2.1 of the nut 2,. The inner cone of nut 2 is marked 2.1.

Screw the nut 2 onto the base of the telescopic attachment 1 through the thread on the base part 1.1 and the inner thread 2.2 in the nut 2. The thread 1.1, 2.2 can be metric, trapezoidal or optional. It is desirable that the thread is made in a small step and with as little tolerance as possible. The condition is that the pitch step is at least so small that the thread connection is between the base portion of the telescopic extension piece 1 and the self-locking nut 2. Tighten nut 2 to the base of the telescopic attachment until you feel the force of the tight inner cone of the nut 2.1 on the cone of the adjusting sleeve 3.1, on the one hand, and the force of the cone of the adjusting sleeve 3.2 on the inner cone of the base part of the telescopic probe 1.2. Then print the entire telescopic attachment on binoculars D or the selected scale so that the edge of the binoculars Dl rests on the cone of the telescopic attachment 1.3. Figures 1 and 4 illustrate this. This ensures that the telescopic attachment 1 and the binoculars D are aligned, as this mounting method prevents the spacing of the longitudinal axes of the binoculars D and the telescopic attachment 1. When the telescopic base attachment 1 with the nut 2 over the inner surface of the adjusting sleeve 3 rests on the outer surface of binoculars D or another selected criterion, we continue pressing the nut 2 onto the base of the telescopic attachment 1. The nut with its inner cone 2.1, presses the cone of the adjusting sleeve 3.1, the adjusting sleeve 3, due to the principle of forces (action-reaction) , presses with its cone 3.2 onto the inner cone 1.2 of the base telescopic attachment 1. The angles of all cones, surface treatments and cone materials are designed so that they are not self-locking and allow the cone surface of the elastic sleeve 3.1 and 3.2 to slip over the surfaces of the inner cones of the nut 2.1 and the inner cone of the base part of the telescopic attachment 1. 2.

Due to the threading, due to the slippage of the surfaces of the cones of the adjusting sleeve 3.1 and 3.2 along the cones of the nut 2.1 and the cone of the base part of the telescopic mounting 1.2, it shrinks or reduces the diameter of the adjusting sleeve 3 by placing them on the outer surface of the binoculars or selected scale D on which we place telescopic measuring system (This can be seen in Figures 1,4,5). Adaptive sleeve 3 with its surface 3.3 engages on the outer surface of the binoculars and creates a force due to the compressive force achieved by turning the nut 2.

C ........;

=> ...........

friction between the inner surface of the adjusting sleeve 3 and the outer surface of the selected binoculars. This can be seen in Figure 1.

The adapter sleeve 3 is made of an elastic polymer which has a fairly high coefficient of friction. The geometry of the elastic adaptive sleeve 3 is designed to have grooves in the jacket (perimeter) that terminate in rounding to prevent the so-called. notch effect. The notches 3.3 have the function of facilitating contraction-compression of the bush 3, which is subsequently performed by tightening the nut 2 to the base part 1, where the cones 3.1, 3.2 slip over the cones 2.1 and 1.2 and the elastic adaptive bush 3, which with its internal diameter, it settles on the outer diameter of the binoculars, resulting in a close fit of all parts.

Because the elastic adaptive sleeve 3 is tightly locked into the fit with the rigid nut 2 and the rigid base part of the telescopic measuring probe 1 and at the same time the rigid edge of the binocular Dl flush with the cone of the telescopic probe 1.3, a very centric and rigid connection of the whole telescopic probe attachment system is achieved. binoculars or other measuring system to which the telescopic measuring attachment is mounted. Due to this very rigid connection, the axis of the telescopic mount and the binoculars axis, even after the lightning-pulse force, are always in the same axis. Due to the very high friction force between the telescopic measuring probe and the binoculars, no re-correction of the telescopic probe is necessary even after repeated firing.

Base plate 4 has the function of installing a camera, camera or phone with a built-in recording system as shown in Figures 1 and 2. The selected base plates may be more than one another, but may differ only in the size and shape of the adjusting slots 4.1, that we can mount as many known camera systems, cameras, phones with built-in cameras as possible.

The base plate 4 is attached to the longitudinal slider 8 by four screws 6, which allow a very rigid connection of the two parts.

Base plate 4 has grooves 4.1 for mounting lugs 5 that are movable in grooves in order to adjust the optimum position for attaching a camera, camera or phone with a built-in camera to the base plate 4, which is determined by the optical beam passing through binoculars centered with camera, camera or phone optics with integrated camera.

Base plate 4 has at least one or more openings 4.2 provided for view of a camera, camera or telephone with a built-in camera through the hole of the telescopic mount and forward through binoculars or other measuring device. This is shown in Figure 2.

c .........

o · * · · ··· «

If the base plate has more openings for the camera, it also has holes for fixing it with screws 6 to the longitudinal slider 8. More than the openings for the camera, more different mounting positions on the longitudinal slider 8 are possible, and consequently, as many different mountings as possible Cameras, Cameras or Phones with Integrated Camera 7 on the Base 4.

The mounting nuts 5 are made of screw 5.1 and nut 5.2, which are secured in slot 4.1 according to the desired position. Twist the mounting nut 5.3 to the tightened screw 5.1, which is used to secure the camera, camera or phone with the built-in camera to the base plate 4. The mounting nut 5.3 is generally made of polymer and can have a softer surface on the underside to avoid damaging the camera surface of the camera. or a phone with a built-in camera. Figures 1 and 2 show the attachment of a phone with a built-in camera to the base panel 4.

The mounting nuts 5 can also be used without the mounting nut 5.3. In this case, tighten the mounting screw 5.1 with nut 5.2 to a position to support the phone or the camera K in a direction complementary to the plane of the base plate 4. This achieves a geometric fit of the phone with the built-in camera K on the base plate 4. The optional 5.3 mounting nuts, which can be used as an attachment, serve to attach the phone with a built-in camera K in a perpendicular direction from the base plate 4. Figure 1 and figure 2 show the matching of the phone with a built-in camera K to the base plate 4 via the mounting pins 5 using the mounting pins 5 nuts 5.3 and without.

Figure 3 shows a system without a baseplate. In this figure, holes are shown with internal threads 6.1 in the longitudinal slider 8 through which, using screws 6, screw the base plate 4 to a position corresponding to the selected phone with a built-in camera K to allow projection of the measuring binoculars D on the screen of the telephone E and thereby enlarge the measuring binoculars D to make it easier to center the desired destination.

As a rule, the mounting brackets 5 are at least three in order to achieve a statically fixed stability of mounting the camera to the base plate 4. However, there may be more than one (camera geometry). This application and figures show a construction with four mounting brackets. The present invention eliminates the shortcomings of the presently known inventions and the prior art in this field, since it enables very precise mounting, enables the so-called. AB's Principle of Mounting - One Axis of Mounting and Looking. At the same time, using different geometries of the base plates 4 and mounting screws 5, it allows the mounting of almost all known cameras, cameras, phones with a built-in camera that can be used for such purposes. By selecting different internal diameters of elastic bushings 3, it is possible to mount on almost all known binoculars, and the mounting is so rigid that it does not need to be adjusted after firing. The system can be easily installed and also easily removed from binoculars D or any other measuring system. By rotating the bushing 9 with the self-locking helix 9.1, the longitudinal slider 8 is moved along the optical axis to adjust the correct focal length of the camera K with respect to the binoculars D. Due to the self-locking of the helix, which is obtained by choosing a helix angle of inclination less than the self-locking-angle of the material plugs and screws, the camera position remains unchanged after the shoot. Maintaining the horizontal-rotational orientation of the plate 4 with respect to the binoculars D is provided by a longitudinal groove 1.4, which is made in the base part 1, in which the plug 8.1 travels, which also travels through the helix 9.1 embedded in the sleeve 9.

The principle of operation of this mechanics is as follows:

When the sleeve 9 is rotated toward the base part 1, it presses the plug 8.1 onto the edge of the helix-guide groove 9.1. For this reason, the helix-guide groove 9.1, depending on the geometry of the climb, pushes or pulls the plug 8.1 longitudinally along the axis of the bushing 9, left or right, depending on the direction of rotation of the bushing 9. That the plug 8.1, which is attached to the longitudinal slider 8, does not rotate about the axis of the longitudinal slider 8 preventing the groove 1.4, which is made in the base part 1 so that the plug 8.1 can travel freely-glide thereon. The plug 8.1 has two functions, namely, to allow the longitudinal displacements of the bush 9 and to keep the longitudinal slider rotating about its axis.

In order to rotate the sleeve 9, it performs the basic movement of pushing the longitudinal slider 8, through the guide groove 9.1 and through the pin 8.1, without the sleeve 9 traveling longitudinally along the axis, preventing the seals 9.2 and 9.3 which, when moved, are seated on the edges of the base part 1 and prevent the sleeve 9 from moving along the axis due to rotation. In this way, the sleeve 9 is secured through the helix-guide groove 9.1 and the plug 8.1, which is attached to the longitudinal slider 8 and at the same time guided-travel through the groove 1.4, which is made in the base part 1 and when the sleeve 9 is stationary, respectively. is rigidly coupled to binoculars D, moving only longitudinal slider 8 longitudinally.

The geometry of the rise of the helix-guide groove 9.1 is designed in such a way that self-confidence is achieved by taking into account the coefficient of friction between the edges of the helix-guide groove 9.1 and the edges of the stud 8.1. In rough terms, the helix angle of inclination should be less than 4 degrees. Of course, it can also be greater if we choose materials that have a higher coefficient of friction than steel.

Claims (19)

A telescopic mount for mounting an imaging apparatus to binoculars or a measuring system, characterized in that it consists of a base telescopic attachment (1), a rigid nut (2), an elastic adjusting sleeve (3) of the base plate (4) with fixing screws (5 ), (5.1), nuts (5.2), (5.3), bushes (9) with a screwdriver (9.1) and a longitudinal slider (8) with a longitudinal channel (1.4.) Into which a plug (8.1) is mounted, which is at the same time screwed into the helix (9.1). 2. A telescopic mount for mounting an imaging apparatus to a binoculars or measuring system according to claim 1, characterized in that, by a torque of 0.5 Nm or more, the rigid nut (2) is threaded (2.2) with its cone (2.2). 2.1) presses on the cone (3.1) of the elastic adaptive sleeve (3), and as a reaction of this force presses the cone of the rigid base part (1.2) equally on the opposite cone (3.2) of the elastic adaptive sleeve (3), thereby creating an axial force in the sleeve (3). Telescopic attachment for mounting an imaging apparatus to a binoculars or measuring system according to claims 1 and 2, characterized in that the angles of the cones (2.1). (3.1), (1.2), (3.2) are always identical-alike and can be contoured within angles of 80 to 20 degrees and a bearing length of 2 to 15mm. Telescopic attachment for mounting an imaging apparatus to a binoculars or measuring system according to claims 1 and 2 and 3, characterized in that the surfaces of the cones (1.1,2.2, 3.1, 3.2) are made at least with a degree of smoothness of the surface N5, which enables , that, at the axial pressure on the cones, which is produced by pushing the rigid nut (2) along the thread of the nut (2.2) with a torque of more than 0.5N / m, the cones slip together and cause radial forces in the elastic adjusting sleeve (3) which seeks to squeeze the elastic adjusting sleeve (3) to a smaller diameter. Telescopic attachment for mounting an imaging apparatus to a binoculars or measuring system according to claims 1 and 4, characterized in that the surfaces of the cones (1.1, 2.2, 3.1, 3.2) are made at least with a degree of smoothness of the surface N5, which allows , at the axial pressure on the cones, which is created by pushing the nut (2) along the thread of the nut (2.2), with a torque greater than 0.5N / m, the cones slip together and cause radial forces in the rigid nut (2) which seeks to extend the rigid nut (2) to a larger diameter. 6. A telescopic mount for mounting an imaging apparatus to a binoculars or measuring system according to claim 1,2 and 4, characterized in that the elastic adjusting sleeve (3) is made of elastic material and has additionally designed longitudinal notches (3.3) which make under the influence of a small radial force on the sleeve (3), resulting, even with minimal nut pressure (2), due to the distribution of forces in the cones (1.1,2.2, 3.1 and 3.2), it can easily shrink and with its inner surface to the outer surface of the binoculars (D). Telescopic attachment for mounting an imaging apparatus to binoculars or a measuring system according to claims 1,4 and 6, characterized in that the rigid nut (2), a pressurized elastic adaptive sleeve (3), with its inner surface, is supported by a relatively large the radial force on the outer surface of the binoculars (D) or other cylindrical measuring system and, because of this force and the friction coefficient between the contact surfaces, creates a very large friction force that causes a very rigid connection of the bush (3) and the binoculars (D) in all directions. 8. A telescopic mount for mounting an imaging apparatus to a binoculars or measuring system according to claim 1, 4 and 6, characterized in that the rigid nut (2), a pressurized elastic adjusting sleeve (3), with a relatively large contact surface radial force on the outer surface of the binoculars (D) or other cylindrical measuring system, while generating very high friction force between the cones (1.1, 2.2, 3.1 and 3.2) which, due to the friction coefficient between the cone surfaces, causes a very rigid connection of the bush (3 ), nuts (2) and basic work (1). • · 10 * * ·· ·· * · ». _a 9. A telescopic mount for mounting an imaging apparatus to a binoculars or measuring system according to claim 1, characterized in that the base plate (4) is screwed onto the longitudinal slider (8) via threads (6.1) by four screws (6). Telescopic attachment for mounting an imaging apparatus to a binoculars or measuring system according to claims 1 and 9, characterized in that the base plate (4) has holes made (6) symmetrically over the axis of the aperture (4.2) which makes it capable of mounting in two different positions, with a displacement of 90 degrees about the longitudinal axis of the entire assembly, to the base portion of the longitudinal slider (8). Telescopic attachment for mounting an imaging apparatus to a binoculars or measuring system according to claims 1 and 9, characterized in that the base plate (4), at any places, may have one or more openings (4.2) with associated holes (6) ) for any mounting of the base plate (4) to the base part of the longitudinal slider (8). Telescopic mount for mounting an imaging apparatus to a binoculars or measuring system according to claims 1 and 9, characterized in that the base plate (4) has grooves (4.1), in any places and in any number, which can be freely moved fix the mounting nuts (5) in the desired position with the nut (5.2) to achieve a rigid connection. 13. A telescopic mount for mounting an imaging apparatus to a binoculars or measuring system according to claims 1 and 12, characterized in that the mounting nozzles (5) may also be provided with mounting nuts (5.3) having a soft washer on the lower surface through which pin a camera, camera or phone with a built-in camera (K) to the base panel (4) Telescopic mount for mounting an image apparatus to the binoculars or measuring system according to claims 1 and 13, characterized in that the mounting nuts (5.3) are made at least 15 mm in diameter so that they can be clamped freely on the camera, camera or phone with built-in camera (K), to such an extent that the attachment • · 11 .. ** ·· · li ·· ·· ♦ · · Ζ. withstands the force of lightning without moving the camera or phone with the built-in camera (K) towards the base panel (4). Telescopic attachment for mounting an imaging apparatus to a binoculars or measuring system according to claim 1, characterized in that a longitudinal movement of the longitudinal slider (8) is achieved by rotating the sleeve (9) with a screwdriver groove (9.1) through the stud (8.1). ) along the length of the groove of the base (1.4), to the correct focal length of the camera or phone with the built-in camera (K) against the binoculars (D), without changing the rotational alignment of the camera or phone with the integrated camera (K) relative to the binoculars (D) ), which allows the longitudinal slider (8.1) to be caught in the groove of the base part (1.4). Telescopic mount for mounting an image apparatus to a binoculars or measuring system according to claims 1 and 15, characterized in that, due to the need for self-locking of the longitudinal slider (8), in the axial direction, by the helix (9.1) in the sleeve (9) , which is made with a helix angle (9.1) less than the self-adhesion angle applicable to the helix material (9.1) against the plug material (8.1) in question and is estimated to be less than 7 degrees. Telescopic mount for mounting an image apparatus to the binoculars or measuring system according to claims 1 and 16, characterized in that, when selected as a helix (9.1) of less than 4 degrees, the longitudinal slider (8.1) can be supported by a ball or sliding bearing , about its center axis. Telescopic mount for mounting an image apparatus to a binoculars or measuring system according to claim 1,15 and 17, characterized in that the width tolerance of the longitudinal channel (1.4) with respect to the diameter of the stud (8.1) determines the free rotations of the base plate (4) against binoculars (D) around the center axis. 19. Telescopic mount for mounting an image apparatus to a binoculars or measuring system according to claim 1,15 and 17, characterized in that it determines the tolerance of the width of the helix (9.1) with respect to the diameter of the stud (8.1), the free rotation about the center axis and the longitudinal movements base plates (4) against binoculars (D).