RU2129695C1 - Device for sighting - Google Patents

Abstract

FIELD: shooting, tuning of geodesic and measuring equipment. SUBSTANCE: weapon is equipped with differential processor, which is designed as mechanical calculation device with at least one working member. Serial sequence of working members provides their rigid connection. Working members are designed as deformed mechanical members, which longitudinal or cross shape depends on required adjustments and corrections using differential equation for relation of deformations of selected group of points of working member. This device is designed as either part of sighting system or part of its body. EFFECT: increased precision of sighting adjustment and adding corrections upon shooting, simplified design, decreased weight and size of sight. 5 cl, 5 dwg

Description

 The invention relates to guidance systems. Devices built in accordance with the invention may be the basis for the construction of metrological and geodetic instruments, sights for artillery and small arms, hunting, sports and game weapons and the like.

 Classic optical sights are widely known, including the mechanism for mounting the sight with a seat on the weapon and the sighting part forming the image of the aiming mark in the vicinity of the target image considered by the eye.

 It is significant that the adjustment of the direction of sight (the angular position in the space of the aiming object or the image of the aiming object taking into account its angular optical magnification at the time of the decision to correctly point the weapon at the target of an imaginary line connecting the center of the pupil of the eye of the shooter and the aiming point of the image of the aiming mark, on which aiming is performed) in such sights is carried out by shifting the reticle in the focal plane of the eyepiece. See, for example, US Patent N 4373269 "Adjustment Mechanism" 1983.

где Δγ - точность (дискретность) изменения направления визирования (например, по вертикали);
Δt - точность (дискретность) изменения положения прицельной сетки (соответственно тоже по вертикали);
f'_e - фокусное расстояние окуляра или эквивалентное фокусное расстояние окуляра и оборачивающей системы (в зависимости от места установки прицельной сетки в телескопической системе прицела и типа оборачивающей системы);

видимое увеличение оптического прицела.Such a constructive solution to the problem of reconciling the sight on the weapon and introducing angular corrections to the target parameters without using cam and other gears that transform the movement of the organs (handles) of introducing amendments and / or reconciliation of the sight (controls) does not allow
1. with the dimensions of the sight mounted on a particular type of weapon, less than the distance between the elements of a mechanical sight (whole and front sight) used on this type of weapon, and with final movements of the controls (which can be measured a) using linear displacement measuring instruments with with a division value of at least 10 μm or b) using instruments for measuring angular displacements with a division value of at least 1 ^o - one angular degree) provide arbitrarily small (of the order of 2 '' - two angular seconds) changes in the direction of the visa really

where Δγ is the accuracy (discreteness) of the change in the direction of sight (for example, vertically);
Δt is the accuracy (discreteness) of the change in the position of the reticle (respectively, also vertically);
f ' _e is the focal length of the eyepiece or the equivalent focal length of the eyepiece and the wrapping system (depending on the installation location of the reticle in the telescopic sight system and the type of wrapping system);

visible increase in the optical sight.

= 1, f'_e = 100 мм и Δγ = 2'' (≈ 0,00001 рад) Δt должно быть равно 1 мкм, что с учетом реальных конструкций механизмов тонкой подачи, существующих в них люфтов и упругих деформаций невыполнимо, даже при использовании дифференциальных винтовых передач;
2. обеспечить требуемую функциональную зависимость изменения направления визирования от поворота органов управления
Θ(γ,χ) = F(φ₁,φ₂..,φ_n), (2)
где Θ(γ,χ) - изменение направления визирования;
γ - угол между осью канала ствола оружия и воображаемой линией, соединяющей центр зрачка глаза стрелка и прицельную точку изображения прицельного знака, по которому осуществляется прицеливание (линией визирования) в момент принятия решения о правильном наведении оружия;
χ - угол между вертикалью и радиус-вектором, проведенным из контрольной точки (точки в плоскости цели, на которую осуществлялось наведение оружия) к средней точке поражения (точке в плоскости цели, являющейся среднеквадратическим центром попадания после принятия решения о правильном наведении оружия) в момент отстрела оружия с установленным на него прицелом;
φ₁, φ₂.., φ_n - углы поворота органов управления;
n - количество органов управления; что очевидно.Then, for example, for

= 1, f ' _e = 100 mm and Δγ = 2''(≈ 0.00001 rad) Δt should be equal to 1 μm, which, taking into account the real structures of the fine feeding mechanisms, the backlash and elastic deformations existing in them, is impossible, even when using differential helical gears;
2. provide the required functional dependence of the change in direction of sight on the rotation of the controls
Θ (γ, χ) = F (φ ₁ , φ ₂ .., φ _n ), (2)
where Θ (γ, χ) is the change in the direction of sight;
γ is the angle between the axis of the channel of the barrel of the weapon and the imaginary line connecting the center of the pupil of the eye of the shooter and the aiming point of the image of the aiming mark along which the aiming is carried out (line of sight) at the time of the decision on the correct aiming of the weapon;
χ is the angle between the vertical and the radius vector drawn from the control point (point in the plane of the target to which the weapon was guided) to the midpoint of the lesion (point in the plane of the target, which is the root-mean-square center of hitting after deciding to correctly point the weapon) shooting weapons with a sight mounted on it;
φ ₁ , φ ₂ .., φ _n - rotation angles of the controls;
n is the number of controls; which is obvious.

 The well-known VGA-50 sight (see, for example, ZAO "R.O.S. GiH", "The night assault sight VGA-50" Operating Instructions, Moscow, 1996, 16 pages), including the mechanism for attaching the sight with a seat on the weapon and the target part, forming the image of the sighting mark in the vicinity of the target itself.

 This sighting device can be mistaken for a prototype.

 It is significant that the correction of the direction of sight in this sight is carried out by angular displacement of the sighting part relative to the seat on the weapon of the mounting mechanism when it is rotated by the controls with respect to the vertical and horizontal axes of rotation.

где Δγ - смотри выше;
p - шаг резьбы винта подачи органа управления;
l - расстояние от оси вращения визирной части до упора в нее толкателя органа управления;
N - число отслеживаемых перемещений рукоятки органа управления (например, число щелчков за один оборот).Such a constructive solution to the problem of reconciling the sight on weapons and introducing angular corrections without the use of gears that transform the nature of the movement of the controls, as well as in the case of classical optical sights (see also the description of classical optical sights above), does not allow
1. with limited dimensions of the sight and the final movements of the controls to provide arbitrarily small changes in the direction of sight, indeed

where Δγ - see above;
p is the thread pitch of the feed screw of the control;
l is the distance from the axis of rotation of the sighting part to the stop in it of the pusher of the control;
N is the number of tracked movements of the control handle (for example, the number of clicks per revolution).

Then, for example, at l = 35 mm (VGA-50), N = 80 (VGA-50) and Δγ = 2``p should be approximately equal to 0.03 mm, which, taking into account real loads on the alignment mechanism, is unacceptable;
2. provide the required functional dependence (2) changes in the direction of sight from the rotation of the controls.

The invention is aimed at solving problems
1. improving the accuracy of adjusting the direction of sight necessary for aligning the sight on the weapon and / or introducing amendments to the target parameters and external conditions (adjustments),
2. reducing the dimensions (and hence the weight) of the aiming devices while maintaining the accuracy of the adjustment necessary to ensure the alignment of the sight on the weapon in accordance with the parameters of the latter and the introduction of amendments in accordance with the probability of the target being used by the type of weapon used,
3. simplifying the design of the sight (reducing the number of parts, their technological simplification and so on) while ensuring the required functional dependence of the change in the direction of sight on the rotation of the controls,
4. reduce the level of requirements for the physico-mechanical properties of the materials used in the sight,
5. weakening the requirements for stiffness and strength of the place on the weapon intended for installation of the sighting device, while maintaining the accuracy of the weapon-sight system,
6. increase the reliability of the sights while reducing their cost.

 The claimed technical result according to the invention is achieved as follows.

 1. In the sighting device containing the mounting mechanism (part or assembly, or an element of the sighting device housing), defining the position in the space of the seat for mounting on the weapon, and the sighting part forming the image of the sighting mark in the vicinity of the target or its image, the following distinctive attribute: it is equipped with a mechanical differential processor (a mechanical computer with one or more sequentially mechanically rigid - excluding all six degrees of freedom of mutual movement - contact interacting with each other working bodies - deformable mechanical elements, the longitudinal and / or cross-sectional profiles of which are determined on the basis of the required bend, see below, solving the differential equation for the connection of deformations (see, for example, V.I. Feodosiev, "Resistance of materials", Moscow, Nauka, 1986, pages 133-189), located between the attachment mechanism and the sighting part and configured to bend at least one of its working bodies to change the angular position of the sighting part relative to said of the seat.

 2. The following distinctive feature is introduced into the sighting device according to claim 1: the mechanical differential processor is made as a separate component of the sighting device or as a part of its body.

 3. The sighting device according to paragraphs. 1 or 2, the following distinctive feature is introduced: between the fastening mechanism and the selected fragment of the mechanical differential processor, a rigid mechanical contact (contact) that excludes all six degrees of freedom of mutual movement of the contacting bodies is provided, the contact is also provided between a different (different from the previous) selected fragment of the mechanical differential processor and the target part, the contacts of the mechanical differential processor with the target part and the mounting mechanism are possible Stu angular displacement reticle portion relative to said seat at a bend working of the mechanical differential processor.

 4. The sighting device according to paragraphs. 1 or 2 or 3, the following distinctive feature was introduced: the length and / or profile of the longitudinal and / or cross section of the working bodies of the mechanical differential processor are made in accordance with the required functional dependence of the magnitude and direction of the angular displacement of the sighting part on the amount of translational and / or rotational movement of the additionally introduced reconciliation bodies and / or amendments.

 5. The sighting device according to paragraphs. 1 or 2 or 3 or 4, the following distinctive feature was introduced: the places of said contact of the working bodies of the mechanical differential processor with each other and / or with the sighting part and / or with the mounting mechanism are made in accordance with the required functional dependence of the magnitude and direction of the angular displacement of the sighting part on the amount of translational and / or rotational movement of the additionally introduced reconciliation organs and / or amendments.

 Currently, as a result of the analysis of all information publicly available on the territory of the Russian Federation, the applicant is not aware of sighting devices that have signs that are distinctive in the claimed invention, that is, these solutions are new. The inventive variant of the sighting device has an inventive step, since for a specialist these technical solutions do not explicitly follow from the existing level of technology. The authors proactively conducted theoretical and experimental studies, which allowed to identify the distinguishing features that ensure the achievement of the above technical result.

 Figure 1 presents a side view of an embodiment of the sight GS-5 (development 1997), which implements the invention.

 In FIG. 2 is a rear view of the GS-5, in which the presented invention is implemented.

 In FIG. 3 is a top view of the GS-5, in which the invention is implemented.

 In FIG. 4 is a front view of a GS-5 in which the present invention is implemented.

 In FIG. 5 is a bottom view of an embodiment of the GS-5 in which the present invention is implemented.

 An embodiment of the GS-5 sight, which implements the presented invention (Figs. 1, 2, 3, 4, and 5), is given to explain the principle of constructing a differential processor. The drawings show the sighting part 6, the seat on the weapon of the mounting mechanism 7, the mounting mechanism 8, the locking screw of the mounting mechanism 9, the first working body of the differential processor 2, the contact point of the first working body with the second working body 11, the contact point of the second working body with the mechanism mounting 1, the second working body of the differential processor 10, bending in place 12, the contact point of the sighting part with the second working body 3, the control 4 and the control 5.

 In 1997, the authors proactively developed and in 1998, together with the Main Directorate of Combat Training of the Armed Forces of the Russian Federation (GUBP Armed Forces of the Russian Federation) tested the GS-3 sight in a standard position for mounting the optical sights of the AK-74 assault rifle, constructed in accordance with the claimed invention. According to the test results approved (08.07.98 Head of the Main Directorate of Civil Defense of the Armed Forces of the Russian Federation, Colonel General A. Golovnev) Act "Evaluation tests of prototypes of collimator sights with a marker of models 1993 and 1997 - VGA-50 and GS-3." Physical modeling has confirmed the feasibility of the present invention. At the same time, the results expected from the implementation of the inventions related to accuracy, functional dependence (see above) and so on were confirmed.

 In FIG. 1 to 5 depict another embodiment of the sight, which implements the invention. This sight (model GS-5) is intended for installation on the aiming strip of the AK-74 assault rifle. The essence of the differential processor used in it is as follows. The sighting part of the sight 6 is mechanically rigidly mounted at the contact point 3 on the working body of the differential processor 10, the bend of which in place 12, introduced by the rotation of the control 5, provides an angular displacement of the sighting part horizontally relative to the seat on the weapon 7 of the mounting mechanism 8, blocked by a screw 9 . On the other hand, the working body of the differential processor 10 is mechanically rigidly connected to another working body 2 at the point of contact 11. The bending of the working body 2 along the entire length except for a thickened is the contact with the operating body 10, rotating body input control section 4, provides angular displacement of the target plate portion vertically relative to the seat fixing mechanism for a weapon. In turn, the working body 2 is mechanically rigidly connected to the fastening mechanism at the point of contact 1.

 From FIG. 1 to 5 shows that the implementation of the invention will allow to obtain a technical result, which can be expressed by the following design characteristics and features of sighting devices.

 1. The achievable accuracy of sight alignment on weapons is theoretically unlimited. Indeed, the displacement, for example, of the contact point 11 of the working bodies 2 and 10 with each other in the direction of the control 5 will allow to arbitrarily reduce the angular displacement of the sighting part vertically relative to the seat on the weapon of the fastening mechanism at a given offset (rotation) of the control 4. The same result can be obtained by increasing the rigidity of the base of the working body 2 (which in the drawing has a triangular profile) or by increasing its length. In the sight shown in FIG. 1 - 5, vertical alignment accuracy - 0.1 TD, horizontal - 0.5 TD.

 2. The approximate dimensions (length) and weight of the sighting device as part of the housing, the mounting mechanism with a seat on the weapon, the target part, as well as the differential processor (see below), providing the deviations of the midpoint from the control point required by the type of weapon (see above) when working with pistols (PM type) and submachine guns - 20 mm, 30 g; when working with machine guns (type AK-74) - 40 mm, 50 g; when working with sniper rifles (type SVD) - 80 mm, 80 g. So, the dimensions of the sight shown in FIG. 1, 2, 3, 4 and 5 are equal to 25 • 40 • 15, and its weight in the metal case is 30 g, plastic - 15 g.

 3. The type of functional dependence of the change in the direction of sight on the rotation of the controls - theoretically any. Indeed, the type of profile shape of the working bodies determines the type of their bend, which in turn determines the angular displacement of the sighting part relative to the seat on the weapon of the alignment mechanism. Therefore, by setting the profile shape, it is possible to predetermine the functional dependence. So, in the sight shown in FIG. 1 - 5, the profile shape of the working bodies of the differential processor was chosen from the following considerations: working body 10 - so that between the rotation of the control 5 and the angular displacement of the sighting part horizontally relative to the mounting position on the weapon of the mounting mechanism there is a linear relationship; working body 2 - so that between the rotation of the control 4 and the angular displacement of the sighting part vertically relative to the seat on the weapon of the fastening mechanism there is a complex power dependence, which involves a) by introducing residual deformations of the working body 2 of the alignment sight on the weapon and b) by rotating the body control - the introduction of amendments to the range to the target. Information on the magnitude of the corrections corresponding to the preset movements of the controls turns out to be “wired” into the profile form of the working bodies.

 4. The material from which 90% of the scope is made can be plastic, which is obviously based on the mass (and therefore, based on the moment of inertia) of the sight.

 5. For the same reasons, the sight can be mounted on movable slide frames.

 6. Estimated cost of sights - 5 ... 50 US $ depending on the type of weapon for which they are intended. From FIG. Figures 1 to 5 show that the entire scope consists of 5 parts — three titanium screws, a plastic case and a target part — an LED target designator with a remote marker. The working bodies of the differential processor of this sight are parts of the body. The cost of its manufacture in mass production is 10 US $.

Claims (5)

 1. The sighting device containing the mounting mechanism (part, or assembly, or element of the body of the sighting device), which sets the position in the space of the seat for mounting on the weapon, and the sighting part forming the image of the sighting mark in the vicinity of the target or its image, characterized in that it is equipped with a mechanical differential processor located between the mounting mechanism and the sighting part and configured to bend at least one of its working body to change the angular position the position of the sighting part relative to said footprint.  2. The device according to p. 1, characterized in that the mechanical differential processor is made as a separate component of the sighting device or as part of its body.  3. The device according to claim 1 or 2, characterized in that between the fastening mechanism and the selected fragment of the mechanical differential processor provide rigid mechanical contact (contact) excluding all six degrees of freedom of mutual movement of the contacting bodies, the contact is also provided between another (different from the previous) the selected fragment of the mechanical differential processor and the sighting part, the contacts of the mechanical differential processor with the sighting part and the mounting mechanism are performed with possibly Tew angular displacement reticle portion relative to said seat at a bend working of the mechanical differential processor.  4. The device according to claim 1, or 2, or 3, characterized in that the length and / or profile of the longitudinal and / or cross section of the working bodies of the mechanical differential processor are made in accordance with the required functional dependence of the magnitude and direction of the angular displacement of the sighting part on the magnitude translational and / or rotational movement of additionally introduced reconciliation organs and / or amendments.  5. The device according to claim 1, or 2, or 3, or 4, characterized in that the places of said contact of the working bodies of the mechanical differential processor with each other, and / or with the sighting part, and / or with the mounting mechanism are made in accordance with the required functional dependence of the magnitude and direction of the angular displacement of the target part on the size of the translational and / or rotational movement of the additionally introduced reconciliation and / or correction organs.

Images