RU2122701C1 - Self-deploying shield - Google Patents

Abstract

FIELD: means of individual protection of personnel of militia, troops of the Ministry of International Affairs, armed forces and other persons used whenever necessary. SUBSTANCE: the shield is made of rigid protective segments with preset resistance to impacts, interconnected for turning through a preset angle by means of a spring-loaded rod hinge joint, whose axle is made in the form of a torsion spring whose ends are engaged with sections of the respective adjacent protective segments. The shield is furnished with rotary retainers of the protective segments, two belts for attachment on the person and elastic shock-absorbing components. EFFECT: enhanced reliability of individual protection, compact in the initial position and quickly deployed in case of necessity, enhanced resistance and high shock- absorbing capability to impacts of rigid bodies. 6 dwg

Description

 The present invention relates to personal protective equipment of militia, internal troops, armed forces and other persons, if necessary.

 Numerous designs of safety shields and protective shields of various types are known [1, 2], designed to protect both individual military personnel and personnel of calculations. The police units (and the police) now also use rigid shields of a similar design, the use of which requires one of the two hands of the defender.

 The closest in the set of features to the analogue is the folding design of the safety shield [3], which includes several rigid sector protective segments connected to each other on the sleeve with the possibility of rotation by a given angle. Among the advantages of the design of this shield should be attributed to compactness in the folded (i.e., initial) state, and among the disadvantages is the limited scope due to the type of constructive use, low cushioning ability of the shield and the need for its forced deployment.

 The task for which the proposed design of the self-deploying shield is intended is to provide individual protection for personnel, protection compact in the initial position and quickly deployed if necessary, protection having a given resistance and high shock absorbing ability to shock solid bodies.

The achieved technical result, in addition to the functionality listed above, is that the following tactical and technical advantages are provided:
- since the design of the shield is fixed to the body with the help of straps, the defender now has both hands free and, consequently, his functionality has been significantly expanded;
- with the shield on, both folded and unfolded, you can sit and lean, and even when folded, the shield already protects a certain and significant part of the body;
- high speed of self-deployment of the shield, since its design is deployed due to the stored in advance (when it is rolled up in the initial position) energy of elastic torsion springs simultaneously in two opposite directions;
- the design of the shield allows you to set it in a multifaceted shape, all the faces of which are located at certain angles to the vertical plane, which greatly increases both the rebounding and the shock-absorbing ability of the structure.

 The indicated technical results are achieved in that the self-expanding shield comprising rigid protective segments connected to each other with the possibility of rotation by a predetermined angle is made as follows: it is made of two parts assembled from the protective segments, one smaller and the other larger, respectively, and each attached to opposite ends of the main protective segment, the upper of the larger longitudinal segments being made of two lateral and middle separate protective of the gaps located butt to each other, each of the protective segments is connected to neighboring segments by means of a spring-loaded ramrod swivel, the axis of which is made in the form of a torsion spring, interacting with its end sections respectively with adjacent protective segments, and provided with outwardly curved sections adjacent to the ramrod hinge connections, while the shield is equipped with rotary latches of the protective segments, connected to the main protective segment, two belts, attached bubbled to main protective segment, and dampers resiliently-elastic elements, one of which is attached to the rear side of the main protective segment over its entire surface, and the other to the upper portions of the outer surface of the belts.

 The essence of the design of the self-expanding shield is illustrated by drawings, where in FIG. 1 shows a longitudinal section of an unfolded shield located on the body of the defender (the dimensions of the folded shield are conventionally shown by dashed lines); in FIG. 2 shows an enlarged image of a longitudinal section of a rolled shield; in FIG. 3 shows an enlarged image of two projections of a spring-loaded ramrod swivel joint of two adjacent shield shield segments; in FIG. 4 shows a front view of the deployed shield located on the body of the defender; in FIG. 5 shows a longitudinal section of an unfolded shield, which is given a convex polyhedral shape, all faces of which are oriented at certain angles to a vertical plane; in FIG. Figure 6 shows an enlarged image of the upper of the protective segments of the shield, which is made of separate middle and two side segments located butt to each other (front view, when all three separate segments are brought together in the same plane - with the hands of the defender - before folding the shield into its original position).

 The design of the self-expanding shield includes (see Fig. 1, 2, 4, 5) the main protective segment 1, which is made the largest in longitudinal size (i.e., vertically), in fact, its longitudinal size is equal to the sum of the sizes of the larger and smaller segments and It is the main structure of the shield, since the rest are attached to it - deployable protective segments and all other auxiliary elements. To the lower horizontal end face of the main segment 1 is attached the lower part of the shield developing downward, assembled from the protective segments 2, 3, 4 connected to each other and having a correspondingly smaller longitudinal dimension. Another, expanding up part of the shield, is attached to the upper end of the main protective segment 1 and is assembled from protective segments 5, 6, 7, made respectively of a larger longitudinal size, and the upper of the protective segments of the shield is made (see Fig. 1, 4, 6 ) of three separate protective segments located end-to-end to each other: middle 7, protecting the neck and lower part of the face, and for the lateral 8 shoulder segments. It should be noted that the middle protective segment 7 can also be made slightly smaller in longitudinal (i.e., vertical) size, since a helmet with a transparent visor is usually worn on the head of the defender.

 All protective segments of the shield are equipped with integral sections 9 which are made integral with them during manufacture (hollow bent and bent at a given angle) adjacent to their ends, respectively, through which the protective segments are connected to each other via rod-shaped [4] hinge joints 10 to a friend. The axis 11 of each ramrod swivel 10 is made of spring steel in the form of a torsion spring 11, the end sections of which are bent when the shield is assembled at predetermined angles in predetermined planes (see Fig. 3) and connected, for example, by plates and rivets, respectively, to adjacent protective segments. The equilibrium (i.e., not deformed) state of the elastic torsion springs 11 is set such that it corresponds to the unfolded (see Fig. 1, 2, 4, 5) state of the shield structure, and when the protective segments are rotated to fold the shield to its original position (see Fig. 2) or when the protective segments are rotated relative to each other due to the impact of the shock load, the elastic torsion springs 11, interacting with their end sections with the corresponding segments, twist, accumulating energy for subsequent deployment segments of the shield at the right time or absorbing impact energy. Those. each torsion spring 11 is both a connecting element - the axis of the ramrod swivel joint 10 and a deploying element of the protective segments of the self-expanding shield structure, and a shock-absorbing element of each of the deployable shield shield segments.

The design of the shield is equipped (see Fig. 1, 2, 4, 5) with two latches 12, the purpose of which is to hold the protective segments 2, 3, 4, and 5, 6, 7, 8 of the two deployable parts of the shield in collapsed (see Fig. . 2) position, i.e. pressed to the outer surface of the main protective segment 1. The latches 12 have a T-shape and can, for example, be made rotatable around its axis and attached in place to the main protective segment 1 also by means of a hinge, which allows them to be rotated downward by 90 ^o and adherence to the surface of the main segment 1 in the free position and excludes the possibility of their mechanical damage when struck by heavy objects. The directions of rotation of the latches 12 are conventionally shown by arrows (see Fig. 4, 5), and the latches 12 themselves are shown in a raised (horizontal) position corresponding to their position before fixing the folded protective segments 2, 3, 4 and 5, 6, 7, 8 relative to the main protective segment 1.

 The design of the shield is equipped (see Fig. 1, 2, 4, 5) also with two belts attached to the main protective segment 1, one of which is belt 13, is worn on the belt of the defender and fastened, and the other is belt 14 - before that, it is simply worn on the shoulders and neck from above. An elastic-elastic element 15 is attached to the back side of the main protective segment 1 over its entire surface - a "shock-absorbing pillow", through which the shield structure is pressed against the body of the defender by a belt 13 in both folded and unfolded state; and to the belt 14 along its outer surface are also attached two longitudinal shock-absorbing elements 16, designed to absorb impact energy when the protective segment 5 is rotated in case of exposure to intense shock load. To protect against weathering and to increase the duration of use, the shock absorbing elements 15 and 16 can be covered with impermeable covers. The protective segment 7 can also be equipped with an elastic-elastic shock-absorbing element 17 attached to its rear surface (see Figs. 1 and 5) and designed to absorb impact energy when the protective segment 7 is rotated, relative to the axis of the ramrod joint 10 and the protective segment 6 , - and its collision with the visor of the defender's helmet. For the convenience of folding the shield structure to its original position, the protective segments 8 can each be equipped (see FIG. 6) with sections 18 connected to the segments 8 on their back and designed to interact with the back surface of the protective segment 7 by engagement, respectively, after that , as all three of these protective segments are brought into one plane, corresponding to the given position of the protective segment 7 (see Fig. 1, 5), due to the equilibrium state of the torsion spring of its ramrod articulated joint inenia. In principle, in sections 18 there is no special need, since the defender, by turning with two hands (the direction of rotation of the shield segments is conventionally shown by arrows in Fig. 1), two protective segments 8, respectively, up to the plane of the protective segment 7, can very well hold these segments in this position , move the hands and, capturing each of the hands and the protective segment 7, rotate further around the axis of the ramrod swivel joint 10 all three protective segments together until they fit to the plane of the protective segment 6, and then, capturing the bol With the fingers of the hands of the protective segment 6, rotate further around the axis of the other ramrod swivel joint 10 all four protective segments together until they fit to the plane of the protective segment 5 and so on.

 The manufacture and assembly of the shield structure is very simple and performed by conventional methods known in the art. All protective segments are made of hard alloys of a certain thickness corresponding to a given level of resistance; ramrod swivel joints [4] are performed by conventional methods, and the manufacture of torsion springs with a given torsional resistance force and their attachment to the protective segments are described previously. The belts are also attached to the main protective segment by conventional known methods, and the waist belt 13 can simply be threaded into narrow slots in the main protective segment for ease of connection, and it is fastened when the shield structure is worn on the body of the defender from the side.

 Folding the shield design is as follows. First of all, they roll up, for example, the upper part of the shield and fix it relative to the main protective segment 1 with rotary latches 12, and then roll up the lower part of the shield and also fix relative to the main protective segment 1 with the same two latches 12. In principle, two separate latches 12 can be used for fixing only the lower part of the shield and two separate clips 12 for fixing only the upper part of the shield, but this is a purely technical solution. Consider the option of folding the deployed shield when it is on the body of the defender. Taking the lowest protective segment 4 with your hands, turn it up (see Fig. 1, where the direction of rotation is conventionally shown by an arrow) until it contacts the surface of the protective segment 3, which abuts at that moment in the body of the defender; this causes elastic twisting of the torsion spring 11 of the lower ramrod swivel 10, which, when twisted, stores energy for the subsequent deployment of this protective segment. Then, the protective segments 3 and 4 are rotated together and in the same direction until they fit to the surface of the protective segment 2, and then, grabbing them with their hands, the protective segments 2, 3, 4 are rotated together until they fit in the surface of the main protective segment 1 and fix them alternately holding the rolled part of the shield with one hand, using the rotary latches 12 relative to the main protective segment 1. Thus, the lower part of the shield structure is folded, and the torsion springs 11 of the three ramrod swivel joints 10 gom twisting from its equilibrium state corresponding to the deployed (see. FIG. 1) position of the shield, the energy accumulated in itself for subsequent deployment in the desired time samorazvertyvayuschegosya bottom of the shield. Secondly, the upper part of the shield is coagulated. As described by Aney, taking two separate protective segments 8 with two hands, rotate them (the direction of rotation is conventionally shown by the arrow in Fig. 1), respectively, to the plane of the protective segment 7, and then, capturing the protective segment 7, rotate further around the axis of the highest ramrod hinge connection 10 all three of the protective segment 7 and 8 to fit to the surface of the protective segment 6; torsion springs 11 of three coaxial ramrod swivel joints 10 connecting segment 6 to segments 7 and 8, while elastically twisting from their equilibrium state, storing energy in themselves for the subsequent deployment of these protective segments. Then, capturing the protective segment 6, the protective segments 6, 7, 8 are rotated in the same direction together until they fit to the surface of the protective segment 5, and then, capturing the segment 5, all the adjacent protective segments 8, 7, 6 are rotated and 5 until they fit to the surface of the main protective segment 1; torsion springs 11 of two ramrod swivel joints 10 connecting the protective segments 5, 6 and the protective segments 5 and 1 with each other are elastically twisted from their equilibrium state, storing energy in themselves for the subsequent deployment of these protective segments. After the upper part of the shield structure is folded, it is also fixed relative to the main protective segment 1 by the latches 12. Thus, after successively folding the lower and upper parts of the shield, its design assumes a folded initial position (see Fig. 2) with very small overall dimensions (shown by the dotted line in Fig. 1) and at the necessary time can be re-deployed. At the same time, the design of the shield, since it is fixed on the body of the defender, continues to protect a significant part of his body, not limiting the possibility of his movements and allowing him to sit and bend freely.

 Deploying the design of a rolled-up self-expanding shield, mounted on the body of the defender, to the deployed protective position is very simple. With both hands, rotate both latches 12 and the upper and lower parts of the shield released from their fixed relative to the main protective segment 1 position simultaneously, but in different directions (see Fig. 2, where the deployment directions are conditionally shown by arrows) carry out sequential deployment of the protective segments due to the stock in advance the energy of elastic, pre-twisted and tending to return to their equilibrium state of the torsion springs 11 of all ramrod articulated joints 10. First, deploy at the same time, protective segments 2 and 5, respectively, then, before the deployment of the indicated segments is complete, the protective segments 3 and 6 begin to deploy, then the protective segments 4, 7 and 8 begin their deployment in the same way, and, in the last turn, are deployed to the specified position protective segments 8 (see Fig. 1, 4, 5).

 The process of deployment and folding of the shield structure is carried out very simply, quickly and repeatedly - at least several tens of thousands of cycles, which is due to the stability of the characteristics inherent in elastic torsion springs, which in this case are reliably protected by ramrod hinge joints of the protective segments.

 The design of the folded self-expanding shield, which compares favorably with its compactness in the folded initial position, being just dressed as a defender and leaving both hands free, provides protection for a significant part of his body, allowing him to sit and bend freely.

 In the expanded state, when the upper and lower parts of the shield are fully deployed or only the upper part of the shield is deployed, the design of the self-expanding shield provides protection for almost the entire body of the defender, with the exception of the arms and legs; protection with a given resistance and high shock absorbing ability to shock solid bodies, due to the use of elastic-elastic elements - shock-absorbing "pillows" and torsion springs, damping shock loads when the protective segments rotate relative to a given position. At the same time, and this is the most important thing, the functionality of the defender has been significantly expanded, since now both hands are free.

 The positive qualities of the proposed design should also include high-speed self-deployment, simplicity and reliability, minimal weight and the ability to set the optimal multi-faceted shape, all faces of which are located at certain angles to the vertical plane, which significantly increases the rebound and shock-absorbing ability of the structure.

 Thus, we can conclude that the above combination of qualities emphasizes the efficiency and wide functionality of the proposed device and provides tactical and technical advantages in comparison with well-known analogues.

Literature:
1. The Great Soviet Encyclopedia, Third Edition, M., Publishing House "Soviet Encyclopedia", 1978, v. 29, p. 539.

 2. Military Encyclopedic Dictionary, Second Edition, M., Military Publishing House, 1986, p. 826.

3. USSR author's certificate N 26572 of 07/30/1930, F 41 H 5/12 "Safety shield for hand-held firearms"
4. Voight E.S. and others, "Design of aircraft structures" M., Mechanical Engineering, 1987, pp. 68-69.

Claims (1)

 A self-expanding shield, including rigid protective segments, connected to each other with the possibility of rotation at a given angle, characterized in that it is made of two parts assembled from protective segments, one smaller and the other of a larger longitudinal size, respectively, and each attached to opposite ends of the main protective segment, and the upper of the larger longitudinal segments is made of two lateral and middle individual protective segments located end-to-end to each other, each of the protective segments is connected to neighboring segments by means of a spring-loaded ramrod swivel, the axis of which is made in the form of a torsion spring, interacting with its end sections respectively with adjacent protective segments, and provided with outwardly curved sections adjacent to the ramrod swivel joints, while the shield is provided with locking tabs for the protective segments connected with the main protective segment, two belts attached to the main protective segment, and elastic-elastic shock absorbing elements, one of which is attached to the back of the main protective segment over its entire surface, and the other to the outer surface of the upper of the belts.

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