RU171507U1 - UNLOADING VENTILATION-DEPRECIATION SUPPORT - Google Patents

Abstract

The utility model relates to devices that comprehensively solve the problems of protecting the human body from developing thermal discomfort, unloading the spine and muscles of the shoulder girdle from additional weight load of wearable protective equipment, as well as mitigating the effects of local traumatic mechanical effects on the body and can be used together with bulletproof vests, special protective suits or other special equipment. The technical result of the development of this useful fashion whether it is imparting universality of use to it in order to comprehensively increase the level of protection against local mechanical influences and to reduce the choking and debilitating effect. The useful model contains frame elements made in the form of separately arranged curved - elastic wavy or trapezoidal - plastic strips, rigidly fixed with an offset of one half-bending at a fixed distance from each other with an orientation perpendicular to the length of the human body from the inside to air- and moisture-permeable m outer and inner fabric base corresponding to the shape and size of the constituent elements of clothing. Additionally, on the outside on the fabric base of the thoracic and dorsal sections of the base module, wholly elastic support spacers with unloading shoulder girth free of fasteners are rigidly fixed along this length. The lower ends of the spacers, containing built-in telescopic devices, individually adjustable to the size of the body when wearing body armor while standing and sitting, are placed in receiving containers located on the waist belt. Description: 6 pages, 2 ill., 3 ex. pr-f-ly floor. models.

Description

The utility model relates to devices that comprehensively solve the problems of protecting the human body from developing thermal discomfort, unloading the spine and muscles of the shoulder girdle from additional weight load of wearable protective equipment, as well as mitigating the effects of local traumatic mechanical effects on the body and can be used together with body armor, special protective suits or other special equipment.

The technical result of the development of this utility model is to give it the universality of use for a comprehensive increase in the level of protection against local mechanical influences and to reduce the fettering and debilitating effect.

From the analysis of the prior art it is known that at present, air or liquid media are most often used to remove endogenous heat of the human body. The efficiency of heat transfer during their use is determined by the level of performance of technical means providing contact of these coolants with the human body [1]. As a rule, all means in the design of which devices are used for the active supply of cooling or, on the contrary, heating media to the human body, despite their high efficiency, are simultaneously energetically high costly, which does not allow their use in stand-alone mode, for example, during prolonged actions of a person on an open terrain. This circumstance is the main reason for their limited use in the actions of personnel in open areas.

To eliminate this drawback, a whole series of special gaskets was developed, in which, thanks to the use of frame elements in various designs [2, 3, 4, 5], stable ventilation channels are formed that contribute to ventilation of the suit space, especially in the upper half of the body. This ensures the activation of the convective component of heat exchange due to air exchange, which occurs due to the natural temperature difference of the ambient air in height, the manifestation of the “fur” effect due to the movement of arms and legs, respiratory movements and wind pressure. It was assumed that the implementation of frame elements using polyethylene foam will reduce the negative effect of the screening effect of protective equipment, primarily body armor, on heat transfer due to the use of moisture- and airtight packages of protective materials and at the same time reduce the effect of backward traumatic action on underlying tissues of the human body by mechanical influences wounding shells on bulletproof vests when they are not penetrated. However, structurally imperfect technical solutions to this problem did not bring the desired result in stabilizing a person’s thermal state in both summer and winter conditions, which necessitated the search for more advanced technical solutions.

The main disadvantages of the typical designs of these were due to the fact that they used continuous rollers or columns, which, due to their dimensions, switched off a large surface area of the body from heat transfer, excluded longitudinal air movements in the suit space, which is especially important in the presence of wind pressure, as a rule , which always takes place during operations in the open, fettered body movements, etc.

However, since the use of protective equipment is inevitably associated with additional negative effects due to the debilitating effect, primarily weight loads on the muscles of the shoulder girdle and back, as well as on the spine, which are forced to compensate for the mass of protective elements held on the shoulders, which is negative on the one hand affects performance when performing complex-coordinated activities, and on the other hand, contributes to the development of occupational hazards and premature general fatigue, due to ennogo constant weight overloads the same time there was a need to minimize the negative effect of the inclusion in the design of special compensating elements.

The closest in technical essence and the possibility of achieving the desired result is clothing equipped with a device for ventilating the undersuit space [6]. These clothes had evenly spaced raised ribs forming channels for air circulation between the skin and outer clothing. The disadvantages of this clothing are the low efficiency of the removal of endogenous heat and low operational and protective properties from local mechanical effects on the human body.

Thus, the purpose of this development was to develop a universal liner that would meet all of the above requirements, and at the same time should be able to use it in operation in combination with various equipment options, including the one that includes individual armor protection.

This goal is achieved by using, as the frame elements forming the ventilation ducts, separately located elastic wave-like or trapezoidal plastic strips, rigidly fixed with an offset by one half-bend at a fixed distance from each other with an orientation perpendicular to the length of the human body between two layers of air- and moisture-permeable fabric, corresponding to the shape and size of the constituent elements of clothing. Moreover, each ventilation module can be mechanically connected to each other in various combinations depending on the task at hand.

Using this design, on the one hand, ensures the stability of the lumen of the ventilation channels in the undersuit space along the height of the whole body, and not only in the upper half of the body, minimal screening with insulating materials of the human body and freedom of movement, and on the other hand, provides a uniform protective area the effect of local mechanical influences.

At the same time, the use of additional tissue bases of the thoracic and dorsal sections, rigidly fixed outside, with a fastener-free zone forming the unloading shoulder girth, one-piece elastic support spacers, the lower ends of which contain integrated telescopic devices individually adjusted to the size of the body and placed in the telescopic devices located on the waist the belt on the outside receiving tanks, provides the ability to transfer the zone of compensation of the mass of equipment from the shoulder girdle and spine to the pelvis new bones, providing due to this freedom of movement for the hands in the shoulder girdle and unloading the spine.

Meanwhile, since the liner is worn directly on the time sheet of everyday clothing, it by its definition has universal applicability.

At the same time, since one of the quite frequent options for using bulletproof vests is to move in airborne and airborne vehicles, to compensate for the adverse effects of the mass of bulletproof vests, including under the influence of shock accelerations caused by mine detonation of vehicles, additionally connected to the lower ends are introduced into the design flexible plastic support spacers mounted on the outside of the fabric base of the back section, individually adjustable telescopic devices made with the possibility of fixing the selected length in contact with the lower end of the supporting plastic spacers with the surface of the seat and the sensation of the actual unloading of the shoulder girdle when using body armor or unloading vests in a sitting position.

Based on the totality of features and achieved effects, the proposed utility model is distinguished by the “non-obviousness of the developed design”, “novelty”, “technical feasibility” and “industrial applicability” for the complex solution of applied problems of optimizing the conditions of human activity in extreme conditions requiring the use of special individual means of protection.

The design of the discharge ventilation-depreciation liner is illustrated in FIG. 1, 2, which depict the constituent elements of the device and a schematic diagram of their layout in various versions of operation.

The unloading ventilation-depreciation liner (Fig. 1, 2) is made in the form of separate ventilation modules corresponding in shape and size to the constituent elements of the clothing, for example, a vest, sleeves, trousers, each of which is equipped with fasteners, for example, fabric fasteners, for connecting them into various combinations with each other and with service clothes.

The basic ventilation module consists of the chest 1 and dorsal 2 sections of the swing vest, mechanically interconnected by shoulder straps 3. On the sides, sections 1 and 2 contain individually adjustable fasteners 4 to fit the base module to the body. Additional modules for sleeves and trousers can be made, with each of these modules having additional fasteners for connecting with each other in a different combination and attaching to service clothes (not shown in the figures).

The pectoral 1 and dorsal 2 sections of the base module contain ventilation ducts 5 with a fixed cross-sectional length, which is formed by separately arranged curved - wavy or trapezoidal - elastic supporting plastic strips 6 made of polypropylene. Each curved plastic strip 6 is rigidly separately attached from the inside to the inner 7 and outer 8 fabric bases of sections 1 and 2 of the base module with an offset by one half-bend at a fixed distance from each other with an orientation perpendicular to the length of the human body (Fig. 2).

Outside, longitudinal fastening nodes 9, made according to the size of the spacers 10, are sewn to the outside of the tissue bases of the thoracic 1 and dorsal 2 sections of the base module.

The elastic support spacers 10, made in the form of two whole tubes or cords, are placed in the fastening nodes 9 during assembly so that in the area of the straps there remains a section free from fasteners, forming an unloading shoulder girth 11. The lower ends of the spacers 10, equipped with built-in, individually adjustable under the size of the body with telescopic devices (not shown in the figure) is placed in the receiving containers 12 located on the outside on the waist belt 13, which on the loops 14 is attached externally to the internal fabric innovations of the thoracic 1 and dorsal 2 sections of the base module.

Individually adjustable telescopic devices 15 are additionally connected to the lower ends of the elastic plastic support spacers 10 mounted on the back section 2, made with the possibility of fixing the selected length in contact with the surface of the seat and the sensation of the actual unloading of the shoulder girdle when using body armor or unloading vests in a sitting position .

The device performs its function after placing it on a person’s body over a time sheet and fitting it to the individual anthropometric dimensions of all its components as follows.

After reviewing the instructions for using this device, the user puts on the base ventilation module (swing vest) over his head, which is combined with each other shoulder straps 3 chest 1 and back 2 sections with two integral ones fixed on them in attachment points 9 on the sides on the outside spacers 10 with a free part in the area of the connecting shoulder straps 3, performing the function of the unloading shoulder girth 11 (Fig. 1 and 2).

Adjusts the size of the compression of the thoracic 1 and dorsal 2 sections using the side straps 4 according to the size of the upper half of their body.

Inserts a waist belt 13 into the loops 14 from the outside of the internal tissue bases of the chest 1 and dorsal 2 sections of the base module.

Inserts spacers 10 into the receiving containers 12 located on the outside of the belts 13. Tightens the waist belt 13 until there is a feeling of tight contact with the body and the belt stops at the upper edge of the ilium.

Exposes the position of telescopic devices (not shown in the figure) by the sensation of the appearance of a full weight unloading of the shoulder girdle from the body armor in a standing position. Exposes the position of the telescopic devices 15 according to the sensation of the appearance of a full weight unloading of the shoulder girdle from the body armor in the sitting position.

The ventilation of the undersuit space when using the proposed lining is carried out passively due to natural convection mechanisms through the ventilation ducts 5 with a fixed cross-sectional length, which form separately arranged curved - sinusoidal or trapezoidal - elastic supporting plastic strips 6 made of polypropylene. In this case, the plastic strips 6 are rigidly fixed from the inside to the tissue bases 7 and 8 of the thoracic 1 and dorsal sections 2 of the base module with an offset by one half-bend at a fixed distance from each other with an orientation perpendicular to the length of the human body (Fig. 2) so as not to impede freedom body movements and at the same time provide ventilation for the undersuit space and the necessary body protection from local mechanical influences.

The use of an unloading ventilation-depreciation liner when using standard body armor made it possible to provide a more comfortable state for users, as evidenced by an increase in the subjective feeling of ease of use of body armor, more comfortable thermal sensations, including those caused by the exception of moistening elements of service clothes, over which a body armor was worn, and the spine was released and shoulder girdle from the weight load of body armor, as well as protecting the body from local mechanical x effects.

Thus, the practical use of an unloading ventilation-depreciation liner containing new structural elements and methods for their interaction has confirmed the industrial applicability and high efficiency of the technology of providing individual protection against a complex of adverse factors in life-threatening situations implemented using this device.

SOURCES TAKEN INTO ACCOUNT WHEN DRAWING UP THE PATENT

1. Kashcheev B.C., Kuznets E.I. Physiology and hygiene of individual protection of a person at high temperatures. M .: Medicine, 1986 ,.

2. The device of domestic combined arms body armor. Portal "Modern Army" 04/22/2012 http://www.modernarmy.ru/article/159 ©

3. Information material of the company NPP "SpetsTekhnika". Climatic and ventilation support for body armor ", 2015

4. Information material of the company NPO "SPECIAL MATERIALS". Climatic and ventilation support for body armor ", 2015

5. Patent for the invention of the Russian Federation No. 2120218

6. UK patent N 2108822.

Claims (3)

1. Unloading ventilation-cushioning liner containing ventilation channels formed by frame elements made in the form of separately located polyethylene protrusions rigidly fixed to a substrate made in the form of body armor elements, characterized in that the frame elements are made in the form of separately arranged curved, for example, elastic or trapezoidal cross-section of elastic support plastic strips made, for example, of polypropylene, which are rigidly closed repellen with an offset of one half-bend at a fixed distance from each other with an orientation perpendicular to the length of the human body from the inside to the air- and moisture-permeable outer and inner fabric bases of the ventilation modules, corresponding in shape and size to the constituent elements of the clothing, for example, vest, sleeves, trousers, each of which is equipped with fasteners, for example, fabric fasteners, for connection in various combinations with each other. 2. The discharge ventilation-depreciation liner according to claim 1, characterized in that it further comprises two integral elastic plastic support spacers with discharge-free shoulder girth, rigidly fixed along the entire length on the fabric bases from the outside of the thoracic and dorsal sections of the basic ventilation module , for example, in the form of elastic tubes or cords, the lower ends of which, containing built-in, individually adjustable to the size of the trunk telescopic devices, in the receiving containers located on the outside on the waist belt, which on loops is rigidly attached externally to the internal tissue bases of the dorsal and thoracic sections. 3. The unloading ventilation-depreciation liner according to claim 1, characterized in that individually adjustable telescopic devices are additionally connected to the lower ends of the elastic plastic support spacers fixed externally to the fabric base of the back section, with the possibility of fixing the selected length when the lower end of the plastic support contacts spacers with the surface of the seat and the sensation of the actual unloading of the shoulder girdle when using body armor or unloading cores s in a sitting position.

Images