RU85816U1 - PNEUMATIC LOADING COVER FOR DEVICE OF NEURO-ORTOPEDIC REHABILITATION - Google Patents

Abstract

A pneumatic loading casing for a neuro-orthopedic rehabilitation device containing a cover of a given shape and a pneumatic chamber placed inside it with a device for supplying and collecting air, characterized in that the pneumatic chamber is made of film material with the possibility of taking a given complex geometric shape of the cover when air is supplied into the pneumatic chamber, while the length pneumatic chambers are equal to the length of the cover, and the maximum and minimum width of the pneumatic chamber are equal to the maximum and minimum width of the cover.

Description

This utility model relates to structures that are used in devices for non-surgical treatment of the musculoskeletal system, in devices for passive medical gymnastics, and more specifically relates to the pneumatic-loading membrane for the device for neuro-orthopedic rehabilitation.

The utility model can be used in medicine and the medical and social sphere in devices for the correction of motor, posotonic and speech disorders in diseases such as traumatic brain injury, spinal cord and spinal cord injuries, the consequences of a stroke, cerebral palsy and other diseases of the nervous system, diseases of the musculoskeletal system complicated by motor disorders (arthrosis, arthropathy, joint dysplasia, impaired retention of the posture, and so on), residual manifestations of fractures awns and spine, postural disorders due scoliosis, degenerative disc disease, for the treatment of diseases associated with metabolic disorders: obesity, osteoporosis and the like. In addition, the invention can be used in space medicine in devices for the prevention of negative phenomena caused by prolonged exposure to zero gravity.

A device for neuro-orthopedic rehabilitation is known - a device for straightening and facilitating the verticalization of patients (RU 2170566), comprising a pneumatic loading membrane having at least one pneumatic chamber, which is a supporting element that has a given complex geometric shape and is made in the form of a λ-shaped elastic tire , and a sheath-cord having a predetermined complex geometric λ-shape and made of dense non-stretch fabric, into which a support element with a device for supplying and discharging air is inserted, then s with pneumatic valves, hose connection to a compressor. The elastic tire is made of rubber or elastic plastic with inlet and outlet valves. The cord cover is made according to the size of the tire from a dense, non-stretchable material (tarpaulin or other similar material and plastic material). On the back surface of the cord cover in the projection of the patient’s back there is a cut fastened with a zipper to insert and remove the tire. The case has holes for the output of hoses. The device is also equipped with fixing elements and elastic rods with clamps. The fixing elements are made in the form of cuffs and are fixed on the sides of the cover-cord in the pelvis, shoulder, hip, knee and ankle joints, and the struts of the λ-shaped element are made at an angle of 45 °, and the stand is deflected 30 ° from the vertical. The shoulder cuffs are made in the form of short sleeves cut in the middle with a wide Velcro along the cut and connected to the front of the cord case. Cuffs in the ankle joints are made in the form of shoe covers without socks attached to the back surface of the cover-cord. Cuffs are made with silicone lining. Case-cord is made in sizes close to the dimensions of the support element, and with holes for hoses. The size of the tire is adjusted to fit the patient. One pair of elastic rods made in the form of wide elastic bands are fixed to the shoulder cuffs at one end in the region of the upper third of the shoulder, and the other ends are attached to the cover cord in the projection area of the mid-thoracic spine, the other pair of elastic rods is fixed to the cuff at the level of the shoulder joints and, crossing in the region of the mid-thoracic spine of the patient with the second ends are fixed to the cuff in the pelvic region to various points. First, the support element is inserted through an opening on the rear surface into the cord case. The lock on the hole closes. Hoses with inlet and outlet valves are led out through additional openings. A pear or compressor joins it. Then air is injected into it at a pressure of 50-100 mm RT. Art., and mount the supporting element to the back of the patient. The vertical position of the patient’s body and limbs is recreated by forcing air into the support element under a pressure of 100-200 mmHg. Art. to straighten the back, decompression of the spine and its extension in the thoracic region, increase the parameters of the chest, straighten the knee and hip joints, rotate the feet outside, then release pressure by 1/10 to allow movement by flexion of the limbs in the joints to the tire, it begins to take a λ-shape, limited in volume by a sheath-cord.

However, this device has a labor-intensive technology for manufacturing a pneumatic chamber, which is a supporting element that has a given complex geometric shape and is made in the form of a λ-shaped elastic tire, labor-intensive technology for the manufacture of a sheath-cord having a given complex geometric shape, low level of manufacturability, and also the probability of reduction level of tightness quality due to the presence of hard-to-reach parts when connecting Also, due to the complex configuration of the details of the cut of the pneumatic chamber, there is a high percentage of inter-lethal waste, i.e. there is an uneconomical consumption of material, which also significantly increases the cost of the product. The complex configuration of the details of the cut of the pneumatic chamber leads to certain inconveniences in the process of connecting it to the case.

Thus, the pneumatic loading shell of this device has an insufficient level of manufacturability, it takes a lot of time to manufacture it due to the complex design of its elements, it has a laborious technology for manufacturing a pneumatic chamber and a cover, and is not convenient for assembly, operation, and maintenance.

The utility model is based on the task of creating a pneumatic loading shell for a neuro-orthopedic rehabilitation device with such a constructive implementation that would allow creating a pneumatic loading shell with an increased level of manufacturability of the structure, with a reduced laboriousness of manufacturing a pneumatic chamber, more reliable and convenient in operation, easy to assemble and in service, providing increased productivity.

The problem is solved in that in a pneumatic-loading shell for a neuro-orthopedic rehabilitation device containing a cover of a given shape and a pneumatic chamber placed inside it with a device for supplying and discharging air, according to a utility model, the pneumatic chamber is made of film material with the possibility of taking a given complex geometric shape of the cover when air is supplied inside the pneumatic chamber, the length of the pneumatic chamber is equal to the length of the cover, and the maximum and minimum width of the pneumatic chamber are respectively max flax and a minimum width of the cover.

This utility model makes it possible to create a pneumatic loading casing for a neuro-orthopedic rehabilitation device with an increased level of technological design, with a reduced laboriousness of manufacturing a pneumatic chamber, more reliable and convenient in operation, easy to assemble and maintain, providing increased labor productivity.

In the future, the utility model is illustrated by a specific example of execution and drawings, in which

Fig 1 depicts a General view of the pneumatic loading shell for a device for neuro-orthopedic rehabilitation in working condition, according to a utility model;

Figure 2 depicts a pneumatic chamber inoperative, according to a utility model;

Figure 3 depicts a pneumatic chamber of a pneumatic loading shell for a device for neuro-orthopedic rehabilitation in working condition in a case, a section along line 1-1 according to a utility model;

The pneumatic loading shell for a neuro-orthopedic rehabilitation device comprises a cover 1 (Fig. 1) of a given complex geometric shape and a pneumatic chamber 2 (Figs. 2, 3) located inside it with a device for supplying and discharging air, made in the form of a tube 3 (Fig. 1) with fitting. The pneumatic chamber 2, shown in FIG. 2 in an idle state, is configured to take a given complex geometric shape of the cover 1 (FIG. 1) when air is supplied inside the pneumatic chamber 2 (FIG. 2). In this case, the length a of the pneumatic chamber 2 is equal to the length a ₁ (FIG. 1 ) of the cover 1, and the maximum width b (FIG. 2) and the minimum width d of the air chamber 2 are equal to the maximum width b in the minimum width d _{1 of the} cover 1 (FIG. 1). The design of the pneumatic chamber 2 (figure 2) of a simplified configuration is constructed as follows. On the vertical axis Oy, a segment OA is deposited, equal to the length a of the pneumatic chamber 2, corresponding to the length a ₁ (Fig. 1) of the cover 1. Then, along the Oy axis, a segment of the OS (Fig. 2), equal to the distance from the lower point of the pneumatic chamber 2 to its wide area. Then horizontally from point C, segments CC ₁ and CC _{2 are} laid to the right and left, equal to the value of b corresponding to the maximum width bi of cover 1 (Fig. 1), and from the lower point O (Fig. 2) and the upper point A are laid to the right and to the left, respectively, the segments OD ₁ , OD ₂ and AA ₁ , AA ₂ equal to the value of d, corresponding to the minimum width d _{1 of the} cover 1 (Fig 1). The resulting points are connected by spline lines. As a result, the design of the pneumatic chamber 2 was obtained (FIG. 2), the contour lines of which are close to straight lines. The shape of the resulting structure is symmetrical about the Oy axis, which provides a more rational cutting of the material. For example, we consider the layout options for the details of the cut of the pneumatic chamber 2 of the declared and complex geometric shape, for example, the pneumatic chamber 2 has the shape of a cover 1 inoperative. Thus, in both versions sets of patterns were decomposed into three units of products. The details of the complicated design of pneumatic chambers 2 are stacked on a sheet 364 cm long, and a simple one - 274 cm with a sheet width of 150 cm. At the same time, interleukal lunges made up 29.7% in the layout of simple chambers, and 65.5% in complex ones. Thus, using the claimed simple design of the pneumatic chamber 2, obtained by approximating any given complex contours of the cover, bringing them closer to straight lines, the manufacturability of the design of the pneumatic loading shell has been achieved, the shape of the part of the pneumatic chamber 2 approaches the figure of a rectangle. Due to this, an economical, rational consumption of material, a reduction in the percentage of inter-lethal attacks to a minimum value is achieved. After cutting the pneumatic chamber 2, a tube 3 (Fig. 1) with a fitting for air supply is installed on the details of the cut of the pneumatic chamber 2, then the sections of the parts are connected using one of the known connection methods; glue or welded. To bring the pneumatic chamber 2 (Fig. 3) to its operational state, it is placed in a cover 1 and filled with air through the nozzle 3 (Fig. 1) with a tube. The pneumatic chamber 2 (FIG. 3) assumes the complex geometric shape of the cover 1 (FIG. 1). Air chamber 2 (figure 2) can be made of film material, for example, made in Germany, which is an airtight (airtight) polyurethane duplicated with 100% nylon, 200-300 microns thick, having high elasticity, elasticity, high strength tensile strength of the weld, and when air is supplied to the pneumatic chamber 2 easily takes a given shape. It is also possible to manufacture a pneumatic chamber 2 from film materials with similar characteristics of other manufacturers and rubberized fabric in an adhesive manner. For example, it is possible to use SOLTANE F / B 4 material with the above characteristics, namely: ultimate elongation - 600%, elastic rebound elasticity - 40%. Case 1 (Fig. 1) of a given complex geometric shape should be made of high-strength fabric with a smooth inner surface, for example, nylon fabric art 56023. The use of new elastic materials and the simplicity of the configuration of the pneumatic chamber 2 design, the implementation with a minimum number of butt joints (one weld seam) reduces the complexity of otovleniya pnevmonagruzhayuschey shell and, consequently, there is a reduction of time for the execution of joints. By reducing the complexity of manufacturing a pneumatic loading shell, labor productivity increases.

Thus, the technological design of the pneumatic loading shell was achieved by approximating the contours of the details of the cut of the pneumatic chamber 2 (Fig. 2) to straight lines, that is, the shape of the part approaches the figure of the rectangle. Due to this, an economical, rational consumption of material, a reduction in the percentage of interleukal attacks to a minimum value is achieved. Also, the complexity of manufacturing a pneumatic loading shell has been reduced due to the simplicity of the configuration of the structure and, as a result, there is a reduction in time to complete the joint seams. By reducing the complexity of manufacturing a pneumatic loading shell, labor productivity increases.

Thus, this utility model makes it possible to create a pneumatic loading shell for a neuro-orthopedic rehabilitation device with an increased level of technological design, with a reduced laboriousness of manufacturing a pneumatic chamber, more reliable and convenient in operation, easy to assemble and maintain, providing increased labor productivity.

Of course, various modifications and changes can be made that will be within the scope of this utility model. Although the utility model has been described in detail for a clear understanding of the essence of the proposed, it is obvious that some changes can be made within the particular cases of execution described in the description.

Claims (1)

A pneumatic loading casing for a neuro-orthopedic rehabilitation device containing a cover of a given shape and a pneumatic chamber placed inside it with a device for supplying and collecting air, characterized in that the pneumatic chamber is made of film material with the possibility of taking a given complex geometric shape of the cover when air is supplied into the pneumatic chamber, while the length pneumatic chambers are equal to the length of the cover, and the maximum and minimum width of the pneumatic chamber are equal to the maximum and minimum width of the cover.