RU196139U1 - Corrective corset - Google Patents

Abstract

The utility model relates to medical equipment, more specifically to functional corrective corsets for correcting spinal curvatures (scoliosis). A corrective corset includes a sleeve made of thermoplastic sheets, insert-pelots and a time sensor, a temperature control system mounted in the said sleeve and consisting of thermoelectric generator, including at least one Peltier module, with a series-connected connector for powering said generator and controller while the foil fragments are in thermal contact with the inner plate facing the sleeve, the Peltier module is glued, and the other plate of this module is placed on the outer surface of the sleeve and is in contact with the environment. In addition, the fragments in the corrective corset foils are made of aluminum or copper; as the power connector of the thermoelectric generator using a standard connector for charging portable electronic devices; the contour of the plates embedded in the sleeve corresponds to the forms of local sections of its surface on which these plates are placed; fragments of foil glued to the inner surface of the sleeve are made in the form of strips; and a foil fragment that is in thermal contact with the outer plates of the Peltier module of the thermoelectric generator is glued to the outer surface of the liner. The technical result of the utility model is to reduce the patient's thermal overload when wearing corsets in heat or cold.

Description

The utility model relates to medical equipment, more precisely to functionally correcting corsets for correcting spinal curvatures (scoliosis).

In world practice, corsetting has been used for over 30 years as the main method of conservative treatment of scoliosis in children and adolescents. For such patients, corsetry prevents the progression of the disease and reduces the likelihood of surgical treatment in the future.

There are a large number of corrective corsets (QC), most of which can serve as an analogue to this proposal. Depending on the nature and degree of curvature of the spinal column (Cobb angle), either soft corsets with stiffeners (for example, Orlett), or more rigid structures made of metal guides (Lyons corset), or corsets consisting of separate plastic fragments fastened by power elements are used (corset Milwaukee, Boston and similar - "Corset for the back of Milwaukee", www.lechenie-sustavy.ru; MoyOrtoped.ru; modular corsets for patents for inventions: RU 2148971 C1, publ. 05.20.2000, bull. No. 14, IPC : A61F 5/01 (2006.01); RU 2234890 C1, publ. 08/27/2004, bull. No. 24, IPC: A61F 5/02 (2006.01); “The Boston Bracing System for idiopathic scoliosis)), Emans J.B. Kaelin A., Spine 1986, vol. 11, p. 8-11). Many similar developments have been done in Ukraine (utility model patents: UA 71298, publ. 15.11.2004, IPC: A61F 5/01 (2000.01), UA 26748, publ. 10.10.2007, IPC: A61F 5/03 (2006.01), UA 62350, publ. 15.12.2003, IPC: A61F 5/02 (2000.01), UA 74497, publ. 15.12.2005, IPC: A61F 5/02 (2006.01), UA 19310, publ. 15.12.2006, IPC: A61F 5/02 (2006.01)). Also, an air-conditioning vest can be considered as an analogue to maintain comfortable conditions at elevated ambient temperatures (patent RU 2110936 C1, publ. 05.20.1998, IPC: A41D 13/00 (1995.01)). At the same time, the vest is not corrective and is intended for tourists and the military. The vest has a three-layer structure and is cooled by evaporation of water located in its middle layer. With large deformations of the spine (Cobb angles greater than 20-40 degrees), with curvature simultaneously in the sagittal and horizontal planes, as well as with the need to rotate the spinal column, the most “rigid” Chenot corset is used (patent for utility model UA 48641, publ. 25.03. 2010, IPC: A61F 5/02 (2006.01), adopted as a prototype) or "Chenot type" ("Orthopedics, Traumatology and Prosthetics", 2009, No. 4: 97-100).

The corset adopted for the prototype has a one-piece plastic sleeve with additional corrective inserts-pelots located on the convex side of the curvature and expansion zones located on the concave side of the curvature and opposite the corresponding pelots. In this case, the corset is made of thermoplastic sheet material according to the size of the patient’s body and in accordance with the type of deformation. In addition to pelots, modern Chenot-style corsets also include a wearing time sensor that monitors the total duration of the corset's force on the body (Grivas T. The Conservative Scoliosis Treatment, 1st SOSORT Instructional Course Lectures (ICL) / T. Grivas, IOS Press, Amsterdam, Berlin, Oxford , Tokyo, Washington DC, 2008). In some cases, in addition to the wearing sensor, sensors of other types are also embedded in the sleeve (Chalmers E. et al. An advanced compliance monitor for patients undergoing brace treatment for idiopathic scoliosis / Medical Engineering and Physics, 2015, No. 2 (37), p. 203- 209). However, it is only necessary to wear the sensor, since Chenot-type corsets are designed primarily for children and adolescents, who are characterized by weakened personal control over the wearing of the corset.

According to SOSORT (International Community for Scoliosis, Orthopedics and Rehabilitation Methods), in the most difficult cases, when long-term and significant impacts are required at several points on the body, such a corset is most effective. Its “closed” design allows you to most accurately set the three-dimensional vector of the impact on the spine. Chenot corrective corsets and Cheno type corsets are made taking into account the individual configuration of the patient's body. Traditionally for this, gypsum torso is used, followed by the manufacture of a corset according to the obtained cast. Currently, instead of plastering, 3D scanning of the patient’s torso is used, followed by the manufacture of a thermoplastic corset sleeve (including on a 3D printer), which requires the use of special software (software). This technique is used, in particular, by the company of the Republic of Kazakhstan ("Russian Corset Center", www.russiancorset.ru) together with the center for the treatment of scoliosis named after Katharina Schrot and the German company Regnier. A characteristic feature of the well-known QC and at the same time its disadvantage is a large degree of "closeness", i.e. the fact that it covers a very significant part of the patient’s body and for them this causes additional discomfort at too high or too low ambient temperatures. In addition to the fact that QC is extremely uncomfortable in terms of force acting on the body, in heat and cold it contributes to overheating or hypothermia of the patient. In hot weather, KK prevents heat removal from the body, since ventilation is difficult, and on the contrary, too much is removed from the body due to the large area of the sleeve of heat. It is known, for example, that the total power (together with breathing) of a person’s heat at rest is 70-100 watts. In view of this, the heat release from the human body under the CC can reach several tens of watts, i.e. without heat removal, this part of the body will heat up significantly. At the same time, wearing QC reaches 18-20 hours per day.

The objective of this proposal is to increase comfort during prolonged wearing of “closed” corrective corsets at too high or low ambient temperatures, which is achieved using a special temperature control system built into the corset sleeve.

The technical result of the utility model is to reduce the patient's thermal overload when wearing corsets in the heat or cold.

The technical result is achieved by the fact that in the corrective corset, which includes a sleeve made of sheet thermoplastic, insert-pelots and a wear time sensor, a temperature control system (CTP) is introduced, mounted in the mentioned sleeve and consisting of a thermoelectric generator (TEG), including at least at least one Peltier module, with a series-connected connector for powering the mentioned generator and current regulator, while foil fragments located on the inner surface of the sleeve are glued I am in thermal contact with the inner plate facing the sleeve of the Peltier module, and another plate of this module is placed on the outer surface of the sleeve and is in contact with the environment.

In addition, in the corrective corset, the foil fragments are made of aluminum or copper; as the power connector of the thermoelectric generator using a standard connector for charging portable electronic devices; the contour of the plates embedded in the sleeve corresponds to the forms of local sections of its surface on which these plates are placed; fragments of foil glued to the inner surface of the liner are made in the form of strips; and a foil fragment in thermal contact with the outer plates of the Peltier module of the thermoelectric generator is also glued to the outer surface of the liner.

The essence of this proposal is to use the concept of thermoelectricity for corsetting. Depending on the polarity of the external power supply, such a system allows both cooling and heating. Although the efficiency of modern Peltier modules, like solar panels, is only slightly higher than 10%, advances in solid state physics make it possible to hope for an increase in the energy efficiency of TEGs in the future. However, at present, such systems are quite functional. To quantify the operation of such a thermal control system in cooling mode, we used the parameters of the Peltier Modul module (model YB3981 DIY), which, with a weight of 26 g, dimensions of 4 × 4 × 0.4 (cm), has the following technical characteristics (www.dx.com) : at a temperature difference of 20 ° C generating current = 225 mA (0.97 V without load); at a temperature difference of 40 ° C generating current = 368 mA (1.8 V without load); at a temperature difference of 60 ° C, the generating current = 469 mA (2.4 V without load). Thus, at an external temperature of 20 ° C and power supply of the Peltier module integrated into the sleeve of the spacecraft with a current of ~ 200 mA, the temperature of its inner plate will be close to 0 ° C, and with a supply current of ~ 300 mA, the internal plate will cool to minus 20 ° C. At an external temperature of 40 ° С and the same current, the internal plate of the module will cool to 0 ° С, and at a supply current of 200 mA - up to 20 ° С.

With a stationary power supply, the operating time of the integrated TEG in the CC is in principle unlimited (more precisely, limited by its resource). In the mobile version, the TEG operating time in addition to the supply current also depends on the capacity of the supply battery. For example, for the same module when using battery power for an Asus N61 / vn laptop with a capacity of 5200 mAh, the operating time with a supply current of 200 mA (cooling at 20 ° C) will be about 5200/200 hours, i.e. about a day. And even with a decrease in the real efficiency of the cooling system by 2-3 times, its operation time will be quite acceptable. The estimates made above prove the fundamental possibility of a fairly efficient operation of the thermoelectric corset thermoregulation system.

The essence of the proposal is illustrated in FIG. 1, where the spacecraft is conventionally depicted as a hollow cylinder and the following notation is accepted: 1 - sleeve; 2 - connector for power supply; 3 - current regulator (for example, variable resistance); 4 - TEG, consisting of at least one (as in Fig. 1) Peltier module; 5 - the outer plate of the Peltier module; 6 - the inner plate of the Peltier module; 7 - fragments (in Fig. 1 - strips) of foil on the inner surface of the sleeve; 8 is a fragment of the foil on the outer surface of the sleeve.

The corrective corset includes a sleeve (1) made of thermoplastic sheet, pelon inserts and a wear time sensor (the last two are not shown in Fig. 1), as well as a temperature control system mounted in the sleeve (1) and consisting of a thermoelectric generator (4) comprising at least one Peltier module, with a TEG (4) and a current regulator (3) connected in series for power supply (2), while foil fragments (7) are glued to the inner surface of the sleeve (1) thermal contact with the internal (p relative to the sleeve) the plate (6) TEG Peltier module (4). The outer plate (5) of the latter is placed on the outer surface of the sleeve (1) and is in contact with the environment.

The configuration of the real sleeve (1) is individual and can be quite complex, as well as the shape of the foil fragments pasted on it. In this case, in any case, the foil should have good thermal conductivity, i.e. be copper or aluminum and have thermal contact with the inner plate (or plates) (6) of the Peltier module of the TEG (4). The outer plate (5) of this generator should have maximum contact with the environment (not covered by the patient’s body and covered with clothing as little as possible). To increase the reliability of the TEG operation (4), a fragment of the same foil (8) that is in thermal contact with the outer plates (5) of the Peltier module of the TEG (4) can also be glued to the outer surface of the sleeve (1).

The power connector (2) is connected in series with the current regulator (3) and the TEG (4) is also mounted in the sleeve (1) in a place convenient for the patient, like the current regulator (3).

The temperature control system operates in the QC cooling mode as follows. When the connector (2) is connected to a power source (not shown in Fig. 1), the system circuit is closed and a direct current is supplied to the TEG (4), the value of which is regulated by the current regulator (3). With the appropriate polarity of the connection, the outer plate (5) of the Peltier module of the TEG (4) is heated, and the inner plate (6) is cooled. Accordingly, the foil (7) in contact with the plate (6) and glued to the inner surface of the sleeve (1) is also cooled. Due to the thermal conductivity of the plastic of which the sleeve (1) is made, its entire inner side, which is in contact with the patient’s body, is gradually cooled. At the same time, the outer plate (5) of the generator (4) is heated. Its cooling occurs due to contact with the environment, therefore, to increase the reliability of the TEG (4) and reduce the temperature of its outer plate (6), a foil fragment (8) in contact with this plate can also be glued to the outer surface of the sleeve (1) and playing the role of an external radiator.

In general, the proposed corset with a plastic sleeve, which includes a thermal control system, allows to reduce the patient's thermal overload when it is worn in heat and cold, and thereby not only reduce general discomfort, but also stimulate the wearing of the corset under these conditions.

Claims (7)

1. Corrective corset, including a sleeve made of thermoplastic sheet, insert-pelots and a wear time sensor, characterized in that a temperature control system is installed therein, mounted in the said sleeve and consisting of a thermoelectric generator, including at least one Peltier module with connected to it in series with a connector for powering the aforementioned generator and current regulator, while foil fragments in thermal contact with the inside are glued to the inner surface of the sleeve renney facing the sleeve, a Peltier module plate, the outer plate of this module is placed on the outer surface of the liner and is in contact with the environment. 2. Corrective corset under item 1, characterized in that the fragments of the foil are made of aluminum. 3. The corrective corset according to claim 1, characterized in that the fragments of the foil are made of copper. 4. The corrective corset according to claim 1, characterized in that a standard connector for charging portable electronic devices is used as the power connector of the thermoelectric generator. 5. The corrective corset according to claim 1, characterized in that the contour of the plates embedded in the sleeve corresponds to the shape of local sections of its surface on which these plates are placed. 6. Corrective corset for PP. 1, 2 and 3, characterized in that the fragments of the foil glued to the inner surface of the sleeve are made in the form of strips. 7. Corrective corset according to paragraphs. 1, 2 and 3, characterized in that a foil fragment is also glued to the outer surface of the sleeve in thermal contact with the outer plates of the Peltier module of the thermoelectric generator.

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