EA037472B1 - Portable telemedical complex - Google Patents

Abstract

The invention relates to medicine, namely to measuring devices for diagnostic purposes, in particular to the portable telemedical complex that is suitable for use and transportation at low temperatures. The portable telemedical complex containing a casing, a control module with a display installed in it, as well as measuring instruments and a power module located inside; whereas the casing is equipped with a network connector mated to the power module characterized by the fact that the power module contains battery chargers connected to the network connector; also the network connector is connected to the control module with the display and its battery; and the complex additionally includes a USB interface connected to the control module; whereas the casing is made of polymer material, and inside the casing there is a foam tray, the cell walls of which are tightly attached to all elements of the portable telemedical complex; whereas the foam rubber tray is made of foam rubber with a density of 32-34 kg/m3, relative elongation of 240-280%, and tensile strength of 120-140 kPa. The technical result is to increase the time of uninterrupted autonomous operation of the complex during transportation at low temperatures while maintaining small weight of the product.

Description

The invention relates to medicine, namely to measuring devices for diagnostic purposes, in particular to a portable telemedicine complex, suitable for use and transportation at low temperatures.

The use of telemedicine technologies opens up additional opportunities for the use of new technologies in diagnostics and treatment, expanding the circle of patients who are under outpatient supervision, and also reducing the number of patient visits to the clinic [1]. The ability to provide medical care remotely allows you to serve patients in hard-to-reach locations, including in regions with extreme climatic conditions. Thus, one of the separate areas of development of telemedicine technologies is polar medicine, which is due to the special climatic conditions of the Arctic and Antarctic [2]. When developing technical solutions for the provision of medical care in polar conditions, special attention must be paid to ensuring uninterrupted autonomous operation of devices during transportation at low temperatures, since medical assistance may be needed in particularly inaccessible locations where there is no possibility of connecting to a network or a generator. However, the currently known devices known from the prior art do not solve this problem.

Known mobile telemedicine complex [3], including a control module in the form of a laptop with elements for communication, a power source, equipment for video communication and measuring instruments. The complex is designed for medical examination of patients.

Also known is a portable telemedicine complex [4], which contains channels for measuring the pulse, taking an electrocardiogram, measuring the patient's body temperature, measuring the respiratory rate and measuring the oxygen content in the blood, made with the possibility of receiving signals from the corresponding sensors located on the patient's body, and forming output signals in digital form for subsequent analysis, as well as a display for visual display of measurement information and a module for processing and analyzing measurement signals, the inputs of which are connected to the outputs by measurement channels, and the output is connected to the display input, and the module for processing and analyzing measurement signals is configured converting the output signals of the measurement channels into video signals for display on the display, while the instrument unit of the wearable medical diagnostic complex is made in a case equipped with batteries and attachments on the patient's body, and the display is placed on its lateral surface with the ability to visualize the results of current measurements displayed on it, moreover, a connector is made in the device body, which provides power supply from the batteries to the pressure measuring device when it is connected to the connector and feeds through the connector the signal of the measurement results from the pressure measuring device to the processing and analysis module measurement signals. This technical solution is taken as a prototype, since it is the closest to the declared one in terms of technical essence.

The disadvantage of the above devices is the insufficient duration of uninterrupted autonomous operation during transportation at low temperatures (in the Far North). This is due to the use of a replaceable battery as the main battery, as well as the lack of protection of the case against the effects of ambient temperature, which negatively affects the battery charge. In the far north, the telemedicine complex is transported to remote locations at low temperatures, and there is often no possibility of changing or charging the battery. Based on this, the performance of the above devices depends only on the charge of one battery, which decreases more than usual due to the influence of the environment.

A technical problem is the need to develop a portable telemedicine complex, devoid of the above disadvantages and suitable for transportation at low temperatures.

The technical result consists in increasing the time of uninterrupted autonomous operation of the complex during transportation at low temperatures while maintaining a low weight of the product.

The technical result is achieved by the fact that in a portable telemedicine complex containing a control module with a display and a built-in battery and a housing, as well as measuring instruments and a power module installed in it, the housing is equipped with a network connector mated with a power module, and according to the invention, a control module with the display is located inside the case, and the power module contains battery chargers connected to the network connector, the network connector is also connected to the control module with the display and its battery, and the complex additionally includes a USB interface connected to the control module, while the case is made of polymer material, and inside the body there is a foam tray, the walls of the cells of which are tightly attached to all elements of the portable telemedicine complex, while the foam tray is made of foam rubber with a density of 32-34 kg / m ³ , with a relative elongation of 240-280% and a tensile strength of 120-140 kPa.

In a preferred embodiment of the invention, polypropylene with reinforcing fibers is used as the polymeric material of the body. Also in a preferred embodiment

- 1 037472 of the invention, a battery based on lithium polymer batteries is used as a built-in accumulator and accumulators of devices. This type of battery was chosen due to its low weight, high current output and lack of memory effect.

The characteristics of the foam rubber for the manufacture of the tray were selected as follows. Made a series of samples of the proposed device with different characteristics of foam rubber and investigated their properties. For this, the samples were placed in a chamber with controlled temperature and humidity, and temperature and humidity sensors were installed inside four sample cells. During the experiment, the room temperature was lowered from 22 ° C to -60 ° C and kept at this level for an hour. During the specified time, the temperature and humidity inside the cells were measured. The decrease in battery charge for each sample was also measured. The results are shown in the table.

Table - Influence of the characteristics of foam rubber on the heat-conducting properties of the body and tray

P / p No. Properties of the foam rubber from which the tray was made Readings after 15 minutes in a room with a temperature of -60 ° C Readings after 60 minutes in a room with a temperature of -60 ° C density relative extension tensile strength average temperature in cells average relative humidity in cells reduced battery charge average temperature in cells average relative humidity in cells reduced battery power kg / m3 % kPa ° C % % ° C % % one 31 220 BY -21 33 four -27 31 eight 2 32 240 120 -eighteen 34 2 -nineteen 32 four 3 33 260 130 -17 36 2 -eighteen 34 3 four 34 280 140 -fifteen 37 2 -17 35 3 five 35 300 150 -fifteen 39 2 -eighteen 35 3

As a result of the tests carried out, it was revealed that when using samples No. 2, 3, 4 and 5 at a temperature of -60 ° C, the decrease in the battery charge does not exceed 4%, which is a fairly good indicator. When using sample 1, there is a noticeable, in comparison with other samples, difference in the decrease in the battery charge, which makes it inexpedient to use these characteristics. At the same time, no significant differences are observed in the properties of sample 5 and sample 4. The change in humidity inside the housing of each sample was negligible. Taking into account the fact that it is an important task for the claimed device to maintain a relatively low weight, the characteristics of sample 5 are impractical to use. Based on this, it can be concluded that the most optimal characteristics of foam rubber for making a tray are a density of 32-34 kg / m ³ , a relative elongation of 240-280% and a tensile strength of 120-140 kPa.

The claimed device is illustrated by a drawing, where the figure shows the claimed portable telemedicine complex with an open lid.

The portable telemedicine complex contains a case 1, in which a control module 2 with a display (for example, a laptop), a built-in battery and a power supply unit for it, as well as measuring instruments 3 and a power supply module 4 with charging compartments for instrument batteries are installed. Also, housing 1 is equipped with a network connector (not shown in the drawing). In this case, the power module contains battery chargers (preferably additional batteries based on lithium-polymer batteries), which are connected to the mains connector, and the mains connector is connected to the power supply connected to the control module 2 with the display and its battery. In addition, the complex is equipped with a USB interface connected to control module 2 with a display. In this case, the housing 1 is made of a polymer material, in particular of polypropylene with reinforcing fibers. Inside the housing 1 there is a foam rubber tray 5, the walls of the cells of which fit tightly to all the elements of the portable telemedicine complex. In this case, the foam rubber tray is made of foam rubber with a density of 32-34 kg / m ³ , with a relative elongation of 240-280% and a tensile strength of 120-140 kPa. The portable telemedicine complex can contain samples from the following list as measuring devices: electric digital thermometer; medical small-sized video camera (endoscope); electronic stethoscope; electrocardiograph; pulse oximeter; tonometer; breathalyzer; glucometer; urine analyzer; portable biochemical blood analyzer. In the most preferred embodiment of the invention, the housing is protected against moisture and dust according to the IP67 standard. All components are connected to the control module 2 and fixed in the housing 1 by means of assembly operations during the manufacture of the claimed portable telemedicine complex.

The claimed invention works as follows.

During operation, the operator lifts the housing cover 1 to access the control module 2 with the display and other components of the complex. The power supply from the built-in battery is supplied to control module 2 with display. The devices are powered from the built-in batteries, which can be replaced by taking them from the power module 4. If it is possible to connect to the mains through the mains connector, the power supply from the mains connector through the power supply is transmitted to the control module 2 with the display and to the built-in battery, as well as power supply goes from the network connector to the power supply module 4

- 2 037472 for charging instrument batteries via chargers. The operator enters the required data, follows the instructions on the display and uses the appropriate measuring device 3 (for example, a tonometer). If necessary, the operator can contact another video communication specialist. In addition, the measurement data is analyzed and, if necessary, transmitted remotely to the main server. With some measurement results, which are considered critical according to the database of the control module 2, a message appears on the display about the need for urgent medical attention and / or hospitalization, the same message is sent to the main server.

The claimed invention is illustrated by examples.

Example 1.

For additional tests, a telemedicine complex was assembled according to the claimed invention. A PAVILION 15-ck032ur laptop (Hewlett-Packard, USA) was used as a control module, which was additionally equipped with a GR-388UA USB hub (GiNZZU, China) and an E3372h-153 2G / 3G / 4G USB modem (HUAWEI, China ). The body was made of polypropylene with reinforcing fibers. Inside the body there is a foam track, the cell walls of which fit tightly to all elements of the portable telemedicine complex. In this case, the foam rubber tray is made of foam rubber with a density of 32 kg / m ³ , with a relative elongation of 240% and a tensile strength of 120 kPa. Eco Temp Basic MC-246-RU (Omron, Japan) was used as a thermometer. The chamber head KG-001 (Axioma, Russia) was used as an endoscope. We also used an electronic ViScope MD stethoscope (HD Medical Group, India), an EK1T-1 / 3-07 electrocardiograph (Axion, Russia), an MD300C318 CHOICEMMED pulse oximeter (Beijing Choice Electronic Tech Co., Ltd, China), a Mit Elite Plus HEM tonometer -7301-ITKE7 (Omron, Japan), breathalyzer E 010 (Dingo, South Korea), One Touch Select Plus glucometer (One Touch, USA), Clinitek Status + urine analyzer (Siemens Healthcare Diagnostics, USA), portable biochemical blood analyzer CardioChek PA (Polymer Technology Systems, USA). We also chose the LiPO Rombica Neo X2 AA 1600mAh (Rombica, China) and LiPO Rombica Neo X3 AAA 400mAh (Rombica, China) batteries, which were fully charged before the experiment.

This device was placed in a temperature and humidity controlled chamber, and temperature and humidity sensors were installed inside four sample cells. During the experiment, the room temperature was lowered from 22 ° C to -60 ° C and kept at this level for an hour. During the specified time, the temperature and humidity inside the cells were measured. The decrease in battery charge was also measured.

As a result of the tests, the humidity inside the cells practically did not change, and the temperature dropped in the first 15 min to -17 ° C, and after 60 min from the beginning of the experiment to -19 ° C. In this case, the battery charge decreased by 2% in the first 15 minutes, and after 60 minutes from the beginning of the experiment by 3%.

After the end of the experiment, all the elements of the device were checked at room temperature. No damage or malfunctioning was found.

Example 2.

For additional tests, a telemedicine complex was assembled according to the claimed invention. An ACER Aspire 3 A315-5351V7 laptop (Acer, Taiwan) was used as a control module, which was additionally equipped with a UH-700 USB hub (TP-LINK, China) and an MF833T USB modem (ZTE, China). The body was made of polypropylene with reinforcing fibers. Inside the body there is a foam track, the cell walls of which fit tightly to all elements of the portable telemedicine complex. In this case, the foam rubber tray is made of foam rubber with a density of 34 kg / m ³ , with a relative elongation of 280% and a tensile strength of 140 kPa. Miaomiaoce MMC W201 (Xiaomi, China) was used as a thermometer. A Full HD video camera Endoscopic (Optimed, Russia) was used as an endoscope. We also used a 3200BK27 electronic stethoscope (3M Littmann, USA), an EK12T-01-R-D electrocardiograph (Axion, Russia), a YX200 pulse oximeter (ARMED, Russia), an iHealth 2 tonometer (Xiaomi, China), a Lion SD 500 breathalyzer (Lion Laboratories Ltd., UK), Accu-Chek Mobile glucometer (Roche Diagnostics, Germany), Laura Smart urine analyzer (Erba Lachema, Czech Republic), AccuTrend Plus portable biochemical blood analyzer (Roche Diagnostics, Germany). We also selected LiPO ZNTER AA 1250mAh (ZNTER, China) and LiPO ZNTER AAA 600mAh (ZNTER, China) batteries, which were fully charged prior to the experiment.

The test setup was identical to example 1.

As a result of the tests, the humidity inside the cells practically did not change, and the temperature dropped in the first 15 min to -14 ° C, and after 60 min from the beginning of the experiment to -16 ° C. In this case, the battery charge decreased by 1% in the first 15 minutes, and after 60 minutes from the beginning of the experiment by 3%.

After the end of the experiment, all the elements of the device were checked at room temperature. No damage or malfunctioning was found.

Thus, a portable telemedicine complex has been developed, which makes it possible to increase the time of uninterrupted autonomous operation of the complex during transportation at low temperatures while maintaining a low weight of the product.

- 3 037472

List of sources

1) Telemedicine - prospects and difficulties before a new stage of development. Baranov A.A. and etc.

Journal of Pediatric Pharmacology, 2013. URL: https://cyberleninka.ru/article/n/telemeditsina- perspektivy-i-trudnosti-pered-novym-etapom-razvitiya [date of access - 14.08.2019].

2) Organization of telemedicine consultations in polar expeditions. Yu.I. Senkevich Biotechnosphere Journal, 2009. URL: https://cyberleninka.ru/article/n/organizatsiya-telemeditsinskih-konsultatsiy-vpolyarnyh-ekspeditsiyah [access date - 14.08.2019].

3) Mobile telemedicine complex: Application No. US 2017024537, United States of America, App. 07.24.2015, publ. 26.01.2017.

4) Instrument unit of a wearable medical diagnostic complex: patent No. 188138, Russian Federation, application No. RU 2018131316, app. 08/31/2018, publ. 04/01/2019.

Claims (6)

CLAIM 1. A portable telemedicine complex containing a control module with a display and a built-in battery and a case, as well as measuring instruments and a power module installed in it, while the case is equipped with a network connector mated with a power module, characterized in that the control module with a display is located inside case, and the power module contains battery chargers connected to the network connector, the network connector is also connected to the control module with the display and its battery, and the complex additionally includes a USB interface connected to the control module, while the case is made of polymer material, and inside the case a foam rubber tray is located, the walls of the cells of which are tightly attached to all elements of the portable telemedicine complex, while the foam rubber tray is made of foam rubber with a density of 32-34 kg / m ³ , with a relative elongation of 240-280% and a tensile strength of 120-140 kPa. 2. A portable telemedicine complex according to claim 1, characterized in that polypropylene with reinforcing fibers is used as the polymer body material. 3. A portable telemedicine complex according to claim 1, characterized in that accumulators based on lithium-polymer batteries are used as chargers in the power module. 4. Portable telemedicine complex according to claim 1, characterized in that a battery based on lithium polymer batteries is used as a built-in battery in the control module. 5. Portable telemedicine complex according to claim 1, characterized in that accumulators based on lithium-polymer batteries are used as accumulators of devices. 6. Portable telemedicine complex according to claim 1, characterized in that the case is protected against moisture and dust IP67.