RU2677050C1 - Radonarium - Google Patents

Abstract

FIELD: medical equipment.SUBSTANCE: invention relates to medical equipment. Radonarium consists of a treatment area, a technological compartment and changing rooms. In the treatment area there is a steam radon emanatorium, radon piscina, radon emanatorium. Steam radar emanatorium is equipped with a steam generator and equipped with benches for patients. Radon piscina is made in the form of a two-tier bowl and is equipped with a filter for continuous water purification. In the technological compartment there is a hood and a special metering device. Three radon lines connect the metering device to the steam generator of the steam radon emanatorium, radon piscina and radon emanatorium. In addition, in the technological compartment there is a steam generator control panel, an emanatorium control panel, climate control systems, steam emanatorium and emanatorium, video surveillance system for patients, Petryanov filter for air purification in emanatorium from the daughter products of radon decay products. Treatment area and the technological compartment are equipped with supply and exhaust ventilation systems.EFFECT: proposed device allows to change the conditions of the procedure release: temperature and humidity of the treatment environment, radon content in the air-radon mixture, emanatorium, in the steam and radon mixture of the steam emanatorium and in the water of piscina, due to which it is possible to regulate the effective dose absorbed by the patients.1 cl, 3 dwg

Description

The present invention relates to medical equipment and can be used in institutions of practical health care: hospitals, clinics, sanatoriums, dispensaries, rehabilitation and rehabilitation medical centers.

The relevance of the invention lies in the widespread occurrence of diseases in which its use is effective (diseases of the organs of support and movement, nervous, cardiovascular, respiratory systems, skin, endocrine diseases, gynecological pathology).

The relevance of the invention also lies in the fact that the device can be used all year round, regardless of the season, in any area; binding to a natural source of radon is not required.

Radon therapy has long been successfully used to treat a wide variety of diseases; general and local procedures apply. The most commonly used general radon procedures are bathing in radon water, airborne radon baths and radon inhalations.

Separate forms of radon therapy are more effective for different pathologies. So, water baths have proven their high efficiency in the treatment of diseases of the musculoskeletal system, endocrine diseases, air baths in the treatment of skin diseases, radon emanatoriums in the pathology of joints and spine; radon inhalations are most effective for diseases of the respiratory system, while radon inhalation procedures are most effective for diseases of the cardiovascular system (Balneotherapy Issues in the Resorts of the Tajik SSR. Dushanbe, 1966. 167 pp.).

Radioactive plaque on the skin and mucous membranes of patients, as well as the effective dose of radiation absorbed by them after different radon procedures, is different [Panov S.V. Radioactive plaque on the skin after radon procedures. Questions of balneology, physiotherapy and exercise therapy. Moscow, 2016. No. 2].

The radon procedure is equally effective in various diseases neither at natural radon resorts, nor at radon therapy centers using radon obtained in radon laboratories.

Natural analogues of the invention are the emanatorium in Bad Gastein, the pararadon emanatorium in Khoja Obi Garm and the radon scribe on the island of Ishia.

The natural radon emanatorium in Bad Gastein in the Austrian Alps is a developed adit. Radon enters the air of caves from rocks containing radium. The concentration of radon in the air is 150 Bq / l, the air temperature is 38-40 ° C, the air humidity is close to 100%, the treatment time is 60 minutes. The main indications for treatment in the emanatorium are diseases of the musculoskeletal system. The disadvantage is the remoteness of the resort and the inability to a large number of patients to visit it and take treatment. In addition, only the air-radon mixture has a therapeutic effect.

In the alpine resort of Khoja Obi Garm (Tajikistan) there is a natural steam-radon emanatorium. At a height of 1800 meters, steam-radon mixture flows through cracks in the rock. At the top of the cliff in the built pavilions are patients. The radon concentration is 15 Bq / l, the relative humidity is 100%, the temperature of the air-vapor-radon mixture is 40-50 ° C, the procedure time is 5-15 minutes. The most effective pararadon emanatorium in the treatment of patients with pathology of the cardiovascular system. Disadvantages - the remoteness of the resort, only the air-vapor-radon mixture has a therapeutic effect.

Radon scribbles on the island of Ischea (Italy) were the first place where warm radon springs began to be used by people for medicinal purposes [Pratzel H.G., Deetjen P. Radon in der Kurortmedizin: Zum Nutzenund vermeindlichen Risiko einertraditionellen medizinischen Anwendung. - I.S.M.H. Verlag, 1997. - S.246]. This island has 69 steam sources and 29 thermal reservoirs; the concentration of radon in scissors is from 0.4 to 5.4 kBq / l. Effective in the treatment of diseases of the musculoskeletal system.

The closest in technical essence to the proposed radarium are inhalation and steam emanatorium.

The inhalation for group radon procedures (Patent No. 2269329 of 02/10/2006) consists of a treatment chamber and utility rooms. In the technical room there is a portion bottle with radon concentrate and a microcompressor. Radon is supplied through the radon conduit to the treatment chamber. For air saturation with radon, an evaporator with an aqueous radon concentrate with an ultrasonic head is installed in the chamber. Exemption from the daughter products of the decay of radon occurs in the Petryanov filter. The patient is exposed to an air-radon mixture on the body. The patient receives an air radon bath and radon inhalation. There is no effect on the body of the vapor-radon mixture and radon water. In addition, the inaccuracy of the dosage of radon in the second half of the procedure is a drawback.

The controlled steam-radon emanatorium (Patent No. 2530766 dated 08/15/2014) consists of a steam generator located in a treatment chamber, into which radon concentrate is fed from portioned bottles through a metering device. The steam generator emits an air-steam-radon mixture of a given radon activity, temperature and humidity.

The disadvantage of this device is that the patient receives only para-radon inhalations. There is no exposure to air-radon mixture (in which the content of radon is much higher) and radon water.

The technical result of the proposed radonarium is the possibility of obtaining and exposure to patients of air-radon, steam-air-radon mixture and radon water given concentrations of radon with its subsequent maintenance in treatment media at the same level throughout the procedure, while the effective dose of radiation absorbed by the patient can be changed depending on the diagnosis and severity of the disease.

The specified technical result is achieved by the fact that the radonarium is a radon emanatorium, a radonarium emanatorium, a radon scribble and a technological compartment equipped with microclimate and video surveillance systems for patients, while the technological compartment is equipped with a metering device consisting of a regulator for the discharge of radon, a storage chamber and three radon pipelines with diameters of 1 mm, 8 mm and 11 mm for the proportional distribution of radon over the three treatment rooms of the radonarium, respectively venno, paroemanatoriya, emanatorium pistsiny and radon and radon activity maintaining constant in them during the procedure.

Description of the radonarium device

The radonarium consists (see Fig. 1) of the treatment area, technological compartment and locker rooms. In the treatment zone are located a radon emanatorium (I), a radon scribe (II), a radon emanatorium (III). The steam-radon emanatorium is equipped with a steam generator (1) and equipped with benches for patients (2). The radon scribe is made in the form of a two-level bowl and is equipped with a filter (3) for continuous water treatment. There are patient benches in the radon emanatorium (2). In the technological compartment (IV) there is a fume hood (4), a metering device (5). Three radon pipelines connect the dosing device to the steam generator of the vapor-radon emanatorium (6), radon scribble (7) and radon emanatorium (8). In addition, a steam generator control panel (9), an emanatorium control panel (10), a microclimate control system for a steam emanatorium (11) and an emanatorium (12), a video surveillance system for patients (13), a Petryanov filter (14) for cleaning are installed in the technological compartment air emanatorium from decay products of radon. Physiotherapeutic hours and a dosimeter are located right there. Patient undress rooms (V, VI) have individual wardrobes (15).

The treatment zone and the technological compartment (see Fig. 2) are equipped with supply (P1, P2, P3) and exhaust ventilation systems (B1, B2). The P-3 and B-2 systems operate continuously during the operation of the radonarium, the P-1, P-2 and B-1 systems turn on at the end of the procedure and last 30 minutes. At the end of the working day, all ventilation systems function for 60 minutes after the end of the last procedure.

The dosing device (see Fig. 3) consists of a distribution chamber (17) and a regulator for the flow rate of radon concentrate (16). Outlets from the distribution chamber radon piping go into the steam emanatorium (20), the emanatorium (18) and the scribble (19). The diameters of radon pipelines are different and calculated in proportion to a given concentration of radon in three treatment environments. The volume ratio of paraemanatoriya / emanatorium / pistsiny is 8 m ^3/25 m ^3/5 m ^3; the ratio of radon concentrations is 15 Bq / l / 150 Bq / l / 1500 Bq / l, the ratio of the product of the volume of the room to the concentration of radon in it is 120/3750 / 7500. Accordingly, to simultaneously obtain the required radon activity in three treatment rooms, the diameter of the pipe the radon conduit to the steam emanatorium is 1 mm, to the emanatorium 8 mm, to the scribble - 11 mm. Dosing is carried out by changing the volumetric activity of radon in a portioned flask and changing the flow of radon concentrate by the flow rate controller.

Calculation of Radon Activity

The basic operating conditions of the radonarium are similar to its natural counterparts - the radon emanatorium in Bad Gastein (the concentration of radon in the air is 150 Bq / l, the air temperature is 38-40 ° C, the air humidity is close to 100%), the radonarium emanatorium in Khoja Ob -Harm (concentration of radon - 15 Bq / l, relative humidity - 100%, temperature of the air-vapor-radon mixture - 40-500) and scissins in the resort of Ischea in Italy (the concentration of radon in the water of most sciscins - 1500 Bq / l) .

Empirically, it was found that the content of radon in the treatment media of the steam emanatorium, emanatorium and scissinum decreases during the procedure. Loss of radon occurs due to its natural decay, adsorption on the walls of rooms, adsorption on the skin and bronchial tree of the patient and absorption into the blood of the patient. The total loss of radon per hour is 1/7 of the initial activity.

Target radon activity in the treatment medium: in the steam-air-radon mixture of the steam emanatorium - 15 Bq / l, in the air-radon mixture in the emanatorium - 150 Bq / l, in the water of the radon scribe - 1500 Bq / l.

To achieve the desired concentration of radon in treatment media, 11.37 MBq of radon will be required: in the steam emanatorium 120 kBq (15 Bq × 8000 l), in the emanatorium 3750 kBq (150 Bq × 25000 l), in the scribble - 7500 kBq (1500 Bq × 5000 l). In the future, in order to maintain the given concentrations of radon in the treatment media, it is necessary to apply 1/7 of this amount of radon - 1.6 MBq (11.37 MBq / 7 = 1.6 MBq) evenly over the course of an hour. Thus, for the treatment procedure in radonarium within 60 minutes, 13 MBq of radon will be needed.

If necessary, to change the activity of radon in the treatment media up or down, the calculation is made in a similar way.

Calculation of the equivalent dose received by the patient

A patient undergoing treatment in the radonarium will receive radiation exposure by inhalation of radon in the steam emanatorium and emanatorium and upon precipitation of the decay products of radon on the skin in the vapor emanatorium, emanatorium and scribe. The sum of these effects will be the effective dose absorbed by the patient during the procedure.

Recommended treatment regimen in the emanatorium: 15 minutes in the steam emanatorium, 15 minutes in the radon piscine and 30 minutes in the emanatorium.

Absorbed effective doses (PED) will be:

PED of the skin when piscina is in radon water - 0.18 meV;

Lung PED when in the steam emanatorium - 0.0024 meV (0.24 / 100);

PED of the skin when in the steam emanatorium - 0.0076 meV (0.76 / 100);

Lung PED when in the emanatorium - 0.048 meV (2 × 0.24 / 10);

PED of the skin when in the emanatorium - 0.152 meV (2 × 0.76 / 10);

The total effective dose absorbed by the patient will be 0.39 meV.

The change in the effective dose absorbed by the patient during the procedure is achieved by changing (decreasing) the duration of the procedure, as well as changing (decreasing or increasing) the activity of radon in a portioned flask, and, accordingly, in the treatment rooms of the radonarium.

Description of the radonarium

An hour before the start of the procedure, the nurse includes a steam generator, heaters and humidifiers in the steam emanatorium and emanatorium, setting the specified microclimate parameters in the treatment rooms of the radonarium. Within an hour, the air temperature in the steam emanatorium will rise to 50-60 ° С, the air humidity will become about 100%, the air temperature in the emanatorium will be 35-39 ° С, and the air humidity will be about 100%.

Immediately before the start of the procedure, a nurse in a fume hood (4) attaches a 1.5-liter flask with a radon concentrate with a total activity of 13 MBq to a dosing device (5).

Patients undress in locker rooms (V, VI), then go to the treatment area.

The nurse sets the regime in the expiry speed regulator, in which 1310 ml of radon concentrate are transferred to the dispensing chamber of the dosing device immediately, and the remaining 190 ml then, gradually, over 60 minutes. Radon coming from the flask into the distribution chamber is sent through radon lines to the treatment rooms of the radonarium in the established proportions. As a result, the radon concentration in the steam generator is set to 15 Bq / l, in the emanatorium - 150, Bq / l, in the scribble - 1500 Bq / l.

Patients are informed about the recommended time spent in the para-emanatorium (15 minutes), the emanatorium (30 minutes) and the scribe (15 minutes).

A nurse through a video surveillance system monitors the condition of patients during treatment.

At the end of the procedure, patients leave the treatment area in the locker room, the nurse turns off the steam generator, heaters and humidifiers, turns on the supply (P1, P2,) and exhaust (B1) ventilation in the treatment area. Supply (P3) and exhaust (B2) ventilation in the technological compartment work continuously during the working day.

The proposed device allows you to change the conditions of dispensing procedures: temperature and humidity of the treatment medium, radon content in the air-radon mixture of the emanatorium, in the steam-air-radon mixture of the steam emanatorium and in the water of scribble, due to which it is possible to regulate the effective dose absorbed by patients.

The radonarium was developed and built in the sanatorium "Radon" in Ulyanovsk and is used in the medical practice of the sanatorium.

The construction of a network of radonariums is of great socio-economic importance and can make a significant contribution to the health of the population of the Russian Federation.

Literature

1. Gusarov I.I. Radon therapy. M .: Medicine, 2000, 200 p.

2. Panov S.V. Practical radon therapy. Ulyanovsk: UlSU, 2014, 172 p.

3. Razumov AN, Gusarov II, Filatov VI, Puzyreva G.A. Panov SV. To the 100th anniversary of radon therapy / Issues of balneology, physiotherapy and exercise therapy. Moscow, 2005, No. 6 and 2006, No. 1.

4. Issues of balneotherapy at the resorts of the Tajik SSR. Dushanbe, 1966. 167 p.

5. Panov SV, Radioactive plaque on the skin after radon procedures / Issues of balneology, physiotherapy and exercise therapy. Moscow, 2016. No. 2.

6. Panov S.V., Khaliullov I.E. Effective doses received by patients during treatment in the emanatorium / Questions of balneology, physiotherapy and exercise therapy. Moscow, 2017. Volume 94, Issue 2.

7. Panov S.V., Khaliullov I.E. Effective doses received by patients during treatment in the pararadon emanatorium / Questions of balneology, physiotherapy and exercise therapy. Moscow, 2017. Volume 94, Issue 2.

8. Patent No. 2269329 dated 02.10.2006. Inhalator for carrying out group radon procedures.

9. Patent No. 2530766 dated 08/15/2014. Guided vapor-radon emanatorium.

10. SP 2.6.1.3247-15 “Hygienic requirements for the placement, arrangement, equipment and operation of radon laboratories, radon therapy departments”.

Claims (1)

Radonarium, consisting of an emanatorium, steam emanatorium, radon scribe and a technological compartment equipped with microclimate and video surveillance systems for patients, characterized in that the technological compartment is equipped with a metering device consisting of a regulator for the flow rate of radon, a storage chamber and three radon wires with diameters of 1 mm, 8 mm and 11 mm for the proportional distribution of radon in the three treatment rooms of the radonarium, respectively, the steam emanatorium, the emanatorium and the radon scribe, as well as Maintaining constant activity of radon in them during the procedure.

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