RU2095050C1 - Inhalation apparatus for performing physiotherapeutic procedures - Google Patents

Abstract

FIELD: medical engineering. SUBSTANCE: inhalation apparatus has sectional body consisting of two parts provided with channels, flexible membrane with conical wedge-type valve, guide nozzle, and bearing flange. Valve base rests upon guide nozzle surface at output. Space behind membrane communicates with atmosphere through holes in body. EFFECT: enhanced reliability. 9 dwg

Description

 The invention relates to medicine, in particular to medical equipment and can be used in devices for influencing the patient's respiratory system, for example, in breathing apparatus for physiotherapy procedures and for improving the design of the valve means in them.

 Known breathing apparatus using disk or flap valves made of elastomeric materials, see copyright certificate of the USSR N 339288, cl. A 62 B 7/04, 1972; N 324034, CL A 62 B 9/02, 1971; N 419227, cl. A 62 B 9/02, 1974; N 812300, class A 62 B 9/02, 1981; N 186100, CL A 61 M 16/20, 1966; N 577038, class A 61 M 16/20, 1977; N 442218, CL A 61 M 16/20, 1988.

 These devices have ease of manufacture, but require mandatory adjustment of resistance to inhalation and exhalation during breathing or physiotherapy using the appropriate interference of the valve petal, which complicates their maintenance.

 Known breathing apparatus with replaceable antimicrobial filters or tips, see ed. USSR N 1833745, class A 61 M 16/00, 1993, European Patent No. 0299481, class. A 61 M 16/00, 1990.

 The disadvantages of these breathing apparatus are the additional time spent on their maintenance during the period when the maximum possible use of the device is required in extreme situations and a continuous procedure is necessary.

 Compared with the described breathing apparatus, breathing apparatus with closing valves is known, see Auto Review. USSR N 812299, class A 61 B 9/02, 1981; N 1382479, CL A 61 M 16/00, 1988; application of Germany N 3416350, CL A 61 M 16/00, 1988.

 The closest analogues are devices with an elastic membrane with a closing valve, presented in European application N 0139363, class. A 61 M 16/00, 1985 and the application of Germany N 2915683, class. A 61 M 16/00, 1980 (Finland priority 1978).

 Their common drawback is the slamming of the valves of the elastic membranes upon exhalation of the patient, which creates a jump in the supplied air flow, adversely affecting the well-being of the patient.

 The application of Germany No. 2915683 is accepted as a prototype, which describes a breathing apparatus for physiotherapeutic procedures, comprising a detachable body with a supply and discharge channels, an elastic membrane with an external annular girdle and a convex hollow wedge-shaped closing valve with a through slotted opening at the end in its central part, directed into the discharge channel, communicated by its membrane cavity through openings in the housing with the atmosphere.

 In addition to the aforementioned drawbacks of the apparatus, when performing it with an elastic membrane with a valve made of a material more elastic, it is possible not only to slam the valve when exhaling, but also to open it in the opposite direction to the feed channel, which impairs its sterile quality and reliability.

 The main objective of the invention is the creation of a breathing apparatus for physiotherapeutic procedures with an elastic membrane with a convex hollow wedge-shaped closing valve of such a design that would ensure highly effective physiotherapy procedures, would eliminate the slamming of the valve.

 The purpose of the invention is to ensure reliability and increase reliability.

 The problem and the stated objective of the invention are achieved by ensuring the directed action of the discharge air flow and preloading it when inhaling into the valve, covering the elastic membrane and the base of the valve when it closes during exhalation.

 For this purpose, in a breathing apparatus for physiotherapeutic procedures, comprising a detachable body with supply and discharge channels, an elastic membrane with an external annular girdle and a convex hollow wedge-shaped closing valve with a through slotted opening at the end in its central part directed into the delivery channel communicated by its membrane cavity through holes in the case with the atmosphere, the wedge-shaped closing valve of the elastic membrane is equipped with a centrally located guide nozzle installed in an outlet at the outlet of the supply channel, made with a shortened confuser with the possibility of supplying air flow to the discharge channel through the valve cavity, a support flange mounted at the housing connector with support on the outer annular zone of the elastic membrane, and an outer cone-shaped surface for expansion of the valve base when it is slammed with the length of the generatrix selected between 0.25-0.35 the length of the lateral generatrix of the wedge-shaped valve with an angle of sharpening selected between 63-67 and the guide nozzle is made ormoustoychivym profile of a material less flexible than the membrane, such a material as the housing unit.

The distinctive features of the proposed breathing apparatus for physiotherapy procedures are the following features:
supplying a wedge-shaped valve of the elastic membrane with a centrally located guide nozzle;
installed in the housing on the exhalation of the supply channel;
made with a shortened confuser;
with the possibility of supplying an air stream to the discharge channel through the valve cavity;
with a support flange fixed at the housing connector with support on the outer annular band of the elastic membrane;
and an outer conical surface for expanding the base of the valve when it is slammed;
with the length of the generatrix selected in the range of 0.25-0.35 the length of the lateral generatrix of the wedge-shaped valve with an angle of sharpening selected in the range of 63-67 ^o ;
the implementation of the nozzle with a form-stable profile of material, as the body of the apparatus.

 These distinctive features are significant, each of them individually and jointly aimed at solving the problem and achieving a new positive effect in accordance with the purpose of the invention. The exclusion of any of them does not allow to solve the task. So, for example, the exclusion of a guide nozzle made with these features characterizes the breathing apparatus with the essential features of a prototype.

 A comparative analysis of the essential distinguishing features of the respiratory apparatus shows their absence in this technical field, their use in other analogues and prototype was not found, which characterizes the proposed technical solution by the novelty of these signs and the compliance with the criterion of "Novelty".

 A single set of new and general essential features of the proposed technical solution allows us to solve the problem and achieve the goal of the invention by supplying a hollow wedge-shaped valve of an elastic membrane with a guide nozzle with new significant features, which characterizes the proposed technical solution with significant differences from the prior art, analogues and prototype. The proposed technical solution is the result of scientific research and creative contribution, obtained without the use of well-known design solutions and reference-regulatory recommendations and meets the criterion of "Inventive step".

 In FIG. 1 shows a General view of the breathing apparatus for physiotherapy; in FIG. 2 upper part of the housing with a feed channel; in FIG. 3 a guide nozzle; in FIG. 4 an elastic membrane with a convex hollow closing valve; in Fig: the lower part of the housing with a discharge channel; in FIG. 6 section AA in figure 1; in Fig.7 section BB in Fig.1; in FIG. 8 diagram of the operation of the elastic membrane when applying the air flow through the feed channel; in FIG. 9 diagram of the operation of the elastic membrane during the reverse exhalation of air through the discharge channel.

 The breathing apparatus for physiotherapeutic procedures contains a detachable body consisting of upper and lower parts 1 and 2, respectively, with the supply and discharge channels 3 and 4, an elastic membrane 5 with an external annular girdle 6 and a convex hollow wedge-shaped closing valve 7 with a through slotted cut 8 on the end in its central part, directed into the discharge channel 4, communicated by its membrane cavity 9 through the holes 10 in the lower part 2 of the housing with the atmosphere, made with a mouthpiece 11.

The wedge-shaped valve 7 of the elastic membrane 5 is provided with a guide nozzle 12 located centrally with it, mounted in the housing at the outlet of the supply channel 3, made with a shortened confuser 13 with the possibility of supplying air flow to the discharge valve 4 through the cavity 14 of the valve 7, a supporting flange 15, fixed at connector 16 of the housing between its upper part 1 and the elastic membrane 5 with the support on its outer annular girdle 6, pressed from the opposite side by the lower part 2 of the housing, and the outer conical surface 17 for time to the base 18 of the valve 7, with the collapse of its length with a generatrix selected between 0.25-0.35 length of the side forming wedge valve 7, with its wedge angle selected in the range 63-67 ^o, wherein the nozzle guide 12 is formed with dimensional stability profile of material less elastic than the membrane 5, for example from a material that the apparatus body, its upper and lower parts 1 and 2, for example from thermoplastic.

 The casing of the apparatus, consisting of the upper and lower parts 1 and 2, is its bearing base, the upper part 1 of the casing is designed to connect to it either a resuscitator, or an autonomous source of periodic air supply through its supply channel 3, the lower part 2 of the casing is designed to be installed in the patient’s oral cavity and fixation on it with a mouthpiece 11 for supplying a fresh air stream through the injection channel 4 and exhaling through it into the membrane cavity 9 and through the openings 10 into the atmosphere.

The elastic membrane 5 is the most important element of the breathing apparatus and performs several functions, the main of which is the separation of the supplied exhaled air flows, timely overlapping of channels 3 and 4 and openings 10 and sealing of the connector 16. Overlapping of channels 3 and 4 is achieved by closing the valve 7 upon exhalation of the patient , the air supply from channel 3 to channel 4 is provided by opening section 8 of valve 7. When the air flow from channel 3 to channel 4 is supplied, the elastic membrane 5 is stretched and blocks the openings 10
The guide nozzle 12 is designed to compress the supplied air flow through the channel 3 by means of a shortened confuser 13 having a length determined by the presence of a conical surface 17 on the nozzle 12. The confuser 13 provides the direction of supply of the compressed air flow directly to the slotted section 8 of the closing valve 7 and opening valve 7 without vibration of its elastic wall, supplying a concentrated air stream to channel 4. The channel of the confuser can be made both conical and chewing, i.e. th transition from the channel 3 to the end edge 13 of the converging tube.

 The length of the generatrix of the conical surface 17 of the guide nozzle 12 is determined experimentally, taking into account the value of the angle of tapering of the valve 7, which provides its functionality together with the elastic membrane 5 to instantly open when the air stream is supplied and to close instantly when it is exhaled by the patient.

 The implementation of the conical surface 17 with a length less than 0.25 of the length of the generatrix of the wedge-shaped valve 7 leads to its slamming into the confuser 13, with a new supply of the air flow under the influence of the elastic forces of the membrane, secondary cotton and flow vibration are observed, which is unacceptable due to the influence on the uniformity of the increase in the feed flow.

 The implementation of a cone-shaped surface 17 with a length greater than 0.35 of the length of the generatrix of the wedge-shaped valve 7 leads to an increase in the percentage of its non-closure upon exhalation of the patient, which is unacceptable due to the return air flow into the channel 3.

The limiting ratio of the lengths of these elements is most effectively realized when the angle of sharpening of the wedge-shaped valve 7 in the range of 63-67 ^o . When the angle of sharpening is greater than 67 ^o , a similar pattern is observed with the valve 7 slamming into the nozzle 12 upon exhalation and the formation of cotton when a fresh air stream is fed into channel 3, which is unacceptable. When the angle of sharpening is less than 63 ^o , sticking of the valve 7 along the slotted section 8 may occur, caused by the deposition of moisture on the walls of the valve, bending it to one side upon exhalation, which also leads to cotton.

For practical implementation, the most effective ratios and angles were adopted: 0.3 of the length of the generatrix of the wedge-shaped valve 7 for the length of the guide nozzle 12 along its generatrix and 65 ^{o the} angle of the valve 7.

 Through the flange 15, which is the reference one, the outer ring girdle 6 is pressed with the upper part 1 of the housing to its lower part 2 and the membrane cavity 9 is adjusted accordingly between the elastic membrane 5 and the lower part 2 of the housing to ensure adequate air backflow and outflow through the housing openings 10 upon exhalation . In this case, the outer annular girdle 6 can be solid or corrugated, depending on the elasticity of the material from which the membrane 5 is made.

 The functioning of the respiratory apparatus for physiotherapy procedures is as follows.

 After being released from the package, the apparatus with the lower part 2 of the case is installed in the patient’s oral cavity with fixation by a mouthpiece 11, and through its upper part 1 and channel 3, a resuscitator or cyclically operating autonomous installation is supplied with air flow, which is compressed in the confuser 13, instantly opens the valve with its pressure 7 and enters the channel 4. Upon termination of supply and exhalation, the slit 8 closes, and the valve 7 closes and the base 18 settles on the conical surface 17 of the guide nozzle 12 and is on it in closed position until the reverse air flow expires upon exhalation through channel 4 into the membrane cavity 9 and through it and openings 10 into the atmosphere. Then follows the next cycle of supply and exhalation of air until then, until the full physiotherapeutic procedure is carried out. After that, the device is removed, disinfected, dried and placed in a sterile packaging.

 Based on the new technical solution, prototypes of the breathing apparatus were made; their tests during physiotherapeutic procedures showed positive results, the effectiveness and feasibility of industrial production and use in medicine.

 Thus, the new technical solution meets the criterion of "Industrial applicability", that is, the level of invention.

Claims (1)

A breathing apparatus for physiotherapeutic procedures, comprising a two-part detachable case with supply and discharge channels connected to them, an elastic membrane placed in the case with an external annular girdle and a central through slotted opening, closed by a wedge-shaped closing valve, the convex part of which is directed into the discharge channel and holes made in the housing for communication of the membrane part of the internal cavity with the atmosphere, characterized in that it is introduced axial to the valve, a guide nozzle mounted in the housing at the outlet of the supply channel, made in the form of a truncated confuser and made of a material less elastic than the membrane, and a support flange fixed in place of the housing connector and resting on the outer annular band of the elastic membrane, while supporting the flange has an outer conical surface for expanding the base of the valve when it is slammed, and the length of its generatrix is 0.25 0.35 of the length of the generatrix of the valve at an angle of its taper 63 67 ^o .

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