WO2022060239A1

WO2022060239A1 - Probe for passing through channels (embodiments)

Info

Publication number: WO2022060239A1
Application number: PCT/RU2020/000491
Authority: WO
Inventors: Искандар Сагитович АЮХАНОВ
Original assignee: Искандар Сагитович АЮХАНОВ
Priority date: 2020-09-17
Filing date: 2020-09-22
Publication date: 2022-03-24
Also published as: RU2746640C1

Abstract

The claimed group of technical solutions relates primarily to the fields of medicine and geophysics and is intended for examining hollow spaces in horizontal, vertical or inclined directions, which may be straight or have a complex curved shape and a varying passage size, as well as for filling cavities between a piston and a cylinder, valves, rods and other reciprocating cylindrical mechanisms in order to protect, lubricate, seal or dissipate heat from same. A probe according to a first embodiment comprises an elastic elongate shell. The technical results are achieved in that the shell is toroidal and has two axially arranged walls (1, 2). The shell is configured from a flat plate that is turned in on itself and glued at the end. Between the outer and inner walls (1, 2) is a cavity containing elastic rings (4) that are mounted equidistantly, perpendicular to the axis of the shell. In the cavity of the probe according to a second embodiment, there is mounted an elastic tube (5). The cavity of the probe according to a third embodiment is hermetically sealed and is pressured by an elastic medium or is under a vacuum.

Description

PROBE FOR CHANNELS (VERSIONS)

The claimed group of technical solutions relates mainly to the fields of medicine and geophysics and is intended for the study of hollow spaces (pipes, wells, hollow organs of the food and circulatory system, etc.) in horizontal vertical and inclined directions, straight or having a complex curved shape, variable value clearance, also for filling the cavities between the piston and the cylinder, valves, stems and other cylindrical mechanisms with reciprocating motion in order to protect, lubricate, seal and remove heat.

Known, for example, endoscopic probe (RU 2246891 C2, 27.02.2005, [1]), containing a flexible sleeve, laid inside the base with the possibility of straightening and uniform supply from the proximal to the distal end.

In analogue [1] the probe contains a guide block, which is made with the possibility of bending the probe head relative to the base. The guide block is used to change the direction of the probe in bends and to avoid obstructions in the gastrointestinal tract. Most preferably, the guiding block comprises a series of opposing bellows and for turning the block, the bellows being inflatable with a gas or liquid supplied through the tubes.

Also known is a catheter (EP 1891914 A, February 27, 2008, [2]) containing a catheter in which an elongated stent with a piston is located.

Analog [2] piston diameter corresponds to the diameter of the lumen of the catheter. When using the device [2], the pressurized medium moves the helical stent through the catheter. The coiled stent is pulled through the catheter with a distal plunger.

Known probe (RU 2012366 C1, 15.05.1994, [3]), containing a hollow elastic tube with a deaf rounded working end. The probe guide is made in the form of a tightly coiled helical spring and is placed in the thickness of the wall of the elastic tube.

The specified analog [3] is the set of essential features the closest analogue of the same purpose to the claimed technical solutions. Therefore, it is adopted as a prototype.

The technical problem to be solved is the need to create a probe for the passage of channels without a limitation in length, as well as for the passage of difficult curved, thin-walled, with variable diameter, multidirectional cavities with minimal damage to their walls.

In analog [1], the capabilities of the device are limited by the overall dimensions of the endoscope, which do not allow the device to be used when moving in small cavities, in particular in vessels, and thus do not provide the ability to move the endoscope in the cavities and vessels of the body. In addition, the elements of the endoscope during operation completely cover the lumen of the organ under study, which also excludes its use in vessels, and does not provide sufficient contact pressure of the inflated elements on the areas of the tissue under study without a traumatic effect on the walls of the cavities, which makes it ineffective when moving the device around cavity channel.

Analogue [2] has limitations on the length of the passage of the cavities.

The disadvantage of the prototype [3] is the friction of the walls of the probe on the walls of the hollow body during translational motion. Also, the probe twists, which makes it difficult to advance and is not safe for the patient, as it can cause damage to the wall of a hollow organ.

The technical result provided by each invention from the group is an increase in the length of the passage of the probe through channels with different shapes and sizes.

Other technical results are:

- exclusion of friction of the walls of the probe against the walls of the channel;

- ensuring the passage of wells with a variable cross section and direction;

- ensuring the passage of the probe in the hollow tubular organs of the gastrointestinal tract, ureters and blood vessels;

- sealing, heat removal and lubrication in the cylinder-piston group.

The technical result according to option 1 is achieved by the fact that the probe for passing the channels contains an elastic elongated shell. It differs in that the shell is made toroidal and has two axially located walls, while the shell is made of a flat plate wrapped on itself and glued at the end, while a cavity is formed between the outer and inner walls, in which elastic rings are installed at an equal distance, perpendicularly shell axes.

The technical result according to option 2 is achieved by the fact that the probe for passing the channels contains an elastic elongated shell. It differs in that the shell is made toroidal and has two axially located walls, while the shell is made of a flat plate wrapped on itself and glued at the end, while a cavity is formed between the outer and inner walls, in which an elastic pipe is installed.

The technical result according to option 3 is achieved by the fact that the probe for passing the channels contains an elastic elongated shell. It differs in that the shell is made toroidal and has two axially located walls, while the shell is made of a flat plate wrapped on itself and glued at the end, while a sealed cavity is formed between the outer and inner walls, which is subjected to pressure of an elastic medium or is under vacuum .

The author of the technical solutions of the declared group produced prototypes of these solutions, the tests of which confirmed the achievement of the technical result.

Figure 1 shows a probe for passing channels according to option 1; in fig. 2 - probe for the passage of channels according to option 2; in fig. 3 - probe for the passage of channels according to option 3; in fig. 4 is a general view of the probe according to option 3 for passing channels with a rod with a piston and a sleeve.

Implementation options for technical solutions.

The probe for the passage of channels according to option 1 (Fig. 1) contains an elastic toroidal shell with two axially located walls (1, 2). The shell is made of a flat plate wrapped on itself and glued at the end.

Between the outer and inner walls (1, 2) a hermetic or non-hermetic cavity (3) is formed, in which elastic rings (4) are installed at an equal distance, perpendicular to the shell axis.

The probe according to option 1 can be located between the piston with the rod and the cylinder in order to protect them (not shown). In addition, the probe can be used to penetrate wells and pass through the hollow tubular organs of the gastrointestinal tract, ureters, and blood vessels. The probe dimensions depend on the application.

Description of the work of the technical solution according to option 1.

The outer wall (1) is fixed motionless. For example, when inserting a probe with a sheath length of 12 m into the esophagus, the outer wall (1) is fixed by hand. Wherein the membrane moves throughout the human gastrointestinal tract. Such artificial fixation does not require close contact with hollow cavities, and the length of the probe should ensure the passage of the entire cavity.

During the movement of the shell, the inner wall (2) comes out from the inside and passes into the outer wall (1) at one end, causing the shell to move in the direction of this end. Accordingly, at the other end, the outer wall (1) passes into the end, and then into the inner wall (2). In this case, the rings (4) rotate.

The probe for the passage of channels according to option 2 (Fig. 2) contains an elastic toroidal shell with two axially located walls (1, 2). The shell is made of a flat plate wrapped on itself and glued at the end. Between the outer and inner walls (1, 2) a hermetic or non-hermetic cavity (3) is formed, in which an elastic pipe (5) is installed. The probe according to option 2 can be located between the piston with the rod and the cylinder in order to protect them (not shown). In addition, the probe can be used to penetrate wells and pass through the hollow tubular organs of the gastrointestinal tract, ureters, and blood vessels. The probe dimensions depend on the application.

Description of the work of the technical solution according to option 2.

The outer wall (1) is fixed motionless. For example, when inserting a probe with a sheath length of 12 m into the esophagus, the outer wall (1) is fixed by hand. In this case, the shell moves throughout the human gastrointestinal tract. Such artificial fixation does not require close contact with hollow cavities, and the length of the probe should ensure the passage of the entire cavity.

During the movement of the shell, the inner wall (2) comes out from the inside and passes into the outer wall (1) at one end, causing the shell to move in the direction of this end. Accordingly, at the other end, the outer wall (1) passes into the end, and then into the inner wall (2). The tube (5) provides rigidity and shape to the device.

The probe for the passage of channels according to option 3 (Fig. 3, 4) contains an elastic toroidal shell with two axially located walls (1, 2). The shell is made of a flat plate wrapped on itself and glued at the end. Between the outer and inner walls (1, 2) a sealed cavity (3) is formed, which is subjected to the pressure of an elastic medium (gas or liquid) or is under vacuum. The probe according to option 3 can be located between the piston (6) with the rod (7) and the cylinder (8) for the purpose of their protection, lubrication, sealing, heat removal (Fig. 4). In addition, the probe can be used to penetrate wells and pass through the hollow tubular organs of the gastrointestinal tract, ureters, and blood vessels. The probe dimensions depend on the application.

Description of the work of the technical solution according to option 3.

The outer wall (1) is fixed in place. For example, when a short-shell probe is introduced into a borehole, the outer wall (1) fits snugly against the walls of the hollow space due to the pressure of the medium. During the movement of the shell, the inner wall (2) comes out from the inside and passes into the outer wall (1) at one end, causing the shell to move in the direction of this end. Accordingly, at the other end, the outer wall (1) passes into the end, and then into the inner wall (2).

The probe according to option 3 is also placed between the piston (6) with the rod (7) and the cylinder (8) in order to protect, lubricate, seal and remove heat.

The proposed technical solution is implemented using commercially available devices and materials and will be widely used in areas where it is required to pass through hollow spaces without damaging their walls.

Claims

Claim

1. A probe for passage of channels, containing an elastic elongated shell, characterized in that the shell is made toroidal and has two axially located walls, while the shell is made of a flat plate, wrapped on itself and glued at the end, while between the outer and inner walls formed a cavity in which elastic rings are installed at an equal distance, perpendicular to the axis of the shell.

2. A probe for passage of channels, containing an elastic elongated shell, characterized in that the shell is made toroidal and has two axially located walls, while the shell is made of a flat plate wrapped on itself and glued at the end, while between the outer and inner walls is formed a cavity in which an elastic tube is installed.

3. A probe for passage of channels, containing an elastic elongated shell, characterized in that the shell is made toroidal and has two axially located walls, while the shell is made of a flat plate wrapped on itself and glued at the end, while between the outer and inner walls is formed a sealed cavity that is subjected to the pressure of an elastic medium or is under vacuum.