RU2648207C1 - Probe for measurement of abdominal pressure - Google Patents

Abstract

FIELD: medicine.

SUBSTANCE: invention refers to the medical technique, in particular to the probe for measuring the intra-abdominal pressure. Probe contains: the sheath of elastic material; the magnetic field sensor; the permanent magnet; and the nipple, which is sealed into the sheath and has a through passage in order to connect the inner volume of the probe to the external atmosphere and to output electrical wires from the magnetic field sensor to the outside. Permanent magnet and the magnetic field sensor are located in the inner volume of the probe. One of them is fixed on either the wall of the shell or on the insert of the rigid material, which is introduced into the shell, and the other one is fixed on the opposite shell wall or on the other side of the insert, with the possibility of detecting changes in the magnetic field by the magnetic field sensor when the difference between intra-abdominal pressure and external atmospheric pressure changes.

EFFECT: technical result consists in simplifying the design and increasing the ease of use while maintaining the accuracy of the measurements.

19 cl, 9 dwg

Description

FIELD OF THE INVENTION

This invention relates to medicine, and more particularly to a probe for measuring intra-abdominal pressure.

State of the art

Currently, gauge sensors are most often used to measure intra-abdominal pressure, such as, for example, described in the patent of the Russian Federation 2488346 (publ. 07.27.2013) and which represents drainage tubes inserted into the abdominal cavity, having elastic containers at the ends with liquid from which they depart elastic tubes to the pressure gauge. In particular, US Pat. No. 8,337,411 (published December 25, 2012) describes an intra-abdominal pressure tracking system in which a catheter is inserted through the urogenital system. A similar device is presented in the patent of the Russian Federation for utility model 68877 (publ. 10.12.2007).

All gauge sensors use probes in the form of an elastic balloon filled with liquid or air. Not to mention the inconvenience to the patient, such probes, in addition to filling the balloon itself and the connecting tubes with liquid, require a strictly defined and motionless location of the patient and are a significant obstacle, therefore, the determination of intra-abdominal pressure using such probes is well compatible with other operational actions of medical personnel.

Known indirect method for measuring intra-abdominal pressure according to the patent of the Russian Federation 2520764 (publ. 06/27/2014), in which air is pumped between the elastic membrane and the plate in contact with the abdominal cavity. A similar solution is known from US patent 6016707 (publ. 25.01.2000), in which the plate is oscillated using a magnetic rod placed inside a generator-powered coil. Such a device has a complex structure and low engineering reliability.

Disclosure of invention

Thus, there is a need to develop such a probe for measuring intra-abdominal pressure, which would have a simple design and sufficient accuracy, create minimal interference with the doctor’s operations, and be reliable and easy to use.

This task with the achievement of the specified result is solved in the present invention, offering a probe for measuring intra-abdominal pressure, comprising: a shell of elastic material; magnetic field sensor; permanent magnet; a nipple hermetically inserted into the shell and having a through channel to ensure the connection of the internal volume of the probe with the external atmosphere and to bring out the electric wires from the magnetic field sensor; wherein a permanent magnet and a magnetic field sensor are located in the internal volume of the probe, one of them being fixed to or in the wall of the shell or on an insert made of hard material inserted into the shell, and the other on the opposite wall of the shell or on the other side of the insert, with detect changes in the magnetic field by the magnetic field sensor when the difference between the intra-abdominal pressure and the external atmospheric pressure changes.

A feature of the probe of the present invention is that the shell can be made in the form of a cap.

Another feature of the probe of the present invention is that the cap may have an end cavity with a side flattened on the sides, while the magnetic field sensor can be placed on the inner surface of one of the walls of the flattened part, and the permanent magnet can be placed in the opposite wall or on its surface.

Another feature of the probe of the present invention is that an insert of rigid material can be placed inside the end cavity to stretch the walls of the cap to form a flattened part designed to accommodate the magnetic field sensor

Another feature of the probe of the present invention is that the magnetic field sensor can be fixed on the inner surface of one of the opposite walls of the flattened part, and the permanent magnet can be fixed on the inner surface of the other of the opposite walls or inside it.

Another feature of the probe of the present invention is that if there is an insert, the magnetic field sensor can be fixed to the insert, and the permanent magnet can be fixed to the inner surface of one of the walls of the flattened part or inside this wall, or the magnetic field sensor can be fixed on the inner surface of one of the walls of the flattened part, and a permanent magnet is fixed to the insert.

Another feature of the probe of the present invention is that the nipple can be made filling the entire inner space of the cap and having a transverse hole, while the magnetic field sensor can be mounted on the inner surface of one of the opposite walls of the cap located above the transverse hole, and a constant the magnet can be fixed on the inner surface of another of the opposite walls, or inside it.

Another feature of the probe of the present invention is that the nipple can be made filling the entire inner space of the cap and having a side recess for receiving a magnetic field sensor, while a permanent magnet can be fixed on the inner surface of the wall of the cap located above the side recess , or inside this wall.

Another feature of the probe of the present invention is that the magnetic field sensor can be placed in the expansion of the through channel in the nipple opposite the top of the cap, and a permanent magnet can be mounted on the inner surface of the wall at the top of the cap or inside this wall.

Another feature of the probe of the present invention is that the magnetic field sensor can be fixed on the inner surface of one of the opposite walls of the flattened part, and the permanent magnet can be fixed on the inner surface of the other of the opposite walls or inside it, while one of the opposite the walls can be made thinner than the other.

Another feature of the probe of the present invention is that the magnetic field sensor can be placed in the expansion of the through channel in the nipple, which is isolated from the external environment by an elastic membrane, while a permanent magnet is fixed on the inner surface of the elastic membrane or in its thickness, and the wall of the shell protruding beyond the elastic membrane can be made of at least one perforation.

Another feature of the probe of the present invention is that an annular groove may be provided on the outer surface of the nipple to accommodate an elastic pressure ring that secures the membrane to the nipple.

Another feature of the probe of the present invention is that the magnetic field sensor can be made in the form of a Hall sensor. In this case, near the Hall sensor from the side opposite to the permanent magnet, a magnetizing magnet can be located, the magnetic induction vector of which is directed opposite to the magnetic induction vector of the permanent magnet.

Another feature of the probe according to the first object of the present invention is that the nipple can be partially inserted into the cap, and the part protruding from the cap is intended to be inserted into the outer tube, while the through channel is made to provide a tight connection with the inner tube passing inside external tube.

Another feature of the probe of the present invention is that the nipple can be partially inserted into the shell from its rear side, and the part of the nipple protruding from the shell can be designed to be inserted into the outer tube, while the through channel in the nipple can be made to provide tight connection with the inner tube passing inside the outer tube.

Another feature of the probe of the present invention is that the through channel of the nipple can be adapted to hermetically insert the inner tube into it, or the nipple on the protruding portion of the shell can be equipped with a fitting for the hermetic insertion into the inner tube.

Finally, another feature of the probe of the present invention is that the elastic tube at its other end can be connected to the housing of the electrical connector, which can be connected to the external atmosphere and to which the connecting wires from the magnetic field sensor can be connected.

Brief Description of the Drawings

The invention is illustrated by drawings, where the same or similar elements are denoted by the same reference numerals.

 In FIG. 1 shows one embodiment of a probe of the present invention.

In FIG. 2 shows another embodiment of the probe of the present invention.

In FIG. 3 shows yet another embodiment of the probe of the present invention.

In FIG. 4 shows yet another embodiment of the probe of the present invention.

In FIG. 5 shows yet another embodiment of the probe of the present invention.

In FIG. 6 shows yet another embodiment of the probe of the present invention.

In FIG. 7 shows yet another embodiment of the probe of the present invention.

In FIG. 8 shows yet another embodiment of the probe of the present invention.

In FIG. 9 shows one embodiment of the probe of the present invention with tubes connected thereto.

Detailed Description of Embodiments

The intra-abdominal pressure probe according to any embodiment of the present invention comprises (Fig. 1) a sheath 1, for example, in the form of a cap, a permanent magnet 2, a magnetic field sensor 3 and a nipple 4.

The sheath 1 may be made of an elastic material, for example, such as silicone, or of another elastic material suitable for use in surgery. The shell 1 has an axially symmetric shape in a free state, for example, cylindrical with a rounded end, or spindle-shaped with a flat end, etc. In some embodiments, sheath 1 may have an open end (see FIG. 8).

The nipple 4, as can be seen from the attached drawings, is inserted into the shell 1 and has a through channel 8, designed to ensure the connection of the internal volume of the probe with the external atmosphere and to bring out the electric wires 9 from the sensor 3 of the magnetic field. The nipple 4 can be made, for example, of plastic and have, for example, a circular outer section of such a size that it is inserted into the casing 1 with force, providing a tight joint with the casing 1. In one embodiment, the nipple 4 is partially inserted into the casing 1 so that on its protruding part, it was possible to put on the outer tube 18, described below with reference to FIG. 9.

In several embodiments, the sheath 1 has an end cavity 5 formed between a rounded or flat top of the cap (sheath 1) and, for example, the end portion 6 of the nipple 4.

In one embodiment (Fig. 1), the cap-shaped shell 1 has a flattened part 7 near its end cavity 5, and in this flattened part 7 a permanent magnet 2 and a magnetic field sensor 3 are in magnetic interaction with each other (described later). Permanent magnet 2 can be placed in the wall of the flattened part 7 or outside on this wall. The flattened part 7 can be obtained either during the manufacture of the shell (cap) 1 (for example, with walls of different thicknesses) or by placing a flat insert inside the shell 1, which does not have the flattened part in the initial state, as described below with reference to FIG. 2 and 3. In FIG. 2a and 3a, and the probe is shown in a plan view, in FIG. 2, b and 3, b - in side view.

Permanent magnet 2 can be made of any magnetic material. In some embodiments, it is attached to the inner wall of the shell 1 either in the manufacture of the latter or with a suitable adhesive. In other embodiments, the permanent magnet 2 may be attached to the outer wall of the sheath 1. There are also possible embodiments in which the permanent magnet 2 is embedded in the wall of the sheath 1 in the manufacture of this sheath (cap).

The magnetic field sensor 3 can have any known to specialists or developed in the future implementation. For example, it can be made in the form of a Hall sensor or magnetoresistive sensor. In some embodiments, the implementation of the magnetic field sensor 3 is attached to the inner wall of the shell 1 with a suitable adhesive.

In the embodiments shown in FIG. 2 and 3, the flattened part 7 of the shell (cap) 1 is obtained by inserting an insert 10 of hard material inside it, intended to stretch the walls of the shell 1 and form a flattened part 7. The hard material of the insert 10 can be, for example, plastic. The shape of the insert 10 is preferably rounded, although other shapes are not excluded (oval, square with rounded edges, etc.). This form should allow the insert 10 to be placed inside the end cavity 5 of the shell 1 without damaging its integrity. For example, if the insert 10 is made of a disk shape, then the diameter of this insert 10 must exceed the transverse diameter of the shell (cap) 1 in its free (unstretched) state, so that when the insert 10 is inserted inside the shell 1, the edges of the insert 10 abut against the surface of the inner wall of the shell 1 and stretched it, forming a flattened part 7.

When using insert 10, a permanent magnet 2 or a magnetic field sensor 3 can be placed on one side of the insert 10 so that the other of these elements is on the other side of the insert 10. For example, if the permanent magnet 2 is mounted on the wall of the shell 1, then the sensor 3 the magnetic field can be mounted on the insert 10, and on the side facing away from the permanent magnet 2 (Fig. 2), and on the side facing the permanent magnet 2. And, conversely, a magnetic field sensor 3 can be mounted on the inner wall of the shell 1 then permanent magn t 2 may be mounted on any side of the insert 10 (FIG. 3).

In FIG. 4 shows an embodiment of a probe with a shell 1 having different stiffness in different parts of the wall. This can be achieved, for example, by making the walls of the shell 1 of the same elastic material, but of different thicknesses. In FIG. 4 shows a permanent magnet 2 embedded in one wall of the shell 1, while a magnetic field sensor 3 is fixed on the inner surface of another wall whose thickness is less than the opposite wall with a built-in permanent magnet 2.

In FIG. 5 shows another embodiment of the probe, in which the shell 1 is cylindrical with a flat top, on which or in which the permanent magnet 2 is placed. In this embodiment, the magnetic field sensor 3 is placed in the extension 11 of the through channel 8 in the nipple 4 opposite the top of the shell 1, made in the form of a cap. While the extension 11 plays the role of the end cavity 5.

In FIG. 6 shows another embodiment of the probe, in which the nipple 4 occupies almost the entire internal space of the shell 1 and has a transverse hole 12, while the magnetic field sensor 3 is mounted on the inner surface of one of the opposite walls of the shell 1 located above the transverse hole 13, and a constant magnet 2 is fixed on the outer or inner surface of another of the opposite walls of the shell 1 or inside it. In this case, the transverse hole 12 plays the role of the end cavity 5.

In FIG. 7 shows another embodiment of the probe, in which the nipple 4 occupies almost the entire inner space of the shell 1 and has a side recess 13 for receiving a magnetic field sensor 3 therein, and a permanent magnet 2 is fixed on the inner surface of the wall of the shell 1, located above the side recess 13 Permanent magnet 2 can be placed on the outer surface of this wall or inside it. The embodiment of FIG. 7 may be preferable for those measurements when the probe is inserted into the lumen between the intra-abdominal organs. In this embodiment, the side recess 13 plays the role of the end cavity 5.

In FIG. 7 and 8, reference numeral 14 denotes a magnetizing magnet located next to the magnetic field sensor 3, made in the form of a Hall sensor, and necessary to create the initial bias and, as a result, expand the dynamic range of the output signal and increase the sensitivity of the sensor. The magnetizing magnet 14 is installed so that its magnetic induction vector is directed opposite to the magnetic induction vector of the permanent magnet 2.

In FIG. 8 shows yet another embodiment of a probe in which a magnetic field sensor 3 is located in the through channel 8 of the nipple 4 in extension 11 on the holder. As seen in FIG. 8, facing outward (to the right in FIG. 8) the end face of the nipple 4 into which the extension 11 opens is isolated from the external environment by an elastic membrane 15. A permanent magnet 2 is placed on the inner surface of this membrane 15, however, it can also be placed on its outer surface, and in the thickness of the membrane itself 15. The membrane 15 is fixed at the end 6 of the nipple 4 in any suitable way. In particular, as shown in FIG. 8, an annular groove 16 is made on the outer surface of the nipple 4 near its end 6, in which an elastic pressure ring 17 is fixed, fixing the edges of the membrane 15 on the nipple 4.

The presence of a membrane 15 that isolates the magnetic field sensor 3 from the intraperitoneal fluid allows the shell 1 to be made with an open end, and one or several perforations 18 can be made in its wall protruding from the elastic membrane 15 to displace air and inflow of the intraperitoneal fluid to the membrane 15. In this case, higher measurement accuracy is provided, since the edges of the shell 1 protruding beyond the end of the sensor protect the membrane 15 from being touched by the walls of internal organs, creating additional pressure on it and distorting the result of measurements, which may occur when other probe embodiments are used.

In FIG. 9 shows an embodiment of the probe of FIG. 2 in an intra-abdominal pressure measurement system. An outer tube 19 is mounted on the part of the nipple 4 protruding from the shell 1 and is usually used as a drain in similar systems. In particular, if the outer tube 19 has an outer diameter of 8 mm, it is advisable to make the sheath 1 of the same diameter and the same material as the outer tube 19. In this case, the nipple 4 will have a diameter such that the sheath 1 and the outer tube 19 are worn on this nipple 4 with an effort to ensure tightness (no leakage of drained fluid). To seal the joints of the nipple 4 with the shell 1 and the outer tube 19 can be applied adhesive sealant. In FIG. 9, reference numerals 21 indicate drainage openings for discharging a drained fluid from an intra-abdominal cavity through an outlet 22 of a splitter 23. In FIG. 9 arrows show the direction of flow of the drained fluid.

In FIG. 9, an inner tube 20 extends inside the outer tube 19. One end of the inner tube 20 (right in FIG. 9) is hermetically inserted into the through channel 8 of the nipple 4. It is also possible to make the nipple 4 when its part protruding from the shell 1 has a fitting with a through channel 8, on which the inner tube 20 (not shown) is fitted. Those skilled in the art will appreciate that since the through passage 8 is smaller than the outer dimension of the nipple 4 itself, the inner tube 20 extending inside the outer tube 19 leaves enough space for the drained fluid to flow through the gap between the inner surface of the outer tube 19 and the outer surface of the inner tube 20. The purpose of the inner tube 20 is to create a relationship between the internal volume of the shell 1 (end cavity 5 in the case of the cap) and the external atmosphere and to provide a stationary pressure inside the cap equal to the external atmospheric pressure, as well as in creating an isolated dry channel for electric wires 9 coming from the sensor 3 of the magnetic field. The other end of the outer tube 19 is sealed on a splitter 23, through the outlet 22 of which drained fluid flows.

The other end of the inner tube 20 (left in Fig. 9) is connected to the inner channel 25 of the splitter 23, isolated from the rest of the splitter 23 and designed to pass wires 9 from the magnetic field sensor 3 and to connect the space surrounding the magnetic field sensor 3 inside the shell 1 , with the atmosphere through the housing 24 connectors. To the corresponding terminals of the connector in the housing 24 are connected connecting wires 9 from the sensor 3 of the magnetic field. The housing 24 is in communication with the atmosphere, i.e. it is not sealed. If drainage is not required, then the side holes 21 in the outer tube 19 are absent, and the inner tube 20 and the splitter 23 are also missing.

Note that in FIG. 8, the shell 1 with an open end can be formed by an outer tube, which is conventionally indicated by the reference numeral 19 in brackets, and the inner tube 20 is shown worn on the fitting of the through channel 8.

It will be apparent to those skilled in the art that some of those shown in FIG. 1-9 embodiments may be combined. For example, in the embodiment of FIG. 6, refined walls may be used, as described for the embodiment of FIG. four.

An intra-abdominal pressure probe according to any of the described embodiments of the present invention operates as follows.

The probe is placed in the abdominal cavity filled with internal organs, as well as, depending on the condition of the patient, intraperitoneal fluid (exudate, transudate, etc.) and free gas, which exert pressure on the outer surface of the shell 1 (cap) or elastic membrane 15 This pressure is the same as that on the abdominal wall, called intra-abdominal pressure. As a rule, this pressure is excessive in relation to atmospheric. The range of variation of intra-abdominal pressure is from 5 to 50 mm RT. Art. relative to atmospheric pressure.

Excessive relative atmospheric intra-abdominal pressure acts on the surface of the shell 1, bending its elastic wall into the shell 1 (or the elastic membrane 15 into the expansion 11 in the through channel 8). As a result, the relative position of the permanent magnet 2 and the magnetic field sensor 3 changes, which causes a change in the signal value of the magnetic field sensor 3, detected by a corresponding external device, to which wires from the magnetic field sensor 3 are connected through connector 24. Those skilled in the art will appreciate that the change in signal at the output of the magnetic field sensor 3 will be maximum when the permanent magnet 2 and the magnetic field sensor 3 are opposite each other, and the walls of the shell 1 bend under the action of a force directed along a conditional line connecting the permanent magnet 2 and magnetic field sensor 3. This condition is best observed, for example, in the case when the permanent magnet 2 and the magnetic field sensor 3 are on opposite walls of the flattened part 7 of the shell 1. If the shell 1 is made with walls of different thicknesses, then thinner sections of the wall will be less rigid and with the same change in the pressure difference between the inner and outer surfaces of the wall, they will bend more than the thicker (more rigid) sections of the wall, causing a change in the relative location of the permanent magnet 2 and sensor 3 magnet field. Placing one element of the magnet-sensor pair on the insert 10 reduces the distance between these elements, and therefore increases the sensitivity of the probe.

When using the Hall sensor, the magnetizing magnet 13 is facing the permanent magnet 2 with the same pole. Preferably, the permanent magnet 2 and the magnetizing magnet 13 are located at equal distances from the magnetic field sensor 3.

Since the abdominal cavity is filled with internal organs, such a medium can be considered liquid only conditionally, therefore Pascal's law in such an environment may not be locally fulfilled. Thus, by directly touching the wall of the internal organ to the sensitive surface of the probe, the output signal from the magnetic field sensor can be significantly distorted. The sensor design shown in FIG. 8, excludes touching the walls of the internal organs of the sensitive surface of the probe. The intra-abdominal pressure is transmitted to the membrane 15 either through the intra-abdominal fluid filling the open end of the membrane 1 in the form of a tube, or, in the absence or insufficiency of the intra-abdominal fluid, through the air that initially fills this cavity. Thus, the sensitive membrane 15 of the probe is always in an amorphous medium for which Pascal's law is fulfilled.

Specialists know the use of a permanent magnet paired with a magnetic field sensor for measuring pressure (see, for example, RF patent 2480724, publ. 04/27/2013). However, this sensor is used outside, it cannot be placed inside the patient’s abdominal cavity, therefore the use of this sensor for the indicated purposes will not differ from the use of any other gauge sensor and will have the same drawbacks that are noted in the “Prior art” section.

An important difference between the probe of the present invention and known pressure sensors is that the sensor is immersed directly in the medium in which the pressure is to be determined, which greatly simplifies the design of the sensor and significantly reduces the inconvenience caused to medical personnel. In this case, a pair of a permanent magnet 2 and a magnetic field sensor 3 is placed inside an elastic sealed shell 1, which accommodates a pressure sensor directly placed in the abdominal cavity through a small hole, without creating any additional traumatic influences and inconvenience compared to conventional drainage tubes long and widely used in medical practice. Note also that the probe system of the present invention performs, if required, the same functions as a conventional drainage tube.

It can be noted that a silicone tube probe with an external diameter of 8 mm and a wall thickness of 1 mm has already been made, inside of which there is a permanent magnet made of NdFeB in the form of a disk with a diameter of 3 mm and a thickness of 1 mm and a linear Hall sensor with a sensitivity of +45 mV / mT in case with dimensions ~ 3 × 2.5 mm. The sensor was tested by immersion in water, as a result of which a change in pressure per 1 mm Hg (less than 0.1 mm Hg) was reliably recorded in the pressure range 0-100 mm Hg. Art.

Thus, the probe for measuring intra-abdominal pressure of the present invention has a simple design, does not require a predetermined position of the patient during the determination of intra-abdominal pressure, injures the patient no more than a conventional drainage tube, and allows real-time monitoring of intra-abdominal pressure, minimizing interference to medical personnel , which during the control of abdominal pressure can freely perform other surgical actions with the patient. The probe of the present invention allows you to connect external devices for continuous monitoring and recording changes in intra-abdominal pressure over time (history), providing the attending staff with very important relevant information, and in case of intra-abdominal pressure exceeding pre-set limits, send control signals to other equipment and notify without delay medical personnel about such events that are necessary for timely adoption of operational measures.

Claims (24)

1. A probe for measuring intra-abdominal pressure, comprising: - sheath made of elastic material; - magnetic field sensor; - permanent magnet; - a nipple hermetically inserted into said sheath and having a through channel for ensuring the connection of the internal volume of the said probe with the external atmosphere and for bringing out the electric wires from the said magnetic field sensor, wherein said permanent magnet and magnetic field sensor are located in said inner volume of the probe, one of which is mounted on or in the wall of said shell or on an insert made of rigid material inserted into said shell, and the other on the opposite wall of said shell or another the side of said insert, with the possibility of detecting changes in the magnetic field of said magnetic field sensor when the difference between the intra-abdominal pressure and the external atmospheric pressure changes. 2. The probe according to claim 1, wherein said shell is made in the form of a cap. 3. The probe according to claim 2, wherein said cap has an end cavity with a part flattened on the sides, said magnetic field sensor is placed on the inner surface of one of the walls of said flattened part, and a permanent magnet is placed on the opposite wall or on its surface. 4. The probe of claim 2, wherein an insert of rigid material is placed inside said end cavity to stretch the walls of said cap to form a flattened portion for receiving said magnetic field sensor. 5. The probe according to claim 3 or 4, in which said magnetic field sensor is fixed on the inner surface of one of the opposite walls of said flattened part, and said permanent magnet is fixed on the inner surface of another of said opposite walls or inside. 6. The probe according to claim 4, in which said magnetic field sensor is fixed to said insert, and said permanent magnet is fixed to the inner surface of one of the walls of said flattened part or inside this wall. 7. The probe according to claim 4, in which said magnetic field sensor is fixed on the inner surface of one of the walls of said flattened part, and said permanent magnet is fixed on said insert. 8. The probe according to claim 2, wherein said nipple is made filling the entire inner space of said cap and having a transverse hole, said magnetic field sensor being fixed to the inner surface of one of the opposite walls of said cap located above said transverse hole, and said constant the magnet is fixed on the inner surface of the other of the mentioned opposite walls or inside it. 9. The probe according to claim 2, wherein said nipple is made filling the entire inner space of said cap and having a side recess for receiving said magnetic field sensor therein, said permanent magnet being fixed to an inner surface of a wall of said cap located above said side recess , or inside this wall. 10. The probe according to claim 2, wherein said magnetic field sensor is located in the extension of said through channel in said nipple opposite the top of said cap, and a permanent magnet is fixed on or inside the wall of the said top of the cap. 11. The probe according to claim 3, in which said magnetic field sensor is fixed on the inner surface of one of the opposite walls of said flattened part, and said permanent magnet is fixed on the inner surface of another of said opposite walls or inside, while one of said opposite walls made smaller than the other. 12. The probe according to claim 1, wherein said magnetic field sensor is located in the expansion of said through channel in said nipple, which is isolated from the external environment by an elastic membrane, said permanent magnet being fixed on the inner surface of the elastic membrane or in its thickness, and at least one perforation is made to the wall of said shell protruding beyond said elastic membrane. 13. The probe according to claim 12, in which an annular groove is made on the outer surface of said nipple, designed to receive an elastic pressure ring that fixes said membrane on said nipple. 14. The probe according to claim 1, wherein said magnetic field sensor is made in the form of a Hall sensor. 15. The probe according to claim 14, wherein, next to said Hall sensor, on the side opposite to said permanent magnet, a magnetizing magnet is located, the magnetic induction vector of which is directed opposite to the magnetic induction vector of said permanent magnet. 16. The probe according to claim 1, wherein said nipple is partially inserted into the said shell from its rear side, and a portion of said nipple protruding from said shell is intended to be inserted into the outer tube, wherein said through passage in said nipple is made to provide a tight connection with an inner tube extending inside said outer tube. 17. The probe of claim 16, wherein said through passage is adapted to hermetically insert said inner tube into it. 18. The probe of claim 16, wherein said nipple on a portion protruding from said shell is provided with a fitting for hermetically inserting into said inner tube. 19. The probe according to any one of paragraphs. 16-18, in which the said inner tube at its other end is connected to the housing of the electrical connector, which is connected with the external atmosphere and to which the aforementioned connecting wires are connected from the magnetic field sensor.

Images