RU24548U1 - SENSOR CARRIER FOR IN-TUBE INSPECTION EQUIPMENT (OPTIONS) - Google Patents

Description

IPC 7: G01B5 / 28, F17D5 / 00, G01 N27 / 72, G01 N29 / 04

Sensor carrier for in-tube inspection shell (options).

The claimed group of utility models (inventions) relates to devices used for in-line inspection of long pipelines, mainly oil pipelines, oil pipelines, and gas pipelines by non-destructive methods by passing an inspection shell inside the pipeline with control sensors installed on it that are sensitive to any diagnostic parameters of the pipeline, namely, for mounting sensors and providing the necessary spatial Assumption relatively pipeline inspection pig when moving.

Known sensor carriers for in-tube inspection projectile with seats for sensors located on a surface with axial symmetry (fit into the surface with axial symmetry).

The carrier is characterized in that it includes a housing and radially spring loaded sensor holders, with seats for the sensors.

The use of these devices does not allow obtaining a resolution sufficient to identify defects such as pitting corrosion or cracks in the pipe wall.

Known sensor carriers for in-tube inspection projectile with seats for sensors located on a surface with axial symmetry (fit into the surface with axial symmetry).

The carrier is characterized in that it includes a housing and one or more belts of radially spring-loaded sensor holders mounted on the housing using articulated joints. In each holder there are seats for sensors.

The advantages of such a carrier include the fact that the rows of sensors allow you to scan the entire surface of the pipeline with overlapping zones controlled by individual sensors.

The main disadvantage of such a carrier is that when passing a section of a pipeline with a geometrical dent type defect, the sensor holders behave like rigid elements, and a collision of the front part of the holder with a dent (protrusion on the inner surface of the pipeline) is accompanied by the departure of the entire holder from the undeformed part of the pipeline. As a result of increasing the distance between the sensors and the inner surface of the pipeline, the efficiency of the sensors decreases, and such sections of the pipeline with geometric defects remain uncontrolled.

Known carrier sensors 33 for in-tube inspection projectile with seats for sensors located on the surface with axial symmetry.

The carrier is characterized in that it includes an elastic cuff, the diameter of which is less than the inner diameter of the pipeline, on the periphery

cuffs installed control sensors that fit into a cylinder whose diameter exceeds the diameter of the cuff.

The advantages of such a carrier include the fact that when passing through a pipeline section with a slight geometric defect such as a dent, the sensors are adjacent to the deformed surface of the pipeline.

The main disadvantage of such a carrier is that, due to the arrangement of the sensors in the form of a single belt, the maximum achievable linear resolution of the inspection projectile is limited due to the finite distance between adjacent sensors and the size of the sensors.

In addition, the carrier passing sections of the pipeline with significant geometry defects in its section is accompanied by the removal of sensors from the undeformed part of the pipeline near the geometry defect, as well as the collapse of the cuff with the sensors. When monitoring a pipeline consisting of pipes with significantly different pipe wall thicknesses, for example, in the presence of previously repaired pipeline sections, in areas with an increased wall thickness, and also if there is an extraneous fixed object on the pipeline surface, the passage of the sensor carrier may be accompanied by a collapse of the cuff with loss orientation of the sensor part.

In addition, installing the sensors outside will damage the sensors on obstacles such as washers.

A prototype of the claimed group of inventions is a known sensor carrier 34 for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry.

The carrier is characterized in that it is made in the form of a cylindrical elastic cuff, the tape convexities of which form a cylinder, the diameter

which is larger than the internal diameter of the pipeline, the sensors are located in the tape recesses of the cuff, the tape bulges and recesses are oriented at an acute angle to the axis of the cuff.

The advantages of such a carrier include the fact that the sensors installed at an angle to the axis of the carrier allow you to scan the entire surface of the pipeline with overlapping zones controlled by individual sensors; the installation of sensors in the recesses of the cuff protects them from damage on obstacles such as washers; when passing a section of a pipeline with a geometrical defect such as a dent, the sensors are adjacent to the deformed and undeformed surface of the pipeline both along the axis and along the perimeter of the pipeline.

The disadvantages of such a carrier include the installation of a large number of sensors on the elastic cuff with cables connected to them (in order to obtain high linear resolution) or the use of sufficiently heavy sensors (for example, magnetic) with a large length and small thickness of the cuff and, accordingly, good elasticity, leads to deformation of the elastic cuff under the total weight of the sensors and cables with the formation of a gap between the sensors in the upper part of the elastic cuff and the inner surface of the pipeline, ora prevents the squeeze uniform cuff to the inner wall of the tube while filling the conveyed medium chamber run. An increase in cuff stiffness (to avoid this phenomenon) is accompanied by a loss of cuff elasticity when enveloping defects in the geometry of the pipeline and the formation of gaps between the sensors and the inner surface of the pipeline near the geometry defect.

In addition, gaps between the sensors and the inner surface of the pipeline occur when enveloping geometry defects with sensors,

installed near the front wall of the cuff, the ability of which is compressed in a plane passing through the axis of the carrier, is significantly less than in the portion of the cuff remote from its front wall.

The claimed group of utility models (inventions) solves the problem of reducing the number of diagnostic passes of inspection shells and reducing, accordingly, the time limit for the flow of the pumped product due to the technical results achieved using the claimed utility models.

The main technical result (common for all variants of the group) obtained as a result of implementing any of the utility models described below is to increase the reliability of predicting the operability of a pipeline according to the results of in-line inspection of pipelines having various types of geometry defects in the section, as well as consisting of pipes with different wall thickness and having repaired plots. For all variants of the group, the result is achieved by increasing the resolution for pipeline flaw detection (by increasing the number of sensors allowed for installation and evenly adhering the sensors to the wall) while reducing data distance gaps, and, accordingly, increasing the information content of diagnostic data for each detected defect.

An additional technical result, common to all variants of the claimed group of inventions, which is an independent element of the mechanism for achieving the previously mentioned main technical result, a decrease in the proportion of sensors whose orientation relative to the inner surface of the pipeline changes when the carrier passes the defect

geometry in the cross section of the pipeline due to an increase in the number of independently fixed and oriented sensors in the region of the defect in the geometry of the pipe.

Each of the sensor carriers, characterized by signs corresponding to one or more of the declared variants of the group, has a preference for use depending on the type and condition of the pipeline being examined and the type of its geometric defects.

So, when examining pipelines with dents, the following options are preferred for the claimed group of utility models (inventions):

The mechanism for achieving the indicated technical result for the following options is that when the carrier passes through a pipe section with a defect, the elasticity of the carrier with the parameters listed below, ensuring (at any required length of the carrier) the carrier's patency at bends and in the constrictions in the cross section (including those formed geometry defects in the section), allows to increase the number of sensors and improve the uniformity of the sensors to fit to the wall.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

the length of the cuff in the direction of its axis is not less than the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile including an elastic material cuff with seats

for sensors located on a surface with axial symmetry, characterized in that

the carrier also includes an elastic collar installed in the front and / or in the back of the carrier, the peripheral surface of which fits into the cylinder concentric with the pipeline, cuts or undercuts are made in the peripheral parts of the cuff lying in a plane passing at an angle from O to 45 degrees to media axis.

Sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, the seats for sensors form rows oriented at an acute angle to the axis of the cuff, characterized in that

the number of seats in the row is at least 5.

Sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, the cuff is corrugated, characterized in that

the inner surface of the cuff rests on a cylinder whose diameter is not more than 0.8 of the diameter of the cylinder into which the cuff fits.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

the diameter of the cylinder into which the cuff fits is not more than 33 cm.

Sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, the cuff is corrugated, characterized in that

the number of convex parts of the corrugations on one cuff is 0.3-5.0 expressed in inches of the diameter of the cylinder into which the cuff fits.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes several (many) connected (kinematically) between these cuffs.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

radial cuts are made in the cuff.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

cuts are made in the cuff at an angle from O to 30 degrees to the cuff axis, the length of the cuts is from 0.3 to 0.8 the length of the cuff.

for sensors located on a surface with axial symmetry, characterized in that

Cuts are made in the cuff, the length of the cuts is from 0.3 to 0.8, the length of the cuff along the axis of the carrier.

A sensor carrier for an in-tube inspection projectile, including a housing, a cuff of elastic material mounted on the housing with seats for sensors located on a surface with axial symmetry, characterized in that

radial cuts and / or cuts are made in the cuff at an angle from O to 30 degrees to the cuff axis, the carrier includes a support in the form of an elastic element with axial symmetry mounted on the housing coaxially with the cuff, the back of the cuff is fastened to the specified support.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

the cuff is made integral and includes a front part, the outer diameter of which increases in the direction from the front to the back, and the rear cylindrical part attached to it. The front part of the cuff is made in a shape close to conical or elliptical, or parabolic.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes an elastic support in the form of a disk and / or cuff, and / or an elastic corrugated element with axial symmetry, the support is mounted coaxially with a cuff with seats for sensors in its middle and / or rear part, a cuff with seats for its sensors The inner part is supported by a support.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes at least two supports in the form of disks and / or cuffs and / or elastic corrugated elements with axial symmetry; the supports are mounted coaxially with a cuff with sensor seats, which relies on its supports for its internal part.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a support in the form of a disk and / or cuff, and / or in the form of an elastic corrugated element with axial symmetry, the support is mounted coaxially with the cuff with seats for sensors in the front and / or middle and / or back of the cuff, which The inner part is supported by a support.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

.

the carrier includes a support in the form of a disk and / or cuff, and / or in the form of a corrugated element with axial symmetry, the support is installed coaxially with a cuff with seats for sensors, which relies on the support with its inner part, the thickness of the support is from 0.007 to 0 , 07 of the diameter of the cylinder into which the support fits.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

The (average) cuff thickness is between 0.04 and 0.1 times the diameter of the cylinder into which the cuff fits.

When examining pipelines from different thickness pipes, the following options are preferred for the claimed group of utility models (inventions):

The mechanism for achieving the specified technical result for the following options is that the use of skids (and supports) with the parameters listed below allows to separate the functions of clamping sensors and enveloping obstacles, and the skids provide clamping with the necessary rigidity, and enveloping is achieved due to the multiplicity of holders.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes many runners with seats for sensors, the length of these runners is from 0.4 to 0.8 of the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a support in the form of an elastic disk with runners mounted on the support with seats for sensors, (average) the thickness of the disk is from 0.01 to 0.1 of the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a support in the form of an elastic cuff with runners mounted on the support with seats for sensors, the (average) thickness of the cuff is from 0.005 to 0.1 of the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes at least two supports in the form of elastic disks and / or elastic cuffs, and / or in the form of corrugated elastic elements with axial symmetry with runners mounted on the supports with seats for sensors.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a support in the form of a corrugated elastic element with axial symmetry, as well as runners mounted on the support with seats for sensors.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes many runners with seats for sensors, runners are connected to adjacent runners using elastic elements made of a polymeric material.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of runners with seats for sensors, the runners are connected to neighboring runners using elastic elements made of stainless or spring steel.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes an elastic support with axial symmetry with runners mounted on the support with seats for sensors, the runners are connected to adjacent runners using elastic V-shaped elements.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of runners with seats for sensors, the length of said runners is not more than 0.8 of the diameter of the cylinder into which the carrier fits, (average) the thickness of the run is not more than 0.1 of the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes many rigid runners with seats for sensors, at least 10 seats for sensors are made on one runner.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of runners with seats for sensors, the seats for sensors form rows oriented at an acute angle to the axis of the carrier, the number of rows on the run is at least three.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of runners with seats for sensors, the seats for sensors form rows oriented at an angle of 20 to 45 degrees to the axis of the carrier.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of kinematically connected runners with seats for sensors, the runners are grouped into runner belts mounted around the axis of the carrier, the carrier includes at least three runner belts.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the media includes many kinematically connected hard

runners with seats for sensors, (average) runner width

is not more than 0.25 of the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a housing and a plurality of inelastic runners with seats for sensors, the runners are kinematically connected to the housing and / or adjacent runners by elastic elements of elastic material.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the seats for the sensors are made in the form of holes with a diameter of not more than 14 mm.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

seats for sensors are made in the form of holes for sensors with an electrical output of the sensor at an angle of 60 to 150 degrees to the axis of the sensor.

One of the elements of the mechanism for achieving the specified technical result for the following options is that the use of differently oriented sensors with respect to the inner surface of the pipeline improves the information content of the data from differently oriented sensors and increases the resolution of the projectile.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes many rigid and / or elastic runners with seats for the sensors, the seats for the sensors are made in the form of holes whose axes are oriented at an angle of five to thirty degrees to the radial line passing through the axis of the hole and the axis of the carrier.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes many rigid and / or elastic runners with sensors installed in them, whose axes are oriented at an angle of five to thirty degrees to the radial line passing through the axis of the sensor and the axis of the carrier.

Sensor carrier for an in-tube inspection projectile including an elastic material cuff with seats

for sensors located on a surface with axial symmetry, characterized in that

the seats for the sensors are made in the form of holes, the axes of which are oriented at an angle from lat to thirty degrees to the radial line passing through the axis of the hole and the axis of the carrier.

Sensor carrier for an in-tube inspection projectile, including a cuff made of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that sensors are installed in the seats, the axes of which are oriented at an angle of five to thirty degrees to the radial line passing through the axis of the sensor and the axis of the medium.

When examining pipelines with deformed linings, fixed on the inner surface of the pipeline with foreign objects, segmented bends, dents with large deformation, and also with small radius bends, the following variants of the claimed group of utility models (inventions) are preferred:

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a support in the form of an elastic disk and / or cuff, and / or in the form of a corrugated element with axial symmetry with elastic runners mounted on the support with seats for sensors.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a support installed in the front and / or middle part of the carrier in the form of an elastic disk and / or cuff, and / or in the form of a corrugated elastic element with axial symmetry with elastic runners mounted on the support with seats for sensors.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes many elastic runners with seats for sensors, the length of these runners is not more than 0.8 of the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of elastic runners with seats for sensors, the (average) runner width is from 0.07 to 0.35 of the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of elastic runners with seats for sensors, (average) the thickness of the runner is from 0.07 to 0.1 of the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of elastic runners with seats for sensors, the length of said runners is not less than 0.7 of the diameter of the cylinder into which the carrier fits, the thickness of the run is from 0.03 to 0.15 of the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a housing and a plurality of elastic runners with seats for sensors, elastic runners are connected to the housing by elastic elements, seats for sensors are made in the form of holes whose axes are oriented at an angle of no more than ten degrees to the radial line passing through the hole and axis carrier.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a support in the form of an elastic cuff or elastic disk, as well as many elastic runners with seats for sensors, elastic runners are connected to a support, the seats for sensors are made in the form of holes whose axes are oriented at an angle of no more than ten degrees to the radial line passing through the hole and the axis of the media.

The mechanism for achieving the indicated technical result for the following options is that the pressing of the elements to the pipe wall is determined by the elasticity of the elements of each holder, regardless of the elements of the adjacent holder, so the indent of the sensor from the inner surface of the pipeline practically does not change when the carrier passes through the defect

geometry. The functions of clamping sensors and enveloping obstacles are separated, and ring holders can provide a fairly rigid clamp, and enveloping is achieved due to the multiplicity of holders, the peripheral parts of which are deformed independently of neighboring ring-shaped holders.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on an axial surface

symmetry, characterized in that

the carrier includes at least one annular sensor holder with sensor seats in kinematically connected elements of the ring-shaped holder.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes annular sensor holders with sensor seats in kinematically connected to each other

elements of ring-shaped holders.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

includes at least one elastic ring with seats for sensors.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

includes interconnected elastic rings with seats for sensors.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

includes a spiral-shaped sensor holder with ice caps for the sensors, the seats form one or more helical lines around the axis of the carrier.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

includes at least one elastic corrugated element with axial symmetry in which the seats for the sensors are made, the length of the element along the axis of the carrier does not exceed half the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

includes many elastic corrugated elements with axial symmetry, in which the seats for the sensors are made.

The length of the elements along the axis of the carrier does not exceed half the diameter of the cylinder into which the carrier fits.

The mechanism for achieving the indicated technical result for the following options consists in the fact that the pressing of kinematically connected elements to the pipe wall is determined by the force of elastic pressing of the element under

by a skid irrespective of the pressing force of the element under an adjacent skid, and the indent of the sensor from the inner surface of the pipeline, specified by the gasket in the form of a skid, practically does not change when the carrier passes through a geometry defect. At the same time, the functions of clamping sensors and enveloping obstacles are separated, and improving the envelope of obstacles due to the multiplicity of gaskets in the form of runners and their elasticity does not affect the force of clamping elements, which in this case can be quite large. In addition, the implementation of these variants of the group allows you to protect the sensors from damage in places of geometry defects, as well as to prevent the wear of elements with sensors, replacing only gaskets as they wear out.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

The carrier includes kinematically connected elements with sensor seats, as well as elastic gaskets that can slide along the inner surface of the pipeline between elements with sensor seats and the inner surface of the pipeline.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of kinematically connected elements with sensor seats, as well as elastic gaskets connected to elements capable of sliding on the inner surface of the pipeline between elements with sensor seats and the inner surface of the pipeline.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of runners with seats for sensors, as well as elastic gaskets capable of sliding along the inner surface of the pipeline between runners with seats for sensors and the inner surface of the pipeline.

A sensor carrier for an in-tube inspection projectile including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of gaskets between the seats for sensors and the inner surface of the pipeline.

The mechanism for achieving the indicated technical result for the following options is that when the carrier passes through a pipe section with a geometry defect, the kinematic connection with the housing of the elements with sensor seats ensures (at any required carrier length) the carrier is passable at bends and in narrowings in cross section (including those formed by geometry defects in cross section) due to the ability of the body to bend, it allows the elements to be pressed against the inner surface of the pipeline sufficient strength regardless of the item's location on the housing; The functions of clamping sensors and enveloping obstacles are thus separated.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a housing and a plurality of elements connected to the housing with seats for sensors, the housing is capable of bending.

The length of the non-bending sections of the housing along the axis of the carrier does not exceed half the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a housing and a plurality of elements connected to the housing with seats for sensors, the housing contains rigid links, as well as articulated joints between the links, the length of the rigid housing link along the axis of the carrier does not exceed half the diameter of the cylinder into which the carrier fits.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a housing and a plurality of elements connected to the housing with seats for sensors, the housing contains rigid links, as well as elastic joints between the links.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a housing and a plurality of elements connected to the housing with seats for sensors, the housing contains elastic links and articulated joints between the links. The elastic links are made of elastic material.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a housing and a plurality of elements connected to the housing with seats for sensors, the housing includes a bundle or cable, or hose, or bellows, or spring, or elastic band.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a housing and a plurality of elements connected to the housing with seats for sensors, the housing is made on the basis of (in the form of) a tow or cable, or a hose, or a bellows, or a spring, or an elastic strip.

The mechanism for achieving the indicated technical result for the following options is that when the carrier passes through a pipe section with a geometry defect, a number of grouped elements undergo bending, and both elements with sensors in the pipe deformation zone and elements with sensors in undeformed are pressed to the inner surface of the pipeline the pipe zone, while the ability to bend around geometry defects is determined by the relative mobility between adjacent elements in each row, regardless of the elasticity of the material and from which the

grouped items; The functions of clamping sensors and enveloping obstacles are thus separated.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes interconnected rows of grouped elements with seats for sensors, each element of the series is kinematically connected with neighboring elements of the series.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes interconnected rows of grouped elements with seats for sensors, the elements of the series form articulated and / or elastic joints with adjacent elements of the same row.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes interconnected rows of grouped elements with seats for sensors, row elements form hinges with adjacent elements of the same row, hinges between adjacent elements of the row are formed by the surfaces of the row elements at the contact points of adjacent row elements.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes interconnected rows of grouped elements with seats for sensors, each row is formed by elements adjacent to each other.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

The carrier includes interconnected rows of grouped elements with seats for sensors, each row of elements is pulled together by an elastic element capable of bending.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes interconnected rows of grouped elements with seats for sensors, each row of elements is pulled together by an elastic element in the form of a bundle or cable, or tape, or tube, or bellows, or spring.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes interconnected rows of grouped elements with seats for sensors, neighboring elements in each row are pressed against each other.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

The carrier includes interconnected rows of grouped elements with seats for sensors, grouped elements have centering elements centering relative to adjacent elements of the row in the form of protrusions and grooves, so that the protrusions of one element enter the grooves of the neighboring element.

The mechanism for achieving the technical result for the following options is that when the carrier passes through a pipe section with a geometry defect, the holder (element) goes around an obstacle: at the beginning of the movement, the front part of the holder is closer to the pipeline axis than the back, at the end of the envelope movement, the back of the holder the belt is closer to the axis of the pipeline than the front. In this case, the belt holders adjacent around the perimeter around the axis of the carrier above the defect-free sections of the pipeline do not produce similar envelope movements, and the indent between the sensors installed in these holders and the inner surface of the pipeline practically does not change. In this case, the functions of clamping sensors and enveloping obstacles are separated, and the rigid clamp provided by the elastic elements does not affect the ability of holders to circumvent obstacles in this way.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a belt of kinematically connected sensor holders with seats for sensors mounted around the perimeter around the axis of the carrier, as well as spring-loaded elements fastened with

the specified holders for the edges of the holders both on one and the other side of the belt of the holders relative to the plane of the belt.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a belt of kinematically connected sensor holders with seats for sensors installed around the perimeter around the axis of the carrier, as well as spring elements fastened to these holders, spring elements include elastic arms mounted at an angle of 45 to 80 degrees to the axis carrier.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a belt of kinematically connected sensor holders with seats for sensors mounted along the perimeter around the axis of the carrier, as well as spring elements fastened to these holders, spring elements include two belts of radially diverging elastic arms on opposite sides of the carrier belt, levers of one belt are mounted towards levers of the second belt.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a belt of kinematically connected sensor holders with seats for sensors mounted along the perimeter around the axis of the carrier, as well as spring elements fastened to these holders, spring elements are made in the form

elastic elements of elastic material, the average thickness of the elastic element is 0.02-0.15 of the diameter of the cylinder into which the carrier fits, the length of the bendable part of the elastic elements is 0.050.5 of the specified diameter.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a belt of kinematically connected sensor holders with seats for sensors installed along the perimeter around the axis of the carrier, as well as spring elements fastened with these holders, spring elements are made in the form of elastic corrugated rings.

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, characterized in that

the carrier includes a plurality of kinematically connected sensor holders with seats for the sensors, as well as several elastic ring-shaped elements, the sensor holders are connected to the specified elastic ring-shaped elements.

For the declared variants of the group, the functions of clamping sensors and enveloping obstacles are provided in a more independent way than for analogs, or are separated.

in development of the first subgroup of the claimed group of utility models (inventions):

A sensor carrier for an in-tube inspection projectile, comprising a cuff of elastic material with seats for sensors located on a surface with axial symmetry,

the length of the cuff in the direction of its axis is not less than the diameter of the cylinder into which the carrier fits,

the carrier also includes an elastic collar installed in the front and / or in the back of the carrier, the peripheral surface of which fits into the cylinder concentric with the pipeline, cuts or undercuts are made in the peripheral parts of the cuff, oriented in a plane passing at an angle from O to 45 degrees to media axis

the seats for the sensors form rows oriented at an acute angle to the cuff axis, the number of seats in the row is at least 5,

the inner surface of the cuff rests on a cylinder whose diameter is not more than 0.8 of the diameter of the cylinder into which the cuff fits,

the diameter of the cylinder into which the cuff fits is not more than 33 cm,

the cuff is corrugated, the number of convex parts of the corrugations on one cuff is 0.3-5.0 expressed in inches of the diameter of the cylinder into which the cuff fits,

the media includes several of these cuffs,

radial cuts and / or cuts are made in the cuff at an angle from O to 30 degrees to the cuff axis, the carrier includes a support in the form

elastic element with axial symmetry mounted on the housing coaxially with the cuff, the back of the cuff is fastened to the specified support,

the cuff is made integral and includes a front part, the outer diameter of which increases in the direction from the front to the back, and the rear cylindrical part attached to it.

the carrier includes a support in the form of a disk or cuff, the support is mounted coaxially with the cuff with seats for sensors, which relies on the support with its inner part,

in a preferred embodiment, the carrier includes at least two supports in the form of disks and / or cuffs and / or corrugated elements with axial symmetry, the supports are mounted coaxially with the cuff with sensor seats, which relies on its supports with its inner part,

the carrier includes a support in the form of a disk and / or cuff, and / or in the form of a corrugated element with axial symmetry, the support is installed coaxially with the cuff with sensor seats in the front of the cuff, which rests on the support with its inner part,

the carrier includes a support in the form of a disk and / or cuff, and / or in the form of a corrugated element with axial symmetry, the support is installed coaxially with a cuff with seats for sensors, which relies on the support with its inner part, the thickness of the support is from 0.007 to 0 , 07 the diameter of the cylinder into which the carrier fits,

the thickness of the cuff is from 0.04 to 0.1 of the diameter of the cylinder into which the cuff fits,

seats for sensors are made in the form of holes for sensors with an electrical output of the sensor at an angle of 60 to 150 degrees to the axis of the sensor.

the seats for the sensors are made in the form of holes, the axes of which are oriented at a right angle and / or at an angle of five to thirty degrees to the radial line passing through the axis of the hole and the axis of the carrier,

sensors are installed in the seats, the axes of which are oriented at a right angle and / or at an angle of five to thirty degrees to the radial line passing through the axis of the sensor and the axis of the carrier.

In development of the second subgroup of the claimed group of utility models (inventions):

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry, the carrier includes a plurality of skids with sensor seats,

the length of these runners is from 0.4 to 0.8 of the diameter of the cylinder into which the carrier fits,

the length of these runners is not more than 0.8 of the diameter of the cylinder into which the carrier fits, the thickness of the run is not more than 0.1 of the diameter of the cylinder into which the carrier fits,

the carrier includes a support in the form of an elastic disk with runners mounted on the support with seats for sensors, the disk thickness is from 0.01 to 0.1 of the diameter of the cylinder into which the carrier fits,

the carrier includes a support in the form of an elastic cuff with runners mounted on the support with seats for sensors, the thickness of the cuff is from 0.005 to 0.1 of the diameter of the cylinder into which the carrier fits.

in a preferred embodiment, the carrier includes at least two supports in the form of elastic disks with runners mounted on the supports with seats for sensors,

the carrier includes at least three supports in the form of elastic disks and / or elastic cuffs, and / or in the form of corrugated elements with axial symmetry with runners mounted on the supports with seats for sensors,

the carrier includes at least two supports in the form of elastic cuffs with runners mounted on the supports with seats for sensors,

the carrier includes a support in the form of a corrugated elastic element with axial symmetry, as well as runners mounted on the support with seats for sensors,

the carrier includes a support with runners mounted on the support with seats for sensors, runners are connected to adjacent runners using elastic elements made of a polymeric material, and / or

the carrier includes a support with runners mounted on the support with seats for sensors, the runners are connected to adjacent runners using elastic elements made of stainless or spring steel,

the carrier includes a support with runners mounted on the support with seats for sensors, runners are connected to adjacent runners using elastic V-shaped elements,

the carrier includes a lot of hard runners with seats for sensors; at least 10 seats for sensors are made on one runner.

the seats for the sensors form rows oriented at an acute angle from 20 to 45 degrees to the axis of the carrier, the number of rows on the run is at least three,

the carrier includes a plurality of kinematically connected runners with seats for sensors, the runners are grouped into runner belts mounted around the axis of the carrier, the carrier includes at least three runner belts,

the carrier includes a number of kinematically connected hard runners with seats for sensors, the width of the runners is not more than 0.25 of the diameter of the cylinder into which the carrier fits,

the carrier includes a housing and a plurality of inelastic runners with seats for sensors, runners are kinematically connected to the housing by elastic elements,

the seats for the sensors are made in the form of holes with a diameter of not more than 14 mm,

seats for sensors are made in the form of holes for sensors with an electrical output of the sensor at an angle of 60 to 150 degrees to the axis of the sensor,

the seats for the sensors are made in the form of holes, the axes of which are oriented at right angles and / or lods with an angle of five to thirty degrees to the radial line passing through the axis of the hole and the axis of the carrier,

sensors are installed in the seats, the axes of which are oriented at a right angle and / or at an angle of five to thirty degrees to the radial line passing through the axis of the sensor and the axis of the carrier.

In development of the third subgroup of the claimed group of utility models (inventions):

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry,

includes a support in the form of an elastic disk and / or cuff, and / or in the form of a corrugated element with axial symmetry with elastic runners mounted on the support with seats for sensors,

the carrier includes a plurality of elastic runners with seats for sensors, the length of said runners is not more than 0.8 of the diameter of the cylinder into which the carrier fits, the width of the run is from 0.07 to 0.35 of the diameter of the cylinder into which the carrier fits, thickness the runner is from 0.07 to 0.1 of the diameter of the cylinder into which the carrier fits, and / or

the carrier includes a plurality of elastic runners with seats for sensors, the length of said runners is at least 0.7 of the diameter of the cylinder into which the support fits, the thickness of the run is from 0.03 to 0.15 of the diameter of the cylinder into which the support is inserted,

seats for sensors are made in the form of holes for sensors with an electrical output of the sensor at an angle of 60 to 150 degrees to the axis of the sensor,

the carrier includes a housing and a plurality of elastic runners with seats for sensors, elastic runners are connected to the housing by elastic elements, the seats for sensors are made in the form of holes whose axes are oriented at an angle of no more than ten degrees to the radial line passing through the hole and axis carrier

the carrier includes a support in the form of an elastic cuff or elastic disk, as well as many elastic runners with seats for sensors, elastic runners are connected to the support, landing

places for sensors are made in the form of holes, the axes of which are oriented at an angle of no more than ten degrees to the radial line passing through the hole and the axis of the carrier, and / or

the seats for the sensors are made in the form of holes, the axes of which are oriented at a right angle and / or at an angle of five to thirty degrees to the radial line passing through the axis of the hole and the axis of the carrier,

sensors are installed in the seats, the axes of which are oriented at a right angle and / or at an angle of five to thirty degrees to the radial line passing through the axis of the sensor and the axis of the carrier.

In development of the fourth subgroup of the claimed group of utility models (inventions):

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry,

the carrier includes at least one annular sensor holder with sensor seats,

includes at least one elastic ring with seats for sensors,

includes a spiral holder of sensors with seats for sensors, the seats form one or more helical lines around the axis of the carrier,

includes at least one elastic corrugated element with axial symmetry, in which the seats for the sensors are made.

The length of the elements (holders, rings) along the axis of the carrier does not exceed half the diameter of the cylinder into which the carrier fits. h The outer surfaces of the ring-shaped holders pass along a cylindrical surface corresponding to the inner surface of the pipeline, the seats for the sensors are made in the convex parts of the ring-shaped holders and form rows oriented at an angle from O to 30 degrees to the axis of the carrier in a spiral line around the axis of the carrier, elements of the ring-shaped holder with the seats for the sensors are resiliently connected to adjacent elements of the same ring-shaped holder with the seats for the sensors. The carrier includes at least four ring-shaped holders, the distance between adjacent ring-shaped holders is not more than half the diameter of the cylinder into which the sensor carrier fits, the width of the ring-shaped holder (along the axis of the carrier) is much less than the specified diameter and is not more than 0.25 of the specified diameter. The implementation of the holder with a width within the specified limits is most preferable for enveloping defects in the geometry of the pipe and passability of the carrier through the turns and narrowings. The angle between the direction of the axis of the ring-shaped holder and the direction of the axis of the pipeline is from O to 30 degrees. The seats for the sensors are made in the form of holes or cutouts, or recesses, the number of seats (corresponding holes or recesses) for the sensors on one ring-shaped holder is from 0.3 to 10 expressed in inches of the diameter of the cylinder into which the specified holder fits. In a possible embodiment, the carrier includes sensors installed in the seats, the sensors fit into the cylinder.

the diameter of which exceeds the diameter of the cylinder into which the ring-shaped holders fit.

In a preferred embodiment, the ring-shaped holders are made in the form of elastic corrugated rings, the features of which in a preferred embodiment are given below after the description of all variants of the group of inventions (utility models).

In the rings (in the convex parts of the rings), recesses or openings, or cutouts for sensors, are made, which ensure the installation of sensors and the unhindered propagation of ultrasound or light (electromagnetic) flux from the sensor (ultrasonic, optical, electromagnetic, respectively) to the pipe wall.

In possible implementation options:

the ring-shaped holder contains rigid links, as well as elastic and / or articulated joints between the links;

the ring-shaped holder comprises rigid and / or elastic links and articulated joints between the links;

the ring-shaped holder fits into a cylinder whose diameter is less than the internal diameter of the pipeline, but not less than half the diameter of the cylinder into which the carrier fits;

successively connected annular holders form a spiral around the axis of the carrier;

ring-shaped holders are installed coaxially, the axis of the holders coincide with the axis of the pipeline;

ring-shaped holders are rigidly or resiliently bonded to adjacent ring-shaped holders, at least some of the ring-shaped

holders are fastened together by strips or rods that are made rigid or elastic;

the carrier includes support elements connected to the ring-shaped holders, which fit into a cylinder whose diameter exceeds the diameter of the cylinder into which the ring-shaped holders fit, the ring-shaped holders are located between these support elements, the support elements are made in the form of elastic corrugated rings and / or elastic cuffs, and / or elastic disks.

The choice of mounting options for holders between themselves and execution

holders are determined by the size of the carrier and the type of pipeline being examined (a gas pipeline with dry walls, or an oil pipeline in which oil plays the role of a lubricant when sliding along the wall): with a larger diameter, rigid ties and the use of articulated joints are preferred, with a smaller diameter, elastic links and ties are preferred.

In development of the fifth subgroup of the claimed group of utility models (inventions):

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry,

the carrier includes many kinematically connected elements with sensors seats, as well as elastic gaskets that can slide on the inner surface of the pipeline between elements with sensors seats and the inner surface of the pipe, elastic gaskets between runners with sensors seats and the inner surface of the pipeline . the carrier includes a cuff of elastic material with seats for sensors located on the surface with axial symmetry, as well as many gaskets between the seats for sensors and the inner surface of the pipeline. the carrier includes many kinematically connected elements (holders) with seats for sensors, as well as elastic runners that can slide along the inner surface of the pipeline, runners form gaskets between elements with seats for sensors and the inner surface of the pipeline, elements with seats for sensors made capable of experiencing elastic squeezing in the radial direction from the axis of the carrier, each skid forms a gasket between several kinematically connected elements with seats for sensors and the inner surface of the pipeline, runners are fixed on elements with seats for sensors, through holes are made through holes and / or cutouts in the areas between the seats for sensors and the inner surface of the pipeline, which allows you to install both magnetic and ultrasonic (optical) sensors, ensuring the unhindered propagation of ultrasound or light (electromagnetic) flux from the sensor to the pipe wall. Skids are oriented along a spiral (helical) and / or annular line around the axis of the carrier; the angle between the direction of the runner and the direction of the axis of the carrier is from O to 30 degrees; the carrier includes elastic elements configured to wring out said skids and / or elements V with seats for sensors in the radial direction from the axis of the carrier. In a preferred embodiment, the skids are elastic, the skid thickness is not less than 0.01 and not more than 0.2 of the diameter of the cylinder into which the support is inserted, the skid width is not less than 0.02 and not more than 0.4 of said diameter. The specified range was found to be optimal for uniformly bending around characteristic defects in pipe geometry, on the one hand, and to avoid misorientation of neighboring elements with sensors, on the other hand. In possible versions of the carrier, the runners sequentially connected to each other form a spiral (helix) around the axis of the carrier, or the runners form rings and / or ring-shaped assemblies coaxial with the axis of the pipeline. In other possible implementation sub-options: the skid contains rigid links, elastic and / or articulated joints between the links; the runner contains rigid and / or elastic links and articulated joints between the links; the seats for the sensors are made in the form of holes and / or cutouts and / or recesses and form rows oriented at an angle from O to 30 degrees to the axis of the carrier in a spiral line around the axis of the carrier, the seats for the sensors are made in the convex parts of the elements. The choice of mounting the holders to each other and the design of the holders are determined by the size of the carrier and the type of pipeline being examined: with a larger diameter and a dry surface of the pipeline, rigid connections and the use of articulated joints are preferable,

smaller diameter and inspection of the pipeline preferred elastic links and connections.

In a preferred embodiment, the elements with seats for sensors are made in the form of elastic corrugated rings, the features of which in a preferred embodiment are given below after describing all variants of the group of inventions.

The number of seats for sensors in one ring is from 0.3 to 10 expressed in inches of the diameter of the cylinder into which the indicated ring fits.

The carrier includes support elements connected to elements with sensor seats, the support elements fit into a cylinder whose diameter exceeds the diameter of the cylinder into which elements with sensor seats fit, elements with sensor seats are located between these support elements, supporting elements are made in the form of elastic corrugated rings and / or elastic cuffs and / or elastic disks.

In development of the sixth subgroup of the claimed group of utility models (inventions):

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry,

the carrier includes a housing and a plurality of elements connected to the housing with seats for sensors, the housing is capable of bending. The housing contains rigid links, as well as elastic and / or joints between the links, or the housing contains rigid and / or elastic joints and joints between the links, elastic links are made of elastic material, the housing is made in the form of a bundle or cable, or hose, or a bellows, or a spring, or an elastic strip, elements with sensor seats are made capable of experiencing elastic squeezing in the radial direction from the axis of the carrier, the housing has an axis of symmetry coinciding with the axis of the pipeline, elements with fit GOVERNMENTAL places for sensors form with the elastic body and / or the pivot joints (via hinge mechanisms); the length of the non-bending sections of the housing along the axis of the carrier does not exceed half the diameter of the cylinder into which the carrier is inserted, the lower boundary of the allowable bending radius of the axis of the carrier is not more than three diameters of the cylinder into which the carrier is inserted (in the preferred embodiment, not more than 1.5 of said diameter). The length of the unbending section and the bending radius determine the effectiveness of smoothing the displacements of adjacent elements with sensors during the passage of pipe geometry defects and bends and determine the possibility of inspecting the pipeline depending on the fittings used in its composition. The choice of housing design is determined by the size of the carrier and the type of pipeline under examination: with a larger diameter and a dry surface of the pipeline, rigid connections and the use of articulated joints are preferred, with a smaller diameter and inspection of the pipeline, elastic links and connections are preferred.

in a preferred embodiment, the elements with seats for sensors are made in the form of elastic corrugated rings, the features of which in a preferred embodiment are given below after the description of all variants of the group of inventions. The number of seats for sensors in one ring is from 0.3 to 10 expressed in inches of the diameter of the cylinder into which the indicated ring fits.

In development of the seventh subgroup of the claimed group of utility models (inventions):

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry,

the carrier includes interconnected rows of grouped elements with seats for sensors, each element of the series is kinematically connected with neighboring elements of the series,

the elements of the row form articulated and / or elastic joints with adjacent elements of the same row,

the elements of the row form hinges with adjacent elements of the same row, the hinges between adjacent elements of the row are formed by the surfaces of the elements of the row at the contact points of adjacent elements of the row,

each row is formed by adjacent elements,

each row of elements is pulled together by an elastic element capable of bending,

each row of elements is pulled together by an elastic element in the form of a bundle or cable, or tape, or tube, or bellows, or spring,

the grouped elements have centering elements relative to the neighboring elements of the row, made in the form of vytyups and grooves, so that the protrusions of one element enter the grooves of the neighboring element. each element of the row is kinematically connected to neighboring elements of the row, elements with seats for sensors are made capable of experiencing elastic compression in the radial direction from the axis of the carrier. the carrier includes spring-loaded elements fastened to the rows of grouped elements (with row elements) and made capable of squeezing the grouped elements in a radial direction from the axis of the carrier, each row of elements is oriented along a spiral and / or ring line around the axis of the carrier, the row of grouped elements has surfaces able to slide along the inner surface of the pipeline. The orientation of the rows of sensors ensures that the sensors overlap the entire perimeter in the pipeline section. In possible embodiments: elements of the series form articulated and / or elastic joints with adjacent elements of the same series; the elements of the row form hinges with adjacent elements of the same row, the hinges between adjacent elements of the row are formed by the surfaces of the elements of the row at the contact points of adjacent elements of the row; the elements of the series form elastic connections with neighboring elements of the same series, the elastic connections between adjacent elements of the series are formed using elastic (elastic) elements (plates and / or springs), each of which is fixed to at least two adjacent elements of the series, elastic

the elements are made capable of squeezing the grouped elements in a radial direction from the axis of the carrier;

rows (adjacent) of grouped elements form articulated and / or elastic joints with other (neighboring) rows, elements of a series form articulated and / or elastic joints with elements of another (neighboring) row;

rows (adjacent) of grouped elements form hinges with other (neighboring) rows, elements of a series form hinges with elements of another (neighboring) row, hinges between (neighboring) rows or elements of different (neighboring) rows are formed by hinge mechanisms;

rows (adjacent) of grouped elements form elastic joints with other (neighboring) rows, elastic joints between different (neighboring) rows are formed using elastic elements, each of which is fixed to at least two rows (neighboring), elastic elements are made capable to squeeze the grouped elements in the radial direction from the axis of the carrier;

the elements of the series form elastic joints with the elements of another (neighboring) row, the elastic joints between the elements of different (neighboring) rows are formed using elastic (elastic) elements (plates and / or springs), each of which is attached to at least two elements belonging to different (adjacent) rows, the elastic (elastic) elements are made capable of squeezing the grouped elements in the radial direction from the axis of the carrier.

The carrier includes a housing, rows of grouped elements are connected to the housing using elastic and / or articulated mechanisms; h The choice of mounting the rows to the case and fixing the elements in the rows is determined by the size of the carrier and the type of the pipeline under test: with a larger diameter and a dry surface of the pipeline, rigid connections and the use of articulated joints are preferred, with a smaller diameter and examination of the pipeline, elastic links and connections are preferred. The carrier includes elastic disk and / or cuff supports mounted on the housing coaxially with the axis of the carrier, rows of grouped elements are mounted on these supports; the carrier includes elastic ring supports mounted on the housing coaxially with the axis of the carrier, rows of grouped elements are mounted on these supports; in a preferred embodiment, the ring supports are made in the form of elastic corrugated rings, the features of which in a preferred embodiment are given below after describing all variants of the group of inventions. The seats for the sensors are made in the form of holes or cutouts, or recesses and form rows oriented at an angle from O to 30 degrees to the axis of the carrier in a spiral line around the axis of the carrier, the seats for the sensors are made in the convex parts of the elements. In a preferred embodiment: each row is formed by adjacent elements, pulled together by an elastic element capable of bending, adjacent elements in each row are pressed against each other, said constricting element is made of elastic material in the form of a bundle or cable, or tape, or tube, or bellows, or springs; grouped elements are made of wear-resistant (polymer) material;

the grouped elements have centering elements centering relative to the neighboring elements of the row, made in the form of protrusions and grooves, so that the protrusions of one element enter the grooves of the neighboring element, the protrusions are formed by metal elements fixed in the grouped elements, the centering elements form hinges between adjacent elements of the row.

In development of the eighth subgroup of the claimed group of utility models (inventions):

Sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry,

the carrier includes a belt of kinematically connected sensor holders with seats for sensors mounted along the perimeter around the axis of the carrier, as well as spring elements fastened with these holders to the edges of the holders on both one and the other side of the holder belt relative to the plane of the belt,

as well as spring elements fastened to said holders, holders or spring elements include elastic elements capable of sliding along the inner surface of the pipeline in the area in front of the sensor seats,

the holders or spring elements include elastic elements that are capable of sliding on the inner surface of the pipeline in the area after the seats for the sensors,

spring elements include two belts of radially diverging levers on opposite sides of the belt holders, the levers of one belt are installed to meet the levers of the second belt,

spring elements are made in the form of elastic elements made of elastic material, the average thickness of the elastic element is 0.02-0.15 diameter of the cylinder into which the carrier fits, the length of the flexible part of the elastic elements is 0.05-0.5 of the specified diameter,

or spring elements are made in the form of elastic corrugated rings,

these spring elements are made capable of radially pressing these holders in the direction from the axis of the carrier.

The elastic elements in front of the sensors make it possible to reduce the rebound and smooth out vibrations when the carrier passes through an obstacle in the pipeline formed by a geometry defect in the pipe section, with a sharp boundary at the moment it encounters the obstacle.

The elastic elements after the sensors (in the direction of travel of the carrier with an inspection projectile in the pipeline) can reduce the rebound and smooth out vibrations when the carrier passes through the pipeline of an obstacle with a sharp boundary at the end of the passage of the obstacle.

On the belt holders or on the spring elements, gaskets are installed that can slide along the inner surface of the pipeline, which can have the elasticity necessary to smooth out vibrations, and wear resistance sufficient for a small number of diagnostic passes of the carrier with the replacement of worn elastic elements without replacing the holders or spring elements.

in the peripheral parts of the levers the fastening elements of the holders are fixed (molded or filled), the angular width of the lever in its peripheral part relative to the axis of the carrier (in a plane perpendicular to the axis of the carrier) is not more than 45 degrees.

The specified design provides a symmetrical squeezing of the holders from the axis of the carrier and independent bending of obstacles by holders fastened with different levers.

The specified parameters of the spring-loaded elements provide smoothing of vibrations on the holders on the one hand, and a sufficient squeezing of the holders from the axis of the carrier, taking into account the weight of the holders with sensors, on the other hand.

The carrier includes elastic elements abutting against the spring elements and squeezing them radially from the carrier soy, these elastic elements are made in the form of elastic corrugated rings, which allows you to choose the material of the levers elastic enough to smooth out vibrations on the holders, regardless of the necessary force to squeeze the holders, which when this is provided by the specified abutting elastic elements. In a possible embodiment, the carrier spring elements are made in the form of elastic corrugated rings. The features of elastic corrugated rings in a preferred embodiment are given below after describing all variants of the group of inventions.

The seats for the sensors are made in the form of holes and / or cuts and / or recesses and form rows oriented at an angle from O to 30 degrees to the axis of the carrier in a spiral line around the axis of the carrier, the seats for the sensors are made in the convex parts of the holders, the carrier Includes many belt holders.

The length of the holder along the axis of the carrier is not more than 0.4 of the diameter of the cylinder into which the carrier fits, the angular width of the holder relative to the axis of the carrier in a plane perpendicular to the axis of the carrier is not more than 45 degrees - a large length of the holder weakens the ability to bend around pipe geometry defects.

In development of the last variant of the claimed group of utility models (inventions), the sensor carrier for an in-tube inspection projectile with seats for sensors located on a surface with axial symmetry includes a number of kinematically connected sensor holders (elements) with sensor seats, as well as several elastic ring-shaped elements made capable of wringing the holders in a radial direction from the axis of the carrier, the sensor holders (elements) are fastened to these elastic ring-shaped elements.

the carrier includes at least four ring-shaped elements;

in a preferred embodiment, the ring-shaped elements are made in the form of elastic corrugated rings, the features of which in a preferred embodiment are given below after describing all variants of the group of inventions.

The seats for the sensors are made in the form of holes or cutouts or recesses and form rows oriented at an angle from O to 30 degrees to the axis of the carrier in a spiral line around the axis of the carrier, the seats for the sensors are made in the convex parts of the holders.

In possible implementations: an annular element fits into a cylinder whose diameter is less than the internal diameter of the pipeline, but not less than half the diameter of the cylinder into which the carrier fits; the ring-shaped element contains rigid links, as well as elastic and / or articulated joints between the links; the ring-shaped element contains rigid and / or elastic links and articulated joints between the links. The choice of the execution of the ring-shaped elements is determined by the size of the carrier and the type of the examined pipeline: with a larger diameter, rigid ties and the use of articulated joints are preferred, with a smaller diameter, elastic links and ties are preferred. The length of the holder along the axis of the carrier is not more than 0.4 of the diameter of the cylinder into which the carrier fits, the angular width of the holder relative to the axis of the carrier in a plane perpendicular to the axis of the carrier is not more than 60 degrees - increasing the width of the holder above this weakens the ability to bend geometry defects. In each of the described variants of the group of inventions, the seats for the sensors form rows oriented in a spiral (helical) line around the axis of the carrier, preferably at an angle from O to 30 degrees to the axis of the carrier, which ensures the sensors to be perforated over the entire cross section of the pipeline, the outer surfaces of the rings (ring-shaped elements, ring-shaped holders) pass near the inner surface of the pipeline and fit into a cylinder concentric with the pipeline. Elastic corrugated rings, which were previously indicated in relation to the described options, in the preferred embodiment are characterized by the following features. The angle between the direction of the corrugation ring and the direction of the axis of the ring is from O to 45 degrees, the corrugations of each ring are offset relative to the corrugations of adjacent rings in an angle around the axis of the ring, the inner surfaces of the corrugations form a cylinder, the diameter of which is 0.3-0.9 of the diameter of the cylinder, into which the ring fits, the number of convex parts of the corrugations on one ring is 0.3-5.0 of the indicated diameter, expressed in inches, the rings are rigidly or elastically bonded to adjacent rings, at least some of the rings are bonded to each other strips or rods that are made rigid or elastic. In a preferred embodiment, the rings are made of elastic material, the average thickness of the ring (the average from the calculation of the integral thickness in the plane perpendicular to the axis of the ring along the perimeter of the ring by the perimeter value) is 0.01-0.2 of the diameter of the cylinder into which the indicated ring fits. The average width of the ring (the average from the calculation of the integral width in the direction of the axis of the ring, along the perimeter of the ring by the size of the perimeter) is not less than 0.01 and not more than 0.4 of the diameter of the cylinder into which the indicated ring fits. The corrugations form rings springing in the plane, the rows of sensors along the helix provide perforation with sensors of the entire perimeter in the pipeline section. With a smaller cylinder diameter, the compression region of the ring is limited when the carrier passes through a defect in the geometry of the pipe; with a larger inner diameter of the ring or a smaller number of convex parts of the corrugations, the spring properties of the rings are weakened; when the number of corrugations is greater than the specified, the compression region between the folds of the corrugations is limited. The specified range of parameters was found to be optimal for uniformly pressing the sensors to the inner surface of the pipeline, taking into account their weight on the one hand, and the ability of the spring to deform when passing dents and other geometry defects, on the other hand. The angle between the direction of the axis of the ring and the direction of the axis of the pipeline is from 0 to 30 degrees, or the rings connected in series with each other form a spiral (helix) in the carrier axis, or (in the preferred embodiment) the rings are aligned, the axis of the rings coincides with the axis of the pipeline. The sensors can be fixed as follows: 1) The seat for the control sensor is made in the form of a sleeve fixed under the element (holder) under the sensor with a thread on the part of the sleeve protruding above the element, under the union nut. Sensors are installed in bushings and clamped with union nuts. 2) The seat for the sensor is made in the form of a hole, near the edge of the hole in the wall formed by the hole, there is a groove for the retaining ring, the sensors are recessed in these holes and clamped by the retaining rings. It is preferable to use the claimed carrier according to any one of the options with ultrasonic sensors. Figure 1 shows the sensor carrier in one of the designs with the location of the sensors on the elements of the elastic cuff; figure 2 shows the sensor carrier in one of the designs with the location of the sensor holders on the elements of the elastic cuff; on Fig.3 shows the sensor carrier in one of the designs with the location of the sensors in the holders in the form of rigid skids; figure 4 shows the sensor carrier in one of the designs with the location of the sensors in the holders in the form of elastic skids; figure 5 shows the carrier of sensors in one of the designs with ring-shaped holders of sensors; figure 6 shows the housing of the sensor carrier, made capable of bending; Fig.7 shows a section of the sensor carrier in one of the designs with skids; Fig. 8 shows a sensor carrier in one of the designs with rows of grouped elements with sensors; figure 9 shows a section of the sensor carrier in one of the designs with a belt of sensor holders; in FIG. 10 shows a section of the sensor carrier in one of the designs with sensor holders mounted on ring-shaped elements. As a result of solving the problem of reducing the number of diagnostic passes of inspection shells and reducing the time limit for the flow of the pumped product, as well as increasing the efficiency of in-line inspection of main pipelines, in-tube flaw detectors (in-tube inspection shells) were developed for inspection

oil pipelines, gas pipelines, condensate pipelines, oil pipelines with a nominal diameter of 10 to 56. An in-line inspection shell includes, as a rule, one or more sections forming flameproof enclosures and a sensor carrier. In the shells there is a power source and electronic equipment for measuring, processing and storing the obtained measurement data on the basis of an on-board computer that controls the operation of the inspection projectile during its movement inside the pipeline. Polyurethane cuffs are installed on the shell of the projectile, providing centering of the projectile inside the pipeline and advancement of the projectile by the medium pumped through the pipeline, as well as odometers measuring the distance traveled inside the pipeline. Information on the distance traveled, measured by odometers, with reference to the measured diagnostic parameters, is recorded in the on-board computer drive and, after performing a diagnostic pass and processing the accumulated data, determines the position of defects on the pipeline and, accordingly, the place of subsequent excavation and repair of the pipeline.

In FIG. 1-10 presents embodiments of sensor carriers characterized by features of the claimed group of utility models (inventions).

The sensor carrier shown in FIG. 1 is characterized by features in the first subset of utility models described above;

the sensor carrier shown in FIG. 2 is characterized by features in the first and second subgroups of utility models described above;

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the sensor carrier shown in FIG. 3 is characterized by features in the second subgroup of utility models described above;

the sensor carrier shown in FIG. 4 is characterized by features in the third subgroup of utility models described above;

the sensor carrier shown in FIG. 5, and the housing of which is shown in FIG. 6, is characterized by features in the fourth and sixth subgroups of utility models described above;

the sensor carrier, the section of which is shown in Fig. 7, is characterized by the fourth and fifth characteristics of the above useful subgroups

V, models;

the sensor carrier shown in Fig. 8 is characterized by features in the seventh subset of utility models described above;

a sensor carrier, the section of which is shown in Fig. 9, is characterized by features of the eighth described above subgroup of utility models;

a sensor carrier, a section of which is shown in FIG. 10, is characterized by features according to the last variant of the claimed group described above and to the second subgroup of utility models described above.

Figure 1 shows a section of the sensor carrier in one of the executions. The sensor carrier includes: a corrugated elastic cuff 101, the peripheral parts of which can slide along the inner surface of the pipeline, as well as a leading cuff 102 installed in the front of the carrier, in which cuts or undercuts can be made oriented in a plane passing at an angle from O up to 45 degrees to the axis of the carrier, these cuffs are flanged on the flange 103 with the fastening element 104 to the hardware sections of the inspection shell. There are W in the cuff

(P573 convex 105 and concave 106 parts of the corrugation. Sensors 107 are installed in the convex parts of the corrugation of the cuff using brackets 108 having holes for the sensors 107. A support 110 is installed at the back of the cuff. The length of the cuff in the direction of its axis is about 1.3 cylinder diameters into which the carrier fits in. Seats for sensors form rows oriented at an acute angle to the cuff axis, the number of seats in a row is 16, the inner surfaces of the cuff rest on a cylinder whose diameter is about 0.75 diameter of the cylinder into which the cuff fits in. The number of convex parts of the corrugations on one cuff .. is 14, which is 0.5 expressed in inches of the diameter of the cylinder into which the cuff fits (28). In another possible design, the cylinder diameter is 10 and the number of bumps the corrugation is 8, ie 0.8 of the indicated diameter, Figure 1 shows one of the sections of the carrier, which may include two to three articulated sections. In a preferred embodiment, the carrier includes two supports in the form of elastic disks mounted coaxially with a cuff that rests on said supports. The cuff can be made integral and include a front part 109, the outer diameter of which increases in the direction from the front to the rear, and the rear cylindrical part attached to it. The seats for the sensors are made in the form of holes for the sensors with an electrical output of the sensor at an angle of 60 to 150 degrees to the axis of the sensor, and the sensors are installed in the seats, the axes of which are oriented at an angle of about 18 degrees to the radial line passing through the axis of the sensor and the axis of the carrier .

Figure 2 shows the sensor carrier in another design. The sensor carrier section includes: an elastic cuff 201, the peripheral parts of which can slide along the inner surface of the pipeline, as well as leading cuffs 202 installed in the front of the carrier, in which cuts or undercuts can be made oriented in a plane passing at an angle from O up to 45 degrees to the axis of the carrier, the cuffs of the front section are mounted on the flange 203, on which the fastening element 204 to the hardware sections of the inspection shell is also installed. The cuffs of the rear section are mounted on flanges pivotally connected to the flange 203. Radial cuts 205 are made in the cuff 201. The sensor holders 206 are elements of the elastic cuff 201 or are made in the form of separate (possibly rigid) runners fixed to the elastic cuff. The sensors 207 are installed in the holders 206. The seats for the sensors form rows oriented at an acute angle to the cuff axis, the number of seats in the row is from 4 to 8, the inner surfaces of the cuff rest on a cylinder, the diameter of which is about 0.75 of the cylinder diameter, which fits the cuff. Figure 2 shows a two-section carrier, which may include three or more articulated sections.

In a preferred embodiment, the carrier includes two supports in the form of elastic disks or cuffs mounted coaxially with a cuff that rests on said supports. The cuff can be made integral and include the front part 209, the outer diameter of which increases in the direction from the front to the back, and the rear cylindrical part attached to it. The length of the runners 206 is 0.3 diameter

cylinder, which fits the carrier (28), the thickness of the runner is 0.05 of the specified diameter.

The seats for the sensors are made in the form of holes for the sensors with an electrical output of the sensor at an angle of 60 to 150 degrees to the axis of the sensor, and the sensors are installed in the seats, the axes of which are oriented at an angle of about 18 degrees to the radial line passing through the axis of the sensor and the axis of the carrier .

On Fig.3 shows the sensor carrier in one of the designs. The section of the sensor carrier includes: sensor holders 306 and elastic arms 301, the peripheral parts of which are capable of sliding along the inner surface of the pipeline, leading cuffs 302 installed in the front and rear of the carrier, in which cuts or undercuts can be made oriented in the plane passing at an angle from O to 45 degrees to the axis of the carrier. Elements of the front section are mounted on a flange 303, on which an element of fastening 304 to the hardware sections of the inspection shell is mounted. Elements of the rear media section are mounted on flanges pivotally connected to flange 303. The sensor holders 306 are connected to the flanges using pivoting mechanisms 308 (in another possible embodiment, the holders can be secured with elastic elements, including levers 301. Sensors 307 are mounted in holders 306 The seats for the sensors form rows oriented at an acute angle to the axis of the cuff, the number of seats in the row is from 4 to 8. Figure 3 shows a two-section carrier that can include three and more its articulated sections.

in a preferred embodiment, the carrier includes two supports in the form of elastic disks or cuffs mounted coaxially with the cuff, which rests on these supports. The length of the runners 306 is 0.3 of the diameter of the cylinder into which the carrier (28) fits, the thickness of the runner is 0.05 of the indicated diameter. (In another design, the length of these runners can be 0.7 of the diameter of the cylinder into which the carrier fits). The sleeve 302 is a support to which the sensor holders 306 and levers 308 are connected. The thickness of the sleeve is 0.02 of the diameter of the cylinder into which the carrier (28) fits. In another embodiment, the carrier may include two or more of these supports. The skids are connected to neighboring skids by elastic elements made of a polymeric material (polyurethane) or stainless or spring steel in the form of V-shaped elements. On one runner, 16 seats for the sensors are made, the seats for the sensors form rows oriented at an angle of about 20 degrees to the axis of the carrier, each row has three rows, the seats for the sensors are made in the form of holes with a diameter of about 14 mm. Runners are grouped into runner belts mounted around a carrier axis. The seats for the sensors are made in the form of holes for the sensors with an electrical output of the sensor at an angle of 60 to 150 degrees to the axis of the sensor, and the sensors are installed in the seats, the axes of which are oriented at an angle of about 18 degrees to the radial line passing through the axis of the sensor and the axis of the carrier . Figure 4 shows a section of the sensor carrier in another design (for more illustrative purposes, the carrier section mounted on the housing is shown. The sensor carrier includes: skids 401 that can slide

on the inner surface of the pipeline. Each runner 401 is fixed to the support using bolt connections through the through holes 402 in the runners 401. Ultrasonic sensors 403 are mounted in the holes of the brackets 404, which, in turn, are fixed in the runners 401. The angle between the direction of the runner and the direction of the carrier axis is about 10 degrees , the runners are oriented along a curve forming a helix around the axis of the carrier.

The support is made in the form of a flange or elastic disk or cuff, the width of the runner is about 0.13 of the diameter of the cylinder into which the carrier fits, the average thickness of the runner is about 0.07 of the diameter of the cylinder into which the carrier fits, the length of these runners is about 2 of these diameters cylinder. The elastic runners are connected to the housing by elastic elements 405, which are runner elements or similar elastic elements connected to the runners 401.

The seats for the sensors are made in the form of holes for the sensors with an electrical output of the sensor at an angle of 60 to 150 degrees to the axis of the sensor. Sensors are installed in the seats, the axes of which are oriented at a right angle and / or at an angle of five to thirty degrees to the radial line passing through the axis of the sensor and the axis of the carrier. The carrier body includes several pivotally interconnected rods. In the embodiment shown in Fig.7, the control sensors are made ultrasonic and secured in the bushings with the help of union nuts.

The sensor carrier in one of the versions of FIG. 5, FIG. 6 (for illustrative purposes, three ring-shaped holders in the middle group of holders are not shown) includes: a housing 10 and 12 ring-shaped holders 11 in the form of elastic corrugated rings of elastic material with 8 convex

/ (with corrugated sections 12 and 8, seats for sensors 13 in the convex parts of corrugations on each ring, and 8 concave sections of corrugations 14; the corrugations of each ring are displaced relative to the corrugations of adjacent rings by an angle around the axis of the rings by approximately 4 degrees, the inner surfaces of the corrugations 15 form a cylinder with a diameter of about 60% of the diameter of the cylinder into which the ring fits in. The distance between adjacent rings is about 3% of the diameter of the cylinder into which the carrier fits, the ring width is about 10-15% of the specified diameter. the seven convex parts of the corrugations on one ring are about 0.8 of the indicated diameter, expressed in inches, the thickness of the ring is about 0.07 of the specified diameter.The rings are grouped into 3 groups of 4 rings, in the back of the carrier and between groups of elements on the carrier body are installed corrugated rings 16 of increased diameter, which fit into a cylinder whose diameter is greater than the diameter of the cylinder formed by the rings with sensors and not less than the inner diameter of the controlled pipeline. In each of the groups, the rings are fastened together and with elements of increased diameter by rigid fastening elements 17, ring elements are mounted coaxially with the axis of the pipeline, rigid elements 18 are abutted in the rings, abutting against adjacent rings. A metal flange 19 and a cone element 20 are installed at the front of the carrier; a cone element is installed between the flange and the rings. The conical element and rings of increased diameter fit into a cylinder with a diameter of about 10, rings with seats for sensors fit into a cylinder with a diameter of about 9, which is about 90% of the inner diameter of the pipeline for which the carrier is designed in the specified design. On the flange there is an element of fastening 21 to the hardware of the in-pipe

inspection shell. The ring closest to the flange is connected to the flange 19 by rigid rod elements 22 of FIG. 6 passing through the cone element 20, the axes of the rod elements 22 form a conical surface that is coaxial with the pipeline. The conical element forms a corrugated conical cuff, the direction of the corrugations coincides with the direction of the axis of the carrier. Rings and cone element are made of polyurethane. In the embodiment depicted in figure 5, the control sensors are made ultrasonic and fixed in the seats for the sensors using the locking rings.

Ring elements are mounted on the housing 10 of FIG. 6, which is capable of bending. The housing includes an elastic polyurethane rod 25 of circular cross section with a core in the form of a metal cable, three cruciform metal flanges 26 of FIG. 5, FIG. 6 are fixed to the rod, to which ring elements of increased diameter 16 and adjacent rings with sensors 11 are connected. In the front part of the housing on the rod is fixed to the flange 19 of Fig.5, Fig.6. The length of the non-bending section of the body in its nose along the axis of the carrier is about 0.15 of the diameter of the cylinder into which the carrier fits, the lower boundary of the allowable bending radius of the axis of the carrier is about 1.5 of the diameter of the specified cylinder.

In possible embodiments, the casing includes three elastic rods pivotally connected to each other, corresponding to three groups of ring elements, each of which has four ring elements with mounting holes for sensors.

Figure 7 shows a section of the sensor carrier in another embodiment (for greater illustrative purposes, one of the skids on the carrier is not shown). Carrier

sensors includes: runners 31 that can slide along the inner surface of the pipeline, as well as kinematically connected elements in the form of elastic corrugated ring elements 32 with 8 convexities of 33 corrugations (and 8 concavities of 34 corrugations, respectively), as well as 8 seats for sensors in convex parts of the corrugations 33 in the form of through holes. Ring elements are installed coaxially with the axis of the pipeline. Each runner 31 is flashed on 7 ring elements 32 with the help of brackets molded (embedded) in the runner

35i forms a gasket between the annular elements and the inner surface of the pipeline. The brackets have a hole for the sensor, union nut

36 presses the sensor 37 and presses the runner 31 against the annular element 32. Each annular element fits into a cylinder with a diameter of about 11, which is slightly smaller than the inner diameter of the monitored pipe 12, for the inspection of which the carrier is intended. The angle between the direction of the runner and the direction of the axis of the carrier is about 10 degrees, the runners are oriented along a curve forming a helical line around the axis of the carrier.

The eight convex parts of the corrugations on one ring element is about 0.8 of its diameter, expressed in inches, the width of the ring element is about 0.05-0.10 of its diameter, the thickness of the ring element is about 0.07 of its diameter, the thickness of the runner is about 0.1 of the diameter of the cylinder into which the ring fits. Ultrasonic sensors 37 fit into a cylinder whose diameter exceeds the diameter of the cylinder into which the ring elements fit.

A metal flange and a cone element 38 are installed in front of the carrier, a cone element is installed between the flange and the ring elements. The conical element fits into a cylinder with a diameter of about 12, ring elements with seats for sensors h fit into a cylinder with a diameter of about 11, which is about 90% of the inner diameter of the pipeline. An element of fastening to the hardware of the in-pipe inspection shell is fixed on the flange. The skids are connected to the flange by rigid rod elements passing through the conical element 38, the axes of the rod elements form a conical surface that is coaxial with the pipeline. The conical element forms a corrugated conical cuff, the direction of the corrugations coincides with the direction of the axis of the carrier. Ring and cone elements are made of polyurethane. In the front part of the carrier, elastic fins 39 radially diverging from the axis are installed, the peripheral edges of the fins are capable of experiencing elastic deformation in a plane passing through the axis of the carrier. The flippers are made of polyurethane and installed in such a way that the seats for the sensors are projected onto the flippers in the plane perpendicular to the axis of the carrier, the flippers form an elastic connection with the carrier in the places of their fastening on the carrier body. In the embodiment depicted in Fig. 7, the control sensors are made ultrasonic, the lenses of the ultrasonic sensors form a surface whose diameter exceeds the diameter of the surface formed by the convexities of the ring elements. The carrier body includes several pivotally interconnected rods. In the embodiment shown in Fig.7, the control sensors are made ultrasonic and secured in the bushings with the help of union nuts. Fig. 8 shows a sensor carrier in another design (for illustrative purposes, only two rows of grouped elements with sensors are shown, the remaining rows are installed similarly). The sensor carrier includes: housing 41 with cuffs 42 mounted on it and pivotally

connected by rows of 43 pressed against each other elements 44 with seats for sensors 45. Each row is pulled by a metal cable and oriented along a helical line around the axis of the carrier and forms an angle of about 10 degrees with the axis of the carrier, the elements of the series form movable (articulated or elastic) joints with its adjacent row elements at the junctions. The surfaces of the elements in contact with the inner surface of the pipeline form a cylinder coaxial with the pipeline. Each row in the front of the carrier is connected to the housing by a hinge, in the rear of the carrier, the row is connected with elastic support elements 46 mounted on the housing 41.

The grouped elements of each row have centering elements relative to the neighboring grouped elements in the form of protrusions and grooves, so that the protrusions of one element enter the grooves of the neighboring element, the protrusions are formed by metal elements molded in the grouped elements. The seat for the control sensor is made in the form of a sleeve attached to the sensor in the elastic element with a thread on the part of the sleeve protruding above the elastic element, under the union nut. In the front part of the carrier, elastic fins 47 radially diverging from the axis are installed, the peripheral edges of the fins are capable of experiencing elastic deformation in a plane passing through the axis of the carrier. The flippers are installed in such a way that the seats for the sensors are projected onto the flippers in a plane perpendicular to the axis of the carrier, the flippers form an elastic connection with the carrier at the points of their attachment to the carrier. In the embodiment shown in Fig. 8, the control sensors are made ultrasonic. Cuffs 42, grouped elements 44, elastic elements 46 and fins 47 are made

from polyurethane. In the embodiment depicted in Fig. 8, the control sensors are made ultrasonic and fixed in the bushings with the help of union nuts.

Fig. 9 shows another embodiment of a sensor carrier (for illustrative purposes, a carrier section mounted on a housing is shown). The carrier includes: a belt of holders 51 with seats for sensors 52, as well as two belts of radially diverging arms 53 in the form of cuff sectors mounted on opposite sides of the belt of the holders towards each other, the edges of the belt holders on both sides are fastened to the peripheral parts of the respective sectors of the cuffs, gaskets 54 are mounted on the holders that can slide along the inner surface of the pipeline, gaskets 54 form pairs on opposite sides of the seats for sensors. The carrier includes a housing with flanges installed at the edges, cuff sectors 53 are secured to the flanges using bolts (studs) passed through through holes 55 in levers (sectors) 53. Three holders are fastened to each cuff sector. Spring elements are mounted on the flange, abutting against the inside of the sectors and bursting them. Sectors 53 of the cuffs and gaskets 54 are made of polyurethane, the average thickness of the sector is 0.06 of the diameter of the cylinder into which the carrier is inserted, the peripheral parts of the cuffs are molded (filled) with the pinch elements 56 of the belt holders 51. The angular width of the cuff sector in its peripheral part is about 26 degrees, the length of the bendable part of the sector is about 0.25 of the diameter of the cylinder into which the carrier fits. In the embodiment depicted in Fig. 9, the control sensors are ultrasonic and secured in the bushings using union nuts.

.3

In FIG. 10 shows another embodiment of a sensor carrier. The carrier section includes a housing 61, elastic corrugated rings 62, sensor holders 63 mounted on the rings 62. A flange 64 is mounted on the housing 61, on which there is an element 65 for attaching to the hardware of the in-tube inspection projectile, the front ring 62 is connected to the flange 64 with using the hinge mechanisms 66. Through the element 68 of the housing 61, the media section is articulated to other media sections. The length of the holders along the axis of the pipeline is about 0.4 in the diameter of the cylinder into which the carrier fits, the width of the rings is about 0.05 of the diameter of the cylinder into which the ring fits, the thickness of the ring is about 0.07 of the indicated diameter. In the embodiment depicted in FIG. 10, the control sensors 67 are ultrasonic and fixed in the seats for the sensors using the locking rings.

The inner surfaces of the corrugations 69 form a cylinder whose diameter is about 60% of the diameter of the cylinder into which the rings fit. The six convex parts of the corrugations on one ring are about 0.6 of its diameter, expressed in inches.

In any described embodiment, the sensor carrier may be pivotally coupled to the hardware sections of the inspection shell.

The device operates as follows:

Sensors are installed in the sensor carrier, connected with cables to the hardware sections of the inspection shell, the inspection shell is placed in the pipeline and the product (oil, gas, oil product) is pumped through the pipeline. During the movement of the inspection shell inside the pipeline, diagnostic parameters characterizing the state of the pipeline are measured. In ultrasonic testing, ultrasonic sensors periodically emit ultrasonic pulses. After the emission of ultrasonic pulses, the ultrasonic sensors switch to the mode of receiving reflected pulses. The obtained data on the time intervals corresponding to the travel time of the ultrasonic pulses, and (if necessary) the pulse amplitudes are digitized, converted and recorded in the digital data storage device of the on-board computer. During magnetic control of the pipe wall, a certain area of the pipe wall is magnetized and, using magnetic field sensors, components of the magnetic field are measured near the magnetized area of the pipe wall. The measurement of the magnetic field is carried out by periodically accessing the magnetic field sensors (by interrogating the sensors). The presence of cracks or defects associated with the loss of metal (corrosion, scoring) leads to a change in the magnitude and nature of the distribution of magnetic induction. In-pipe inspection is carried out in a similar manner by periodically turning to other types of sensors (magneto-optical, optical, electromagnetic-acoustic, sectional profile sensors, for example, by periodically turning leverage angle sensors pressed to the inner surface of the pipeline, and other sensors), amplifying pulses from sensors, digitizing amplitudes and storing digital data in a drive. Upon completion of the control of a given section of the pipeline, the projectile is removed from the pipeline and the data accumulated during the diagnostic pass is transferred to a computer outside the projectile.

Subsequent analysis of the recorded data allows you to identify defects in the wall of the pipeline and determine their position on the pipeline for the subsequent repair of defective sections of the pipeline.

Sources of information

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5.US3539915 dated November 10, 1970, UPC 324/37

6.US3810384 dated May 14, 1974, UPC 73 / 67.8, IPC G01 N29 / 04

7.US3835374 dated September 10, 1974, UPC 324/37 IPC G01R33 / 12

8.US3940689 dated February 24, 1976, UPC 324/37, IPC G01R33 / 12

9.US3949292 dated April 6, 1976, UPC 324/37, IPC G01R33 / 12

10.US3967194 dated June 29, 1976, UPC 324/37, IPC G01R33 / 12

11.US3973441 dated August 10, 1976, UPC 73/432, IPC G01B5 / 28

12.GB2020023 dated November 7, 1979, IPC G01S7 / 52

13.US4342225 of August 3, 1982, UPC 73/432, IPC G01B5 / 28

14.US4457073 dated July 3, 1984., NPK USA 33/178, IPC Е21В47 / 08

15.SU1157443 of May 23, 1985, IPC G01 N27 / 82

16.US4717875 dated January 5, 1988, UPC 324/220, IPC E21B47 / 02

17.US4598250 dated July 01, 1986, UPC 324/220, IPC G01 N27 / 72

18.DE3706622 dated August 28, 1986 IPC G01B7 / 12

19.DE3706660 dated September 15, 1988, IPC G01B21 / 14

20.US4910877 dated March 27, 1990, NPK US 33/544, IPC G01B7 / 28

22.US4953412 dated September 04, 1990 UPC 73 / 865.8, IPC G01B5 / 00

23.US5115196 dated May 19, 1992, UPC 324/220, IPC G01 N27 / 72

24.US3755908 dated October 27, 1992, UPC 33 / 544.3, IPC Е21В47 / 08

25.US5460046 dated October 24, 1995, UPC 73/623, IPC G01 N29 / 24

26.DE19747551 dated December 23, 1999 MPKR1705 / 02

27.DE3719492 dated April 13, 1995, IPC F17D5 / 06

28.US3529236 dated September 15, 1970 CDD US 324/37

29.US3543144 dated November 24, 1970 CDD US 324/37

30.US3786684 dated January 22, 1974, UPC 73/432, IPC G01R3 / 12

31.RU2139469 dated October 10, 1999, IPC: P1705 / 00

32.RU2139468 dated October 10, 1999, IPC F17D5 / 00

33.US4098126 dated July 4, 1978, MnK: G01B5 / 28

34.US4807484 dated February 28, 1989, MnK: G0185 / 28 (equivalents: CA1307129, DE3626646, EP0255619, ES2026869, NO172956, NO873252).

Claims (54)

1. A sensor carrier for an in-tube inspection projectile, comprising a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the length of the cuff in the direction of its axis is less than the diameter of the cylinder into which the carrier fits. 2. A sensor carrier for an in-tube inspection projectile, comprising a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the carrier also includes an elastic cuff installed in the front and / or in the back of the carrier , the peripheral surface of which fits into a cylinder concentric with the pipeline, cuts or undercuts are made in the peripheral parts of the cuff lying in a plane passing at an angle from 0 to 45 ^o to the nose axis Itel.  3. Sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, the seats for sensors form rows oriented at an acute angle to the axis of the cuff, characterized in that the number of seats places in a row is at least 5.  4. Sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, the cuff is corrugated, characterized in that the inner surfaces of the cuff are supported by a cylinder whose diameter is not more than 0 , 8 diameter of the cylinder into which the cuff fits.  5. A sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the diameter of the cylinder into which the cuff fits is not more than 33 cm.  6. A sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, the cuff is corrugated, characterized in that the number of convex corrugations on one cuff is 0.3-5 , 0 expressed in inches of the diameter of the cylinder into which the cuff fits.  7. A sensor carrier for an in-tube inspection projectile, comprising a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes several interconnected cuffs.  8. A sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the cuff is made of radial cuts. 9. A sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the cuff is cut at an angle from 0 to 30 ^o to the cuff axis.  10. A sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the cuff is cut, the length of the cuts is from 0.3 to 0.8 length cuffs along the axis of the carrier. 11. A sensor carrier for an in-tube inspection projectile, comprising a housing, a cuff made of elastic material mounted on the housing with seats for sensors located on a surface with axial symmetry, characterized in that the cuff is made of radial cuts and / or cuts at an angle from 0 to 30 ^o to the axis of the cuff, the carrier includes a support in the form of an elastic element with axial symmetry mounted on the housing coaxially with the cuff, the back of the cuff is attached to the specified support.  12. A sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes at least two supports in the form of disks, and / or cuffs, and / or elastic corrugated elements with axial symmetry, the supports are mounted coaxially with the cuff with seats for sensors, which relies on its supports with its inner part.  13. A sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a support in the form of a disk and / or cuff, and / or in the form of an elastic corrugated element with axial symmetry, the support is mounted coaxially with the cuff with seats for sensors in the front and / or middle and / or back of the cuff, which relies on its support with its inner part.  14. A sensor carrier for an in-tube inspection projectile, comprising a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a support in the form of a disk and / or cuff, and / or in the form of a corrugated element with axial symmetry, the support is mounted coaxially with a cuff with sensor seats, which relies on the support with its inner part, the thickness of the support is from 0.007 to 0.07 of the diameter of the cylinder into which it fits I am a carrier.  15. A sensor carrier for an in-tube inspection projectile, comprising a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the thickness of the cuff is from 0.04 to 0.1 of the diameter of the cylinder into which cuff.  16. A carrier of sensors for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of runners with seats for sensors, the length of these runners is from 0.4 to 0.8 the diameter of the cylinder into which the carrier fits.  17. A sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a support in the form of an elastic disk with runners mounted on the support with sensor seats, the disk thickness is from 0.01 to 0.1 of the diameter of the cylinder into which the carrier fits.  18. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a support in the form of an elastic cuff with runners mounted on the support with sensor seats, the thickness of the cuff is from 0.005 to 0.1 of the diameter of the cylinder into which the support fits.  19. A sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of runners with seats for sensors, the runners are connected to adjacent runners using elastic elements made of polymer material.  20. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of runners with seats for sensors, the runners are connected to adjacent runners using elastic elements made of stainless or spring steel.  21. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes an elastic support with axial symmetry with runners mounted on the support with sensor seats, the runners are connected to adjacent by skids using elastic V-shaped elements.  22. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of runners with seats for sensors, the length of these runners is not more than 0.8 cylinder diameter, into which the carrier fits, the thickness of the runner is not more than 0.1 of the diameter of the cylinder into which the carrier fits.  23. A sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of rigid runners with seats for sensors, at least 10 seats for sensors are made on one runner .  24. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of runners with seats for sensors, the sensor seats form rows oriented at an acute angle to axis of the carrier, the number of rows on the runner is at least three. 25. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of runners with seats for sensors, the sensor seats form rows oriented at an angle from 20 up to 45 ^o to the axis of the carrier.  26. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of kinematically connected skids with sensor seats, the skids are grouped into skid belts mounted around the axis of the carrier , the carrier includes at least three snake belts.  27. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of kinematically connected rigid runners with sensor seats, the width of the runners is not more than 0.25 diameter cylinder into which the media fits.  28. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the seats for the sensors are made in the form of holes with a diameter of not more than 14 mm. 29. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the seats for sensors are made in the form of holes for sensors with an electrical output of the sensor at an angle of 60 to 150 ^o to the axis of the sensor . 30. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes many rigid and / or elastic runners with seats for sensors, the sensor seats are made in the form holes, the axes of which are oriented at an angle of 5 to 30 ^o to the radial line passing through the axis of the hole and the axis of the carrier. 31. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes many rigid and / or elastic runners with sensors installed in them, whose axes are oriented at an angle from 5 up to 30 ^o to the radial line passing through the axis of the sensor and the axis of the carrier. 32. Sensor carrier for an in-tube inspection projectile, including a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the seats for the sensors are made in the form of holes whose axes are oriented at an angle from 5 to 30 ^o to the radial line passing through the axis of the hole and the axis of the carrier. 33. A sensor carrier for an in-tube inspection projectile, comprising a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that sensors are installed in the seats, the axes of which are oriented at an angle of 5 to 30 ^o to radial line passing through the axis of the sensor and the axis of the carrier.  34. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a support in the form of an elastic disk and / or cuff, and / or in the form of a corrugated element with an axial symmetry with elastic runners mounted on the support with seats for sensors.  35. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of elastic runners with seats for sensors, the length of these runners is not more than 0.8 cylinder diameter The media fits into.  36. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of elastic runners with seats for sensors, the runner width is from 0.07 to 0.35 the diameter of the cylinder into which the carrier fits.  37. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of elastic runners with seats for sensors, the thickness of the runner is from 0.07 to 0.1 the diameter of the cylinder into which the carrier fits.  38. The carrier of sensors for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of elastic runners with seats for sensors, the length of these runners is at least 0.7 cylinder diameters into which the carrier fits, the thickness of the runner is from 0.03 to 0.15 of the diameter of the cylinder into which the carrier fits. 39. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a housing and a plurality of elastic skids with sensor seats, elastic skids are connected to the housing by elastic elements, landing places for sensors are made in the form of holes, the axes of which are oriented at an angle of not more than 10 ^o to the radial line passing through the hole and the axis of the carrier. 40. The carrier of sensors for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a support in the form of an elastic cuff or elastic disk, as well as many elastic skids with seats for sensors, elastic runners are connected to the support, the seats for the sensors are made in the form of holes, the axes of which are oriented at an angle of not more than 10 ^o to the radial line passing through the hole and the axis of the carrier.  41. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes at least one annular sensor holder with sensor seats in kinematically connected elements ring-shaped holder.  42. A sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that it includes at least one elastic ring with seats for sensors.  43. The sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that it includes a spiral-shaped sensor holder with seats for sensors, the seats form one or more helical lines around the axis of the carrier.  44. A sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that it includes at least one elastic corrugated element with axial symmetry, in which the seats for the sensors are made, the length of the element along the axis of the carrier does not exceed half the diameter of the cylinder into which the carrier fits.  45. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes kinematically connected elements with sensor seats, as well as elastic gaskets that can slide along the inner surface of the pipeline between elements with seats for sensors and the inner surface of the pipeline.  46. A sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of runners with sensor seats, as well as elastic gaskets between the runners that can slide on the inner surface of the pipeline with seats for sensors and the inner surface of the pipeline.  47. A sensor carrier for an in-tube inspection projectile, comprising a cuff of elastic material with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a plurality of gaskets between the sensor seats and the inner surface of the pipeline.  48. A sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a housing and a plurality of elements connected to the housing with sensor seats, the housing contains rigid links, and swivel joints between the links, the length of the rigid link of the housing along the axis of the carrier does not exceed half the diameter of the cylinder into which the carrier fits.  49. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a housing and a plurality of elements connected to the housing with sensor seats, the housing includes a bundle or cable or a hose, or a bellows, or a spring, or an elastic band.  50. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes interconnected rows of grouped elements with sensor seats, each element of the series is kinematically connected to adjacent elements row.  51. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes interconnected rows of grouped elements with sensor seats, each row is formed by elements adjacent to each other .  52. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes interconnected rows of grouped elements with sensor seats, each row of elements is pulled together by an elastic element capable of bend.  53. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a belt of kinematically connected sensor holders with seats for sensors mounted around the perimeter of the carrier axis, and spring-loaded elements bonded to said holders by the edges of the holders on both one and the other side of the belt of the holders relative to the plane of the belt. 54. Sensor carrier for an in-tube inspection projectile, with seats for sensors located on a surface with axial symmetry, characterized in that the carrier includes a belt of kinematically connected sensor holders with seats for sensors mounted around the perimeter of the carrier axis, and spring elements fastened to said holders, spring elements include elastic arms mounted at an angle of 45 ^° to 80 ^° to the axis of the carrier.