RU2631408C1 - Underwater device for optoelectronic equipment (versions) - Google Patents

Abstract

FIELD: physics.

SUBSTANCE: underwater device for optoelectronic equipment in 1 and 2 embodiments contains a cylindrical body with end caps, fiber-optic cable sealing assemblies located on the end caps, a cassette located inside the sealed housing. Herewith the cassette, installed in the housing with a gap and with the possibility of its rigid fixation, is a design of the regular tetrahedral prism type without lateral ribs. The lateral faces are formed along the long axis of the housing by four lodgements attached at both ends of the housing to the grounds in the form of a rigid disc-shaped bearings with an outer contour in the shape of a rectangle with rounded corners and with a central hole for the fiber-optic cable. Herewith all the lodgements are made identical, having in the cross-section a circular segment with a height h, the arc of which is formed by a circle of the radius equal to the inner radius of the shell R₀, are installed with a convex side to the housing, and with a flat side - inside the cassette. On the flat sides of the lodgements of width L₀, it is possible to fix one or more cards with the optoelectronic equipment and heat sink radiators using screws. The outer contour of both supports is formed by the circumscribed circle of radius R₁, which is bounded by four chords located on the sides of the unclosed rectangle, each of which has length L₁, L₂, L₃, L₄. Supports on all sides of the unclosed rectangle of its contour are equipped with corners, on the shelves of which projecting from the outside of the cassette the ends of the lodgments are stacked with the flat side. In the 2-nd embodiment of the device, a central module is provided inside the cassette located in the plane intersecting the both supports, particularly in the diagonal plane.

EFFECT: increasing the convenience of installation of optoelectronic equipment inside the sealed enclosure, as well as increasing the reliability of this equipment and the entire device by effectively removing heat from the enclosed space of the hermetic housing into the external environment.

3 cl, 10 dwg

Description

The invention relates to the field of marine instrumentation and can be used in the design of underwater equipment for placement in it of optoelectronic equipment for amplification and control of optical signals.

The prior art design of the connectors for underwater fiber optic cables (US patent No. 4601536, NKI 350-96.20, French application No. 2607939, MKI G02B 6/38). A feature of these designs is the full filling of polyethylene with a durable body with power attachment points of the armored carrier with the transition to the polyethylene sheath of the cable. Such structures with polyethylene filling provide reliable sealing of the robust coupling housing and have a long service life in sea water, but require very complicated equipment during installation and repair of the cable line, a long lead time (more than a day for mounting one coupling) and high cost.

Known RF patent No. 2433431 for the invention, “Coupler for an underwater fiber optic cable” according to application No. 201001432 with a priority of January 20, 2010, IPC G02B 6/38, published November 10, 2011, selected as a prototype.

The design of the coupling includes a sealed enclosure in the form of a glass with end caps, nodes for power sealing armored and cable sealing nodes located on the end caps, cassettes for laying optical fibers and places for their welding, located inside the sealed enclosure, and end flexural couplings.

In this design, the coupling does not use polyethylene casting, which greatly simplifies the equipment for mounting and repairing the coupling. However, during installation or repair work, the laying of optical fibers and their connection (welding) have to be carried out inside a sealed enclosure, which is extremely inconvenient. In addition, the described coupling does not allow the installation of additional electronic equipment inside the housing, as the design does not provide means for removing heat from the sealed enclosure to the surrounding space.

The task to which the invention is directed is the development of a device that provides ease of installation and installation of optoelectronic equipment inside a cylindrical sealed enclosure of an underwater device, as well as ensuring the reliability of this equipment and the entire device due to efficient heat removal from the enclosed space of the sealed enclosure to the external environment .

To solve this problem, an underwater device that contains a cylindrical body with end caps, fiber-optic cable sealing units located on the end caps and a cassette inside a sealed enclosure, according to the invention in the first embodiment, is designed to accommodate optoelectronic equipment (optoelectronic boards and heat sinks) the cassette is a spatial structure such as a regular tetrahedral prism, the side faces of which do not have each other common parties i.e. without lateral ribs, and the lateral faces are formed by four lodges extended along the axis of the housing, attached at both ends of the housing to the bases in the form of hard disk-shaped supports with a central hole for a fiber optic cable. In this case, the cartridge is installed in the housing with a gap and with the possibility of its rigid fixation in the desired position after installation.

All lodgments are made identical and have a circular segment with a height h in cross section, and the arc of the segment is formed by a circle with a radius equal to the inner radius of the body R ₀ . The lodgements are installed with the convex side to the body, and flat - inside the cassette. On the flat sides of the lodgements with a width of L ₀ equal to (0.2-1.4) R ₀ , it is possible to fasten one or, depending on the layout, several boards with optoelectronic amplification and optical signal control units, termination units optical fibers and heat sinks.

Both supports have the same external contour in the form of a rectangle with rounded corners (open), which is formed by the circumscribed circle of radius R ₁ bounded by four chords located on the sides of this open rectangle. Moreover, each of its sides, the chords, which form a straight section of the outer contour of the supports, has a length L ₁ , L ₂ , L ₃ , L ₄ , and the parts of the circumscribed circle that form the rounded corners and make the rectangle of the contour of the supports open, have a radius R ₁ equal to ( 0.95-0.96) R ₀ , i.e. less than the inner radius of the housing R ₀ 4-5%.

At the same time, on both supports two adjacent chords - the sides of the open rectangle L ₁ and L _{2 are} removed from the body axis by a distance equal to R ₀ -h, therefore two adjacent lodgements fixed to these straight sections of the supports located at 90 ° relative to each other , with their convex surface adjacent to the inner surface of the housing closely, since: (R ₀ -h) + h = R ₀ .

At the same time, two other adjacent chords - the sides of the open rectangle L ₃ and L ₄ on both supports are removed from the body axis by a smaller distance than the first two, namely, by the distance: (0.98-0.92) R ₀ -h therefore, two other adjacent lodges fastened close to these straight sections of the supports form a gap of size (2-8)% R ₀ between their convex surface and the inner surface of the body.

In this case, the supports on straight sections of the external contour, i.e. on the sides of an open rectangle, equipped with corners, on the shelves protruding from the outside of the cassette, the ends of the lodges are laid on a flat surface. Moreover, the ends of two adjacent lodgements laid on the corners of two adjacent sides of the open rectangle L ₁ and L ₂ are attached to the corners on both supports rigidly with bolts, and the ends of the other two lodgements are connected with the corresponding corners on two other adjacent sides of the open rectangle L ₃ and L _{4 of} both supports with guide pins. At the same time, for rigid fixation of the cartridge in the device case, the protruding shelves of the last two corners on the supports, in addition to the holes for the guide pins of the lodgements, have holes for the bolts. After installing the cartridge in a cylindrical body with the help of these two bolts on each of the supports, the above clearance is selected and the lodgements on the sides of the supports L ₃ and L ₄ are pressed against the body in a spacer, rigidly fixing the cartridge.

The inventive design allows all electrical and optical connections to perform on the lodgement boards before assembling and installing the cartridge inside the cylindrical sealed enclosure of the underwater device, which greatly facilitates its installation. Moreover, due to the fact that the circumference of the outer contour of the disk-shaped supports R ₁ has a diameter of 4-5% less than the internal diameter of the device casing R ₀ , and also due to the fact that in the cassette the ends of two adjacent lodgements are fixed to the corners of the supports, and the ends the other two lodgements are connected to the corresponding corners of the supports using guide pins, i.e. not rigidly, and installed in the cassette with a clearance of (2-8)% R ₀ between its convex surface and the inner surface of the housing, the design of the inventive underwater device provides the convenience of installing the cartridge inside the housing.

Fixing the installed cassette inside the cylindrical case of the device is carried out by simply unloading two adjacent lodgements using bolts on the outer shelves of the corners of both supports in a spacer.

Moreover, the design of the device provides good heat dissipation from the confined space of the sealed enclosure into the environment during the operation of the electronics. This is due to the fact that heat-removing radiators are installed on the boards, which are rigidly connected with the tool holders and come in contact with them over a large area, and the tool holders in the fixed state of the cartridge have hard contact over the entire area of their convex surfaces with the inner surface of the cylindrical body, since the radii coincide, as a result of which there is an effective heat dissipation when the electronics work through heating the walls of the case directly into the environment. Efficient heat removal increases the reliability of the optoelectronic equipment and the device as a whole.

To solve this problem, there is also an underwater device, which contains a cylindrical body with end caps, fiber-optic cable sealing units located on the end caps and a cassette inside a sealed enclosure, according to the invention, in a second embodiment, a cassette for placing optoelectronic equipment, made as described in the first embodiment, further comprises inside a Central module located in a plane intersecting the supports, in particular in the diagonal plane sets.

In this case, the central module consists of two studs with at least two brackets mounted on them and fixed with bolts, on which, on the one or two opposite sides, depending on the number of necessary optoelectronic equipment, are fixed with screws of the circuit board for mounting on optoelectronic nodes and optical fiber embedment nodes.

Both supports of the cassette are made with the same external contour as described above in the first embodiment of the device: in the form of a rectangle with rounded corners, but the supports have additional holes for the studs of the central module, in particular, located on the diagonal of an open rectangle between the vertices obtained by continuing its sides - the chords L ₁ , L ₂ , L ₃ , L ₄ until they intersect. In this case, the studs are threaded at the ends, inserted into the corresponding holes of the supports and fixed with nuts to one of them.

In this embodiment, the device has a geometric ratio of the same as in the first embodiment.

The presence of an additional central module in the described design of the underwater device made in the 2nd embodiment, compared with the design made in the 1st embodiment, allows you to place more optoelectronic equipment inside the device and arrange it more optimally when you get the same technical results as and in the 1st embodiment: providing ease of installation of equipment and installation of the cassette inside the device body, as well as providing effective heat removal from the sealed internal volume underwater device to the environment when using electronic equipment.

Thus, the claimed invention is an underwater device for optoelectronic equipment in both versions of its implementation provides great convenience for installation and installation of optoelectronic equipment inside the device’s case, as well as improving the reliability of its operation by providing efficient heat dissipation when the electronics work from the enclosed space of the sealed enclosure to the external Wednesday

The claimed invention "Underwater device for optoelectronic equipment (options)" is illustrated by the following drawings.

In FIG. 1 shows an underwater device for optoelectronic equipment assembly in general terms according to 1 and 2 options;

in FIG. 2 shows a general view of the assembled cartridge according to the 1st embodiment;

in FIG. 3 shows the cradle of the cartridge in 1 and 2 options: a) an end view, b) a straight view;

in FIG. 4 shows the support of the cassette with the corners according to the 1st option: a) straight, b) in profile, c) general view;

in FIG. 5 shows a view of the assembled cartridge according to the 1st embodiment from the side of the support;

in FIG. 6 shows the central module of the cartridge according to the 2nd embodiment with a mounting plate;

in FIG. 7 shows an example of the construction of the bracket of the central module of the cartridge according to the 2nd embodiment;

in FIG. Figure 8 shows the support of the cassette with corners according to the 2nd variant: a) straight, b) in profile, c) general view;

in FIG. 9 shows a partially assembled cartridge according to the 2nd embodiment with a central module in a diagonal plane;

in FIG. 10 shows the assembled cartridge according to the 2nd embodiment, view from the side of the support.

The underwater device for optoelectronic equipment in the 1st and 2nd embodiments contains (Fig. 1) a cylindrical housing 1 with end caps 2, sealing units 3 of the fiber optic cable located on the end caps and a cassette 4 inside the sealed enclosure 1.

Cassette 4 in the 1st embodiment (Fig. 2) is a spatial structure of the type of a regular tetrahedral prism without side ribs, and the side faces are formed by four lodges 5 extended along the axis of the casing, attached to both ends of the casing to the bases in the form of hard disk-shaped supports 6 with an external circuit (Fig. 3) in the form of a rectangle with rounded corners and with a central hole for a fiber optic cable.

All lodgements 5 (Fig. 3) have a cross section in cross section of a circular segment with height h, the arc of which is formed by a circle with a radius equal to the inner radius R _{0 of the} housing 1. On the flat sides of the lodgments 5 with a width L ₀ equal to (0.2-1.4 ) R ₀ , it is possible to fix using screws one or more boards with nodes of optoelectronic equipment and heat sink radiators (not shown). Lodgements 5 (Fig. 2, 5) are installed with the convex side to the housing 1, and flat - inside the cassette.

The outer contour of both supports 6 (Fig. 4) is formed by a circumscribed circle of radius R ₁ bounded by four chords located on the sides of an open rectangle, each of the chords having a corresponding length L ₁ , L ₂ , L ₃ , L ₄ , and the circumference described, the parts of which form rounded corners in an open rectangle of the contour, has a radius R ₁ equal to (0.95-0.96) R ₀ , i.e. less than the inner radius of the body R ₀ by 4-5%, while the centers of two adjacent chords of the sides of the open rectangle L ₁ and L _{2 are} removed from the axis of the body by a distance of R ₀ -h, and the centers of two other adjacent chords of the sides L ₃ and L _{4 are} removed from the axis of the housing by a distance equal to (0.98-0.92) R ₀ -h.

Supports 6 (Fig. 4) on all chords - the sides of the open rectangle L ₁ , L ₂ , L ₃ , L ₄ are equipped with corners 7, 8, 9, 10, respectively, on the shelves protruding from the outside of the cassette, the ends of the lodges 5 are laid on their flat side .

In this case (Fig. 4, 5), the ends of two adjacent lodgements on the sides L ₁ , L ₂ on both supports 6 are fixed rigidly to the corners 7, 8 with bolts 11 (usually two), for which the protruding shelves of the corners 7, 8 have holes threaded. In the case of using narrow lodgements 5 with a small width L ₀ , each of their ends on the sides L ₁ , L _{2 of the} supports 6 is attached rigidly to the corners 7, 8 with one bolt 11, for which the protruding shelves of the corners 7, 8 have one hole threaded (not shown).

The ends of the other two lodgements 5 on the sides L ₃ and L ₄ on the supports 6 are connected with the corresponding corners 9, 10 using the guide pins 12 (usually two), for which the protruding shelves of these two corners 9, 10 have simple holes for the guide pins 12 lodges 5. In the case of narrow lodges 5 with a small width L ₀ , each of their ends on the sides L ₃ , L _{4 is} connected to the corners 9, 10 on the supports 6 using one guide pin 12, for which the protruding shelves of the corners 9, 10 have one simple hole for the guide pin 12 narrowly 5 of the recess (not shown).

At the same time, on the protruding shelves of two corners 9, 10 on the sides L ₃ and L _{4 of the} supports 6, in addition to simple holes for the guide pins 12 of the cradles 5, holes are made with threads for the bolts 13 (Fig. 4, 5) for the possibility of rigid fixation of the cartridge 4 in the device using these bolts 13 by pressing the lodgements 5 on the sides L ₃ and L _{4 of} both supports 6 to the housing 1 in the strut. When connecting each of the lodgements 5 with the corner 9 and 10, respectively, using two guide pins 12, the threaded holes for the bolt 13 for rigidly fixing the cartridge 4 are located at the corners 9 and 10, as a rule, between simple holes for the guides 12 (Fig. 4 , 5). In the case of narrow lodgements 5 with a small width L ₀ , the threaded holes for the bolt 13 for rigidly fixing the cassette 4 can be located at the corners 9 and 10 either on the side or in front or behind the simple holes for the guide 12 of the narrow lodgement 5 (not shown) .

The cassette 4 of the underwater device for optoelectronic equipment in the 2nd embodiment contains the same structural elements having the same geometric dimensions, also interconnected as in the 1st embodiment, with the exception of the following.

The cassette 4 (Fig. 9), in comparison with the 1st embodiment, further comprises inside a central module 14 located in a plane intersecting both supports 6, in particular in its diagonal plane. The central module 14 (Fig. 6) consists of two studs 15 with at least two brackets 16 mounted on them and fixed with bolts (an example of the brackets is shown in Fig. 7), on which from one or two opposite sides, depending on the amount of necessary optoelectronic equipment, the boards 17 are fixed with screws for mounting optoelectronic nodes and optical fiber termination nodes on them.

Both supports 6 in the 2nd embodiment (Fig. 8) are made the same as in the 1st embodiment: in the form of a rectangle with rounded corners with a central hole for the fiber optic cable, but they have additional holes 18 for the studs 15 of the central module 14 with a central hole for a fiber optic cable, in particular, located on the diagonal of an open rectangle, which can be built between its vertices by extending the sides - chords L ₁ , L ₂ , L ₃ , L ₄ to their intersection.

At the same time (Fig. 10), the studs 15 are threaded at the ends, inserted into the corresponding holes 18 of the supports 6 and fixed by nuts 19 to one of them.

The inventive device is used for placement and operation of optoelectronic equipment for amplification and control of optical signals inside a standard underwater coupling containing a cylindrical sealed housing 1 with end caps 2, sealing units 3 of the fiber optic cable located on the end caps 2 (Fig. 1). Optoelectronic equipment (boards with optoelectronic components and heat sinks) is located in the cassette 4 installed inside the sealed enclosure 1.

Cassette 4 in the 1st embodiment (Fig. 2), which is a spatial structure such as a regular tetrahedral prism without side ribs, with side faces formed by four lodges 5 extended along the axis of the housing (Fig. 3) attached to both ends of the housing to the bases in the form of hard disk-shaped supports 6 (Fig. 4) in the form of a rectangle with rounded corners and with a Central hole for fiber optic cable, before installing it inside the sealed enclosure 1 is assembled as follows.

On the flat sides of the lodgements 5 (Figs. 2, 3), one or more boards with optoelectronic equipment and heat sink radiators pre-mounted on them are fixed with screws on one or more boards, depending on their composition, quantity and layout (not shown).

First, two lodgements 5 with boards fixed to them with optoelectronic equipment with their ends of a flat surface are laid on the shelves of adjacent corners 7, 8 on the sides L ₁ , L _{2 of the} two supports 6 that protrude from the outside of the cassette and are rigidly fixed to them by bolts 11 (Fig. 5 )

Then, the necessary electrical and optical connections are made between the boards mounted on all lodges 5, as well as their connection to the ends of the fiber optic cable stretched through the central holes in the supports 6 on both sides of the housing 1.

The remaining two lodgements 5, on which boards with nodes of optoelectronic equipment are also pre-mounted, are installed with their ends on a flat surface on the shelves of the other adjacent corners 9, 10 protruding from the outside of the cassette on the sides L ₃ , L _{4 of} both supports 6 using guide pins 12, which are fixed by a threaded connection on the lodgements 5 and inserted into the corresponding holes at the corners 9, 10 of both supports 6.

Thus, in the assembled cartridge 4, the lodgements 5 (Fig. 2, 5) are installed with the flat side (surface) inside the cartridge, and convex - outward, i.e. to housing 1.

After that, the assembled cartridge 4 with the optoelectronic equipment mounted on it is installed inside the cylindrical body 1.

In this case (FIG. 4) the cartridge design of the claimed device 4 provides the convenience of its installation inside a sealed cylindrical housing 1. Ease of installation of the cassette is provided by the fact that the radius R of the circumcircle ₁ of the outer contour of the two supports 6 smaller than the inner radius R ₀ on the housing 4- 5%, and also due to the fact that the ends of two adjacent lodgements 5 on the sides L ₁ and L _{2 are} fixed at the corners 7, 8 of both supports 6 with bolts 11, and the ends of two other lodges 5 on the sides L ₃ and L ₄ are connected with corners 9, 10 on both supports 6 due to the fact that the guide pins 12 are simply inserted into the holes at these corners, i.e. not rigidly, and the last two adjacent lodges 5 are installed with a gap of (2-8)% R ₀ between its convex surface and the inner surface of the body.

After installing the cartridge 4 inside the housing 1, it is rigidly fixed. To do this, with the help of bolts 13 from the side of each of the supports 6, the above-mentioned clearance (2-8)% R ₀ is selected and pressed against the housing 1 into the spacer of two lodgements 5, installed on the sides L ₃ and L ₄ and connected with corners 9, 10 on both supports 6 with guide pins 12.

Thus, the design of the inventive underwater device allows all electrical and optical connections to be performed on the lodgement boards 5 prior to assembly and installation of the cartridge 4 inside the cylindrical sealed housing 1, which greatly facilitates its installation.

When working with electronics, the design of the device provides good heat dissipation from the confined space of the sealed enclosure 1 into the environment. This is due to the fact that heat sink radiators (not shown) are installed on the lodgement boards 5, which are rigidly connected to the lodgements 5 and come in contact with them over a large area, and the lodgements 5 in the fixed state of the cassette 4 have hard contact over the entire area of their convex surfaces with the inner surface of the cylindrical body 1, since their radii coincide, as a result of which there is an effective heat dissipation when the electronics work through heating the walls of the housing 1 directly into the environment. Efficient heat removal increases the reliability of the optoelectronic equipment and the device as a whole.

In the 2nd embodiment, the cartridge 4 (Fig. 9, 10), which is a spatial structure such as a regular tetrahedral prism without side ribs with a central module in the diagonal plane, with side faces formed by four lodges 5 extended along the axis of the housing, attached to both the ends of the housing to the bases in the form of hard disk-shaped supports 6 (Fig. 8) in the form of a rectangle with rounded corners and with a central hole for the fiber optic cable, before installing it inside the sealed enclosure 1 It strips the same way as in the 1st embodiment, except as indicated below.

The central module 14 is assembled after two lodgements 5 with their boards with optoelectronic equipment fixed at their ends are laid on the protruding shelves of adjacent corners 7, 8 on the sides L ₁ , L _{2 of} both supports 6 and are rigidly fixed to them by bolts 11 (Fig. 9).

The central module 14 (Fig. 6) is assembled as follows: first, at least two brackets 16 are mounted and fixed with bolts on the studs 15, threaded at the ends (for example, the brackets are shown in Fig. 7), then on the brackets 16, in Depending on the number of necessary optoelectronic equipment, boards 17 with optoelectronic components pre-mounted on them are fixed on one or two opposite sides with screws.

After assembling the central module 14, the necessary electrical and optical connections are made between the boards fixed on all lodges 5 and the boards of the central module 14, as well as their connection to the ends of the fiber optic cable stretched through the central holes in the supports 6 on both sides of the housing 1.

After that, the central module 14 is installed in a partially assembled cartridge 4 (Fig. 9) with two lodges 5, rigidly fixed with bolts 11 at the corners 7, 8 on the sides L ₁ , L _{2 of} both supports 6, with boards installed with optoelectronic equipment 17 In this case, the studs 15 are inserted into the special holes 18 of the supports 6 (Fig. 8), located, in particular, on the diagonal of the open rectangle of the outer contour of the supports 6 between its vertices, which can be obtained by continuing the sides - chords L ₁ , L ₂ , L ₃ , L ₄ to their intersection. Then the studs 15 of the Central module 14, made with threads at the ends, are fixed by nuts 19 to one of the supports 6 (Fig. 9).

After installing the central module 14, as in the 1st embodiment, on the corners 9, 10 of both supports 6 on the sides L ₃ , L ₄ , the remaining two lodgements 5 are installed using the guide pins 12, on which the boards are also pre-fixed with nodes of optoelectronic equipment 17.

The assembled cartridge 4 with the optoelectronic equipment mounted on it is installed inside the cylindrical body 1 with a gap (Fig. 10) and rigidly fixed in it with the help of bolts 13 as in the 1st embodiment of the device.

Thus, the proposed design of the underwater device for optoelectronic equipment in both versions of its implementation allows to increase the convenience of mounting optoelectronic equipment and its installation inside the device’s case, as well as to increase the reliability of its operation due to the efficient heat removal when the electronics work in the environment.

The inventive device underwater for optoelectronic equipment in both versions of its execution can be made of materials usual for this type of device using standard equipment using tools used to make components and parts of industrial equipment.

So, a cylindrical body 1 with end caps 2, supports 6, corners 7-10, can be made, for example, of steel 3.

The lodgements 5 can be made, for example, of aluminum alloy, and the guide pins 12 of the lodgements 5, for example, of steel 3.

Board 17 for mounting optoelectronic equipment can be made, for example, of fiberglass.

The studs 15 of the central module can be made, for example, of steel 3, and the brackets 16 can be made, for example, of aluminum alloy.

The fixing bolts 13 can be made, for example, of alloyed stainless steel.

Fasteners are common for this type of device.

Claims (14)

1. Underwater device for optoelectronic equipment containing a cylindrical body with end caps, fiber optic cable sealing units located on the end caps, a cassette located inside the sealed enclosure, characterized in that the cassette installed in the housing with a gap and with the possibility of its rigid fixation is a spatial structure such as a regular tetrahedral prism without side ribs, and the side faces are formed by four lodges extended along the body axis attached to both ends of the housing to the bases in the form of hard disk-shaped supports with an external contour in the form of a rounded rectangle and with a central hole for a fiber optic cable; in this case, all lodges are made identical, having in cross section a circular segment with height h, the arc of which is formed by a circle with a radius equal to the inner radius of the casing R ₀ , are installed with the convex side to the casing, and the flat side inside the cassette, and on the flat sides of the cradles of width L ₀ , equal to (0.2-1.4) R ₀ , it is possible to fix one or several boards with nodes of optoelectronic equipment and heat sink radiators with screws; the outer contour of both supports is formed by the circumscribed circle of radius R ₁ equal to (0.95-0.96) R ₀ , which is limited by four chords located on the sides of an open rectangle, each of which has a length L ₁ , L ₂ , L ₃ , L ₄ , and the chords are remote from the axis of the body: each of two adjacent chords - sides L ₁ and L ₂ - at a distance R ₀ -h, and each of the two other adjacent chords - sides L ₃ and L ₄ - at a distance (0 98-0.92) R ₀ -h; while the supports on all sides of the open rectangle of their contour are provided with corners, on the shelves protruding from the outside of the cassette, the ends of the lodgements are laid on their flat side, and the ends of two adjacent lodgements on the sides L ₁ and L ₂ are rigidly bolted to the corners on both supports, and the ends two other lodgements on the sides L ₃ and L ₄ are connected with the corresponding corners on the supports using guide pins, and on the protruding shelves of these last two corners, except for the holes for the guide pins of the lodges, holes for the bolts are made for the possibility of rigid fixation of the cartridge in the device with the help of clamping tool holders on the sides of both supports L ₃ and L ₄ to the body in the spacer. 2. Underwater device for optoelectronic equipment, containing a cylindrical body with end caps, fiber optic cable sealing units located on the end caps, a cassette located inside the sealed enclosure, characterized in that the cassette installed in the housing with a gap and with the possibility of its rigid fixation is a spatial structure such as a regular tetrahedral prism without side ribs with a central module inside, and the side faces are formed by four lodges extended along the axis of the housing attached to both ends of the housing to the bases in the form hard disk-shaped supports with an external contour in the form of a rectangle with rounded corners and with a central hole for a fiber optic cable, and the central module is located false in a plane intersecting both supports; in this case, all lodges are made identical, having in cross section a circular segment with height h, the arc of which is formed by a circle with a radius equal to the inner radius of the casing R ₀ , are installed with the convex side to the casing, and the flat side inside the cassette, and on the flat sides of the cradles of width L ₀ equal to (0.2-1.4) R ₀ , it is possible to fix one or several boards with nodes of optoelectronic equipment and heat sink radiators with screws; the outer contour of both supports is formed by the circumscribed circle of radius R ₁ equal to (0.95-0.96) R ₀ , which is limited by four chords located on the sides of an open rectangle, each of which has a length L ₁ , L ₂ , L ₃ , L ₄ , and the chords are remote from the axis of the body: each of two adjacent chords - sides L ₁ and L ₂ - at a distance R ₀ -h, and each of the two other adjacent chords - sides L ₃ and L ₄ - at a distance (0 98-0.92) R ₀ -h; while the supports on all sides of the open rectangle of their contour are provided with corners, on the shelves protruding from the outside of the cassette, the ends of the lodgements are laid on their flat side, and the ends of two adjacent lodgements on the sides L ₁ and L ₂ are rigidly bolted to the corners on both supports, and the ends two other lodgements on the sides L ₃ and L ₄ are connected with the corresponding corners on the supports using guide pins, and on the protruding shelves of these last two corners, except for the holes for the guide pins of the lodges, holes for the bolts are made for the possibility of rigid fixation of the cartridge in the device with their help by pressing the lodgements on the sides of both supports L ₃ and L ₄ to the body in the spacer; the central module consists of two studs with at least two brackets installed and fixed on them with bolts, on which one or two sides are fixed with screws of the circuit board for mounting the optoelectronic equipment nodes, and the supports have additional holes for the studs, and the central studs the modules are threaded at the ends, inserted into the corresponding holes of the supports and fixed with nuts to one of them. 3. Underwater device for optoelectronic equipment according to claim 2, characterized in that the central module inside the cartridge is located in the diagonal plane, for which additional holes in the supports for the studs are made diagonally of an open rectangle between its vertices, obtained by continuing the pairs of sides - chords L ₁ , L ₂ , L ₃ , L ₄ to their intersection.

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