SU1714739A1 - Water-tight lead-in - Google Patents

Description

The invention relates to electrical engineering and can be used for the installation of cable bundles through the shells of deep-sea apparatuses, to the vitality of which there are increased requirements.

The hermetic cable gland is known, which contains a branch pipe welded into the shell with sealing assemblies located on the end membrane, made in the form of sleeves with rubber covers.

However, this device has disadvantages in large dimensions when entering multi-cable beams.

These shortcomings are due to the fact. that the sleeves are mounted on a stiff thick

membrane under hydrostatic pressure of the outboard environment. Therefore, the sleeves are made thick-walled (with a wall thickness of about 5 mm). The distance between the welded seams on the thick-walled parts of the membrane and the glands, which work at the same time as the intake pressure, is determined by the rules of design by consideration of the survivability of the object. It should not be less than one and a half diameters of the sleeves. Therefore, the number of cables passing through the hermetic inlet is limited.

The closest in technical essence to the present invention is an inlet comprising a lid and a membrane articulated along the perimeter, the cavity between which is filled with a sealant, cables passing through the holes of the lid and membrane, snaps off each cable with sealing units with self-sealing covers and bushings mounted on the membrane .

However, this device also has drawbacks, which consist in limited water tightness in the event of accidental damage to sealing assemblies (self-sealing covers).

The invention is a reduction in size and an increase in emergency safety.

The drawing shows a sealed cable entry, cut.

Sealed entry contains membrane

1 and a cover 2 forming a cavity filled with an elastic sealant between them. In the membrane there are bushings 4. Through them and the holes 5 aligned with them 5 in the cover 2 pass cables 0. Each membrane cable 1 has & enveloped by inspection assemblies 7. Nodes 7 snvVbbN self-sealing covers 8, covering part of the outer surfaces of the sleeves 4. Part of the length of the inner surface of the sleeve 4 and the holes 5 in the cover

2 are made in the form of truncated cones with large bases facing each other. The membrane 1 has a cup-like shape and the edges are articulated with a lid; at 3ITOM, the elastic sealant 3 is in a cavity in a stressed state.

When installing the input after sealing the sealing units 7 into the cavity between the membrane 1 and the cover 2 under pressure

sealant 3 is injected until the membrane 1 is depressed from the rigid cover 2 within its elastic deformation. The sealant 3 around each cable fills the beveled portions of the openings 5 and the openings of the sleeves 4, forming conical sections during polymerization, due to the elasticity of the membrane 1 with the conical outer surface to the conical side of the perforation of these openings. Pull down

The membrane provides an initial seal due to the stress state of the sealant at low outboard pressures and, with an increase in the intake pressure, stacks with it, ensuring a satisfactory level of water tightness.

Claims (1)

Claims Hermetic inlet containing a membrane and a lid, forming between them a cavity filled with an elastic sealant, installed in the membrane of the sleeve, passage 1SCh through them and coaxial holes with them in the (cable spike and extending each cable, seal the fourth bundle; 9y with self-sealing covers, auger part of the outer surfaces | "Ost @ P | bushings , characterized by the fact that, in order to gain size and increase emergency safety, the suit The inner inner surface of the iota8a {zht | 1 "bushings in the {} tube is made in the form of a truncated core with a large base to each other. The membrane has a cup shape and the edges are articulated with a lid, while the elastic gerMetics is in the cavity in tense condition.