RU16316U1 - RADIO-TRANSPARENT HOUSING FOR GEOPHYSICAL EQUIPMENT - Google Patents

Abstract

Radiolucent case for geophysical equipment, containing a series of hollow ceramic cylinders located end-to-end, an outer plastic cylinder made of fibrous filler and a binder, characterized in that the outer plastic cylinder has a shock-absorbing shell, and a prestressed fiber filler is wound in layers with different winding directions in adjacent layers.

Description

RADIO-TRANSPARENT HOUSING FOR GEOPHYSICAL

EQUIPMENT

The utility model relates to geophysical exploration of wells and can be used for those types of well logging, for which they use a high-strength radio-transparent sealed protective case.

Known radiotransparent housing 1 for geophysical equipment and deep-sea apparatus, consisting of an external sealing shell, cylinders of insulating material with high compressive strength, for example, ceramic or porcelain, in which the cylinders of the housing are made of individual elements separated by elastic gaskets and are divided among themselves so the same elastic pads.

Closest to the claimed utility model is the casing of the probe part of the downhole induction device 2, comprising a series of hollow ceramic cylinders located end-to-end, two adapters located end-to-end at both ends of a series of ceramic cylinders, an outer plastic cylinder made of fiber filler and a binder in which either clamps made in the form of pins located in blind holes on the outer surfaces of the ends of the adapters and pre-stressed fibrous will fill the spruce is placed along the axis of the casing and fixed with clamps, or annular grooves are made on the outer surfaces of the ends of the adapters and the prestressed fibrous filler is placed at an acute angle to the longitudinal axis of the casing.

The disadvantages of these radiotransparent cases is the low strength in bending, torsion and impact, which is a consequence of the winding of a strained fiber

filler in one direction over the entire thickness of the body and the absence of an external shock-absorbing layer.

The author of the claimed utility model was faced with the task of providing the possibility of using

radiolucent case for logging in complicated boreholes, according to technologies for conducting geophysical research of wells, both using and without using vertical assembly of geophysical equipment at the wellhead.

This goal is achieved by the fact that in a radiolucent case for geophysical equipment containing a series of hollow ceramic cylinders located end-to-end and an outer plastic cylinder made of fibrous filler and a binder, the outer plastic cylinder has a shock-absorbing shell, and a prestressed fiber filler is wound in layers with different directions winding in adjacent layers.

New in relation to the state of the art is that the outer plastic cylinder has a cushioning shell, and the prestressed fibrous filler is wound in layers with different winding directions in adjacent layers.

Conducted research of the claimed

radio-transparent housing for geophysical equipment showed that the set of essential features of a utility model is not known from the prior art, therefore, the utility model is new.

The technical essence of the utility model is illustrated by the drawing, which shows a section of a radio-transparent housing for geophysical equipment.

Radio-transparent housing is as follows.

The inner cylinder is made of hollow ceramic cylinders 1 located end-to-end. Over its entire length, an outer plastic cylinder 2 is tightly pressed against it, to which, in turn, a shock-absorbing shell 3 is adjacent tightly along its entire length.

The prestressed fibrous filler is wound in layers with different directions of winding 4, 5 adjacent layers. For example, in one of the layers 4, the filler is wound at an angle close to 90 ° with respect to the longitudinal axis of the casing - and in the adjacent layer 5, at an angle close to 0 ° with respect to the casing axis.

The proposed device operates as follows.

A probe of the geophysical instrument is placed in the internal cavity of the housing. The housing is hermetically connected to adjacent nodes. When descending into the well, the radiostransparent body is affected by the hydrostatic pressure of the drilling fluid, body impacts against the well walls and high temperature. From impacts on the walls of the well, the casing is protected by a shock-absorbing shell 3 made, for example, of rubber or polyethylene. Thanks to the internal ceramic cylinders 1, the casing withstands high hydrostatic pressure of the drilling fluid, while normal air pressure is maintained inside the casing. The outer plastic cylinder 2 fastens the ceramic cylinders 1 into a single strong pipe, provides sealing of the housing and provides high bending strength of the housing due to the fact that the fibrous filler of the windings is layered with a different direction of winding 4,5 in adjacent layers. Alternately alternate, for example, winding at an angle of 4 close to 90 ° relative to the longitudinal axis of the housing and 5 close to 0 ° relative to the longitudinal axis of the housing.

The proposed design of the radiolucent case can be used in apparatus for deep-sea research.

USEFUL MODEL FORMULA

RADIO-TRANSPARENT HOUSING FOR GEOPHYSICAL

EQUIPMENT

Radiolucent case for geophysical equipment, containing a series of hollow ceramic cylinders located end-to-end, an outer plastic cylinder made of fibrous filler and a binder, characterized in that the outer plastic cylinder has a shock-absorbing shell, and a prestressed fiber filler is wound in layers with different winding directions in adjacent layers.

Sources of information: 1.A.S. USSR No. 2.A.S. USSR No. 608437, class OOL / 13/00, 1976. 1242603, cl. ЕВВ 47/00, 1966. Bul. Number 25.

Claims (1)

Radiolucent case for geophysical equipment, containing a series of hollow ceramic cylinders located end-to-end, an outer plastic cylinder made of a fibrous filler and a binder, characterized in that the outer plastic cylinder has a shock-absorbing shell, and a prestressed fibrous filler is wound in layers with different winding directions in adjacent layers.