RU2114303C1 - Template for pipes - Google Patents

Abstract

FIELD: bore-hole drilling and operating appliances. SUBSTANCE: this can be used for checking passability of bore-holes in operation of various purpose wells. Template has body with connecting sleeves. Located on outer surface of template are calibrating members and stops which are fixed to prevent axial displacement. Stops are displaced relative to each other through value which exceeds height of calibrating members which are installed between stops for possible axial displacement and interaction with end faces of stops. Used in function of end stops are connecting sleeves. Application of aforesaid template improves efficiency, cuts material and labour expenses in releasing template in case of its sticking, and affords possibility for straightening deformed pipe string. EFFECT: higher efficiency. 3 cl, 2 dwg

Description

 The invention relates to drilling equipment used to control mainly production wells with the aim of determining the patency of their trunk during the descent of long units, for example submersible electric centrifugal pumps.

 A well-known template for testing production casing, including the housing and gage rings rigidly fixed on it (Lavrushko PN Underground well repair. - M .: Nedra, 1968, p. 272 - 273). The disadvantage of this template is the indistinguishability of the design and the complexity of its release in case of sticking in the pipe string being inspected.

 The closest to the proposed technical essence and the achieved result is a template for pipes containing a housing with connecting couplings and calibrating elements placed on its outer surface with stops fixed from axial movement (ed. St. USSR N 1086142, class E 21 B 47 / 08, 1982).

 This template is collapsible, which allows you to use it to control the patency of pipes of different diameters by selecting calibrating elements of the appropriate size.

 Its disadvantage is low efficiency, significant material and labor costs when it is released in the event of a sticking, and the inability to straighten a deformed column. In this regard, even with a slight deformation of the tested column, the known template requires its lifting and lowering of a special tool to correct the detected defect of the column, re-lowering the template and only after lifting it is possible to lower the submersible assembly. In addition, when using the prototype, it is possible to receive a false signal about the deformation of the tested string, especially when working in deviated wells. All this leads to an increase in the cost of work.

 The technical result of the invention is the elimination of these disadvantages of the prototype.

 This is achieved by the fact that the template for pipes containing a housing with connecting couplings and calibrating elements placed on its outer surface with stops fixed against axial movement, according to the invention, the stops are offset one from another by an amount exceeding the height of the calibrating elements installed between the stops with the possibility of axial movement and interaction with the ends of the stops, while connecting sleeves are used as end stops. The achievement of the specified technical result is also the fact that the template is equipped with mounting sleeves for fixing the stops, and the outer diameter of the sleeves is smaller than the inner diameter of the gauge elements, but larger than the inner diameter of the stops, while the gauge elements are made in the form of rings, the minimum stroke of which is determined by the formula : b = 0.3 + 0.0001H, m, where H is the well depth in the installation area of the unit, m.

 It also contributes to the achievement of the indicated technical result that the template can be made of separate interconnected sections, each of which has one stop located in the middle part of the body and made with it in one piece.

 In FIG. 1 shows a General view of the template in longitudinal section; in FIG. 2 - option for installing the stop.

 - The template for pipes contains a housing 1 with connecting couplings 2 at the ends, supports 3 mounted on the outer surface of the housing, and gauge elements in the form of rings 4 placed between the supports 3 with the possibility of axial movement along the housing until contact with the ends of the stops 3. The template can be made with rigidly and detachably connected stops. In the first case, the stops 3 are made in the form of rings that are rigidly connected to the housing 1, for example, by welding or in the form of protrusions as a whole with the housing. In this embodiment, the template is assembled from separate sections, each of which includes a housing 1 with one centrally located stop 3 and two calibrating rings 4 mounted between the stops and connecting couplings 2 (Fig. 1). In the second embodiment, the stops 3 are fixed on the housing 1 from axial movement by means of mounting sleeves 5, the outer diameter of which is smaller than the inner diameter of the gauge rings 4, but larger than the inner diameter of the stops 3 (Fig. 2). In this case, any number of stops and gauge rings can be installed on one body part. In both cases, the minimum distance L between the stops is determined by the formula: L = a + 0.0001H + 0.3, m, where a is the height of the gauge elements, m. The outer diameter of the gauge rings 4 is selected depending on the diameter of the immersion unit, and it must exceed the diameter of the latter by several millimeters, while the height "a" of the ring 4 must be at least its radius.

 When executing a template with rigid stops, it is mounted in the following sequence. Calibration rings 4 are put on the body 1 with a stop 3 and then connected to each other until a device of the required length is obtained. When executing a template with removable ledges, the assembly is carried out as follows. A sleeve 5 is put on a housing 1 with one connecting sleeve 2, on which a calibrating ring 4 is mounted. Then an emphasis 3 is put on, which rests on the end face of the sleeve 5 and forms the working section of the template. After that, the subsequent sections of the template are assembled in the same sequence and the assembly is completed by screwing on the housing of the second connecting sleeve 2. If necessary, a mandrel can be attached to the lower end of the template to straighten the deformed sections of the tested string.

 The template works as follows. Before lowering into the well, check the size and mobility of the gauge rings 4 along the housing 1. After this, the template is attached to the string of drill or tubing and lowered into the well 50-100 m below the depth of descent of the submersible unit. During the descent of the template, the gauge rings 4, depending on the state of the tested column, occupy a different position. In the absence of deformation of the walls of the column string, the rings 4 are in the lowermost position, and in the presence of deformation, the rings move to the upper position until they contact the end face of the stop 3. If, under the action of the axial force transmitted through the pipe string to the gauge rings 4, the latter passing through the tested string jam there, then proceed to release them by striking with the stops located below the jammed rings 4. If the grabbing of the calibrating rings 4 occurred while lifting the template, then they are released by ramie caused by stops at the top. In both cases, due to the telescopic connection of the gauge rings 4 with the housing 1, the template works as a jar, which allows not only to increase the efficiency of releasing the stuck gauge rings 4, but also to straighten the crumpled column. This also contributes to the presence of the mandrel 6. All this allows you to reduce the cost of the hoisting operations. The use of removable calibrating elements, stops and mounting sleeves allows you to assemble a template of different diameters and lengths, which reduces the total cost of the work.

Claims (4)

 1. A template for pipes, comprising a housing with connecting couplings and calibrating elements placed on its outer surface with stops fixed from axial movement, characterized in that the stops are displaced one from another by an amount exceeding the height of the calibrating elements installed between the stops with the possibility of axial moving and interacting with the ends of the stops, while connecting couplings are used as end stops.  2. The template for pipes according to claim 1, characterized in that it is equipped with installed sleeves for fixing the stops, the outer diameter of the sleeves being smaller than the inner diameter of the gauge elements, but larger than the inner diameter of the stops. 3. The template for pipes according to claim 1, characterized in that the calibrating elements are made in the form of rings, the minimum stroke of which b is determined by the formula
b = 0.3 + 0.0001H,
Where
H - well depth in the installation area of the submersible unit, m  4. The template for pipes according to claim 1, characterized in that it is filled from interconnecting sections, each of which has one stop located in the middle of the body and made with it in one piece.

Images