Casing conveyed well perforating apparatus and method

Abstract

Disclosed is a device and method for externally perforating a well-bore casing. The perforating apparatus is attached to the outside of the casing itself and is conveyed along with the casing when it is inserted into the well bore. The perforation is accomplished using two groups of charges which are contained in protective pressure chambers which are arranged radially around the outside of the wellbore casing. The pressure chambers form longitudinally extending ribs which conveniently serve to center the casing within the well bore. One group of charges is aimed inward in order to perforate the casing. A second group is aimed outward in order to perforate the formation. In an alternative embodiment, only one group of bi-directional charges is provided.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS [0001] None. STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT [0002] None. BACKGROUND OF THE INVENTION [0003] 1. Field of the Invention [0004] The present invention relates to a method and apparatus for perforating the walls of a well bore and, in particular, to a method and apparatus which will provide accurate and controlled perforating of a tubular casing during the process of creating a subterranean well. More specifically, a perforating assembly is deployed along with the casing to be used for the perforation and stimulation of zones for the ultimate withdrawal of hydrocarbons therefrom or injection of fluids (liquid or gas) for the purpose of voidage replacement or stimulation of the production interval wherein said perforating assembly comprises a frame supporting a plurality of pressure chambers configured as longitudinally extending ribs which conveniently serve to centralize the casing within the well bore. [0005] 2. D...

AI Technical Summary

Benefits of technology

[0025] It is a further object of the present invention to provide a perforating gun arrangement in which the perforations created are not imprecise, ragged, and asymmetrical, but instead, equally spaced and precise so that the perforated casing will have desirable in-flow characteristics and not be obstructed.

[0033] It is a further object of the present invention to provide a method of protecting sensitive transmission lines during perforation of the casing.

Problems solved by technology

A second disadvantage is that all of the charges in the Snider gun are fired from the same point of origin relative to the circumference of the casing.

The asymmetrical nature and raggedness of the perforations will cause the well to have poor in-flow properties when the well is placed into production.

Additionally, the raggedness of casing perforations 11 and 15 may occur to the extent that the ruptured inner surface of the casing could damage or even prevent passage of down-hole tools and instruments.

The structural integrity of the casing string might even be compromised to a degree.

A third disadvantage inherent in the method disclosed in Snider relates to the size of the cement-filled annulus created between the outer surface of the casing 12 and the inner surface of the bore hole.

Both of these solutions have disadvantages.

Even a slight increase in bore size will result in significant additional drilling costs.

Therefore, because deploying the Snider gun requires extra space outside the casing, the user must either pay additional drilling costs or suffer the consequence of reduced conduction of processing fluids.

A fourth disadvantage is that the Snider gun assembly is constructed of metal.

This is disadvantageous in that when the guns are fired, metal fragments from the assembly 20 will cause collateral damage thus impairing the flow performance of the perforation tunnel.

However, the necessity of tripping in and out of the well bore to perforate and stimulate each of multiple zones and / or formations is time consuming and expensive.

Another disadvantage in conventional systems regards the deployment of sensitive transmission lines outside the casing.

Where such a device is deployed outside a casing and where that casing is subsequently perforated, there exists a substantial risk that the device will be damaged by being directly impinged upon by the jet created by an exploding charge because the cables are not fixed at a known location to prevent being hit by the charge.

This risk is elevated if the perforating system is difficult to orient within the well bore.

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