TH77614B - Composite material for controlling release of well treatment agent - Google Patents

Abstract

DC60 (25/10/56) A composite material for pit treatment, which makes it possible to delay discharge. One or more well-treatment agents enter the underground shale and/or the borehole inserted into the shale. It has a porous substrate that is calcine and nanoscale. (absorbent material) with a high surface area There is a pitting treatment agent. Composite materials are suitable for use in borehole treatment operations. in such a way that the rock strata is hydraulically broken and sand controlled. A composite material for treating a type of well, which makes it possible to slow down the discharge. One or more well-treatment agents enter the underground shale and/or the borehole inserted into the shale. It has a porous substrate that is calcine and nanoscale (absorbent) with a high surface area. There is a pitting treatment agent. Composite materials are suitable for use in borehole treatment operations. in such a way that the rock strata is hydraulically broken and sand controlled.

Claims (1)

Disclaimer (all) which will not appear on the advertisement page. : ------ 09/05/2018 ------ (OCR) Page 1 of 3 pages Disclaimer 1. A well treatment composite material containing a wellhead treatment agent. And calcine porous metal oxide, with porosity and The permeability of calcined porous metal oxides is characterized by Where the pit treatment agent is adsorbed onto porous metal oxides which are calcined or absorbed in The gaps inserted in the porous metal oxide content and further, where: (a) the surface area of the calcined porous metal oxide is between 1 m 2 / g to 10 m 2 / g; (b) The diameter of the calcined porous metal oxide is between 0.1 and 3 mm; And (c) the pore volume of the calcined porous metal oxide ranges from 0.01 to 0.10 cc / g. 2. Composites for well treatment according to claim 1, where The composite material ranges from 1 to 50% by weight of the well treatment agent. 3. The composite material for well treatment according to claim 1 where the metal oxide is The porosity makes up the sorbent for the well treatment and where the sorbent contains silica. 4. The composite material for the well treatment according to claim 1, where the well treatment agent is Choose from a category that includes a scale inhibitor, corrosion inhibitor, paraffin inhibitor, salt inhibitor, gas hydrate inhibitor. , Asphaltene inhibitor, oxygen scavenger (oxygen scavenger), disinfectant (biocide), foaming agent, emulsion breaker and surfactant. And these compounds are mixed. 5. Method of claim 4, where the well treatment agent is a scale inhibitor, corrosion inhibitor, paraffin inhibitor, salt inhibitor, gas hydrate inhibitor. , Asphaltine inhibitors Page 2 of the number 3. Page 6. Composites for well treatment according to claim 5, where metal oxides are Ruphun which is calcined to alumina 7. Composite material for well treatment according to claim 1 where the metal oxides are porous. Porous alumina 8. Composite material for well treatment according to claim 7, where alumina is porous. The calcined porous alumina is alpha / delta, theta alumina, or alpha alumina. 9. Composite material for pit treatment according to Claim 1, whereby the well treatment agent Water solubility 1 0. The composite material for well treatment according to claim 1, where the well treatment agent Solubility in hydrocarbons 1. 1. A type of proppant made up of composite materials for treatment. Holes according to claim 1, not exceeding 15% of the proppant was exposed at 10,000 psi closed chamber stress when composite material was present 10% by weight of well treatment agent 1 2. Well treatment component consisting of composite material for the Pit treatment according to Claim 1 and at least one prop. Where composite materials for pit treatment have Between 1 and 50% by weight of well treatment agent 1 3. Well treatment element according to claim 12 where porous metal oxides Of composite material for alumina well treatment 1 4. Wellhead treatment composite material for substrate feeding, composite material for well treatment containing water solvent treatment agent. Can or dissolve in A hydrocarbon and a porous alumina, which is calcined with porosity and The permeability of the calcined porous alumina is characterized by the 3 pore pore treatment agents are absorbed on the porous alumina surface. Which is calcined or absorbed into the space That is inserted in the body of the porous alumina that is calcined And also by which composite materials for Well treatment ranges from 1 to 50% by weight of well treatment agent which can be This is generally maintained for a long period of time in the shale fluids contained in the basement 1 5. Composite materials for well treatment according to claim 14, where alumina is calcified. Sine At a temperature greater than or equal to 1200 (symbol) c 1 6. Composite material for well treatment according to claim 15 where alumina is calcined. At a temperature greater than or equal to 1400 (symbol) c 1 7. Composite material for well treatment according to claim 14 where alumina is porous. Calcined as sorbent for the well treatment agent and where the sorbent is made Further, silica 1 8. Composite material for well treatment according to claim 14 where (a) the surface area of the porous metal oxide being calcined is between 1 m 2 / Gram to 10 m 2 / g; (b) The diameter of the calcined porous metal oxide is between 0.1 and 3 mm; (c) The pore volume of the calcined porous metal oxide ranges from 0.01 to 0.10 cc / g; (d) The bulk density of the composite material is between 75 and 150 lb / ft3; And (e) the specific gravity of the composite material for well treatment is less than or equal to 3.75 g / cc. According to claim 14 and a type of prop ------------ 1. A type of wellhead treatment composite containing a type of wellhead treatment agent. And metal oxides (metal is a porous oxide) that is calcine with porosity and The permeability of calcined porous metal oxides is characterized by The lump curing agent is adsorbed into the cavity inserted in the porous metal oxide content, and where: (a) the surface area of the porous metal oxide to be calcined is Between from about 1 m 2 / g to about 10 m 2 / g; (b) The diameter of the calcined porous metal oxide is between approximately 0.1 and approximately 3 mm; and (c) the pore volume of the calcined porous metal oxide. The sine is between approximately 0.01 and approximately 0.10 g / cc.