Slips are used for various downhole tools, such as bridge plugs and packers. One particular type of downhole tool having slips is a composite fracture plug used in perforation and fracture operations. After the fracture operations, the composite plugs need to be drilled up (milled out) in as short of a period of time as possible and with no drill up issues. Conventional composite plugs used metallic wicker style slips, which were composed of cast iron. These metallic slips increased the metallic content of the plug and caused issues during drill up in horizontal wells, especially when coil tubing is used during the milling operation.
Due to the drawbacks of cast iron slips, composite slips typically use inserts or buttons to grip the inner wall of a casing or tubular, while reducing the issues associated with metallic slips. For example, inserts used on a non-metallic slips can be arranged and oriented as shown in
Typically, the inserts used for a composite slip are composed of carbide, which is a dense and heavy material. Still, the inserts also need to be easily milled up and/or removable to assist in the removal of the downhole tools from the wellbore. In any event, when the downhole tool having composite slips with inserts are milled out of the casing, the inserts tend to collect in the casing and are hard to float back to the surface. In fact, in horizontal wells, the inserts may tend to collect at the heel of the horizontal section and cause potential problems for operations. To deal with this, a gel sweep or cleanup run must be performed during the mill up operation to remove the inserts. Given that a well may have upwards of forty or fifty bridge plugs used during operations that are later milled out, a considerable number of inserts may be left in the casing and difficult to remove from downhole.
To deal with this issue, it is known to use a composite slip having inserts composed of ceramic or composed of a powdered metal, such as described in U.S. Pat. No. 9,416,617, which is incorporated herein by reference. It is also known to use a composite slip having inserts with holes or partial holes, such as disclosed in U.S. Pat. No. 9,416,617. It is further known to use a composite slip having inserts composed of different layers of material, such as described in U.S. Pat. No. 10,415,335, which is incorporated herein by reference.
Even with these solutions, operators are continually striving to reduce the amount of material left in a wellbore after milling out composite tools. To that end, the subject matter of the present disclosure is directed to overcoming, or at least reducing the effects of, one or more of the problems set forth above.
In one arrangement disclosed herein, an insert is used on a slip of a downhole tool to engage in a downhole tubular. The insert comprises a body defining an internal cavity at least partially therein. The body comprises a ceramic material having a first density of about 3 g/cc to about 6 g/cc. A volume of the insert is about 0.4 cc to about 0.6 cc, and a mass of the insert is about 1.2 g to about 3.6 g.
The body can comprise a first end configured to extend beyond a surface of the slip; and can comprise a second end configured to install in the surface of the slip. At least one of the first and second ends defines an opening to the internal cavity.
The ceramic material can be selected from the group consisting of silicon nitride (about 3.3 g/cc), alumina, aluminum oxide density (about 3.95 g/cc), zirconia, and zirconium dioxide (about 5.68 g/cc).
The insert can further comprise a filler disposed in the internal cavity. The filler can comprise a second material having a second density at least less than about 3 g/cc. For example, the second material can be selected from the group consisting of aerogel (about 0.1 to 1.0 g/cc), a dissolvable material, polyglycolide (about 1.53 g/cc), magnesium (about 1.74 g/cc), and aluminum (about 2.70 g/cc).
In one arrangement disclosed herein, an insert is used on a slip of a downhole tool to engage in a downhole tubular. The insert comprises a body and a filler. The body defines an internal cavity at least partially therein and has a first volume. The body comprises a first material having a first density. The filler is disposed in the internal cavity and has a second volume. The filler comprises a second material having a second density less than the first density.
A total volume of the insert combining the first and second volumes can be about 0.4 cc to about 0.6 cc. The first volume of the body can be about 0.4 cc to 0.5 cc, and the second volume of the filler can be about 0.1 cc to about 0.2 cc inverse to the first volume. The first density can be about 6 g/cc to about 16 g/cc, and the second density can be about 0.1 g/cc to about 6 g/cc. A mass of the insert can be about 3 g to about 9.2 g.
The first material can be selected from the group consisting of ceramic, zirconia, zirconium dioxide (about 5.68 g/cc), a metallic material, a non-metallic material, a powdered metal, iron (about 7.86 g/cc), brass (about 8.50 g/cc), cermet (about 6 to 7.5 g/cc), and tungsten carbide density (about 15.25-15.88 g/cc). Meanwhile, the second material can be selected from the group consisting of aerogel (about 0.1 to 1.0 g/cc), a dissolvable material, polyglycolide (about 1.53 g/cc), magnesium (about 1.74 g/cc), aluminum (about 2.70 g/cc), silicon nitride (about 3.3 g/cc), alumina, aluminum oxide (about 3.95 g/cc), zirconia, and zirconium dioxide (about 5.68 g/cc).
The body can define a bore therethrough as the internal cavity. The filler can fill the bore from a first end of the body to a second end of the body; or the filler can fill the bore from the first end of the body to below the second end of the body and can form a base of the insert below the second end of the body.
The body can comprise a first end enclosing the internal cavity and can have a second end being open to the internal cavity. The filler can fill the internal cavity from the first end to the second end; or the second end can define a counterbore about the internal cavity such that the filler can fill the counterbore.
The first material of the body can comprise a silicon nitride with the first density of about 3 g/cc; and the second material of the filler can have a second density at least less than 3 g/cc. The second material can be selected from the group consisting of an aerogel, a dissolvable material, polyglycolide, magnesium, and aluminum.
In one arrangement disclosed herein, a downhole apparatus for engaging in a downhole tubular comprises a mandrel, a sealing element, a first slip, and a second slip. The mandrel has a first end and a second end. The sealing element is disposed on the mandrel between the first and second ends and is compressible to engage the downhole tubular. The first slip is disposed toward the first end of the mandrel and is movable relative to the mandrel to engage the downhole tubular. The first slip has inserts. The second slip is disposed toward the second end of the mandrel and is movable relative to the mandrel to engage the downhole tubular. The second slip also has the inserts. One or more the inserts can include an insert according to any one of arrangements disclosed above.
The non-metallic material can comprise a plastic, a molded phenolic, a laminated non-metallic composite, an epoxy resin polymer with a glass fiber reinforcement, an ultra-high-molecular-weight polyethylene (UHMW), a polytetrafluroethylene (PTFE), or a combination thereof.
The foregoing summary is not intended to summarize each potential embodiment or every aspect of the present disclosure.
The tool 100 has a mandrel 102 having the slip assemblies 110U-D and backup rings 140 arranged on both sides of a packing element 150. Outside the inclined cones 112, the slip assemblies 110U-D have slips 120. Together, the slips 120 along with the cones 112 can be referred to as slip assemblies, or in other instances, just the slips 120 may be referred to as slip assemblies. In either case, either reference may be used interchangeably throughout the present disclosure. Thus, reference herein to a slip is not meant to refer only to one slip body, segment, or element, although it can. Instead, reference to slip can refer to more than just these connotations. As shown herein, slip assemblies 110U-D can have the same types of slips 120, but other arrangements could be used.
As a bridge plug, the tool 100 is preferably composed mostly of non-metallic components according to procedures and details as disclosed, for example, in U.S. Pat. No. 7,124,831, which is incorporated herein by reference in its entirety. This makes the tool 100 easy to mill out after use.
When deployed downhole, the tool 100 is activated by a wireline setting tool (not shown), which uses conventional techniques of pulling against the mandrel 102 while simultaneously pushing upper components against the slip assemblies 110U-D. As a result, the slips 120 of the slip assemblies 110U-D ride up the cones 112, the cones 112 move along the mandrel 102 toward one another, and the packing element 150 compresses and extends outward to engage a surrounding casing wall. The backup elements 140 control the extrusion of the packing element 150. In the process, the slips 120 on the assemblies 110U-D are pushed outward to engage the wall of the casing (not shown), which both maintains the tool 100 in place in the casing and keeps the packing element 150 contained.
The force used to set the tool 100 may be as high as 30,000 lbf and could be as high as 85,000 lbf. These values are only meant to be examples and could vary for the size of the tool 100. In any event, the set tool 100 isolates upper and lower portions of the casing so that fracture and other operations can be completed uphole of the tool 100, while pressure is kept from downhole locations. When used during fracture operations, for example, the tool 100 may isolate pressures of 10,000 psi or so.
As will be appreciated, any slippage or loosening of the tool 100 can compromise operations. Therefore, the slips 120 need to sufficiently grip the inside of the casing. For this reason, inserts 130 disposed on the slips 120 are used for engaging (biting into) the casing.
At the same time, however, the tool 100 and most of its components are preferably composed of millable materials because the tool 100 is milled out of the casing once operations are done, as noted previously. As many as fifty such tools 100 can be used in one well and must be milled out at the end of operations. Therefore, having reliable tools 100 composed of entirely of millable material is of particular interest to operators. To that end, the slip assemblies 110U-D of the present disclosure are particularly suited for tools 100, such as bridge plugs, packers, and other downhole tools, and the challenges they offer.
As shown in the example of
In other arrangements such as shown in
In general, the slips 120 of
As disclosed in more detail below, at least some of the inserts 130 of the present disclosure are composed of a ceramic material. Additionally, the inserts 130 preferably have a sufficient hardness, which may be a hardness equivalent to at least about 50-60 Rc. In a preferred embodiment, the inserts 130 of the composite plug assembly are ceramic inserts 130 installed into the slips 120 and used on the composite plug 100 as an upper and lower slip 110U-D, just a lower slip 110D, or just an upper slip 110U. Accordingly, the ceramic inserts 130 can be arranged one, the other, or both the uphole and downhole assemblies 110U-D of the tool 100. One, more, or all of the segments 122 of the assembly 110U-D can have the ceramic inserts 130.
As shown in
In one arrangement, the inserts 130a-d can be the same size and can be disposed in equivalent sized holes 123 in the slip segment 122. In another arrangement, the depth of holes 123 can vary on a given segment 122, can vary from segment 122 to segment, and can vary from slip assembly to slip assembly. Therefore, one or more inserts 130a-d can be longer than the others. Additionally, the height that the inserts 130a-d extend beyond the segment 122 can be the same on the given slip segment 122 once installed, but the depth of the holes 123 can vary. This can reduce the stress around the insert 130a-d in the base material of the segment 122. Other arrangements may have the inserts 130a-d at different heights and different depths relative to the slip segment 122.
Still further, the diameter of holes 120 for inserts 130a-d in the slip 120 can vary from one another on the same segment, from segment to segment, or from slip assembly to slip assembly. For example, the holes 123 toward the ramped end of the segment 122 can be narrower than the holes 123 toward the opposite end. A reverse arrangement could be used.
The shape of the inserts 130a-d can be the same or different from one another. In general, the inserts 130a-d can be cylindrical or can have other shapes as discussed below. Additionally, as shown in
Just as the insert 130a-d can be hollow or partially hollow and filled with material, embodiments of the present disclosure can include slips 120 that are hollow (or partially hollow) and filled with a filler material. For example,
Having an understanding of the slips 120 and the types of inserts 130a-d, discussion now turns to particular examples of the inserts 130a-d. As first noted above with reference to
In
These configurations of ceramic inserts 130a-b with the full holes 135 or partial holes 137 still provide the necessary gripping. Yet, being composed of ceramic, the insert 130a-b with the full or partial hole 135, 137 allows for: (1) breakup of the ceramic insert 130a-b more thoroughly into smaller pieces during milling; and (2) less insert material being left in the wellbore per downhole tool (e.g., composite plug) milled up. All of this can save time and money during well operations. For example, less cleanup would be required, and the risk of the BHA (bottom hole assembly) getting stuck in the wellbore from large insert debris would be reduced during milling operations.
The ceramic insert 130a-b can use various types of ceramic material, including, but not limited to, alumina, zirconia, cermet, or other ceramic. Preferably, the ceramic material has a density of approximately 3 g/cc. Although reference to density is used in the present disclosure, specific gravity of the ceramic material can be of consideration for use in the wellbore because the wellbore includes drilling fluids. Therefore, including the consideration of density as disclosed, the specific gravity of the various materials disclosed herein may be considered. As is known, specific gravity refers to the density of a material relative to a reference density, such as of drilling fluid or the like in a wellbore application.
Preferably, the ceramic material used for the ceramic inserts 130a-b is silicon nitride. Silicon nitride can consist of Si3N4 and has a density of about 3.3 g/cc. By comparison, zirconium oxide has a density of about 6 g/cc. Based on the general dimensions discussed herein, a ceramic insert of silicon nitride without a hole would have a mass of about 1.83 grams (given a total volume of 0.555 cc for the insert without the hole). For a composite plug having about 48 inserts, the total mass for all of such solid silicon nitride inserts on the entire plug assembly would add up to about 87.8 grams.
However, the inserts 130a-b composed of silicon nitride having a full or partial cavity or hole 135, 137 as disclosed herein may have a mass of about 1.38 grams (given a total volume of the 0.418 cc for the insert 130a-b with the cavity 135, 137 and given the cavity 135, 137 having a volume of about 0.136 cc). For a composite plug having about 48 inserts, the total mass for all of the hollow silicon nitride inserts 130a-b on the entire plug assembly would thereby add up to about 66.2 grams.
In other arrangements, the ceramic material for the ceramic insert 130a-b can have a density in a range of about 3 g/cc to about 6 g/cc, such as associated with silicon nitride having a density of about 3.3 g/cc, alumina or aluminum oxide having a density of about 3.95 g/cc, and zirconia or zirconium dioxide having a density of about 5.68 g/cc.
As noted herein, existing inserts are typically composed of a metallic material, such as carbide. Consequently, the existing inserts have a high density (weight) are difficult to circulate out of the wellbore, especially out of a horizontal extended reach well. The hollowed ceramic inserts 130a-b of the present disclosure are considerably lighter, making them easier to circulate out and/or easier to break up during milling operations. The hollowed ceramic insert 130a-b has a high-strength (high-compression) outer exoskeleton (i.e., sleeve body 132) with a hollow 135 or partially hollow 137 inside diameter.
In this way, the hollow insert 130a-b composed of ceramic requires less material to be circulated out of the wellbore after milling, and the insert 130a-b are easier to break up into small pieces during milling. Moreover, the lower density ceramic material of the inserts 130a-b can make floating/circulating the material to surface easier. This reduces the risks typically encountered when milling up composite plugs.
As noted above with reference to
In
In general, the hollowed insert 130c-d has a full cavity, hole or bore 135 or has a partial cavity, hole or bore 137 comparable to the other inserts 130a-b discussed above. The filler material 140 disposed in the hole 135, 137 of the insert 130c-d can be a material of exceptionally low density and/or can be a dissolvable material.
In one example, the filler material 140 can be an exceptionally low density material, such as an aerogel having a density of about 0.10 to 1.0 g/cc. For example, one type of aerogel includes silica aerogel, which consists of C23H22N2O3S2. Other aerogels include carbon aerogels, metal oxide aerogels, and the like Alternatively, the filler material 140 can be a low density metallic or non-metallic material, such as magnesium, aluminum, dissolvable/degradable material, or polyglycolide (PGA).
Overall, the filler material 140 can have a density of at least about 3 g/cc or less, such as associated with aerogel of about 0.1 to 1 g/cc, magnesium of about 1.74 g/cc, polyglycolide (PGA) of about 1.53 g/cc, and aluminum of about 2.70 g/cc.
Overall, the insert material for the exoskeleton or body 132 of these inserts 130c-d can have a density of at least about 3 g/cc or greater, such as associated with silicon nitride having a density of about 3.3 g/cc, alumina or aluminum oxide having a density of about 3.95 g/cc, zirconia or zirconium dioxide having a density of about 5.68 g/cc, powdered metal, iron having a density of about 7.86 g/cc, brass having a density of about 8.50 g/cc, cermet having a density of about 6-7.5 g/cc, tungsten carbide density having a density of about 15.25-15.88 g/cc, etc.
Depending on the materials used, the filler material 140 can be manually installed with adhesive or molded in place using a process such as molding, metal injection, powdered metal, or pressing. The outer exoskeleton or body 132 of the insert 130c-d can be produced from metallic or non-metallic materials, such as powdered metal, ceramic, or cermet. The outer exoskeleton 132 can also be made of a high strength dissolvable material.
In
Although shown with full holes 135, the insert 130c in
In order for the filled inserts 130c-d of
Overall, the inserts 130a-d of
Mass (grams), volume (cubic centimeters), density (grams per cubic centimeters), length (inches), and the like are referenced herein with approximate values, variations, ranges, and the like. As will be appreciated, a value for a given mass, volume, density, length, etc. disclosed herein can vary by a certain percentage thereof (e.g., ±5%), by a certain tolerance thereof (e.g., ±0.1 g, ±0.1 cc, ±0.1 g/cc, ±0.1 in), or by other factor while still achieving the purposes disclosed herein. Therefore, reference to a given mass, volume, density, length, etc. as being “about” a given value, being within a given range, etc. should be constructed to include acceptable variations and tolerances to achieve the purposes disclosed herein.
The foregoing description of preferred and other embodiments is not intended to limit or restrict the scope or applicability of the inventive concepts conceived of by the Applicants. It will be appreciated with the benefit of the present disclosure that features described above in accordance with any embodiment or aspect of the disclosed subject matter can be utilized, either alone or in combination, with any other described feature, in any other embodiment or aspect of the disclosed subject matter.
In exchange for disclosing the inventive concepts contained herein, the Applicants desire all patent rights afforded by the appended claims. Therefore, it is intended that the appended claims include all modifications and alterations to the full extent that they come within the scope of the following claims or the equivalents thereof.
Number | Date | Country | |
---|---|---|---|
Parent | 16782498 | Feb 2020 | US |
Child | 16818784 | US |