This disclosure relates to wellbore operations, and specifically to accessing a wellbore with a stuck valve.
Hydrocarbons (for example, oil, gas or combinations of them) entrapped subsurface reservoirs can be produced by wellbores drilled from the surface of the Earth through subterranean zones to access the reservoirs. To perform wellbore operations during drilling and production, a wellhead is installed at the surface. During drilling, the wellhead includes multiple spools, valves and other well tools to provide pressure control. During production, the wellhead additionally includes hangers and other well tools to hang production tubing and to install a Christmas tree to control flow of the production fluid through the wellbore. The Christmas tree is also an assembly of valves, spools, pressure gauges and chokes fitted to the wellhead of a completed well. Sometimes, a well tool, for example, a valve, in a wellhead Christmas tree can malfunction. Unless the malfunction is rectified, the wellbore cannot be accessed.
This disclosure describes technologies relating to cutting wellhead gate valve by water jetting.
Certain aspects of the subject matter described here can be implemented as a well tool assembly that includes a water jetting head configured to be lowered into a wellhead tree that can be coupled to a wellbore. The water jetting head includes a housing, an orifice plate and a jetting port. The housing defines a tubular region configured to receive water. The orifice plate is positioned within the tubular region downstream of a first end of the housing and upstream of a second end of the housing. The orifice plate defines an orifice configured to accelerate a flow rate of the water received at a first flow rate upstream of the orifice plate to a second flow rate, greater than the first flow rate, downstream of the orifice plate. At the second flow rate, the water can mill a gate valve disposed within the wellhead. The jetting port is downstream of the orifice plate. The jetting port is configured to receive the water at the second flow rate and to guide the received water to the gate valve.
An aspect combinable with any other aspect includes the following features. The water jetting head can mill a pilot hole through the gate valve. A diameter of the pilot hole is equal to a diameter of the water flowed through the jetting port at the second flow rate.
An aspect combinable with any other aspect includes the following features. A rotary drive is coupled to the jetting port. The rotary drive is configured to cause the jetting port to traverse a circumferential path about a longitudinal axis of the housing to mill a circular portion of the gate valve.
An aspect combinable with any other aspect includes the following features. The housing includes threading at the first end, which is configured to threadedly couple the water jetting head to the coil tubing.
An aspect combinable with any other aspect includes the following features. The assembly includes coil tubing.
An aspect combinable with any other aspect includes the following features. The assembly includes a motor that can be coupled to the water jetting head to power a pump to flow the water to the orifice plate at the first flow rate.
An aspect combinable with any other aspect includes the following features. The pump is a positive displacement pump.
An aspect combinable with any other aspect includes the following features. The motor is upstream of the water jetting head.
Certain aspects of the subject matter described here can be implemented as a method. Water is flowed at a first flow rate through a first portion of a tubular region defined between a first end of a housing of a water jetting head and an orifice plate positioned downstream of the first end. The housing has been lowered into a wellhead tree configured to be coupled to a wellbore. The orifice plate includes an orifice. The water is accelerated from the first flow rate to a second flow rate greater than the first flow rate by flowing the water through the orifice in the orifice plate and into a second portion of the tubular region defined between the orifice plate and a second end of the housing downstream of the orifice plate. At the second flow rate, the water can mill steel. The water at the second flow rate is flowed toward a jetting port installed at the second end of the housing. The jetting port guides the water at the second flow rate onto a gate valve installed in the wellhead tree downhole of the housing. The water at the second flow rate cuts the gate valve.
An aspect combinable with any other aspect includes the following features. Using the water at the second flow rate, a pilot hole is milled through the gate valve. A diameter of the pilot hole is equal to a diameter of the water flowed at the second flow rate.
An aspect combinable with any other aspect includes the following features. A rotary drive coupled to the jetting port rotates the jetting port to traverse a circumferential path about a longitudinal axis of the housing.
An aspect combinable with any other aspect includes the following features. Using the water at the second flow rate, a circular portion of the gate valve is milled. A diameter of the circular portion is based on the circumferential path.
An aspect combinable with any other aspect includes the following features. The first end of the housing is threadedly coupled to coil tubing.
An aspect combinable with any other aspect includes the following features. To flow the water at the first flow rate through the first portion of the tubular region, a pump, fluidically coupled to the water jetting head, pumps the water towards the first end of the housing.
An aspect combinable with any other aspect includes the following features. A motor powers the pump.
An aspect combinable with any other aspect includes the following features. The pump is a positive displacement pump.
An aspect combinable with any other aspect includes the following features. The motor is upstream of the housing.
The details of one or more implementations of the subject matter described in this specification are set forth in the accompanying drawings and the description below. Other features, aspects, and advantages of the subject matter will become apparent from the description, the drawings, and the claims.
Like reference numbers and designations in the various drawings indicate like elements.
A wellhead Christmas tree can include gate valves to control flow of hydrocarbon production fluid through a wellbore to which the wellhead is connected. Sometimes, a gate well in the wellhead Christmas tree can get stuck in a closed position. Such a stuck gate valve can pose a serious challenge that restricts options of securing the wellbore ahead of gate valve repair or replacement. In some instances, the stuck valve needs to be removed by milling using wireline or coiled tubing. The milling process can be challenging and time-consuming. Such repair operations also pose safety issues and other complications including the milling tool getting stuck in the stuck gate valve that can lead to a well control incident.
This disclosure describes a method of cutting the stuck wellhead gate valve using water jets in order to regain full wellbore accessibility for well intervention. The water jet can be formed without the use of concentrically arranged coil tubing of different diameters. A water jet can cut through the materials having thickness as high as 12 inches, thereby providing a faster, safer, cleaner option compared to conventional milling using milling bits. In addition, using water jet for milling negates a need for physical contact between a milling tool and the stuck gate valve, thereby increasing safety. Because the water jet can be implemented without using any hazardous chemicals or acids, the techniques described here are also environmentally friendly. Using only water will prevent damage to the wellbore and the reservoir. Implementations of the techniques described here will result in smaller footprint with no mixing requirements negating the need for chemical tanks. Cost savings will also be realized.
Water jetting, i.e., cutting using a high-speed water jet, is also a better and more convenient cutting option compared to laser or plasma cutting. In particular, laser and plasma cutting generate heat that can create hazardous conditions around hydrocarbons in wellbores. Abrasive jetting, i.e., cutting using a slurry of a liquid and abrasives, is used in intervention jobs to create slots or perforations into casing or rock formations. However, the techniques described here use water alone without any sand or other abrasive materials.
Implementations of the subject matter are described in the context of cutting through stuck gate valves in wellhead Christmas trees. The subject matter can similarly be implemented to cut through other malfunctioning components in wellhead Christmas trees or in wellbores that prevent access to regions of the wellbores downhole of the malfunctioning components. Examples of such components include pipes or stuck valves made of steel or similar metal. The jetting technique described here can be implemented in areas other than oil fields such as to cut steel or metal plates in factories that implement machines made of steel or metal plates. Such factories can manufacture components used in industries including aerospace, and automotives. The jetting technique can also be used to cut stone, glass, marble, jewellery and other industries where focused cutting is needed,
Also, water is used as an example liquid to form the jet used to cut the stuck gate valve in the wellhead Christmas tree. Other liquids can similarly be used to form the jet, for example, mud brine, or oil-based or synthetic metal cutting fluids. In addition, implementations of the subject matter are described using coiled tubing with a hydraulic activation and providing enough inlet pressure for a water jetting head (described below). Alternatively, the water jetting operation can be deployed by a stand-alone unit.
In operation, the first end 202 of the housing 200 is threaded to an end of the coiled tubing 112, and the housing 200 is lowered into the wellhead Christmas tree 104. The motor 116 (
In the implementation described with reference to
At 404, water is flowed through the orifice plate in the water jetting head to accelerate the water from a first flow rate upstream of the orifice plate to a second flow rate downstream of the orifice plate. A diameter of the orifice in the orifice plate, dimensions of the tubular region upstream of the orifice plate and a pressure of the water flowed at the first rate are selected such that when the water is accelerated to the second flow rate, the flow velocity of the water is sufficient to cut through steel or other material with which a stuck gate valve or other malfunctioning component of the wellhead tree 104 is made.
At 406, the accelerated water is flowed toward a jetting port (for example, jetting port 220). At 408, the accelerated water is guided toward a surface. For example, the water jet (i.e., the water at the second flow rate) is guided by the jetting port to impinge onto a surface that needs to be cut such as the stuck first gate valve 108 or other malfunctioning component of the wellhead tree 104. The cut piece will drop into the well rat hole and need not be fished or recovered to the surface. The gate valve 108 can then be bullheaded from above and pushed into the wellbore.
Thus, particular implementations of the subject matter have been described. Other implementations are within the scope of the following claims.