Patent Application
20110185717
This invention relates to a hydraulic manifold pump. More particularly, the invention relates to a hydraulic manifold pump which may be used to drive a mechanical system in a well.
Conventional hydraulic systems that are used to drive mechanical systems in down-hole applications in wells, such as oil or gas wells, mainly employ two or more hydraulic solenoid valves to orient the flow in the hydraulic lines. These conventional systems, however, do not have a very good reliability due to oil pollution and/or internal leaks. In addition, the hydraulic oil flow rate can be poor through the solenoid valves used in wireline tools due to the small passageways used in these systems. This poor rate of flow increases the time that it takes the hydraulic systems to drive the mechanical systems in the well.
In typical wireline tools which use hydraulic circuits to move a mechanical system, one of the important factors that affects the success of the job is the time spent activating the hydraulic system. Frequent changes in position, and the setting and retracting of hydraulic pistons in such a system lead to an increase in the drilling time that is lost during the completion of these procedures.
The simplicity or complexity of the hydraulic systems used in a well is a factor of reliability as well. This invention discloses a hydraulic manifold pump that can set and retract a piston in an actuator by hydraulic means using a 2-way flow of hydraulic fluid, without the use of solenoid valves. One of the advantages of the current invention is that the hydraulic flow mechanisms are more simple, and thus more efficient and reliable. This simplicity results in the minimum amount of drilling time lost as a result of the activation of the hydraulic system.
In addition, using a faster hydraulic system to drive the kinematics in a wireline tool offers many advantages in terms of the reduction in cost-of-logging. This is accomplished by less drilling time being lost when the hydraulic mechanism is set and retracted, and by a reduction in the electrical power needed to run the tool as the tool needs fewer electrical components in order to drive the hydraulic high pressure portion of the pump system and thus also needs less electricity in order to function.
A first aspect of the invention provides a hydraulic manifold pump comprising:
Preferably the bidirectional motor controls the fluid flow rate in the first hydraulic circuit and in the second hydraulic circuit. Typically the motor is an electric motor and the rotational speed produced by the motor controls the fluid flow rate.
In one form of the invention the first hydraulic circuit is connected to a first hydraulic chamber of the hydraulic actuator, and the second hydraulic circuit is connected to a second hydraulic chamber of the hydraulic actuator.
The bidirectional motor is preferably connectable to the first hydraulic circuit and the second hydraulic circuit via a bidirectional pump mechanism.
Each of the first and second hydraulic circuits may include at least a non-return valve, a pressure limiting valve and a relief valve.
Preferably both the first hydraulic circuit and the second hydraulic circuit are closed hydraulic circuits. The flow of hydraulic fluid through both the first and second hydraulic circuits may be regulated by the valves in each circuit and the fluid may vent into the fluid reservoir when the fluid flows in a first direction through each circuit, and the fluid may be drawn out of the reservoir when the fluid flows in a second direction through each circuit.
The bidirectional motor is preferably an electric motor.
A second aspect of the invention provides a method of hydraulically activating a mechanical system by means of a hydraulic manifold pump according to the first aspect of the invention, the method comprising:
Preferably the valves in each of the first and second hydraulic circuits may include at least a non-return valve, a pressure limiting valve and a relief valve.
a shows a schematic isometric side view of the manifold pump from the actuator connection side, according to the invention;
b shows a schematic isometric side view of the manifold pump from the electrical motor connection side, according to the invention;
A preferred embodiment of this invention is illustrated in
The first hydraulic circuit 16 is indicated using the letter “A” and the second hydraulic circuit 18 is indicated using the letter “B” in
Hydraulic actuator 12 has two hydraulic chambers 24 and 26, which are connected to manifold pump 10 and separated from each other by a piston 28. Chamber 24 is connected to first hydraulic circuit 16 of manifold pump 10 and chamber 26 is connected to second hydraulic circuit 18.
Manifold pump 10 is a bidirectional pump with an integrated flow manifold incorporating first and second hydraulic circuits 16 and 18, respectively, driven by electric motor 14, which is capable of turning in both directions, clockwise and counter clockwise. Electric motor 14 drives the bidirectional pump mechanism 20 in one direction to activate hydraulic circuit 16, and in the other direction to activate hydraulic circuit 18. Electric motor 14 also controls the rate of the fluid flow through each of the hydraulic circuits 16, 18 by changing the speed of rotation that it produces.
The bidirectional functionality of the manifold pump 10 is physically obtained by the use of the two axially placed hydraulic circuits 16 and 18 being packaged into one block, as shown in
In this embodiment, the single inner shaft shown in
As illustrated in
The first hydraulic fluid circuit 16 and the second hydraulic fluid circuit 18 each use a pilot valve, namely P1 and P2, respectively, a relief valve, namely LP1 and LP2, respectively, and a check valve AR1 and AR2, respectively. Pressure line A of hydraulic circuit 16 connects the relief valve LP2 and the piloted valve P2, which then drives the relief valve LP1. Pressure line B of hydraulic circuit 18 connects the relief valve LP1 and the piloted valve P1, which then drives the relief valve LP2.
To fill chamber 24 (A″) in actuator 12, manifold pump 10 is activated by electrical motor 14 in a counter clockwise direction, to pump fluid through the first circuit 16 side. Fluid from bidirectional pump mechanism 20 flows along pressure line A of the first circuit 16, and feeds pilot valve P2 and chamber 24 (A″) via the check valve AR2. Chamber 26 (B″) of actuator 12 is sealed by the check valve AR1 and the pressure limiter relief valve LP1, and thus the piston shaft 34 of actuator 12 does not move. The pressure of the fluid in pressure line A of the first circuit 16 then increases and reaches the activation pressure of pilot valve P2, which in turn activates the relief valve LP1 and thus connects chamber 26 (B″) to the internal reservoir 22. No o-ring seal is used between pilot valve P2 and the housing of manifold pump 10, to allow the decompression of the fluid in pressure line A of second circuit 16, and thus also the closure of the relief valve LP1. Pilot valve P2 is lapped with the housing seat of manifold pump 10 to minimize the leak rate. Decompression only occurs between the bidirectional pump 20 and the check valve AR2, the sealing of the chamber 24 occurring via by the check valve AR2 and the relief valve LP2. The piston 28 of actuator 12 then moves from chamber 24 to chamber 26. Once the fluid pressure in line A decreases, it causes relief valve LP1 to close, and thus the bidirectional pump 20's rotation can be inverted to obtain a fluid flow in pressure line B of second circuit 18.
To fill the chamber 26 (B″) in actuator 12, the bidirectional pump 20 is activated by electrical motor 14 being activated in the clockwise direction, to pump the fluid through the second circuit 18 side of manifold pump 10. Fluid flows along the pressure line B, and feeds pilot valve P1 and chamber 26 (B″) via the check valve AR1. Because chamber 24 of actuator 12 is sealed by means of check valve AR2 and the pressure limiter relief valve LP2, the piston shaft 34 and piston 28 of actuator 20 do not move. The fluid pressure in pressure line B then increases and reaches the activation pressure of pilot valve P1, which in turn activates the relief valve LP2 and thus connects chamber 24 to reservoir 22. No o-ring seal is used between the pilot valve P1 and the housing of the manifold pump 10 in order to allow the decompression of the fluid in pressure line B and thus the closure of the relief valve LP2. The pilot valve P1 is lapped with the housing seat of manifold pump 10 in order to minimize the leak rate. Decompression only occurs between bidirectional pump 20 and the check valve AR1, the sealing of chamber 26 occurring via by the check valve AR1 and the relief valve LP1. Piston 28 of actuator 12 then moves from chamber 26 to chamber 24. Once the fluid pressure of pressure line B decreases, it causes relief valve LP1 to close and bidirectional pump 20's rotation can be inverted to again obtain a fluid flow in line A of first circuit 16.
Manifold pump 10 finds particular application in the activation of mechanical systems used in down-hole wells, such as oil or gas wells, particularly with those used with typical wireline tools.
While the present invention has been described with respect to a limited number of embodiments, those skilled in the art having the benefit of this disclosure, will appreciate numerous modifications and variations therefrom. It is intended that the appended claims cover all such modifications and variations as fall within the true spirit and scope of this present invention.
| Number | Date | Country | Kind |
|---|---|---|---|
| 0722931.3 | Nov 2007 | GB | national |
The present application is based on and claims priority to GB Application No. 0722931.3, filed 23 Nov. 2007; and International Patent Application No. PCT/EP2008/009698, filed 17 Nov. 2008. The entire contents of each are herein incorporated by reference.
| Filing Document | Filing Date | Country | Kind | 371c Date |
|---|---|---|---|---|
| PCT/EP08/09698 | 11/17/2008 | WO | 00 | 9/2/2010 |
