Apparatus and methods for oriented-fracturing of formations

The invention claimed is: 1. An apparatus for treating a formation, comprising: a first string for placement in the wellbore, the first string including a first flow port that enables a treatment fluid to flow from inside the first string to the formation; a second string for placement in the first string, the second string including a second flow port that supplies the treatment fluid to the first flow port; and an orientation device for orienting the second port in the wellbore along a selected radial direction for supplying the treatment fluid to the first flow port; and a module that rotates the second flow port within the second string, wherein the orientation device includes: (i) one of an accelerometer and gyroscope, and (ii) a circuit for transmitting a signal corresponding to a signal from the one of the accelerometer and the gyroscope to a remote location. 2. The apparatus of claim 1 , wherein the orientation device is selected from a group consisting of: (i) a first guide associated with the first string and a second guide in the second string for engaging with the first guide in the second string to orient the second flow port along the selected direction; and (ii) a magnetic device on the first string that provides a magnetic field and a sensor on the second string for detecting the magnetic field from the magnetic device. 3. The apparatus of claim 1 , wherein the second flow port rotates about bearings in the second string. 4. The apparatus of claim 3 further comprising: (i) a motor that rotates the second flow port; (ii) a control circuit for controlling the motor to orient the second flow port along the selected radial direction. 5. The apparatus of claim 4 , wherein the control circuit controls the motor in response to one of: (i) a signal sent from a remote location; and (ii) programmed instructions associated with the control circuit. 6. The apparatus of claim 5 further comprising a telemetry device configured to transmit signals from the control circuit to the remote location as one of: (i) pressure signals via a fluid in the wellbore; (ii) electrical signals via an electrical conductor; and (iii) optical signals via a fiber optic link. 7. The apparatus of claim 5 , wherein the pressure signals are sent by a device that generates pulses by one of: (i) by bypassing a fluid circulating in the wellbore to generate negative pressure pulses; and (ii) by blocking a fluid circulating in the wellbore to generate positive pressure signals. 8. The apparatus of claim 1 , wherein the first flow port is configured to include multiple openings around the wellbore and the second flow port includes one of: (i) a single opening that covers less than 30 percent of the radial space of the wellbore; and (ii) two openings substantially opposite to each other, each covering a portion of the wellbore radial section. 9. A method of treating a formation surrounding a wellbore, comprising: placing a first string in the wellbore, the first string including a first flow port that enables a treatment fluid to flow from inside the first string to the formation; placing a second string inside the first string, the second string including a second flow port for supplying the treatment fluid to the first flow port; using a sensor of the second string to determine an orientation of the second flow port, wherein the sensor includes one of an accelerator and a gyroscope; providing a motor configured to rotate the second flow port; providing a control circuit configured to control the motor; and controlling the motor to orient the second flow port in response to a signal sent from a surface location or programmed instruction provided to the control circuit for automatically orienting the second flow port along the selected radial direction; and supplying the treatment fluid under pressure to the second port to supply the treatment fluid to the first port to treat the formation. 10. The method of claim 9 further comprising: orienting the second flow port in the selected direction before supplying the treatment fluid under pressure to the second port. 11. The method of claim 10 , wherein determining the orientation of the second flow port in the wellbore comprises: orienting the second port along the selected radial direction based on the determined orientation of the second flow port. 12. The method of claim 9 further comprising: (i) providing an orientation device that includes a first guide in the first string and a second guide in the second string for engagement with the first guide to orient the second flow port along the selected radial direction; and (ii) manipulating the second string inside the first string to engage the second guide with the first guide to orient the second flow port along the selected radial direction before supplying the treatment fluid to the second flow port. 13. The method of claim 9 further comprising: (i) providing a magnetic device on the first string and a magnetic detector on the first string; and (ii) manipulating the second string inside the first string to detect the magnetic device by the magnetic detector; and (iii) orienting the second flow port along the selected direction in response to the detection of the magnetic device. 14. The method of claim 9 , wherein the signal is sent via one of: (i) pressure signals; (ii) electrical signals via a communication link between the control circuit and the surface location; and (iii) optical signals via a fiber optic link. 15. The method of claim 14 , wherein the pressure signals are sent by a device that generates pulses by one of: (i) by bypassing a fluid circulating in the wellbore to generate negative pressure pulses; and (ii) by blocking a fluid circulating in the wellbore to generate positive pressure signals. 16. The method of claim 9 , wherein the first flow port is configured to include multiple openings around the wellbore and the second flow port includes one of: (i) a single opening that covers a portion of the radial section of the second string; and (ii) two openings substantially opposite to each other, each covering a portion of the radial section of the second string. 17. An apparatus for treating a formation, comprising: a first string for placement in the wellbore, the first string including a first flow port that enables a treatment fluid to flow from inside the first string to the formation, wherein the first flow port provides an opening that covers a portion of radial portion section of the first string; a second string placed inside the first string, the second string including a second flow port for supplying the treatment fluid to the first flow port for treating the formation; an orientation device including one of an accelerometer and a gyroscope for orienting the second port in the wellbore along a selected radial direction for supplying the treatment fluid to the first flow port and a circuit for transmitting a signal corresponding to a signal from the one of the accelerometer and the gyroscope to a remote location; and a module that rotates the second flow port within the second string. 18. A method of treating a formation surrounding a wellbore along a selected radial direction, the method comprising: placing an inner string within an outer string, the inner string having a flow port that provides an opening that covers a selected segment of radial section of the inner string; using a sensor of the inner string to determine an orientation of the flow port, wherein the sensor inc