Receive coils with low-loss detune circuits for magnetic resonance (MR) systems and method of operation thereof

The invention claimed is: 1. A radio-frequency (RF) coil assembly for acquiring magnetic resonance (MR) signals, comprising: at least one radio-frequency (RF) receive coil for acquiring the MR signals; a detune circuit comprising one or more circuit arms serially coupled to the at least one RF receive coil, each of one or more circuit arms having at least two low-loss switches serially coupled to each other, each of the at least two low-loss switches of each circuit arm is configured to control impedance of a corresponding receive coil to tune or detune each corresponding receive coil during tune or detune states, respectively; an energy storage device configured to store power; a power control switch coupled to each of the one or more circuit arms at a location that is between the at least two serially-coupled low-loss switches of each of the one of more circuit arms and coupled to the energy storage device; and a controller configured (i) to control the detune circuit to detune the RF receive coil to enter a detune state and (ii) to control the power control switch when the RF receive coil is in the detuned state to connect the RF receive coil to the energy storage device to draw power from the RF receive coil during the detuned state. 2. The apparatus of claim 1 , wherein the energy storage device includes a battery. 3. The apparatus of claim 1 , wherein the at least one power control switch is selectively controlled to control an impedance of the detune circuit. 4. The apparatus of claim 1 , wherein the controller controls each of the at least two low-loss switches of each of the one or more circuit arms to be substantially non-conductive when it is determined to enter the detune state. 5. The apparatus of claim 1 , wherein the controller controls each of the at least two low-loss switches of each of the one or more circuit arms to be substantially conductive when it is determined not to enter the detune state. 6. The apparatus of claim 1 , wherein the one or more circuit arms are coupled in parallel to each other to form a full-bridge circuit. 7. The apparatus of claim 1 , wherein the detune circuit is configured to tune the at least one RF receive coil to a resonance frequency when in a tune state and to detune the at least one RF receive coil when in the detune state. 8. A radio-frequency (RF) coil assembly for acquiring magnetic resonance (MR) signals, comprising: at least one radio-frequency (RF) receive coil for acquiring the MR signals; a detune circuit comprising two circuit arms serially coupled to the at least one RF receive coil and coupled in parallel to each other, each of the two circuit arms having at least two low-loss switches serially coupled to each other, each of the at least two low-loss switches of each circuit arm is configured to control impedance of a corresponding receive coil to tune or detune each corresponding receive coil during tune or detune states, respectively; and a charge control circuit comprising an energy storage device configured to store power, at least one power control switch coupled between one of the two circuit arms and the energy storage device to control a drawing of power from the RF receive coil to energy storage device in the detune state, the charge control circuit coupled to each of two circuit arms at a location that is between the at least two serially-coupled low-loss switches of each of the two circuit arms and configured to in the detuned state draw power from the at least one RF receive coil and store the drawn power in the energy storage device. 9. The apparatus of claim 8 , further comprising a controller configured to control a duty cycle of the at least one power control switch during the detuned state to control the impedance of the detune circuit in the detune state. 10. The apparatus of claim 8 , the RF coil assembly further comprising a housing configured to contain the at least one RF receive coil, the detune circuit and the charge control circuit. 11. The apparatus of claim 8 , further comprising a controller configured to control each of the at least two low-loss switches of each of the two circuit arms to be substantially conductive during a tune state and substantially non-conductive during a detune state. 12. The apparatus of claim 11 , wherein the controller is further configured to selectively control the draw of power from the RF receive coil in the detuned state by controlling a duty cycle of the at least one power control switch. 13. The apparatus of claim 8 , wherein the detune circuit is configured to tune the at least one RF receive coil to a resonance frequency when in a tune state and to detune the at least one RF receive coil when in a detune state. 14. A magnetic resonance (MR) system, comprising: at least one main magnet for generating a main magnetic field comprising a substantially homogenous magnetic field within a scanning volume; a radio frequency (RF) portion comprising RF transmit coils configured to output RF pulses, and an RF reception portion configured to acquire MR signals from the scanning volume during a tune state and to digitize the acquired MR signals within a housing of the RF reception portion, the RF reception portion comprising: at least one radio-frequency (RF) receive coil for acquiring the MR signals, a detune circuit coupled to the at least one RF receive coil and configured to detune the at least one RF receive coil during a detune state, the detune circuit comprising: one or more circuit arms serially coupled to the at least one RF receive coil, each of one or more circuit arms having at least two low-loss switches serially coupled to each other, each of the at least two low-loss switches of each circuit arm is configured to control impedance of the at least one RF receive coil to tune or detune each corresponding receive coil during tune or detune states, respectively, an energy storage portion configured to store energy from the at least one RF receive coil when the RF reception portion is in the detune state, and a power control switch configured to decouple the energy storage portion from the at least one RF receive coil when the RF reception portion is in the tune state and couple the energy storage portion to the at least one RF receive coil while the RF receive coil is in the detuned state. 15. The apparatus of claim 14 , wherein the RF reception portion comprises a plurality of channels, one or more of the channels comprising at least one of: the at least one radio-frequency (RF) receive coil; the detune circuit; and the energy storage portion. 16. The apparatus of claim 14 , wherein the power control switch has a controlled duty cycle to control an amount of energy drawn off the RF receive coil by the energy storage portion when in the detune state.