Pumped heat energy storage system with convey able solid thermal storage media directly thermally coupled to working fluid

What is claimed is: 1. A pumped heat energy storage system comprising: a charging assembly configured to implement a thermodynamic heat pump cycle that consumes electrical energy from an electrical grid to raise and lower temperature of conveyable, solid thermal storage media respectively in a hot heat exchange and storage apparatus and in a cold heat-exchange and storage apparatus; and a discharging assembly configured to implement a thermodynamic engine cycle to lower and raise the temperature of the conveyable, solid material respectively in the hot heat exchange and storage apparatus and in the cold heat exchange and storage apparatus, while extracting work, thereby returning to the electrical grid at least a portion of the electrical energy consumed by the charging assembly, and further configured to concurrently return the conveyable, solid thermal storage media in the hot heat exchange and storage apparatus and in the cold heat exchange and storage apparatus to respective initial temperatures of the conveyable, solid thermal storage media therein, wherein the hot heat exchange and storage apparatus comprises: a thermal storage assembly including a low temperature store arranged to operate at substantially atmospheric pressure and accommodate a sufficient quantity of the conveyable, solid thermal storage media to facilitate a desired rate and duration of energy absorption or delivery by the pumped heat energy storage system, and further including a high temperature store arranged to operate at substantially atmospheric pressure and accommodate substantially the same quantity of the conveyable, solid thermal storage media as the low temperature store; a heat exchanger assembly arranged to directly thermally couple the conveyable, solid thermal storage media that is conveyed to the heat exchanger assembly from the low temperature store or from the high temperature store associated with the hot heat exchange and storage apparatus with a flow of working fluid that passes through the heat exchanger assembly; and a feeder assembly arranged to circulate the conveyable, solid thermal storage media between the low temperature store and the high temperature store associated with hot heat exchange and storage apparatus. 2. A pumped heat energy storage system comprising: a charging assembly configured to implement a thermodynamic heat pump cycle that consumes electrical energy from an electrical gird to raise and lower temperature of conveyable, solid thermal storage media respectively in a hot heat exchange and storage apparatus and in a cold heat-exchange and storage apparatus; and a discharging assembly configured to implement a thermodynamic engine cycle to lower and raise the temperature of the conveyable, solid material respectively in the hot heat exchange and storage apparatus and in the cold heat exchange and storage apparatus, while extracting work, thereby returning to the electrical gird at least a portion of the electrical energy consumed by the charging assembly, and further configured to concurrently return the conveyable, solid thermal storage media in the hot heat exchange and storage apparatus and in the cold heat exchange and storage apparatus to respective initial temperatures of the conveyable, solid thermal solid media therein, wherein the cold heat exchange and storage apparatus comprises: a thermal storage assembly including a low temperature store arranged to operate at substantially atmospheric pressure and accommodate a sufficient quantity of the conveyable, solid thermal storage media to facilitate a desired rate and duration of energy absorption or delivery by the pumped heat energy storage system, the thermal storage assembly further including a high temperature store arranged to operate at substantially atmospheric pressure to accommodate substantially the same quantity of material as the low temperature store; a heat exchanger assembly arranged to directly thermally couple the conveyable, solid thermal storage media that is conveyed to the heat exchanger assembly from the low temperature store or from the high temperature store associated with the cold heat exchange and storage apparatus with a flow of the working fluid that passes through the heat exchanger assembly; and a feeder assembly arranged to circulate the conveyable, solid thermal storage media between the low temperature store and the high temperature store associated with the cold heat exchange and storage apparatus. 3. The pumped heat energy storage system of claim 2 , wherein the conveyable solid thermal storage media comprises conveyable bulk solid thermal storage media, wherein the feeder assembly comprises a first rotary airlock disposed at or proximate a top end of the heat exchanger assembly, the first rotary airlock connected to a bulk solid thermal storage media inlet arranged to pass conveyable bulk solid thermal storage media to a pressurized chamber of the heat exchanger assembly from the thermal storage assembly at atmospheric pressure. 4. The pumped heat energy storage system of claim 3 , wherein the feeder assembly further comprises a second rotary airlock disposed at or proximate a bottom end of the heat exchanger assembly, the second rotary airlock connected to a bulk solid thermal storage media outlet arranged to transfer from the pressurized chamber of the heat exchanger assembly to the thermal storage assembly at atmospheric pressure the bulk solid thermal storage media passed to the heat exchanger assembly. 5. The pumped heat energy storage system of claim 3 , wherein the heat exchanger assembly is connected to a working fluid inlet disposed at or proximate the bottom end of the heat exchanger assembly, and is further connected to a working fluid outlet disposed at or proximate the top end of the heat exchanger assembly so that the working fluid flows upwardly between the working fluid inlet and the working fluid outlet to establish a direct thermal coupling with the conveyable bulk solid thermal storage media that falls downwardly into the pressurized chamber of the heat exchanger assembly between the bulk solid thermal storage media inlet and the bulk solid thermal storage media outlet. 6. The pumped heat energy storage system of claim 3 , wherein the heat exchanger assembly comprises a valve assembly arranged downstream from and proximate the bulk solid thermal storage media inlet to control a mass flow rate of the conveyable bulk solid thermal storage media passed to the pressurized chamber of the heat exchanger assembly. 7. The pumped heat energy storage system of claim 3 , wherein the first rotary airlock and the second rotary airlock are arranged to operate as continuous rotary airlocks so that the feeder assembly in operation continually circulates the conveyable bulk solid thermal storage media between the thermal storage assembly and the heat exchanger assembly. 8. The pumped heat energy storage system of claim 2 , wherein the conveyable solid thermal storage media comprises conveyable bulk solid thermal storage media, wherein the feeder assembly comprises a rotary airlock connected to a first bulk solid thermal storage media inlet (I) coupled to a first operating stage of the rotary airlock fillable with conveyable bulk solid thermal storage media received from the thermal storage assembly at atmospheric pressure, the rotary airlock further including a first bulk solid thermal storage media outlet (II) arranged to supply to a pressurized chamber of the heat exchanger assembly conveyable bulk solid thermal storage media from the first operating stage of the rotary airlock. 9. The pumped heat energy storage system of claim 8 , wherein the rotary airlock is further connected to a second bulk solid thermal storage media outl