Measurement of dynamic battery pack properties

The invention claimed is: 1. A method, comprising: positioning a battery pack within an internal space of a test enclosure, the battery pack including an outer casing; positioning a tip of a plunger proximate to a top surface of the outer casing, wherein the plunger extends from within the internal space to a location external to the test enclosure and is moveable relative to the test enclosure in a first direction toward the battery pack; causing a first impact between a mass disposed opposite to the plunger and a piece of material having a known strain rate coupled to the plunger, the piece of material being disposed external to the test enclosure, wherein: the mass is moveable in the first direction along a guide of a first frame, the first impact causes the plunger to move in the first direction, and contact between the plunger and the outer casing punctures the casing at a failure point of the outer casing; determining a displacement of the plunger, caused by the first impact, at the failure point of the outer casing; determining a force applied to the piece of material, by the mass, at the failure point of the outer casing; and determining a dynamic strength (σ(ε) of the outer casing or a dynamic modulus (M(ε) of the outer casing, wherein the dynamic strength is determined as a function of the strain rate and the force applied to the piece of material and the dynamic modulus is determined as a function of the strain rate and the displacement of the plunger. 2. The method of claim 1 , further comprising: applying a magnetic counterforce to the plunger, wherein the counterforce immobilizes the plunger, the piece of material, and the tip relative to the test enclosure; detecting a position of the mass relative to the piece of material at the first impact; and discontinuing application of the counterforce in response to detecting the position of the mass. 3. The method of claim 1 , further comprising: detecting a position of the mass relative to the piece of material at the first impact; and applying a counterforce to the mass in response to detecting the position of the mass, wherein the counterforce is applied in a second direction opposite the first direction, and the counterforce prohibits a second impact between the mass and the piece of material separate from the first impact. 4. The method of claim 1 , wherein the piece of material comprises a first piece of material characterized by a first strain rate, the battery pack comprises a first battery pack, and the failure point of the outer casing comprises a first failure point, the method further comprising: replacing the first piece of material with a second piece of material characterized by a second strain rate different from the first strain rate; replacing the first battery pack with a second battery pack; causing a second impact between the mass and the second piece of material, wherein the second impact causes the plunger to puncture an outer casing of the second battery pack at a second failure point of the outer casing of the second battery pack; determining a force applied to the second piece of material, by the mass, at the second failure point of the outer casing of the second battery pack; determining a dynamic strength of the outer casing of the second battery pack or a dynamic modulus of the outer casing of the second battery pack, wherein the dynamic strength of the outer casing of the second battery pack and the dynamic modulus of the outer casing of the second battery pack are based on the force applied to the second piece of material and the second strain rate; and determining an actual strength of an outer casing material or an actual modulus of the outer casing material, wherein the actual strength is based on the dynamic strength of the outer casing of the first battery pack and the dynamic strength of the outer casing of the second battery pack, and the actual modulus is based on the dynamic modulus of the outer casing of the first battery pack and the dynamic modulus of the outer casing of the second battery pack. 5. The method of claim 1 , wherein the plunger extends within the internal space via a passage of the test enclosure, the method further comprising: evacuating air from the internal space of the test enclosure such that a pressure within the internal space is less than an atmospheric pressure; and directing pressurized nitrogen into the internal space to suppress combustion resulting from the first impact. 6. A system, comprising: a frame including a guide and a mass movable along the guide in a first direction; a test enclosure disposed opposite to the mass and including a top wall, a base opposite to the top wall, a pair of sidewalls extending from the top wall to the base, and a passage formed in the top wall, the top wall, base, and pair of sidewalls defining an internal space of the test enclosure; a plunger movably disposed within the passage and having a portion extending into the internal space; a modulator connected to the plunger opposite to the mass, wherein the modulator is characterized by a strain rate and is moveable with the plunger in response to an impact between the mass and the modulator, the impact moves the plunger in the first direction and causes the plunger to contact a casing of a battery sample disposed within the internal space, and contact between the plunger and the casing results in failure of the casing; a first sensor configured to detect a displacement of the plunger at a point in time at which the casing fails; a second sensor configured to determining a force applied to the modulator, by the mass, at the point in time at which the casing fails; and a controller coupled to the first and second sensors, the controller configured to determine at least one of a dynamic strength of the casing or a dynamic modulus of the casing, wherein: the dynamic strength is based on the force applied to the modulator and the strain rate, and the dynamic modulus is based on the displacement of the plunger and the strain rate. 7. The system of claim 6 , further comprising: an electromagnet supported by the test enclosure and configured to selectively apply a magnetic counterforce to the plunger in a second direction opposite the first direction, wherein the counterforce immobilizes the plunger and the modulator relative to the test enclosure; and a third sensor coupled to the controller and configured to detect a position of the mass at the point in time at which the casing fails, the controller being configured to discontinue application of the counterforce by the electromagnet at least partly in response to detection of the position of the mass. 8. The system of claim 6 , further comprising: a third sensor coupled to the controller and configured to detect at least one of a position of the mass at the point in time at which the casing fails or the impact between the mass and the modulator; and a pull solenoid connected to the frame and configured to apply a counterforce to the mass at least partly in response to detection of the at least one of the position of the mass and the impact, wherein the impact between the mass and the modulator comprises a first impact, the counterforce is applied in a second direction opposite the first direction, and the counterforce prevents a second impact between the mass and the modulator separate from the first impact. 9. The system of claim 6 , further comprising a vacuum pump fluidly connected to the internal space via the passage and configured to evacuate air from the internal space of the test enclosure such that a pressure within the internal space is less than an atmospheric pressure. 10. The system of