The invention provides a heat pump system and method heat pump system comprising a first Shape-Memory Alloy (SMA) or Negative Thermal Expansion (NTE) core and adapted to convert movement of the core into energy in response to a temper-reature change. A second Shape-Memory Alloy (SMA) or Negative Thermal Expansion (NTE) core in fluid communication with the first core and adapted to convert movement of the second core into energy. A third Shape-Memory Alloy (SMA) or Negative Thermal Expansion (NTE) or elastocaloric core in fluid communication with the first and second cores and adapted to convert movement of the third core into energy. The first core, second core and the third core are arranged in series and a control system provides waste pressure from the first core to the second core and/or third core.

Disclosed are examples of devices, systems and techniques for delivering a liquid drug. An example delivery pump device may include a chamber body defining a pump chamber, an inlet valve to receive a liquid drug and a hard stop. A plunger configured with a plunger channel. A sliding fluidic member including a needle coupling, a flow orifice, a face seal and an anchor portion that may be movable within the pump chamber. A pump mechanism may be coupled to the anchor portion and operable to pull the anchor portion and the plunger toward the hard stop. Techniques may include determining a time to output a liquid drug from the delivery pump device; generating a control signal to actuate the delivery pump device; applying a control signal to the pump mechanism; determining that a control signal is to be removed from the pump mechanism; and delivering the liquid drug.

A magnetic shape memory (MSM) microfluidic device may include a flexible membrane positioned between a channel and an MSM element. The MSM element may engage the flexible membrane to deform the channel at portions of the flexible membrane that are adjacent to non-contracted portions of the MSM element. The flexible membrane may prevent contact between a fluid within the channel and the MSM element. Magnetic field components may be applied to the MSM element and moved along the MSM element enable fluidic flow within the channel while. The device may include an upper portion including the flexible membrane and a lower portion including the MSM element. The upper portion may be interchangeable with additional upper portions.

The invention relates to a transport device (100) comprising a housing (110), an actuator (130), a drive (150) and a sealing element (170). The housing has a fluid inlet (111, 113), a fluid outlet (113, 111), and a partially contains the actuator (130), which comprises a magnetic shape-memory alloy. The actuator (130) can be deformed by the drive (150) in such a way to form a cavity (135) for the fluid in order to transport the fluid in the cavity (135) from the fluid inlet (111, 113) to the fluid outlet (113, 111). The sealing element (170) is arranged between the actuator (130) and the housing (110) in such a way that the cavity (135) is edge-sealed or end-sealed during the transport of the fluid from the fluid inlet (111, 113) to the fluid outlet (113, 111).

A drive system based on cyclic conversion of thermal energy into mechanical or electrical energy by using a difference in temperature between at least two media and the contraction of a metal element with shape memory properties, and a method for generating energy using the drive system. The drive system has a first and a second store containing media at different temperatures, the second store having a passage opening through a bottom of a housing. The housing is a cylinder containing a liquid-tight and gas-tight cylinder piston dividing the cylinder into two cylinder spaces of variable volumes. One cylinder space contains the metal element and the other cylinder space contains a restoring element. The metal element is secured to the piston at a fixing point and to a fixing point within the second store so that the metal element is in contact with the medium of the second store.

The invention provides a heat pump system and method comprising a Shape-Memory Alloy (SMA) or Negative Thermal Expansion (NTE) core (2a, 2b) positioned in a housing and adapted to absorb heat and store energy in response to a first fluid inputted at a first temperature. The housing is configured to receive a second fluid via an inlet wherein a device changes pressure in the housing to cause the SMA or NTE core to change state to release the heat absorbed into the second fluid. An outlet is adapted to output the second fluid at a higher temperature than the first temperature.

A system for heating/cooling includes a plurality of thermoelastic modules. Each of the modules includes one or more structures formed of shape memory alloy, which converts from austenite to martensite upon application of a first stress and release latent heat from the conversion. During a first part of a heating/cooling cycle, a first module is stressed to cause conversion. The latent heat released from the first module is rejected to a heat sink while a second unstressed module absorbs heat from a heat source. During a second part of the heating/cooling cycle, the first and second modules are connected together to transfer heat therebetween for heat recovery. The cycle can be repeated indefinitely with the first and second modules alternating roles. Structures of the thermoelastic cooling material and specific applications thereof are also disclosed.

A cooling system based on thermoelastic effect is provided. The system comprises a heat sink, a refrigerated space and a regenerator coupled to the refrigerated space and to the heat sink to pump heat from the refrigerated space to the heat sink. The regenerator comprises solid thermoelastic refrigerant materials capable of absorbing or releasing heat.

A drive system based on cyclic conversion of thermal energy into mechanical or electrical energy by using a difference in temperature between at least two media and the contraction of a metal element with shape memory properties, and a method for generating energy using the drive system. The drive system has a first and a second store containing media at different temperatures, the second store having a passage opening through a bottom of a housing. The housing is a cylinder containing a liquid-tight and gas-tight cylinder piston dividing the cylinder into two cylinder spaces of variable volumes. One cylinder space contains the metal element and the other cylinder space contains a restoring element. The metal element is secured to the piston at a fixing point and to a fixing point within the second store so that the metal element is in contact with the medium of the second store.

A thermo-pump includes a sealed casing, divided into a main casing volume and one or more secondary volumes. A thermo-pump includes a shaft. A thermo-pump includes a displacer, coupled to the shaft and oscillates to create a pressure gain between a high-pressure phase and a low-pressure phase. A thermo-pump includes one or more displacer rings, wherein the displacer rings are made from a material with thermal properties below a threshold. A thermo-pump includes an insert, wherein the insert is configured to form a perimeter of the main casing volume, wherein the insert is made from a material with thermal properties below the threshold. A thermo-pump includes one or more bushings, wherein the one or more bushing separate the main casing volume and the one or more secondary volumes. A thermo-pump includes one or more gas bearings configured to prevent contact between the shaft and the sealed casing.