A method and system for blending and dispensing liquid cannabis enables dispensaries, pharmacies or other users to fulfill custom cannabis blends of THC, CBD terpenes, and the like. The variety of custom cannabis blends would accommodate the wide range of formulas needed to satisfy the next stage of the cannabis industry. Personalized cannabis solutions can be created using the hardware and software of the method and system.

A method and system for blending and dispensing liquid cannabis enables dispensaries, pharmacies or other users to fulfill custom cannabis blends of THC, CBD terpenes, and the like. The variety of custom cannabis blends would accommodate the wide range of formulas needed to satisfy the next stage of the cannabis industry. Personalized cannabis solutions can be created using the hardware and software of the method and system.

Provided is a melting device for discharging a melt of a substance to the inside of a tank to melt the substance stored in the tank, the melting device being capable of discharging a desired amount of the melt into the tank, while reducing the diameter of a discharge pipe that discharges the melt of the substance. The melting device 1 of the present invention comprises a suction pipe 2 and a discharge pipe 3 that are attached to the wall T of a tank; and a circulation flow path 4 that is disposed outside the tank T. The inside of the tank T and the inside of one end 4a of the circulation flow path 4 communicate with each other through the inside of the suction pipe 2. The inside of the tank T and the inside of the other end 4b of the circulation flow path 4 communicate with each other through the inside of the discharge pipe 3. A pump 5 is provided at a midway position of the circulation flow path 4. By driving the pump 5, a melt Ma of substance M that is present inside the tank T can be suctioned into the suction pipe 2, circulated through the circulation flow path 4, and discharged from the inside of the discharge pipe 3 to the inside of the tank T; and the entirety of the inside of the discharge pipe 3 is used as a flow path for the melt Ma.

Provided is a melting device for discharging a melt of a substance to the inside of a tank to melt the substance stored in the tank, the melting device being capable of discharging a desired amount of the melt into the tank, while reducing the diameter of a discharge pipe that discharges the melt of the substance. The melting device 1 of the present invention comprises a suction pipe 2 and a discharge pipe 3 that are attached to the wall T of a tank; and a circulation flow path 4 that is disposed outside the tank T. The inside of the tank T and the inside of one end 4a of the circulation flow path 4 communicate with each other through the inside of the suction pipe 2. The inside of the tank T and the inside of the other end 4b of the circulation flow path 4 communicate with each other through the inside of the discharge pipe 3. A pump 5 is provided at a midway position of the circulation flow path 4. By driving the pump 5, a melt Ma of substance M that is present inside the tank T can be suctioned into the suction pipe 2, circulated through the circulation flow path 4, and discharged from the inside of the discharge pipe 3 to the inside of the tank T; and the entirety of the inside of the discharge pipe 3 is used as a flow path for the melt Ma.

A thermal controlled hose assembly is provided and includes an adapter which defines an adapter cavity, wherein the adapter is configured to receive a DEF fluid within the adapter cavity, a hose, wherein the hose defines a hose cavity and wherein the hose is connected to the adapter such that the hose cavity is in flow communication with the adapter cavity, a nozzle, wherein the nozzle includes an inlet port and an outlet port and defines a fluid flow channel which communicates the inlet port with the outlet port, and wherein the nozzle is connected with the hose such that the fluid flow channel is in flow communication with the hose cavity and a heating system, wherein the heating system includes a heating element which is configured to be in contact with at least a portion of at least one of the adapter, the hose and the nozzle.

A thermal controlled hose assembly is provided and includes an adapter which defines an adapter cavity, wherein the adapter is configured to receive a DEF fluid within the adapter cavity, a hose, wherein the hose defines a hose cavity and wherein the hose is connected to the adapter such that the hose cavity is in flow communication with the adapter cavity, a nozzle, wherein the nozzle includes an inlet port and an outlet port and defines a fluid flow channel which communicates the inlet port with the outlet port, and wherein the nozzle is connected with the hose such that the fluid flow channel is in flow communication with the hose cavity and a heating system, wherein the heating system includes a heating element which is configured to be in contact with at least a portion of at least one of the adapter, the hose and the nozzle.

Device and method for filling pressurized gas tanks, particularly vehicle pressurized hydrogen tanks, the device comprising a liquefied gas source, a transfer circuit comprising two parallel transfer lines each having an upstream end linked to the liquefied gas source, at least two separate downstream ends intended to be each removably connected to a tank to be filled, each of the two transfer lines comprising: a pump, a vaporizer for evaporating the pumped fluid, a branch for bypassing the vaporizer and a distribution valve(s) set configured to control the flow of fluid pumped and distributed between the vaporizer and the branch line, the device further comprising a storage buffer(s), which storage buffer(s) is(are) connected in parallel to each of the two transfer lines via a set of valves.

Device and method for filling pressurized gas tanks, particularly vehicle pressurized hydrogen tanks, the device comprising a liquefied gas source, a transfer circuit comprising two parallel transfer lines each having an upstream end linked to the liquefied gas source, at least two separate downstream ends intended to be each removably connected to a tank to be filled, each of the two transfer lines comprising: a pump, a vaporizer for evaporating the pumped fluid, a branch for bypassing the vaporizer and a distribution valve(s) set configured to control the flow of fluid pumped and distributed between the vaporizer and the branch line, the device further comprising a storage buffer(s), which storage buffer(s) is(are) connected in parallel to each of the two transfer lines via a set of valves.

Content containers and vessels, one aspect including a deformable fluid-tight container shell defining an internal volume and separating the internal volume from an external environment; a room-temperature semi-solid content contained within the internal volume; and a valve operationally connected to and disposed at least partially without the deformable container shell; where the semi-solid content is a hydrophobic matrix with at least partially emulsified hydrophilic components; where the container shell is substantially fluid-tight; where the valve has open state(s) and a closed state; where the valve may be actuated between the open state(s) and the closed state; where the valve is self-cleaning; where during the open state(s), the internal volume is in fluidic communication with the external environment; where during the closed state, the internal volume content cannot fluidically communicate with the external environment; and where the content remains moisture-stable while the valve is in the closed state.

Content containers and vessels, one aspect including a deformable fluid-tight container shell defining an internal volume and separating the internal volume from an external environment; a room-temperature semi-solid content contained within the internal volume; and a valve operationally connected to and disposed at least partially without the deformable container shell; where the semi-solid content is a hydrophobic matrix with at least partially emulsified hydrophilic components; where the container shell is substantially fluid-tight; where the valve has open state(s) and a closed state; where the valve may be actuated between the open state(s) and the closed state; where the valve is self-cleaning; where during the open state(s), the internal volume is in fluidic communication with the external environment; where during the closed state, the internal volume content cannot fluidically communicate with the external environment; and where the content remains moisture-stable while the valve is in the closed state.