A system for processing essential oils includes a mixing tank, three winterization vessels, three respective filtering vessels, a fine filtering vessel, a holding tank, an evaporator, an essential oil reservoir, a solvent reservoir, and a solvent filtering vessel. The evaporator can include a heat exchanger configured to heat a plate down which a mixture including the oils flows, to evaporate other components of the mixture. Fluids can be advanced through the system using a pressurized inert gas.

A system for processing essential oils includes a mixing tank, three winterization vessels, three respective filtering vessels, a fine filtering vessel, a holding tank, an evaporator, an essential oil reservoir, a solvent reservoir, and a solvent filtering vessel. The evaporator can include a heat exchanger configured to heat a plate down which a mixture including the oils flows, to evaporate other components of the mixture. Fluids can be advanced through the system using a pressurized inert gas.

A method of extracting essential oil from plant matter for personal use includes positioning an amount of medicinal herb in a mini oven. A heating element is at least partially covered by a metallic heat exchanger and positioned in the mini oven. The medicinal herb is pyrolysized by energizing the heating element. Vaporized essential oil from the medicinal herb is moved out of the mini oven and toward the user. Oxygen is displaced from the mini oven responsive to decarboxylation of the medicinal herb, to inhibit combustion at elevated temperatures.

A method of extracting essential oil from plant matter for personal use includes positioning an amount of medicinal herb in a mini oven. A heating element is at least partially covered by a metallic heat exchanger and positioned in the mini oven. The medicinal herb is pyrolysized by energizing the heating element. Vaporized essential oil from the medicinal herb is moved out of the mini oven and toward the user. Oxygen is displaced from the mini oven responsive to decarboxylation of the medicinal herb, to inhibit combustion at elevated temperatures.

The present invention relates to an extraction apparatus for extracting at least one constituent in a substance. The extraction apparatus comprises an extractor, an extraction separator and an extraction condenser. The extractor is used to mix the substance and an extraction fluid, wherein the extraction fluid is a subcritical fluid. The extraction separator is connected to the extractor for receiving and heating the extraction fluid to gasify the extraction fluid and to separate the constituent and the gasified extraction fluid. The extraction condenser is connected to the extraction separator and the extractor for receiving and liquefying the gasified extraction fluid from the extraction separator and sending the liquefied extraction fluid to the extractor.

The present disclosure belongs to the technical field of extraction of fragrance substances, and specifically relates to Cymbidium goeringii balsam and a preparation method and use thereof. The present disclosure is implemented by cultivating multiple plants of Cymbidium goeringii with unravelling bloom collectively in a relatively small enclosed space, and enriching fragrance substances of Cymbidium goeringii in the air by lipid for adsorption. The method of the present disclosure can obtain Cymbidium goeringii balsam rich in a variety of fragrance components in a relatively short time. GC-MS detection indicates as many as 50 components. The present disclosure significantly improves the prior art in which only a small amount of fragrance components in Cymbidium goeringii can be extracted or even cannot be obtained. The present disclosure can be further used in extracting essential oils or applied directly.

The present disclosure belongs to the technical field of extraction of fragrance substances, and specifically relates to Cymbidium goeringii balsam and a preparation method and use thereof. The present disclosure is implemented by cultivating multiple plants of Cymbidium goeringii with unravelling bloom collectively in a relatively small enclosed space, and enriching fragrance substances of Cymbidium goeringii in the air by lipid for adsorption. The method of the present disclosure can obtain Cymbidium goeringii balsam rich in a variety of fragrance components in a relatively short time. GC-MS detection indicates as many as 50 components. The present disclosure significantly improves the prior art in which only a small amount of fragrance components in Cymbidium goeringii can be extracted or even cannot be obtained. The present disclosure can be further used in extracting essential oils or applied directly.

A device for automatic extraction, storage and encapsulation of fatty compounds, the device may include: an extraction unit configured to provide a liquid mixture comprising fatty compounds extracted from biological material and a liquid solvent; an evaporation and reaction unit; a storage unit comprising one or more storage outlet ports; and a controller configured to: control delivery of the liquid mixture from the extraction unit to the evaporation and reaction unit; control evaporation of the solvent from the liquid mixture in the evaporation and reaction unit; control delivery of the liquid mixture from the evaporation and reaction unit to the storage unit; detect safe connection of each of at least one of one or more capsules to one of the one or more storage outlet ports of the storage unit; and control filling of at least one of the one or more connected capsules with the liquid mixture.

A system and method for extracting essential oils from organic material is provided. One embodiment places organic material into an extraction chamber that is a cylindrical wall of rigid material, wherein a diameter and a height of the extraction chamber is sized to define an interior that accommodates a desired amount of an organic material having essential oils; fills the extraction chamber with a solvent after the organic matter has been placed into the extraction chamber; and moves a vortex plunger disposed over the surface of the organic material in a repeated upward and downward motion during an agitation process so that the vortex vanes generate a fluid vortex in the solvent, wherein the fluid vortex causes the solvent to be drawn upward into the organic material and then to be pushed downward through the organic material so that the solvent extracts essential oils from the organic material.

A method for producing valuable organic liquid from a biomass wherein a gas is heated to a predetermined temperature to produce a heated gas. The heated gas is mixed with a biomass to produce an enriched organic vapor and a biomass waste product. The biomass waste product is separated from the enriched organic vapor. The enriched organic vapor is cooled to produce a liquid organic oil and the liquid organic oil is collected. A system for producing the liquid organic oil wherein the system includes a heat source for heating a gas to produce a heated gas and a first separation unit to separate an enriched organic vapor and a biomass waste product. The enriched organic vapor and the biomass waste product are generated from mixing the heated gas and a biomass. The system also includes a wet scrubber for cooling the enriched organic vapor to remove certain compounds from the enriched organic vapor to generate an enriched organic smoke. The organic smoke can be transformed to the liquid organic oil in an electrostatic precipitator.