Method for removing contaminants from cannabinoid distillates

Information

  • Patent Grant
  • 10507404
  • Patent Number
    10,507,404
  • Date Filed
    Monday, October 8, 2018
    6 years ago
  • Date Issued
    Tuesday, December 17, 2019
    5 years ago
  • Inventors
  • Original Assignees
    • (Hayfork, CA, US)
  • Examiners
    • Meller; Michael V
    Agents
    • Arc IP Law, PC
    • Mayo; Joseph J.
Abstract
A method for removing contaminants such as pesticides and fungicides from cannabinoid extracts. Cannabinoid extracts containing contaminants may be dissolved in a water and ethanol solution, and then cooled to allow water-soluble contaminants to settle out of the mixture. The water and ethanol may then be removed via evaporation or distillation, leaving purified cannabinoids without contaminants. Contaminant removal may be incorporated into a method for producing a blended extract of cannabinoids and terpenes, which extracts terpenes using supercritical CO2, and extracts a cannabinoid concentrate from the residual material using a cold ethanol flush followed by distillation and then by contaminant removal; the CO2-extracted terpenes are then added back to the purified cannabinoid concentrate in a final blending step. Blending terpenes at the end of extraction may enhance the flavor and effectiveness of the purified cannabinoid concentrate.
Description
BACKGROUND OF THE INVENTION
Field of the Invention

One or more embodiments of the invention are related to the field of extraction of substances from plant material. More particularly, but not by way of limitation, one or more embodiments of the invention enable a method for removing contaminants from cannabinoid distillates.


Description of the Related Art

Several methods for extracting cannabinoids from cannabis plant material are known in the art. A limitation of many of these methods is that the terpenes in the cannabis plant are often lost or greatly reduced in the final extracted product. While cannabinoids provide a major element of the medicinal or psychoactive effect of cannabis, the many terpenes in the cannabis plant also contribute significantly to the plant's properties.



Cannabis processors have explored techniques to simultaneously extract cannabinoids and preserve terpenes, with limited success. Processes and parameters that are optimal for cannabinoid extraction may be ineffective for terpene extraction, and vice-versa. Moreover, tuning the ratio of terpenes to cannabinoids is difficult or impossible when attempting to extract both simultaneously. A potential solution to these difficulties, which is not known in the art, is to combine separate procedures for terpene extraction and cannabis extraction, and to blend the outputs of these procedures into a final product. This approach allows optimal processes and parameters to be used for each step, and it provides maximum flexibility for the composition of the final blend. There are no known methods that use such an approach to generate a terpene-enhanced cannabinoid concentrate. In addition, the only method known in the art for terpene extraction is steam distillation, which extracts a limited profile of terpenes because it is water based. There is a need for combining a more effective terpene extraction process with a blending process that combines terpenes and cannabinoids.


Existing methods for cannabis extraction may also fail to remove contaminants, such as pesticides and fungicides, from the extracted cannabis material. While some purification techniques are known, there are no known methods that provide a simple and cost-effective process for removing contaminants from cannabinoid distillates.


For at least the limitations described above there is a need for a method for removing contaminants from cannabinoid distillates.


BRIEF SUMMARY OF THE INVENTION

One or more embodiments described in the specification are related to a method for removing contaminants from cannabinoid distillates. Embodiments of the invention may be combined with an extraction process for terpene oil and an extraction process for cannabinoids, to yield a blend with combined benefits of terpenes and purified cannabinoids.


One or more embodiments of the invention may produce a terpene-enhanced cannabinoid concentrate using the following steps: Cannabis plant material is ground, then exposed to a carbon dioxide solvent, for example using a supercritical CO2 fluid. The CO2 extracts terpene oil and terpene hydrosols from the cannabis. The residual plant material (after CO2 extraction) is then washed with cold ethanol, and the resulting ethanol oil solution is separated into ethanol (which may be recycled) and cannabis oil. The cannabis oil is then distilled to obtain cannabinoid distillates. These cannabinoid distillates are blended with the terpene oil from CO2 extraction, yielding a terpene-enhanced cannabinoid concentrate. Terpenes may for example add flavor to the cannabinoid concentrate or enhance the effects of the concentrate.


Cannabinoid distillates may include any or all of THC, CBD, CBG, CBN, and THCV. In one or more embodiments, the concentration of cannabinoids in the cannabinoid distillates may be 80% or higher. The cannabinoid distillates may be optionally redistilled (multiple times if desired) to increase the cannabinoid concentration.


Terpenes extracted in the terpene oil and terpene hydrosols may include any or all of alpha-Bisabolol, Camphene, 3-Carene, beta-Caryophyllene, Citronellol, Cymene, Eucalyptol, Famesene, Fenchol, Geraniol, Guaiol, Humulene, Isopropyltoluene, Isopulegol, Linalool, delta-Limonene, beta-Myrcene, Nerolidol, alpha-Pinene, Ocimene, alpha-Terpinene, gamma-Terpinene, and Terpinolene.


Terpene oil and cannabinoid concentrate may be combined in any ratio. In one or more embodiments, the ratio by volume of terpene oil to cannabinoid concentrate may be in the range of 1:25 to 1:5. In one or more embodiments the ration may be in the range of 1:12 to 1:8. As an illustration, one or more embodiments may generate a blend with a terpene-to-cannabinoid concentrate ratio of approximately 1:10.


Illustrative parameters used for CO2 extraction of terpene oil and terpene hydrosol in one or more embodiments may include for example: CO2 pressure in the range of 1000 psi to 1300 psi, forming a supercritical fluid; temperature between 80 F and 100 F; and elapsed time of exposing the cannabis plant material to the supercritical CO2 in the range of 15 minutes to 6 hours. After CO2 extraction and removal of CO2 (for example by reducing pressure to allow the CO2 to evaporate), the terpene oil and terpene hydrosol may be filtered at a temperature between −80 F and 40 F, using a filter with pore size greater than 0.25 micron.


Illustrative parameters used for cold ethanol extraction and ethanol recovery in one or more embodiments may include for example: flushing of residual plant material with cold ethanol at a temperature of 30 F or below; and distilling the ethanol oil solution at a temperature between 120 F and 165 F under a vacuum between 10 inches Hg and 25 inches Hg. Recovered ethanol may be optionally reused for subsequent washing of a second batch of material.


Distilling of cannabis oil into cannabinoid distillates may be performed in one or more embodiments under vacuum with a pressure at or below 5 torr. Cannabinoid distillates may be obtained at a temperature of between 157 C and 230 C. In one or more embodiments, distillation may also yield terpene distillates, for example at a temperature between 140 C and 157 C. Distillation of these products may be performed multiple times to increase concentration or purity, followed by blending of terpene oil with the cannabinoid distillates.


One or more embodiments of the invention may remove contaminants from cannabinoid distillates or other cannabinoid extracts. Cannabinoid distillates containing contaminants may be mixed with ethanol and water, and the contaminants may then be allowed to settle out of the solution. After separating the purified solution from the settled contaminants, the water and ethanol may be removed, leaving purified cannabinoid distillates. This contaminant removal process may be used as a standalone process for purifying cannabinoid extracts, or it may be incorporated into the extraction and blending process described above. For example, contaminant removal may be performed after distillation and prior to blending of the cannabinoid distillates with terpenes.


Contaminants removed by one or more embodiments of the invention may include for example, without limitation, pesticides and fungicides. These contaminants may be for example water-soluble. Illustrative contaminants that may be removed using the invention include for example, without limitation, Abamectin, Acephate, Acetamiprid, Aldicarb, Azoxystrobin, Bifenazate, Boscalid, Carbaryl, Carbofuran, Chlorpyrifos, Daminozide, Dichlorvos, Dimethoate, Ethoprophos, Fenarimol, Fenchlorphos, Fenhexamid, Fenoxycarb, Fipronil, Flonicamid, Fludioxonil, Fonofos, Imazalil, Imidacloprid, Iprodione, Kresoxim-methyl, Malathion, Metalaxyl, Methiocarb, Methomyl, MGK-264, Myclobutanil, Naled, Oxamyl, Paclobutrazol, Parathion, Phosmet, Piperonyl butoxide, Pirimiphos, Prallethrin, Promecarb, Propiconazole, Propoxur, Pyraclostrobin, Spinetoram, Spirotetramat, Spiroxamine, Tebuconazole, Thiacloprid, and Thiamethoxam.


Illustrative parameters used in one or more embodiments for mixing of cannabinoid distillates with water and ethanol may include for example: adding ethanol to cannabinoid distillates at a ratio between 2:1 and 4:1 of ethanol by volume in mL to cannabinoid distillates by mass in grams; heating the cannabinoid-ethanol solution to a temperature between 40° C. and 80° C.; adding distilled water to the dissolved cannabinoid-ethanol solution at a ratio between 1:4 and 1:10 of distilled water by volume in mL to cannabinoid distillates by mass in grams; and heating the cannabinoid-ethanol-water solution to a temperature between 40° C. and 60° C.


Illustrative parameters used in one or more embodiments for allowing contaminants to settle out of the cannabinoid-ethanol-water solution may include for example: cooling the cannabinoid-ethanol-water solution to a temperature between −30° C. and 10° C.; and allowing contaminants to settle out of the cooled solution for a period of time between 2 hours and 7 days.


Illustrative methods used in one or more embodiments for separating the cannabinoid-ethanol-water solution into a purified cannabinoid-ethanol-water solution and the residual contaminants may include for example: pouring the purified cannabinoid-ethanol-water solution off of the cannabinoid-ethanol-water solution; siphoning the purified cannabinoid-ethanol-water solution off of the cannabinoid-ethanol-water solution; and filtering the residual contaminants out of the cannabinoid-ethanol-water solution.


Illustrative methods used in one or more embodiments for removing ethanol and water from the cannabinoid-ethanol-water solution after contaminants have settled out may include for example: heating the purified cannabinoid-ethanol-water solution to cause the ethanol and water to evaporate; and distilling the purified cannabinoid-ethanol-water solution to recover the purified cannabinoid distillates.





BRIEF DESCRIPTION OF THE DRAWINGS

The above and other aspects, features and advantages of the invention will be more apparent from the following more particular description thereof, presented in conjunction with the following drawings wherein:



FIG. 1 shows a high-level flowchart of an embodiment of a method for producing a terpene-enhanced cannabinoid concentrate.



FIGS. 2 and 3 show a detailed flowchart of an embodiment of the invention, illustrating steps, products, and optional flow paths in the process.



FIG. 4 shows illustrative equipment that may be used in the CO2 extraction step of the process of FIG. 1.



FIG. 5 shows how the equipment of FIG. 4 relates to selected steps and products shown in the process flowchart of FIGS. 2 and 3.



FIG. 6 shows illustrative equipment that may be used in the cold ethanol extraction and ethanol recovery steps of the process of FIG. 1.



FIG. 6A shows a variation of the illustrative equipment of FIG. 6 for ethanol recovery.



FIG. 7 shows how the equipment of FIG. 6 relates to selected steps and products shown in the process flowchart of FIGS. 2 and 3.



FIG. 8 shows illustrative equipment that may be used in the distillation step of the process of FIG. 1.



FIG. 9 shows how the equipment of FIG. 8 relates to selected steps and products shown in the process flowchart of FIGS. 2 and 3.



FIG. 10 shows a variation of the flowchart of FIG. 1 that incorporate a procedure for removing contaminants from cannabinoid distillates.



FIG. 11 shows an illustrative detailed flowchart for the contaminant removal step of FIG. 10.





DETAILED DESCRIPTION OF THE INVENTION

A method for removing contaminants from cannabinoid distillates will now be described. In the following exemplary description, numerous specific details are set forth in order to provide a more thorough understanding of embodiments of the invention. It will be apparent, however, to an artisan of ordinary skill that the present invention may be practiced without incorporating all aspects of the specific details described herein. In other instances, specific features, quantities, or measurements well known to those of ordinary skill in the art have not been described in detail so as not to obscure the invention. Readers should note that although examples of the invention are set forth herein, the claims, and the full scope of any equivalents, are what define the metes and bounds of the invention.



FIG. 1 shows a high-level flowchart of an embodiment of the invention. The steps shown are illustrative; one or more embodiments may use additional steps, or a subset of the steps shown. One or more embodiments may perform these steps in any desired order. One or more embodiments may perform one or more of these steps in parallel. The process shown in FIG. 1 generates a cannabinoid extract 112 that is enhanced with terpenes. Addition of terpenes to the cannabinoid extract may add flavor and may introduce compounds into the final blend that may have beneficial effects. The process may be performed at any scale, ranging for example from a micro scale such as on a benchtop to a large industrial scale such as in a refinery.


In the illustrative flowchart of FIG. 1, raw cannabis material 101 is obtained and is input into the grinding step 102. Cannabis material 101 may include for example, without limitation, the leaves, flowers, or buds of one or more cannabis plants. The flowers or buds have the highest concentration of cannabinoids and terpenes; however, any part or parts of the cannabis plant may be processed. The grinding step 102 may use any grinding method or methods, such as hand grinding, machine grinding, or use of a chipper or mulcher. In one or more embodiments, the grinding step may grind the material to a particle size similar to that of typical coffee grounds. Initial grinding may be followed in one or more embodiments by one or more filtering stages, for example to filter out stems or sticks. An illustrative mesh size used in one or more embodiments for filtering may be in the range of ¼ inch to ½ inch.


Grinding step 102 may be followed by CO2 extraction step 103. This step may be used for example to extract a terpene oil 104 from the ground plant material; some or all of this oil may be added back into the refined material in a later stage, as illustrated in blending step 111 in FIG. 1. CO2 extraction may for example extract terpenes more effectively and completely from cannabis material than the steam distillation process that is generally used for terpene extraction. CO2 extraction 103 may for example use a supercritical CO2 fluid. In this process CO2 is pressurized to form a liquid, and the liquid is mixed with the ground cannabis material to extract the desired compounds (in this case, terpenes). The CO2 may be removed from the solution by reducing the pressure, which allows the CO2 to evaporate as a gas and leaves the terpene extract behind. Illustrative process parameters used in one or more embodiments for the CO2 extraction step include: CO2 pressure in the range of 1000 psi to 1300 psi for the extraction; extraction temperature in the range of 80 F to 110 F; and separation temperature (after extraction) in the range of 40 F to 70 F. Run time for the CO2 extraction step may be for example in the range of 15 minutes to 6 hours.


After the extraction into the CO2 solution, terpene oils and hydrosols may be harvested from the solution. The oil may contain for example a mixture of terpenes and some cannabinoids, and the hydrosol may contain water-based terpenes and water. After removing the CO2 (via evaporation, for example), the remaining solution may be separated by allowing it to settle until the oil and the hydrosols separate, and then bleeding off the hydrosols. These products may then be filtered to remove waxes and cannabinoids by chilling them to a temperature in the range −80 F to 40 F, and then filtering with a coffee filter or a lower micron filter, for example with a pore size above 0.25 microns. Terpene oil 104 extracted in step 103 may be useful as a separate product (such as an essential oil), or it may be blended into further cannabinoid extracts in blending step 111.


Terpenes present in the extracted terpene oil and terpene hydrosol may include for example, without limitation, any or all of the terpenes alpha-Bisabolol, Camphene, 3-Carene, beta-Caryophyllene, Citronellol, Cymene, Eucalyptol, Famesene, Fenchol, Geraniol, Guaiol, Humulene, Isopropyltoluene, Isopulegol, Linalool, delta-Limonene, beta-Myrcene, Nerolidol, alpha-Pinene, Ocimene, alpha-Terpinene, gamma-Terpinene, and Terpinolene. Hydrosols may include primarily humelene and pinene, but any other terpenes may also be present in the hydrosols. Typical terpene concentration in hydrosols may be in the range of 1% to 10%, while typical terpene concentration in terpene oil may be up to 99%. Hydrosols and oil may also include some cannabinoids, for example up to 15% cannabinoids in terpene oils and up to 5% in hydrosols. The terpene oil and terpene hydrosols may be used for example as flavoring, or in aroma therapy products, in salves, in creams, or in topical treatments. These terpene compounds may have medicinal uses when taken internally or applied externally.


After extracting terpenes in step 103, the remaining non-extracted plant material may then be processed in cold ethanol extraction step 105. For example, the plant material that was exposed to the CO2 may be emptied from the CO2 extraction vessel and placed into one or more sanitary steel tubes, which may then be placed into a cryogenic freezer or other cooling apparatus to cool the plant material to a temperature in the range of −80 F to 30 F. Each tube may then be attached to a catch pot, possibly with a filter between the tube and the catch pot, and cold ethanol may be introduced into the tube and exposed to the plant material. After exposure, a dump valve may be opened to allow the cold ethanol solution to flow into the catch pot. A vacuum may also be applied to facilitate removal of the cold ethanol solution from the tube. The tube may be flushed for example for a time in the range of 5 minutes to 30 minutes. Flushing may continue for example until the ethanol stops or until it begins to turn greenish in color. The catch pot then contains an ethanol oil solution with extracted compounds from the plant material.


The ethanol oil solution may then be processed in ethanol recovery step 106 to remove some or all of the ethanol from the solution, leaving a cannabis oil product 108. As illustrated in FIG. 1, some or all of the recovered ethanol 107 may be recycled into the cold ethanol extraction step 105. The ethanol recovery process may for example use a vacuum distillation method to remove ethanol from the solution. The ethanol oil solution may be transferred into a recovery column which may be warmed in a water bath or in a jacketed column, for example to a temperature in the range of 120 F to 165 F. The recovery column may be connected to a condenser with circulating cold water and connected to a vacuum to accelerate ethanol evaporation. In an illustrative ethanol recovery process, after starting the cold water circulation the vacuum pump level may be set in the range of −10 inches Hg to −25 inches Hg. Condensed ethanol may be recovered into a container, which may then be used as input to the cold ethanol wash step for subsequent batches. Recovery run time may for example range from approximately 30 minutes to 3 hours, yielding recovered ethanol at a rate of approximately 7.5 L to 10 L per hour.


The remaining oil in the recovery column after the ethanol recovery step is an organic cannabinoid concentrated oil 108. This oil may be referred to colloquially (although not completely correctly) as “Rick Simpson Oil,” or “RSO.” It may contain for example cannabinoids in a concentration of approximately 50% to 90%, and may contain for example up to 20% terpenes. Cannabinoids contained in the oil may include for example, without limitation, THCa, THC, THCV, CBDa, CBD, CBC, CBG, and CBN. The oil may be processed further to form a concentrate (as described below), or it may be used directly as a final product. The oil may be smoked or vaped, for example as a “shatter” or in a vape pen as an oil. It may be activated, for example by heating in an oven to approximately 180 F, and incorporated into edible products, topicals, creams, or salves.


The cannabis oil 108 may then be further concentrated in distillation step 109. Distillation 109 may for example use any distillation devices and techniques, including for example, without limitation, short path distillation, thin film distillation, wipe film distillation, and spinning band distillation. An illustrative distillation process is as follows. The cannabis oil 108 is placed on a hot plate with a stir rod or stir bar, at a temperature of no more than 140 C in one or more embodiments. Distillation may be performed under vacuum or without vacuum. With a vacuum under 5 torr, most terpenes distill out before 157 C; cannabinoid distillates 110 distill out between 157 C and 185 C; and some additional products such as CBG, CBN, and THCV distill out between 185 C and 230 C. Without a vacuum, distillation may be performed for example between 370 C and 440 C. In one or more embodiments, the products of distillation may be redistilled, possibly multiple times, to increase the concentration of the final product. The cannabinoid distillates 110 may for example have cannabinoid concentrations between 80% and 99.99%, with higher levels possible using multiple distillations. Cannabinoid distillates may be smoked or vaped, for example as a “shatter” or in a vape pen as an oil. They are already activated as a result of the distillation process; therefore, they may be incorporated into edible products, topicals, creams, or salves.


In one or more embodiments, the cannabinoid distillates 110 may be blended in step 111 with the terpene oil 104 extracted using CO2 extraction 103, to create a terpene-enhanced cannabinoid concentrate 112. This blending may for example add flavor and may create additional effects when smoking, vaping, or ingesting the blend. Blending terpene oil with the cannabinoid distillates may also make the product 112 thin enough to be used in vape pens. In one or more embodiments, the blending step 111 may use a ratio by volume of terpene oil to cannabinoid distillates in the range 1:25 to 1:5. An illustrative embodiment may use for example a ratio of terpene oil to cannabinoid distillates of 1:10.



FIGS. 2 and 3 show a more detailed flowchart of an embodiment of the invention. (FIG. 3 is a continuation of FIG. 2). Cannabis material 101 is input into grinding step 102, yielding ground/sifted material 202a. This material 202a is then filtered to remove sticks, stems, and stalks 202c. The remaining ready plant material 202b is input into the CO2 extraction process. If needed or desired, additional grinding, sifting, and filtering may be performed on either or both of the sticks, stems, and stalks 202c, and the ready plant material 202b, prior to CO2 extraction. Unused stems, sticks and stalks 202c are dried and bagged into waste products 202c, and sent to a waste disposal/composting process 220.


The material 202b is then loaded into a CO2 extraction vessel, forming loaded material 103a. Terpene extraction 103b is then performed using CO2 203b as a solvent. This extraction yields terpene oil 104 and terpene hydrosols 104b. The remaining dry plant material 203a is further processed with the next steps in the process. CO2 203b removed from the solution may be recycled and used for additional terpene extraction steps 103b.


The cold ethanol extraction process then proceeds with dry plant material 203a placed into a container and cryogenically frozen, yielding frozen material 205a. Ethanol wash 205b is then performed over this frozen material, yielding ethanol concentrate solution 205c. The remaining soaked plant material 205d may be reprocessed with additional cryogenic freezing 205a and ethanol wash 205b if desired, or formed into waste material 205e that is transmitted to waste disposal/composting process 220. The solution 205c is then transferred to a solvent recovery vessel 206a, and ethanol recovery process 106 removes ethanol 107 from the solution. The ethanol may be recycled if desired for subsequent cold ethanol extraction steps. After removing ethanol, the solution contains plant concentrate oil 108a.


Turning now to FIG. 3, which is a continuation of FIG. 2, plant concentrate oil 108a (“C” from FIG. 2) may be used directly as cannabis oil 108 (also referred to colloquially as “RSO”). It may also be further processed with distillation and blending. Oil 108 may be placed in a distillation vessel 309a. In addition, if desired, some or all of the ethanol 107 removed from the oil (“B” from FIG. 2) may be further distilled to obtain any residual cannabinoids or other products. Molecular distillation steps 109 may yield various fractionally distilled products 309b (for example at different distillation temperatures), including cannabinoid distillates 110 and isolated terpenes 309a. Remaining plant material 309d after distillation to extract products 110 and 309c may be transformed into waste 309e and disposed in step 321, or it may be redistilled. Products 110 and 309c may also be redistilled, for example to increase product concentration. Cannabinoid distillates 110 may then be blended with the terpene oil 104 from CO extraction (“A” from FIG. 1), yielding terpene-enhanced cannabinoid oil 112.



FIGS. 4 through 9 show illustrative equipment that may be used in one or more steps of the process in one or more embodiments of the invention. This equipment is illustrative; one or more embodiments may use any desired equipment for any step or steps. Any of the steps may be manual, automated, or semi-automated. FIG. 4 shows illustrative equipment that may be used for CO2 extraction in one or more embodiments of the invention. CO2 extraction may for example use an Apeks® 1500-20 L Botanical Oil Extraction System, or any similar equipment. FIG. 4 shows selected components of the system; it does not show all components and all connections. CO2 gas is obtained from CO2 tank 401. This gas flows to chiller 402, which cools the gas using heat exchanger 403. The pressure of the gas is increased with compression pump 404, yielding a supercritical CO2 fluid. This fluid is passed over ground and frozen cannabis material in extraction vessel 405. The CO2 solution with extracted terpenes then flows to separation vessel 406, which has a collection cup 407 at the bottom. The CO2 evaporates from vessel 406, leaving the terpene oil and hydrosols in collection cup 407. If desired or needed, further separation may be performed using separation vessel 408.



FIG. 5 annotates the equipment of FIG. 4 with selected process steps and products from the flowchart of FIGS. 2 and 3. After grinding 102, material 103a is loaded into the CO2 system in extraction vessel 405. The products of CO2 extraction including terpene oil 104 and terpene hydrosols 104b are collected in collection cub 407. After CO2 extraction, the plant material 203a remaining in vessel 405 is removed and is transferred to cold ethanol extraction step 105, which is described next.



FIG. 6 shows illustrative equipment that may be used for cold ethanol extraction in one or more embodiments of the invention. Frozen plant material is placed into tube 601, which is flushed with cold ethanol. The cold ethanol solution containing extracted compounds is drained into receiving vessel 602, assisted by a vacuum. The vacuum pump 611 pulls air through line 621 to a connection at the top of vacuum cold trap 610, and from the cold trap through line 622 to the pump. The ethanol solution is then transferred to container 603, which is placed into hot water bath 605. The hot water bath is heated by heating element 604. The heat causes the ethanol in the solution to evaporate; ethanol vapor reaches condenser 606 which is cooled by cold water flowing from cold solution bath 608 through water line 631, and then returned via line 632 to the cold bath 608. Water flow is driven by pump 609 in the cold solution bath. Distillation of ethanol is vacuum assisted with vacuum line 623 attached to receiving vessel 607 that collects condensed ethanol. An additional vacuum cold trap 610 captures residual ethanol that may be in the vacuum line.



FIG. 6A shows another embodiment of equipment that may be used for ethanol recovery. In this embodiment, the equipment is mounted on rack 6A30, for example to comply with building and health codes. The equipment arrangement in FIG. 6A may also support more efficient operation than the arrangement of FIG. 6; for example, a batch of material may be processed using the embodiment of FIG. 6A in approximately 10 minutes, as compared to approximately an hour using the equipment configuration of FIG. 6. Efficiency improvements are achieved for example by providing mechanisms for the input of material and output of products without requiring equipment to be disassembled, reassembled, moved, or transferred. For example, the embodiment of FIG. 6A adds a feed spout 6A40 for container 603, so that users can add more material to the oil base without having to dismantle equipment. It also adds jacketed collection bottoms to each of the collection bases, which allows for material harvesting directly off the system without disassembling the equipment. A spout is attached to each collection bottom for harvesting of material: spout 6A41 may be used for harvesting of oil from collection vessel 603; spout 6A42 may be used for harvesting of ethanol from vacuum cold trap 610; and spout 6A43 may be used for harvesting of ethanol from recovered ethanol receiving vessel 607.


As in the embodiment of FIG. 6, an ethanol solution added to container 603 after frozen plant material has been washed with cold ethanol to extract plant compounds into the ethanol solution. In the embodiment shown in FIG. 6, container 603 is placed in a hot water bath. In the embodiment shown in FIG. 6A, a separate hot water reservoir 605a is used and hot water is pumped along water lines to a jacket surrounding container 603, thereby heating the ethanol solution and generating ethanol vapors that are recovered. For example, in the embodiment shown in FIG. 6A, hot water flows from reservoir 605a along water line 6A01 to a jacket surrounding container 603, and then along water line 6A02 to a jacket surrounding the collection bottom of container 603, and then along water line 6A03 back to the hot water reservoir 605a. As in the embodiment of FIG. 6, ethanol vapors reach condenser 606, and condensed ethanol flows to recovered ethanol receiving vessel 607. In the embodiment of FIG. 6, receiving vessel 607 is placed in a cold water bath. In the embodiment shown in FIG. 6A, a separate cold water reservoir 608a is used. Cold water is pumped along water lines from reservoir 608a to the condenser and to a jacket surrounding the ethanol receiver. Also as in FIG. 6, there may be an additional vacuum cold trap 610 to capture residual ethanol that may be in the vacuum line, but in FIG. 6A this vacuum cold trap receives cold water along water lines rather than being placed directly in a cold water bath. In the embodiment of FIG. 6A, cold water flows along water line 6A11 from the cold water reservoir 608a to the condenser 606, then along line 6A12 to a jacket surrounding recovered ethanol receiving vessel 607. The cold water then flows along line 6A13 to a jacket surrounding the collection bottom of the receiving vessel 607. Cold water then flows along line 6A14 to a jacket surrounding vacuum cold trap 610, then along line 6A15 to a jacket surrounding the collection bottom of the vacuum cold trap, and then along line 6A16 to return to the cold water reservoir 608a. Vacuum pump 611 provides a vacuum, with vacuum lines 6A22 and 6A21 connecting the vacuum pump to the vacuum cold trap 610 and to the recovered ethanol receiving vessel 607. The specific configuration and routing of the air and water lines shown in FIG. 6A are illustrative; one or more embodiments may route and configure these lines in any desired manner. One or more embodiments may use continuous sources of hot or cold water instead of or in addition to water reservoirs as illustrated in FIG. 6A.



FIG. 7 annotates the equipment of FIG. 6 with selected process steps and products from the flowchart of FIGS. 2 and 3. Material 205a that is cryogenically frozen is placed into tube 601. Ethanol 107 is added to the tube and cold ethanol extraction step 105 removes the ethanol concentrate solution 205c from tube 601 into receiving container 602. This solution 205c is then transferred to container 603 as solution 206a for solvent (ethanol) recovery. Ethanol recovery step 106 occurs in condenser 606 (and possibly in vacuum cold trap 610 as well) as ethanol vapor condenses, and recovered ethanol is collected in container 607 (and possibly in container 610). This recovered ethanol 107 may be recycled for additional cold ethanol flushes of material in tube 601. The material remaining in container 603 after ethanol recovery is cannabis oil 108.



FIG. 8 shows illustrative equipment that may be used for cannabis oil distillation in one or more embodiments of the invention. This figure shows a short path distillation process; one or more embodiments may use any desired distillation process, including but not limited to short path distillation. Flask 801 containing cannabis oil is placed on heating element 802. Distillation head 803 attached to flask 801 has an attached thermometer 804, and has connections for vacuum and water. Water line 821 provides cooling water to the condenser water jacket 805 from water source 806, and return water line 822 drains or recirculates this water. Vacuum line 831 attaches connection 807 to vacuum pump 809, and vacuum line 832 attaches to connection 808 on distribution bulb 811. In this illustrative embodiment, three collection flasks 810a, 810b, and 810c are attached to distribution bulb 811.



FIG. 9 annotates the equipment of FIG. 8 with selected process steps and products from the flowchart of FIGS. 2 and 3. Cannabis oil placed in distillation 309a is placed in flask 801. Molecular distillations 109 occur in distribution head 803, and distillation products such as cannabinoid distillates 110 and isolated terpenes 309c are collected in collection flasks 810a, 810b, or 810c. Thermometer 804 may be used to monitor the distillation temperature in order to separate and identify products such as cannabinoid distillates 110 and terpene distillates 309c that distill out at different temperatures.


One or more embodiments of the invention may include techniques or steps to remove contaminants from a cannabis extract. These contaminants may include for example, without limitation, pesticides or fungicides. Contaminant removal procedures may be applied to any cannabis extract. These procedures may be combined with the steps and methods described above for extracting cannabis and blending the extract with terpenes. Contaminant removal procedures may also be used as independent standalone methods to purify any cannabis extract, regardless of how the extract was obtained and regardless of how the purified extract is used after purification.



FIG. 10 shows an illustrative variation of the flowchart of FIG. 1 with contaminant removal step 1001 incorporated into the flowchart. In this illustrative flowchart, contaminant removal is performed on cannabinoid distillates 110, which are the product of distillation step 109 performed on cannabis oil 108. One or more embodiments of the invention may insert a contaminant removal step at any other point or points in an extraction process pipeline, and potentially at multiple such points. In the flowchart of FIG. 10, the purified cannabinoid distillates obtained as the output of step 1001 are input into blending step 111, which may for example add terpene oil 104 to the purified cannabinoid distillates. In one or more embodiments of the invention, the purified cannabinoid distillates output from contaminant removal step 1001 may be a final product, or they may be further processed in any desired manner.



FIG. 11 shows an illustrative detailed flowchart for an embodiment of contaminant removal process 1001. These contaminant removal steps may be incorporated into an extraction and blending process, as illustrated in FIG. 10, or used standalone for any cannabinoid extract. The steps illustrated in FIG. 11 may be used for example with contaminants such as pesticides and fungicides that are water soluble. Since most cannabinoids (such as for example THC, CBD, CBC, CBG, and CBN) are not very soluble in water, mixing cannabinoid distillates 110 in water may be an effective method for separating contaminants from the cannabinoids. This process works effectively for water-soluble contaminants, which includes many pesticides and fungicides. For example, without limitation, the steps of FIG. 11 may be used with water-soluble contaminants such as Abamectin, Acephate, Acetamiprid, Aldicarb, Azoxystrobin, Bifenazate, Boscalid, Carbaryl, Carbofuran, Chlorpyrifos, Daminozide, Dichlorvos, Dimethoate, Ethoprophos, Fenarimol, Fenchlorphos, Fenhexamid, Fenoxycarb, Fipronil, Flonicamid, Fludioxonil, Fonofos, Imazalil, Imidacloprid, Iprodione, Kresoxim-methyl, Malathion, Metalaxyl, Methiocarb, Methomyl, MGK-264, Myclobutanil, Naled, Oxamyl, Paclobutrazol, Parathion, Phosmet, Piperonyl butoxide, Pirimiphos, Prallethrin, Promecarb, Propiconazole, Propoxur, Pyraclostrobin, Spinetoram, Spirotetramat, Spiroxamine, Tebuconazole, Thiacloprid, and Thiamethoxam.


In step 1101, cannabinoid distillates 110 are mixed with ethanol 1102 and then warmed to allow the distillates to dissolve. Any type of container of any size may be used to mix the distillates, the ethanol, and the water (described below), such as for example a beaker or a mason jar. Any type of heat source may be used to warm the solution, including for example, without limitation, a hot plate, a warm water bath with a Sous Vide cooker, a Cascade Sciences TVO-2B Vacuum Purge Oven, and a Thermo Scientific Heratherm 51029336 Advanced Security Incubator (for example 24.8 cu ft. SS, Dual; 120V).


In one or more embodiments of the invention, ethanol 1102 may be mixed with cannabinoid distillates 110 in a ratio between 2:1 and 4:1 of ethanol by volume (in mL) to cannabinoid distillates by mass (in grams). The mixture may be warmed for example to a temperature between 40° C. and 80° C. to allow the cannabinoid distillates 110 to dissolve into dissolved distillate 1103.


In step 1104, distilled water 1105 is added to dissolved distillate 1103. In one or more embodiments of the invention, distilled water 1105 may be mixed with dissolved distillate 1103 in a ratio between 1:4 and 1:10 of water by volume (in mL) to cannabinoid distillates by mass (in grams). The mixture may be warmed for example to a temperature between 40° C. and 60° C. Heat sources such as those described above may be used. The distillate then breaks down with the water and the ethanol.


The dissolved solution of cannabinoid distillate, ethanol, and water is then cooled in step 1106. In one or more embodiments, the solution may be cooled to a temperature between −30° C. and 10° C. Any desired cold source may be used, including for example, without limitation, a refrigerator, an ice bath, a freezer, snow, or dry ice.


In step 1107, the cooled distillate-ethanol-water solution is left in the cooled environment for a period of time to allow the denser molecules of the water-soluble contaminants to settle out of the solution. These contaminants will sink to the bottom of the container under gravity over time. In one or more embodiments, the solution is allowed to settle for a period of time between 2 hours and 7 days.


In step 1108, the now purified solution is separated from the contaminants that have settled to the bottom. This separates the mixture into contaminants 1111 and the dissolved clean distillate 1110. These components may be separated by various techniques, including for example, without limitation, pouring the clean solution off the top of the container into a clean beaker, siphoning the clean solution off the top of the container into a clean beaker, or filtering the contaminants out of the solution. Filtering options may include for example, without limitation, filtering with a coffee filter, filtering with a Buchner funnel and filter paper (0.025 micron to 10 micron) with or without vacuum assist, and using a separator funnel. The removed contaminants 1111 are sent to a waste disposal process 1112, for example in a sealed jar or other hazardous material container.


Dissolved clean distillate 1110 is then processed in step 1115 to remove the ethanol and water that were added in steps 1101 and 1104, leaving the purified cannabinoid distillates 1120. Removal of water and ethanol may be done for example, without limitation, by heating the mixture 1110 (for example on a hot plate) to burn off the water and ethanol, or by distilling the mixture 1110 to recover the cannabinoid distillates (for example, using a short path distillation apparatus). In one or more embodiments, the purification process may be repeated as many times as necessary or desired to achieve a target level of purity, for example by returning some or all of the purified cannabinoid distillates 1120 on path 1121 to the initial step 1101.


Purified cannabinoid distillates 1120 may then be input into blending process 111 (to add terpenes, for example); in one or more embodiments, the purified cannabinoid distillates 1120 may be used directly as a final product, or they may be further processed in any desired manner.


While the invention herein disclosed has been described by means of specific embodiments and applications thereof, numerous modifications and variations could be made thereto by those skilled in the art without departing from the scope of the invention set forth in the claims.

Claims
  • 1. A method for removing contaminants from cannabinoid distillates and producing a terpene-enhanced cannabinoid concentrate consisting essentially of: extracting terpene oil from cannabis to yield a residual cannabis and said terpene oil; wherein said extracting said terpene oil from said cannabis to yield said residual cannabis and said terpene oil consists essentially of pressurizing carbon dioxide to a pressure between 1000 psi and 1300 psi to form a supercritical carbon dioxide fluid;exposing said cannabis to said supercritical carbon dioxide fluid at a temperature between 80° F. and 110° F. for an elapsed time between 15 minutes and 6 hours to obtain a carbon dioxide extraction solution consisting essentially of said terpene oil and residual cannabis; obtaining cannabis oil from said residual cannabis; distilling said cannabis oil to obtain cannabinoid distillates;separating said cannabinoid distillates into purified cannabinoid distillates and residual contaminants separately; wherein said separating said cannabinoid distillates into purified cannabinoid distillates and residual contaminants separately consists essentially of mixing said cannabinoid distillates with at least a contaminant attractant consisting essentially of a hydrophilic compound to yield a cannabinoid contaminant attractant water solution consisting essentially of: adding said contaminant attractant to said cannabinoid distillates at a ratio between 2:1 and 4:1 of said contaminant attractant by volume in mL to cannabinoid distillates by mass in grams, to yield a cannabinoid contaminant attractant solution;heating said cannabinoid contaminant attractant solution to a temperature between 40° C. and 80° C. to yield a dissolved cannabinoid contaminant attractant solution;adding distilled water to said dissolved cannabinoid contaminant attractant solution at a ratio between 1:4 and 1:10 of distilled water by volume in mL to cannabinoid distillates by mass in grams, to yield said cannabinoid contaminant attractant water solution; and,heating said cannabinoid contaminant attractant water solution to a temperature between 40° C. and 60° C.separating said cannabinoid contaminant attractant water solution into a purified cannabinoid contaminant attractant water solution and said residual contaminants separately; and,removing said contaminant attractant and said water from said purified cannabinoid contaminant water solution to yield said purified cannabinoid distillates; and,blending said purified cannabinoid distillates with said terpene oil to obtain a terpene oil enhanced cannabinoid concentrate.
  • 2. The method of claim 1 wherein said allowing said one or more contaminants to settle out of said cannabinoid contaminant attractant water solution consists essentially of cooling said cannabinoid contaminant attractant water solution to a temperature between −30° C. and 10° C., yielding a cooled cannabinoid contaminant attractant water solution; and,allowing said one or more contaminants to settle out of said cooled cannabinoid contaminant attractant water solution for a period of time between 2 hours and 7 days.
  • 3. The method of claim 1 further consisting essentially of: freezing said residual cannabis to obtain a frozen cannabis; washing said frozen cannabis with cold ethanol to obtain an ethanol oil solution of cannabis; separating said ethanol oil solution of cannabis into ethanol and said cannabis oil separately;said separating said ethanol oil solution of cannabis into ethanol and cannabis oil separately consists essentially of distilling said ethanol oil solution of cannabis at a temperature between 120° F. and 165° F. under a vacuum measuring between 10 inches Hg and 25 inches Hg.
  • 4. The method of claim 3 further consisting essentially of reusing said ethanol for a subsequent washing step of a second batch of frozen cannabis.
  • 5. The method of claim 1 wherein said distilling said cannabis oil to obtain cannabinoid distillates consists essentially of generating a vacuum in a distillation vessel with a pressure at or below 5 torr; heating said cannabis oil to a temperature between 140° C. and 157° C.; collecting a first condensed vapor to yield terpene distillates; heating said cannabis oil to a temperature between 157° C. and 230° C.; and, collecting a second condensed vapor to yield said cannabinoid distillates.
  • 6. The method of claim 1 further consisting essentially of redistilling said purified cannabinoid distillates to obtain a higher concentration of purified cannabinoid distillates; and,blending said higher concentration of purified cannabinoid distillates with said terpene oil to obtain a higher concentration of said terpene oil enhanced cannabinoid concentrate.
  • 7. The method of claim 1, wherein said extracting terpene oil further consists essentially of separating a terpene hydrosol from said carbon dioxide extraction product.
Parent Case Info

This application is a continuation of U.S. Utility patent application Ser. No. 15/937,789 filed 27 Mar. 2018, issued as U.S. Pat. No. 10,092,852, which is a divisional of U.S. Utility patent application Ser. No. 15/688,713 filed 28 Aug. 2017, issued as U.S. Pat. No. 9,956,498, which is a continuation-in-part of U.S. Utility patent application Ser. No. 15/477,668 filed 3 Apr. 2017, issued as U.S. Pat. No. 9,744,200, which is a continuation-in-part of U.S. Utility patent application Ser. No. 15/410,289 filed 19 Jan. 2017, issued as U.S. Pat. No. 9,649,349, the specifications of which are hereby incorporated herein by reference.

US Referenced Citations (2)
Number Name Date Kind
9095555 Winnicki Aug 2015 B2
20160324091 Lewis et al. Nov 2016 A1
Foreign Referenced Citations (1)
Number Date Country
2911168 May 2015 CA
Related Publications (1)
Number Date Country
20190038995 A1 Feb 2019 US
Divisions (1)
Number Date Country
Parent 15688713 Aug 2017 US
Child 15937789 US
Continuations (1)
Number Date Country
Parent 15937789 Mar 2018 US
Child 16154674 US
Continuation in Parts (2)
Number Date Country
Parent 15477668 Apr 2017 US
Child 15688713 US
Parent 15410289 Jan 2017 US
Child 15477668 US