The present general inventive concept relates to handheld piston operated hot melt dispensers, and in particular a handheld cannabis heated press and dispenser for dispensing rosin oil.
Myriad propositions have been made to provide apparatus for heating, melting and dispensing material supplied in the form of a cylindrical rod or slug with or without the use of a piston. Such apparatus usually comprises a melt body having a liquefier chamber in which material is melted, an inlet for the rod or slug and an outlet comprising an orifice or extrusion array element for dispensing melted material, and means for heating the melt body so that composition fed into the melt chamber under force may be dispensed in molten condition from the orifice or extrusion array element. Such apparatus finds use in various fields of application, and is of particular interest in the field of applicators for hot melt adhesives and sealants and especially in hot-melt glue guns having provision for feeding a rod of adhesive to the melt body, for example by a trigger operated means.
The present general inventive concept is concerned with a heated press for melting and dispensing cannabis rosin oil and is more particularly concerned with a hand held gun-type device comprising improved feeding means adapted to feed a piston to apply pressure to cannabis floral material within the melt body.
Rod feeding means employed in hand held hot-melt gun apparatus generally includes a trigger and associated mechanism arranged to grasp a rod of composition to be fed, and to advance it towards the melt chamber. It is a general practice to provide an inlet sheath of durable material at the entrance to the melt chamber which is intended to assist in guiding the composition into the melt chamber and also to grasp the surface of the composition as it is fed into the melt chamber and to minimize the flow of melted material from the melt chamber inlet. For example, there is described in GB Patent Specification No. 1402648 a hand held hot-melt glue gun having feeding means for feeding a cylindrical rod of hot melt material in solid form through an inlet sheath into a melt body, under the control of an operator, in which the feeding means comprises a carriage mounted in such a way to permit movement towards and away from the melt body, a clamping element pivotally mounted on the carriage and a trigger connected to the clamp element by connecting means and arranged to be actuated by the operator to pivot the clamp element into engagement with the cylindrical rod of hot-melt supported by the carriage to grasp the rod and, on added pressure on the trigger by the operator, to controllably feed the rod into the melt chamber. The clamping means comprises a blade element by which the rod is engaged in the operation of the feeding means to feed the rod into the melt chamber.
The feeding means described in GB No. 1402648 is effective to feed cylindrical rod adhesive through the inlet sheath and into the melt chamber. However when excessive pressure is exerted on the trigger, the blade element may tend to indent or otherwise deform the rod. Deformation of the rod in many cases is not generally deleterious to effective operation of melt guns, however, this deformation could be detrimental to a piston, for example, causing excessive wear or even failure. The problem of outflow of melted material from the inlet of a melt chamber has been recognized previously and various means have been proposed to ameliorate the problem. One proposed solution involves use of an inlet sheath of durable material having internal lip means which are expanded by passage of the rod so as to grasp the outer surfaces of the rod. However, severe deformation of the rod surfaces renders it impossible to rely upon the inlet sheath to provide a sufficient seal on remaining rod entering the melt chamber to exclude the possibility of melted material being forced between the inlet sheath and the rod.
Another known disadvantage associated with currently available hand operated hot-melt guns, with or without a piston, has been that a comparatively large application force is required to maintain the grasping of the rod or piston whilst the carriage and clamp are moved forwards toward the melt chamber. Not only may this accentuate the disadvantage of deforming the rod or piston but also may give rise to control challenges and operator fatigue.
Among the several objects of the present general inventive concept are to provide an improved piston grasping and feeding means.
The invention provides in one of its aspects a hand held gun-type cannabis rosin oil press comprising a melt body having a melt chamber and feeding means for feeding a piston against cannabis floral material in solid form, the feeding means comprising clamping means comprising a carriage mounted for sliding movement towards and away from the melt body and having a shaped portion shaped to accept a piston to be fed to the melt body, a clamp element pivotally mounted on the carriage and having a clamping arm portion disposed along the direction in which the carriage is arranged to move and a crank arm portion having an operating portion arranged to co-operate with pressure means of pivotally mounted connecting means in response to operation of a trigger of the gun whereby upon operation of the trigger the clamp element may be caused to pivot into engagement with a piston in the carriage to grasp the piston against said shaped portion and on continued operation of the trigger the clamp element may be caused to move with the carriage to feed the piston towards the melt chamber applying force on the cannabis material, the operating portion of the crank arm having a convex surface and being so disposed that an acute angle between a plane which includes a line of contact between the convex surface and the pressure means and a plane which includes the direction in which the carriage is arranged to move is increased as the clamp element is pivoted to grasp the piston whereby to increase a component of force applied in the direction in which the carriage is arranged to move.
The invention provides in another of its aspects a handheld gun-type cannabis rosin oil press comprising a melt body having a melt chamber and feeding means for feeding a piston against cannabis floral material in solid form, the feeding means comprising clamping means comprising a carriage mounted for sliding movement towards and away from the melt body and having a shaped portion shaped to accept a piston to be fed to the melt body, a clamp element pivotally mounted on the carriage and having a clamping arm portion disposed along the direction in which the carriage is arranged to move and a crank arm portion having an operating portion arranged to cooperate with pressure means of pivotally mounted connecting means in response to operation of a trigger of the gun whereby upon operation of the trigger the clamp element may be caused to pivot into engagement with a piston in the carriage to grasp the piston against said shaped portion and on continued operation of the trigger the clamp element may be caused to move with the carriage to feed the piston towards the melt chamber applying force on the cannabis material, the operating portion of the crank arm having a convex surface and being so disposed that prior to operation of the trigger means the line of contact between the convex portion and the pressure means lies to the rear (in the direction in which the carriage is arranged to move) of a plane P including the axis of rotation of the clamp element on the carriage and which is normal to the direction in which the carriage is arranged to move and that after the piston has been grasped the line of contact between the convex portion and the pressure means lies before said plane in the direction in which the carriage is arranged to move.
The invention provides in another of its aspects a handheld gun-type cannabis rosin oil press comprising a melt body having a melt chamber and feeding means for feeding a piston into the melt body against cannabis floral material in solid form, under the control of an operator into the melt chamber, the feeding means comprising clamping means comprising a carriage mounted for sliding movement towards and away from the melt body and having a shaped portion shaped to accept a piston to be fed to the melt body, a clamp element pivotally mounted on the carriage and a trigger connected with the clamp element by connecting means and arranged to be operated by the operator to pivot the clamp element into engagement with a piston in the carriage to grasp the piston against said shaped portion and, on continued pressure on the trigger by the operator, to move the clamp element towards the melt chamber thus to feed the piston into the melt chamber applying force on the cannabis material, the clamp element comprising a clamping arm portion in the form of a rack providing several blade portions arranged transversely of the direction in which the carriage is arranged to move.
A preferred embodiment of a handheld gun-type cannabis rosin oil press according to the present general inventive concept is hereinafter described by way of example to illustrate the present general inventive concept. This illustrative gun comprises a melt body having a melt chamber and feeding means according to the present general inventive concept for feeding a piston into the melt body against cannabis floral material in solid form. The feeding means includes clamping means comprising a carriage mounted for sliding movement towards and away from the melt body and having a shaped portion shaped as a curved portion to accept a piston to be fed to the melt body, and a clamp element pivotally mounted on the carriage and having a clamping arm portion disposed along the direction in which the carriage is arranged to move. The clamping arm portion is in the form of a curved element having a piston engaging surface. The piston engaging surface of the illustrative gun has several blade portions arranged transversely of the direction in which the carriage is arranged to move. The blade portions are arranged so that two or more thereof may engage the piston to grasp it against the shaped portion. The clamp element also comprises a crank arm portion having an operating portion in the form of a cam lobe arranged to cooperate with a cam surface of a lever which provides pressure means of pivotally mounted connecting means in response to operation of a trigger of the gun. Upon operation of the trigger the clamp element is caused to pivot into engagement with a piston in the carriage to grasp the piston against said shaped portion and on continued operation of the trigger the clamp element is caused to move with the carriage to feed the piston towards the melt chamber applying pressure to the cannabis material. The cam lobe of the crank arm has a convex surface so disposed that an acute angle between a plane which includes a line of contact between the convex surface and the cam surface and a plane which includes the direction in which the carriage is arranged to move is increased as the clamp element is pivoted to grasp the piston. The cam lobe is also so disposed that prior to operation of the trigger means the line of contact between the convex surface and the cam surface lies to the rear (in the direction in which the carriage is arranged to move) of a plane including the axis of rotation of the clamp element on the carriage and which is normal to the direction in which the carriage is arranged to move and that after the piston has been grasped the line of contact between the convex portion and the pressure means lies before said plane in the direction in which the carriage is arranged to move.
In the illustrative gun, the clamp element comprises stabilizing pins located to cooperate with recesses in portions of the carriage located in front of the pivotal mounting of the clamp element (in the direction in which the carriage is arranged to move) as the carriage is moved towards the melt chamber, and to limit the extent of pivotal movement of the clamp element.
In the illustrative gun the trigger is slidably mounted in body portions of the gun and arranged to operate the connecting lever to move the clamp element to grasp and feed a piston against the recoil action of a spring. The connecting lever carries a roll 206 trapped in a curved slot, so that the pressure exerted to rotate the connecting lever is varied with increased feeding movement of the trigger.
In the illustrative gun a resilient sheath is mounted at the entrance to the melt chamber which is arranged to be expanded by a piston as it is fed into the melt chamber.
In the illustrative gun, a resilient mouthpiece is mounted on body portions of the gun through which a piston may be supplied to the feeding means.
The body of the illustrative gun comprises two parts of robust polymer material secured together with screws or the like to provide a gun assembly for use in the hand of an operator.
By imparting curvature to the piston engaging surface of the clamping arm portion of the gun according to the present general inventive concept it is possible to grasp satisfactorily pistons of various dimensions, e.g., lengths, and by arranging that two or more blade portions on the piston engaging surface of the clamping arm portion may engage the piston during grasping, substantial deformation of the piston may be minimized. Thus the risk that the seal between the flexible inlet sheath to the melt chamber and the piston may be rendered ineffective to prevent blowback of melted cannabis material from the melt chamber under pressure of the advancing piston is virtually eliminated. Also, due to the shape of a cam surface of the crank arm portion, and its disposition with respect to the direction in which the carriage is arranged to move and with respect to the axis about which the clamp element is arranged to pivot, the effort applied to the trigger during a feeding stroke of the carriage is applied (after initial grasping has been accomplished) primarily in the direction in which the carriage is arranged to move. Preferably the axis about which the clamp element is arranged to pivot is also positioned sufficiently close to the surface of a piston to be fed that the force transfer occurs in such a way that the clamping force for the piston is not directly affected by pressure on the trigger but rather by self clamping i.e. increasing self-clamping with increasing trigger force. In this way, excessive deformation of the piston is avoided, and the effort required to effect feeding of the piston is applied principally to movement of the carriage thus providing for convenient operation and improved trigger control.
Thus, a gun-type cannabis rosin oil press having feeding means according to the present generally inventive concept can be used with advantage to feed a piston into a melting chamber of high capacity containing cannabis floral material in solid form in a rapid and reliable manner without severely deforming the surface of the piston. This is of considerable importance in relation to handheld melt guns where the strength of applied trigger force varies from operator to operator and may be large in relation to melt guns which are designed to accept floral material with considerable size tolerances.
There now follows a description to be read with the accompanying drawings of the illustrative gun-type cannabis rosin oil press. It is to be clearly understood that this embodiment has been selected for description by way of example to illustrate the present general inventive concept and is not by way of limitation thereof.
The illustrative gun-type cannabis rosin oil press is intended for use with pistons of circular cross-section and comprises a gun body having two parts 10, 12; the part 12 of the body is broken away in
The melt body 16 is constructed of a heat conductive alloy and is formed with a generally cylindrical melt chamber 17 (
The melt body comprises three housings 39 each having a tunnel bore having an axis parallel to the axis of the melt chamber 17 for receiving electrically operated resistive heating means in the form of cylindrical self-regulating heaters 45 (
The melt body has a threaded bore 47 coaxial with the melt chamber into which the extrusion element 18 is threaded. The extrusion element 18 contains a spring loaded ball valve (not shown) which is arranged to be opened by pressure of extracted material when the piston 54 is fed into the melt chamber.
An outer surface of the melt body at the inlet is formed to provide a tube 25 onto which a flexible inlet sheath 22 is secured (
A locating ring 19 of resilient heat resistant material encircles a forward portion of the melt body adjacent the extrusion element and is received in co-operating recesses formed in the body portions 10 and 12. The sleeve 26 is formed with a locating ring 27 which is received in co-operating grooves formed in the body portions 10 and 12. The melt body is thus mounted in the body portions 10 and 12 at its outlet and inlet ends by means of the rings 19 and 27 and at a mid-portion by means of the bosses 55.
A resilient mouthpiece in the form of a guide collar 30 is mounted in the body of the gun at the rear and has a guide opening therethrough coaxial with the melt chamber to guide a piston and maintain the piston properly aligned with the melt chamber as it is supplied to the feeding means. The inlet sheath 22, guide collar 30 and ring 19 are conveniently made of silicone rubber, for example.
The parts 10, 12 of the gun body are molded of robust polymer material. The two parts 10, 12 of the body are secured together by fastenings included screws or the like (not shown).
The feeding means 14 (
The carriage 42 comprises an upstanding part 110 having a guide aperture 58 through which the piston 54 passes with a small clearance, as it is fed to the melt chamber. The piston 54 is thus supported by the upstanding part 110.
The clamp element 48 has a clamping arm portion 71, extending generally in the direction of the piston feed by which the piston may be engaged in the operation of the feeding means to feed the piston 54 into the melt chamber 17 applying pressure to the cannabis floral material contained therein. In order for the clamping element to adequately grasp the piston 54 without creating indentations on the piston's surface as it is fed even under substantial trigger force and despite variations in diameter of the piston 54, and thus to minimize the risk that the seal between the flexible inlet sheath 22 and the piston 54 be rendered ineffective to prevent blow back of extracted material from the melt chamber 17 under pressure of the advancing piston 54, a piston engaging surface of the clamping arm portion has a somewhat arcuate configuration. The surface is serrated in order to enhance grasping of the piston, the serrations taking the form of several blade portions 72 disposed transversely of the direction of piston feed. These are arranged so that one or more and preferably not less than two may engage the piston 54 during feeding. The piston engaging surface is located so that on operation of the trigger at least two of its blade portions are swung into contact with the piston, even though the piston 54 may be under or oversized compared with the optimal diameter piston.
The clamp element 48 is provided by a casting having pivot pins 60, by which the clamp element is pivotally mounted in the carriage 42, and stabilizing pins 61 located for movement heightwise in guideways 63 in the carriage to an extent limited by slotted surfaces of the guideways. The pivot pins are located at an upper, rearward portion of the clamp element 48. The clamp element is provided with a crank arm 70 having an operating portion in the form of a cam lobe 49 having a convex curved surface 64 located below the pivot pins as viewed in
The lever 52 is mounted on a dowel 53 formed in the part 10 of the gun body for pivotal movement about the dowel. An upper end portion of the lever is formed as a cylindrical cam surface 202 arranged to provide pressure means to co-operate with the cam lobe 49. A lower end portion of the lever is provided with a roller bearing 206 received in a curved slot 208 formed in a rearward portion of the trigger 50 arranged so that pressure exerted to rotate the connecting lever 52 is varied with increased travel of the trigger during a feeding movement. In the rest position shown in
The trigger 50 is formed with flanges 210 received in slideways 212 formed in the body parts 10, 12. The trigger and lever are so arranged as to facilitate entry of the roller bearing 206 into the open end of the slot 208 during assembly without risk of disassembly when the apparatus is in use. The trigger 50 is molded of a stiff robust polymer material. The trigger 50 has a pressure plate 98 arranged to be contacted by the finger of an operator to operate the trigger 50. The extent of movement of the trigger is restricted by engagement of the pressure plate 98 with the gun body and by engagement of a stop element also molded integrally with the trigger 50, with the parts 10, 12 of the gun body.
The trigger 50 is arranged to be operated by the operator to pivot the clamp element 48 about the pivot pins 60 to bring blade portions 72 into engagement with the piston 54 supported by the carriage 42, inlet sheath 22, and guide collar 30 to grasp the piston 54 and, with further pressure on the trigger 50 by the operator, to feed the piston 54 into the melt chamber.
Viewing
The feeding means 14 comprises a spring 56 extending between an elongated slot in the clamp element 48 and the lever pivot 53, by which the clamp element 48 is biased in a counter clockwise direction as viewed in
The feeding means 14 comprising the carriage 42, clamp element 48, lever 52, trigger 50, and spring 56 are constructed such that they can all be assembled to one another and into the parts 10, 12 of the gun body without further equipment or fastening means. The feeding means 14 has been designed to have as few parts as possible and to be assembled reliably and simply in such a way that when the parts 10, 12 of the gun body are secured together the feeding means remains securely assembled. Each of the pivot pins 60 has two arcuate coaxial bearing portions 62 and two parallel flat faces 79 at opposite sides of the pin 60 (
The feeding means 14 can be assembled simply: the trigger 50 is assembled with the lever 52, and assembled to the body part 10. The clamp element 48 is assembled with the carriage 42 by introduction of the pivot pins 60 into the bearing openings 66, and the carriage is mounted with flanges 44 in the slideways 46 of the body part 10. The spring 56 is assembled with the clamp element and the peg 53. When the feeding means 14 is assembled, the carriage 42 will be urged by the spring 56 to a rear-most position along the slideway 46 and the clamp element 48 will be urged in a counter-clockwise direction, so that the blade portions 72 are lowered with respect to the carriage and the trigger will be urged to an outward position. The stop element will engage the part 10 of the body, preventing further clock-wise movement of the lever (viewing
When the trigger is moved rearwardly of the gun by pressure on the pressure plate 98, the lever 52 is caused to pivot about the dowel 53 and to bring about pivotal movement of the clamp element on the carriage and sliding movement of the carriage as described above. Maximum travel of the trigger means is governed by contact of the pressure plate 98 with the body parts 10, 12, in which condition the upstanding part 110 of the carriage 42 is adjacent an inlet end of the inlet sheath 22. When the trigger 50 is released the blade portions are disengaged from the piston and the piston is released from the upstanding part 110 of the carriage 42. The piston 54 is restrained against movement rearwardly by the collar 30 and inlet sheath 22. The carriage 42 slides rearwardly under the pressure of the spring 56 to an extent determined by engagement of the stop element with the body part 10, 12 the carriage sliding relative to the piston 54 so that on a subsequent operation of the trigger 50 a fresh part of the piston 54 is grasped by the blade portions 72 and upstanding part 110 of the carriage 42. As the piston 54 is urged into the melt chamber 17 by the feeding means 14, heat supplied to the melt body 16 by the heating element melts the trichome heads of the cannabis floral material and the extracted material is dispensed through the extrusion element 18 under pressure applied by the feeding means 14 to the piston 54. Relaxation of pressure on the trigger 50 stops feed of piston 54 into the melt chamber 17 and thus extracted material ceases to be dispensed through the extrusion element 18.
The illustrative apparatus comprises electrical circuitry for connecting the heaters to a source of electricity.
When it is desired to use the illustrative apparatus, the circuitry is connected to an electrical power source, e.g., wall outlet, and a piston 54 of circular section may be pushed into the apparatus through the guide collar 30, between the upstanding part 110 and the clamp element 48, into the inlet sheath 22, where it is grasped by the distended lip 32 of the inlet sheath 22, and into the inlet of the melt chamber. Operation of the trigger when cannabis floral material in the melt chamber 17 is heated brings about feeding of the piston as aforesaid. As the piston 54 is fed into the melt chamber 17, the cannabis rosin oil is softened and melted, leaving a substantially cone-like solid residue which during continued feeding is forced onto the inner edge surfaces of the fin elements. Thus, the melt chamber walls and the fin elements transfer heat to the cannabis floral material. As the piston 54 is progressively fed into the melt chamber 17, it serves to force heat softened or extracted material before it between the fin elements and through the slots of the outlet and ultimately from the extrusion element.
The above described embodiments are set forth by way of example and are not for the purpose of limiting the scope of the present general inventive concept. It will be readily apparent that obvious modifications, derivations and variations can be made to the embodiments without departing from the scope of the invention. Accordingly, the claims appended hereto should be read in their full scope including any such modifications, derivations and variations.
Number | Date | Country | |
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62747200 | Oct 2018 | US |