US3670516A - Machine for making dry ice pellets - Google Patents

Machine for making dry ice pellets Download PDF

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US3670516A
US3670516A US10552A US3670516DA US3670516A US 3670516 A US3670516 A US 3670516A US 10552 A US10552 A US 10552A US 3670516D A US3670516D A US 3670516DA US 3670516 A US3670516 A US 3670516A
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snow
die
ring
horn
specified
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US10552A
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Paul P Duron
Harold T Rich
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Airco Inc
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Air Reduction Co Inc
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B30PRESSES
    • B30BPRESSES IN GENERAL
    • B30B11/00Presses specially adapted for forming shaped articles from material in particulate or plastic state, e.g. briquetting presses, tabletting presses
    • B30B11/20Roller-and-ring machines, i.e. with roller disposed within a ring and co-operating with the inner surface of the ring
    • B30B11/201Roller-and-ring machines, i.e. with roller disposed within a ring and co-operating with the inner surface of the ring for extruding material
    • CCHEMISTRY; METALLURGY
    • C01INORGANIC CHEMISTRY
    • C01BNON-METALLIC ELEMENTS; COMPOUNDS THEREOF; METALLOIDS OR COMPOUNDS THEREOF NOT COVERED BY SUBCLASS C01C
    • C01B32/00Carbon; Compounds thereof
    • C01B32/50Carbon dioxide
    • C01B32/55Solidifying

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  • PATENTEnJux 20 1912 3. 670,5 1 6 sum 1 or a /N I/E N 7095 PA UL R DURON By HARO 0 .R/CH
  • the invention relates to the production of high density carbon dioxide (CO ice, especially to production of the ice in small sticks or pellets for convenient and efficient flowhandling, ice packing for refrigerating food containers, etc., and general packaging and distribution.
  • a known method of making CO ice in moderate size pieces, as distinguished from block ice comprises feeding CO liquid to a cylinder where it is flashed to form CO snow. The snow is then compressed by a piston or ram into a disc-like dry ice cake against a releasing gate or the like at the compression end of the cylinder.
  • a practical disadvantage moreover, of most of the prior art ice machines is that the production process is cyclic, i.e. there is a periodic pause for recharging, etc., during which the output of the machine is either nil or greatly reduced.
  • the present invention is directed to overcoming the problems involved in the continuous production of high density CO ice pellets by extruding press equipment and thereby increasing the rate of pellet production.
  • CO- in liquid form is flashed by conventional snow-horn means or the like, into snow, and the snow is deposited in a rotary-type extruder that consists of a fixed ring die and a centrally pivoted carrier with coacting rotary extruder elements.
  • the extruder elements may take the form of either cylinder-like rolls or gear pinions that are caused suc cessively to traverse draw-hole openings around the inner periphery of the ring die.
  • the ring die constitutes an internal ring gear with draw holes in and between the teeth extending from the inner periphery radially through the ring.
  • the gear pinions are mounted at diametrically opposite positions on the carrier within the ring gear for continuous meshing therewith in planetary motion so that the draw holes around the ring periphery come into successive alignment with the rotating pinions.
  • the flashed snow as it collects in the extruding region of the ring die is entrained by the pinions, compressed between the meshing gear teeth and extruded through the draw holes as CO: or dry ice" pellets in a continuous extrusion process.
  • the ring die surface at the inner periphery is circular and includes openings for the radial draw holes.
  • a principal object of the invention therefore is to provide an improved extruding machine of the rotary type that is capable of quantity production of dry ice pellets in a continuous noncyclic operation.
  • Another and related object of the invention is to provide improved extruding apparatus having a ring die with internal planetary type rotating extruder elements, that is efficient and positive in its operation, readily adaptable for receiving the output of conventional CO, snow-making equipment for continuous production of dry ice pellets, and that is simple, rugged and inexpensive in construction and economical in operation.
  • FIG. 1 is an elevational view, mainly in section, of a rotary extruder embodying the invention for making CO ice pellets;
  • FIG. 2 is an enlarged plan view, partly in section, of rotary extruding equipment shown generally in FIG. 1;
  • FIG. 3 is a cross-sectional view taken along the line 3-3 of FIG. 2;
  • FIG. 4 is an elevational view, partly in section, of a modified form of the rotary extruder
  • FIG. 5 is an exploded view of the coacting extruder elements of FIG. 4.
  • FIG. 6 is a sectional view similar to FIG. 4, illustrating a variation thereof.
  • the essential combination of the CO, ice pellet making machine of the invention consists of a suitable source of liquid CO generally indicated by a supply line manifold 10, a snow horn 12 or equivalent, within which liquid CO is flashed in conventional manner into snow, a rotary extruder with ring die at 14 for receiving the snow and converting it into high density ice pellets, the extruder having an exhaust chute 16 for directing the ice pellets into a container, storage bin or the like, a main drive shaft 18 for the rotating unit of the extruder, and an operating motor M connected through a suitable transmission system to the drive shaft.
  • a suitable source of liquid CO generally indicated by a supply line manifold 10, a snow horn 12 or equivalent, within which liquid CO is flashed in conventional manner into snow, a rotary extruder with ring die at 14 for receiving the snow and converting it into high density ice pellets, the extruder having an exhaust chute 16 for directing the ice pellets into a container, storage bin or the like, a main drive shaft
  • the pressurized liquid CO from the supply at 10 is continuously fed through conventional snow horn precooling coils 35 to the throat of the snow horn 12 that has a standard orifice-controlled discharge nozzle 22.
  • the liquid C0 is fed from the cooling coils to the discharge nozzle through a liquid receiving manifold 19, feed line 20 and noule coupling 21.
  • the CO liquid is for the most part flashed as indicated at 23 into snow, the remainder being cold CO gas.
  • a cylindrical metal housing 26 made of stainless steel for example, encloses the snow horn and forms a so-called snow chamber 28 for collecting both the snow and excess gas.
  • This housing has a cover 24 in which the coupling 21 is mounted for conveniently supporting the throat or inlet end of the horn 12.
  • the divergent or exhaust end of the horn is supported by peripherally spaced resilient struts 13 that are connected to the lower inner wall of the cylinder 26.
  • the cylindrical housing 26 itself is mounted above the extruder 14 that in turn, is supported by a centrally positioned tube-like bearing housing 27 for the drive shaft 18, and also at its outer periphery by the main base housing H as further described below.
  • the function of the snow chamber 28 also includes the collection of excess CO, gas apart from the snow, for removal by venting for precooling purposes.
  • the gas in chamber 28 (which is under positive gauge pressure in the normal operation of the snow horn) flows into a venting line 30 at the top of the chamber, and into a gas manifold 32. From the manifold the cold gas is suitably directed to heat-transfer coils 34 that encircle the cylinder 26 for cooling the snow chamber and for subcooling the incoming liquid, thereby improving subsequent flashing efiiciency of the snow horn. Afier passage through the cooling coils 34, the gas is vented at 36 to an exterior recovery line for ultimate recycling in known manner as liquid CO
  • the cylindrical housing for the snow chamber is provided with an outer insulating jacket or housing indicated at 38.
  • the extruder consists essentially of rotary extruder elements mounted on a central rotating carrier 40, FIG. 2, and a complementary fixed extruding die 44.
  • the die in the form of the invention shown by FIG. 1 constitutes an internal ring gear within which the carrier is concentrically pivoted.
  • the carrier is keyed at 42 to the drive shaft 18 for rotation therewith, and has mounted thereon at opposite ends two gear pinions 46 and 48 that have planetary motion within the ring gear.
  • the diametrically positioned pinions continually mesh with the internal teeth 50 of the ring gear as the carrier is rotated.
  • the ring gear in turn has at least two extruding die passages or draw-holes 52 and 54 per tooth pitch throughout the circumference of the ring die depending on the transverse width of the teeth and draw-hole diameters, i.e., there is a minimum of twice as many draw-holes as teeth in the extruding die.
  • the number of draw-holes can be increased according to the transverse length of the extruding teeth as shown in FIG. 3. Specifically the draw-holes extend along radial lines transversely through the ring of the die, a draw-hole 52 extending from the top of a respective tooth 50, and the adjacent draw'hole 54 extending from the foot line between the tooth and a following tooth, FIG. 2.
  • each such pair of draw-holes is within a span corresponding in length to a tooth pitch.
  • the entrance end of each draw-hole is counter-bored as shown at 52 for the draw-holes 52, and at 54 for the draw-holes 54.
  • the gear pinions 46 and 48 have the same tooth pitch as the ring gear, and are symmetrically positioned at opposite ends of the pivoted carrier 40 for continuous and precise meshing with the die teeth 50. Assuming clockwise rotation of the carrier as viewed in FIG. 2, the respective pinion teeth 56 and 58 engage the fixed die teeth 50 to cause counterclockwise rotation of the pinion gears.
  • the mating tolerance or limit of backlash of the engaging gear teeth is approximately 0.0l to 0.015 in. so that positive and continuous rolling contact is for practical purposes, established between the coacting gear teeth surfaces.
  • the collected CO tends to settle within the ring, FIG. I, where it is first entrained by the gear pinions as the rotating carrier sweeps the circular area.
  • the snow is tightly compressed as it is progressively forced into the respective valleys" between the pinion teeth and the die teeth.
  • the snow is further compressed into ice and finally forced into a respective draw-hole, as for example a draw-hole 52, during coincidence of the radial axis of the draw hole and the line of centers of the ring die and the corresponding pinion respectively.
  • the cylindrical extrusions consist of high-density CO ice that can readily be broken into short pellets for convenient handline.
  • the ice exhaust chute 16, FIG. 1 can be formed as an annular baffle plate that is inclined at a suitable angle with respect to the draw hole outlets for causing the extruded ice cylinders to break up into small lengths as they meet the baffle, as indicated at 60.
  • the draw holes were made for onefourth in. diameter pellets, and the ring die was sufficiently wide (transverse direction) for accommodating transverse rows of six draw-holes, FIGS. 1 and 3, thereby providing a total of 12 draw-holes per tooth pitch of the ring die.
  • the number of draw-holes for increasing the production of pellets can be increased by increasing the transverse dimensions of the ring die and pinion gears respectively; also, it will be apparent that the tooth height and the ratios of tooth pitch circumference indicated in the drawings are for purposes of illustration only. According to extrusion stresses, depending on rate of production and other mechanical factors, the gear teeth can be strengthened as required by increasing the tooth base width (and hence the tooth pitch) for a given tooth height, or, simply by reducing the tooth height.
  • the extruder 14 as described above, is suitably mounted in a generally vertical arrangement between the snow chamber 28 and the main base housing H.
  • the ring die 44 is bolted at 62 between an annular retaining ring 64 (on which is mounted the upper cylindrical housing 26 for the snow chamber) and a fixed die supporting plate 66.
  • This plate is in turn centrally positioned by and bolted at 68 to the upper part of the cylindrical bearing housing 27 for the drive shaft.
  • the housing 27 has secured thereto at its upper end an annular bearing support 70 to which the die plate 66 is bolted in centered relationship.
  • a main bearing 72 of standard type for the shaft journal is mounted within the support 70.
  • the carrier 40 consists of a central hub 74 (that is keyed as mentioned above to the upper end of the drive shaft at 42) and a pair of parallel spaced arms 76 and 78 that are integrally secured to the hub and extend equal distances therefrom for diametrically positioning the gear pinions 46 and 48 with respect to the ring die 44.
  • the corresponding ends of the arms at diametrically spaced points on the pinion carrier are provided with aligned holes at 80, 81 and at 82, 83, in which are mounted tightly fitted bushings 84 and 85 for positioning the pinions 46 and 48 respectively.
  • Suitable heavy duty bearings 86 and 88 respectively, FIG. 3, are positioned between the bushings and the bearing surfaces of the corresponding pinions.
  • the dry ice pellets are extruded at the ring die generally as described above, except that extrusion is achieved by relatively movable portions of substantially cylindrical surfaces, rather than by meshing gears.
  • the inner periphery of the ring die 44a has a generally circular or cylinder-like contour with closely spaced draw holes 45 throughout.
  • the hole openings each have a counter-sink 45a which overlap, so that the die entrance 50a has a hexagonal or honey-comb appearance as indicated in FIG. 5.
  • the coacting rotary extruder elements constitute cylinders or rolls 46a and 48a that can be mounted within the carrier 40 in the same manner as the pinions 46 and 48.
  • each roll has at its upper edge gear teeth 47 for meshing with aligned corresponding teeth 49 on thering die, thereby obtaining uniform rotation in relation to carrier rotation.
  • the coacting roll and die surfaces are preferably spaced for slight tolerance, rather than in metal-to-metal contact. The snow as it settles into the die is entrained by the advancing rolls, compressed, and forced into the draw holes for extrusion, generally as described above.
  • FIG. 6 illustrates a rugged and simple form of roll-type extruder wherein the rolls 46b and 48b are idler-mounted on the carrier for free rotation with respect to the ring die 44b.
  • snow or ice may tend to accumulate or ball" on the upper side flat surfaces of the rolls or pinions near the periphery. This is readily prevented by extending at 90 the inner edge of the upper die retaining ring 64 in overhanging relation to the roll or pinion as indicated in FIGS. 1 and 3 for scraping clear such accumulations as the carrier rotates beneath. Also, the tendency of snow from the horn 12 to settle in the hub areas of the pinion carrier rather than outwardly toward the ring die can be at least partly offset by deflecting slightly the longitudinal axis or center line 12 of the horn with respect to the carrier axis of rotation 14.
  • a mechanical horn vibrator operable by the drive shaft may consist of a star-wheel, or as shown, a disc 92 having peripherally spaced pegs 94, secured to the end of the drive shaft.
  • a spring steel strip 96, FIG. 1, secured at 98 to the snow chamber housing 26 extends laterally over the pinion carrier so that the free end of the strip tends to position itself a short distance within the peg circle.
  • the spring strip has a transverse vertical extension 100 with a notched portion 102 at its upper end that is positioned next to the lower edge of the horn.
  • the snow from the symmetrically positioned horn is deflected and distributed generally in a radial direction toward the ring die by a cone 104 that is centered beneath the horn and seated on the carrier.
  • a leveler strip 106 is connected to the cylinder 26 at 107 so as to extend above and across the dished inner edge of the retaining ring 64, FIGS. 2 and 3, and the annular region at the die entrance. This region which is open (except for the carrier) therefore receives uniform snow feed as leveling proceeds.
  • the entire upper assembly unit including the horn and cylinder 26 can be vibrated by mounting an electric vibrator of conventional type on the side wall of housing 38 for example, as indicated at 105, FIGS. 1 and 4, thereby freeing the horn of sticking snow, as well as causing piled-up low mass snow at the bottom of the snow chamber to settle evenly around the base of the cone. This insures more uniform feed by the leveler 106 into the extruder.
  • the unit vibrator 105 may if desired also be used along with the horn vibrator arrangement of FIG. 1.
  • the motive means for rotating the drive shaft 18 is not limited to any specific arrangement.
  • an electric motor M vertically mounted at the base of the machine is connected through its shaft pulley 108 and belt-drive transmission 110 to a large diameter drive pulley 112 operatively connected to the lower end of the drive shah.
  • the hub 114 of the drive pulley has a free fit on a centering bushing 116 that in turn is keyed to the lower end of the drive shaft at 1 18.
  • the drive connection between the power pulley 112 and the drive shaft 18 (at the keyed bushing 116) includes a springloaded clutch 120 of conventional type having a clutch disc 122 splined to the bushing 116 for engagement with the mating clutch surface 123 of the pulley l 12.
  • the drive shaft has a second main bearing 124 that is suitably mounted within the cylindrical bearing housing 27 at its lower end.
  • the lower end of the drive shaft may be supported if desired by a vertical thrust bearing (not shown) suitably mounted in a structural steel base on which the main base enclosing housing H is fastened.
  • a carbon dioxide pellet machine for producing carbon dioxide ice pellets comprising, housing means at least partly defining a snow chamber, carbon dioxide snow generating means at least partly within said snow chamber to direct snow generally vertically downwardly, said snow generating means including nozzle means and means to supply liquid carbon dioxide to said nozzle means under pressure, further means to remove carbon dioxide vapor from said snow chamber, extrusion means at least partly defining the bottom of the snow chamber, said extrusion means including an extruding die formed as a ring, said ring die being horizontally positioned for receiving by vertical gravity feed carbon dioxide snow within the circumscribed ring area said ring die having draw holes extending therethrough around the ring periphery, rotary extruder elements mounted for planetary motion within the ring die for successive traversing of the die draw holes, and power means for driving the rotary elements around the inner periphery of the extruding die for causing snow settling within the ring area to be entrained and compressed between the rotary elements and die, and extruded through the draw holes as ice
  • An ice pellet machine as specified in claim 2 wherein the die is formed as an internal ring gear with the draw hole openings extending from the gear teeth side of the die, and the extruder elements are gear pinions that rotate about the ring gear center in planetary motion and mesh with the die teeth for entraining and extruding snow at the draw holes.
  • each tooth pitch throughout the periphery of the ring gear spans at least two peripherally spaced draw holes.
  • An ice pellet machine as specified in claim 1 wherein liquid carbon dioxide is continuously flashed within a snow horn into said snow chamber, the horn having its exhaust opening opposite and over the extruding die for deposit of snow within the circumscribed ring area of the die.
  • An ice pellet machine as specified in claim 10 wherein the snow horn and extruding die are mounted on common supporting structure and vibrator means is operatively connected to the structure for loosening collected snow within the horn and above the ring die area.
  • An ice pellet machine as specified in claim 10 wherein the horn is engaged by a vibrator operated by the power means, the vibrator including a percussion element for successively engaging the horn for freeing snow sticking to the inner surface thereof.
  • An ice pellet machine as specified in claim 10 wherein the longitudinal axis of the snow horn is deflected by a small angle from the projected axis of rotation of the extruder means for eccentric deposition of snow with respect to the extruder axis.
  • An ice pellet machine as specified in claim 10 wherein a flat ring dished at its inner periphery is mounted above and closely overhangs the inner side of the ring die and the traversing rotary extruder elements for guiding snow thereto, and a radially positioned snow leveler overhangs the dished ring.
  • a dry ice pellet machine comprising, housing meansat least partly defining a snow chamber, carbon dioxide snow generating means at least partly within said chamber to direct snow into an extrusion means, said snow generating means including noule means and means to supply liquid carbon dioxide to said nozzle means under pressure, further means to remove carbon dioxide vapor from said snow chamber, said extrusion means at least partly defining the lower part of the snow chamber, said extrusion means including an annular extruding die positioned to receive the descending snow particles within its annular extent, said die having draw holes extending therethrough around the die periphery, rotary extruder elements mounted on a carrier for planetary motion within the annular die for successive traversing of the die draw holes, and power means for rotating the carrier for driving the rotary elements around the inner periphery of the extruding die for causing snow settling within the die area to be entrained and compressed between the rotary elements and die and extruded through the draw holes as ice pellets.
  • a carbon dioxide pellet machine for producing carbon dioxide ice pellets comprising, housing means at least partly defining a snow chamber, a frusto conical snow horn mounted in said chamber and being substantially vertically arranged with its wider end at the bottom, nozzle means at the upper end of the horn, means'to supply liquid carbon dioxide to said nozzle means, means to remove carbon dioxide vapor from said chamber, extrusion means below said s now horn to receive the snow generated therein, said extrusion means including an extrusion ring die having an inner diameter greater than the diameter of the wider end of the snow horn so that the snow is deposited within the ring die, said ring die having draw holes extending therethrough around the ring periphery, extruder elements mounted within the ring die for successive traversing of the die draw holes, power means for driving the extruder elements for causing snow to be compressed by the extruder elements and extruded through the draw holes as ice pellets.
  • a pellet machine as set forth in claim 21 further including electrically powered means to free the snow horn from sticking snow.

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  • Engineering & Computer Science (AREA)
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  • Chemical Kinetics & Catalysis (AREA)
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Abstract

A dry ice pellet machine having a snow horn for flashing liquid carbon dioxide into snow; an extruding ring die for receiving the snow and consisting of an internal ring gear with radial drawholes in and between the gear teeth around the ring periphery; a concentrically pivoted carrier within the ring die having diametrically positioned gear pinions for planetary movement in meshing engagement with the ring gear, and alternatively, rolls on the carrier for traversing a corresponding surface of the ring die; a drive motor for rotating the carrier and causing collected snow to be entrained and forced by the rolls (meshing gears) into the draw-holes and extruded therefrom as ice pellets.

Description

United States Patent Duron et al. [451 June 20, 1972 [54] MACHINE FOR MAKING DRY ICE 2,200,577 5/ 1940 Lozon ..62/35 PELLETS 2,295,743 8/1942 Meakin..
3,070,967 1/1963 Uren [721 lnvemom Bum", Anahelm; Rich, 3,492,829 2/1970 Standford ..62/35 Fullerton, both of Calif. [73] Assignee: Air Reduction Company, Incorporated, FOREIGN PATENTS OR APPLICATIONS New York, NY. 1,188,462 4/1970 Great Britain ..100/4 [22] Filed: Feb. 11, 1970 Primary mmner Nonnan Yudkofi [211 App], No; 10,552 Assistant Examiner-S. Silverberg Attorney-Edmund W. Bopp and H. Hume Matthews [52] US. Cl. ..62/35, 18/12 RR, l00/DIG. 4, [57] ABSTRACT 107/14 F 51 1 1111. C1. ..B29c 3/00 A dry icepellet {nachine having 8 q q flashing ly 58 Field of Search 18/12 RR; 107/14 F; made ""9 890W; f "P8 f f loo/DIG 62/35 the snow and conslstmg of an lntemal nng gear wlth radlal draw-holes in and between the gear teeth around the ring 56] References Cited peripherx; a concentricallxpivoted carrienwithin the ting die havmg dlametncally posmoned gear p1n1ons for planetary UNITED STATES PATENTS movement in meshing engagement with the ring gear, and alternatively, rolls on the carrier for traversing a corresponding 1,804,283 5/1931 SIZE! ..107/14 F surface of the ring die; a drive motor for rotating the carrier 3,144,840 8/1964 Crane "107/14 F and causing collected snow to be entrained and forced by the 313271653 6/1967 Crane "107/14 F rolls (meshing gears) into the draw-holes and extruded 3,117,343 1 1964 Soars, Jr.. 18/12 RR therefmm asice pallet, 3,307,501 3/1967 Wenger.... .lOO/DIG. 4 3,312,530 4/1967 Sachett IOU/DIG. 4 22 Claims, 6 Drawing Figures M m I 32 2i H 3 3o 20 l 24 l9 T I l 26 f 22 i F-:;
1 1 E21 7 I ZLZ 35- 1,! ,35
PATENTEnJux 20 1912 3. 670,5 1 6 sum 1 or a /N I/E N 7095 PA UL R DURON By HARO 0 .R/CH
AT TORNEV PATENTEDJum i912 SHEET 3 OF 3 FIG. 4 12 26 38 v L|O5 I04 m Hi 40 lqe -}A.c.
49 47 46a 46a l W/M/A INVENTORS PAUL R DURON HAROLD 71 RICH ATTORNEY MACHINE FOR MAKING DRY ICE PELLETS BACKGROUND OF THE INVENTION The invention relates to the production of high density carbon dioxide (CO ice, especially to production of the ice in small sticks or pellets for convenient and efficient flowhandling, ice packing for refrigerating food containers, etc., and general packaging and distribution. A known method of making CO ice in moderate size pieces, as distinguished from block ice, comprises feeding CO liquid to a cylinder where it is flashed to form CO snow. The snow is then compressed by a piston or ram into a disc-like dry ice cake against a releasing gate or the like at the compression end of the cylinder. The
gate is operated by manual or automatic means at the end of the compression or work stroke for ejecting the ice cake; the gate is then closed and the cycle repeated. Although this method produces dry ice in pieces much smaller than block ice, the disc-like cakes are still in most cases too large for efficient flow-handling and for convenient packing around refrigerated containers and the like. In such instances, the cake may be broken up into pieces that ordinarily vary in size down to powder. This is objectionable as pieces of fairly uniform size and contour are more desirable for facilitating handling, and for general use.
Various methods have been proposed for producing CO, ice in small pellet-like pieces, one method, for example, comprising forcing CO slush ice into multiple sectionalized molds within a press, after which the molds containing ice pellets are removed as units for shipping and storage. In another method, compressed snow is divided into parallel streams within a press having a reciprocating piston, and the streams are converged and solidified under pressure against an extrusion plate having multiple draw holes for the pellets.
Insofar as is presently known, none of the proposed methods and apparatus for producing dry ice pellets have been found satisfactory in practice. The pellets in mold packages do not lend themselves to convenient general use, and proposed extruding presses tend to clog and back up ice at the extruding plate, thereby causing excessive stresses and pressures in the press and temporary shut-down of the equipment.
A practical disadvantage moreover, of most of the prior art ice machines is that the production process is cyclic, i.e. there is a periodic pause for recharging, etc., during which the output of the machine is either nil or greatly reduced.
The present invention is directed to overcoming the problems involved in the continuous production of high density CO ice pellets by extruding press equipment and thereby increasing the rate of pellet production.
SUMMARY OF THE INVENTION In accordance with the invention, carbon dioxide (herein sometimes termed CO- in liquid form is flashed by conventional snow-horn means or the like, into snow, and the snow is deposited in a rotary-type extruder that consists of a fixed ring die and a centrally pivoted carrier with coacting rotary extruder elements. The extruder elements may take the form of either cylinder-like rolls or gear pinions that are caused suc cessively to traverse draw-hole openings around the inner periphery of the ring die. Where pinions are used, the ring die constitutes an internal ring gear with draw holes in and between the teeth extending from the inner periphery radially through the ring. The gear pinions are mounted at diametrically opposite positions on the carrier within the ring gear for continuous meshing therewith in planetary motion so that the draw holes around the ring periphery come into successive alignment with the rotating pinions.
The flashed snow as it collects in the extruding region of the ring die is entrained by the pinions, compressed between the meshing gear teeth and extruded through the draw holes as CO: or dry ice" pellets in a continuous extrusion process.
Where the carrier has extruder rolls of cylindrical form for example, the ring die surface at the inner periphery is circular and includes openings for the radial draw holes.
A principal object of the invention therefore is to provide an improved extruding machine of the rotary type that is capable of quantity production of dry ice pellets in a continuous noncyclic operation.
Another and related object of the invention is to provide improved extruding apparatus having a ring die with internal planetary type rotating extruder elements, that is efficient and positive in its operation, readily adaptable for receiving the output of conventional CO, snow-making equipment for continuous production of dry ice pellets, and that is simple, rugged and inexpensive in construction and economical in operation.
Other objects, features and advantages will appear from the following description with reference to the accompanying drawings.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is an elevational view, mainly in section, of a rotary extruder embodying the invention for making CO ice pellets;
FIG. 2 is an enlarged plan view, partly in section, of rotary extruding equipment shown generally in FIG. 1;
FIG. 3 is a cross-sectional view taken along the line 3-3 of FIG. 2;
FIG. 4 is an elevational view, partly in section, of a modified form of the rotary extruder;
FIG. 5 is an exploded view of the coacting extruder elements of FIG. 4; and
FIG. 6 is a sectional view similar to FIG. 4, illustrating a variation thereof.
DESCRIPTION OF THE PREFERRED EMBODIMENT Referring to FIG. 1, the essential combination of the CO, ice pellet making machine of the invention consists of a suitable source of liquid CO generally indicated by a supply line manifold 10, a snow horn 12 or equivalent, within which liquid CO is flashed in conventional manner into snow, a rotary extruder with ring die at 14 for receiving the snow and converting it into high density ice pellets, the extruder having an exhaust chute 16 for directing the ice pellets into a container, storage bin or the like, a main drive shaft 18 for the rotating unit of the extruder, and an operating motor M connected through a suitable transmission system to the drive shaft.
In the snow-making process indicated above, the pressurized liquid CO from the supply at 10 is continuously fed through conventional snow horn precooling coils 35 to the throat of the snow horn 12 that has a standard orifice-controlled discharge nozzle 22. The liquid C0 is fed from the cooling coils to the discharge nozzle through a liquid receiving manifold 19, feed line 20 and noule coupling 21. Upon discharge from the nozzle, the CO liquid is for the most part flashed as indicated at 23 into snow, the remainder being cold CO gas. A cylindrical metal housing 26 made of stainless steel for example, encloses the snow horn and forms a so-called snow chamber 28 for collecting both the snow and excess gas. This housing has a cover 24 in which the coupling 21 is mounted for conveniently supporting the throat or inlet end of the horn 12. The divergent or exhaust end of the horn is supported by peripherally spaced resilient struts 13 that are connected to the lower inner wall of the cylinder 26. The cylindrical housing 26 itself is mounted above the extruder 14 that in turn, is supported by a centrally positioned tube-like bearing housing 27 for the drive shaft 18, and also at its outer periphery by the main base housing H as further described below.
The function of the snow chamber 28 also includes the collection of excess CO, gas apart from the snow, for removal by venting for precooling purposes. To this end, the gas in chamber 28 (which is under positive gauge pressure in the normal operation of the snow horn) flows into a venting line 30 at the top of the chamber, and into a gas manifold 32. From the manifold the cold gas is suitably directed to heat-transfer coils 34 that encircle the cylinder 26 for cooling the snow chamber and for subcooling the incoming liquid, thereby improving subsequent flashing efiiciency of the snow horn. Afier passage through the cooling coils 34, the gas is vented at 36 to an exterior recovery line for ultimate recycling in known manner as liquid CO The cylindrical housing for the snow chamber is provided with an outer insulating jacket or housing indicated at 38.
The CO snow from the horn that collects in the lower part of the snow chamber, feeds directly by gravity into the extruder that is vertically beneath and in fact constitutes the bottom of the snow chamber. The extruder consists essentially of rotary extruder elements mounted on a central rotating carrier 40, FIG. 2, and a complementary fixed extruding die 44. The die in the form of the invention shown by FIG. 1 constitutes an internal ring gear within which the carrier is concentrically pivoted. The carrier is keyed at 42 to the drive shaft 18 for rotation therewith, and has mounted thereon at opposite ends two gear pinions 46 and 48 that have planetary motion within the ring gear. Thus, the diametrically positioned pinions continually mesh with the internal teeth 50 of the ring gear as the carrier is rotated.
The ring gear in turn has at least two extruding die passages or draw- holes 52 and 54 per tooth pitch throughout the circumference of the ring die depending on the transverse width of the teeth and draw-hole diameters, i.e., there is a minimum of twice as many draw-holes as teeth in the extruding die. The number of draw-holes can be increased according to the transverse length of the extruding teeth as shown in FIG. 3. Specifically the draw-holes extend along radial lines transversely through the ring of the die, a draw-hole 52 extending from the top of a respective tooth 50, and the adjacent draw'hole 54 extending from the foot line between the tooth and a following tooth, FIG. 2. Accordingly, each such pair of draw-holes is within a span corresponding in length to a tooth pitch. For facilitating extrusion flow, the entrance end of each draw-hole is counter-bored as shown at 52 for the draw-holes 52, and at 54 for the draw-holes 54.
As indicated above, the gear pinions 46 and 48 have the same tooth pitch as the ring gear, and are symmetrically positioned at opposite ends of the pivoted carrier 40 for continuous and precise meshing with the die teeth 50. Assuming clockwise rotation of the carrier as viewed in FIG. 2, the respective pinion teeth 56 and 58 engage the fixed die teeth 50 to cause counterclockwise rotation of the pinion gears. Preferably, the mating tolerance or limit of backlash of the engaging gear teeth is approximately 0.0l to 0.015 in. so that positive and continuous rolling contact is for practical purposes, established between the coacting gear teeth surfaces.
As the snow chamber 28 is continuous with the lower fixed ring die 44, the collected CO tends to settle within the ring, FIG. I, where it is first entrained by the gear pinions as the rotating carrier sweeps the circular area. During meshing of the snow-entraining teeth with the die teeth, the snow is tightly compressed as it is progressively forced into the respective valleys" between the pinion teeth and the die teeth. As the socalled rolling contact between a pair of engaging gear teeth continues, the snow is further compressed into ice and finally forced into a respective draw-hole, as for example a draw-hole 52, during coincidence of the radial axis of the draw hole and the line of centers of the ring die and the corresponding pinion respectively. In other words, when the carrier center line is brought into coincidence with the longitudinal axis of a given draw-hole, the ice charge in question is entirely forced by the corresponding pinion gear into the aligned draw-hole, from which it is later extruded in cylindrical form as succeeding charges of compressed snow and ice are formed and forced into the draw-hole by successive passes of the pinions.
The cylindrical extrusions consist of high-density CO ice that can readily be broken into short pellets for convenient handline. For example, the ice exhaust chute 16, FIG. 1, can be formed as an annular baffle plate that is inclined at a suitable angle with respect to the draw hole outlets for causing the extruded ice cylinders to break up into small lengths as they meet the baffle, as indicated at 60.
In a practical example, the draw holes were made for onefourth in. diameter pellets, and the ring die was sufficiently wide (transverse direction) for accommodating transverse rows of six draw-holes, FIGS. 1 and 3, thereby providing a total of 12 draw-holes per tooth pitch of the ring die. It will be apparent that the number of draw-holes for increasing the production of pellets can be increased by increasing the transverse dimensions of the ring die and pinion gears respectively; also, it will be apparent that the tooth height and the ratios of tooth pitch circumference indicated in the drawings are for purposes of illustration only. According to extrusion stresses, depending on rate of production and other mechanical factors, the gear teeth can be strengthened as required by increasing the tooth base width (and hence the tooth pitch) for a given tooth height, or, simply by reducing the tooth height.
The extruder 14 as described above, is suitably mounted in a generally vertical arrangement between the snow chamber 28 and the main base housing H. The ring die 44 is bolted at 62 between an annular retaining ring 64 (on which is mounted the upper cylindrical housing 26 for the snow chamber) and a fixed die supporting plate 66. This plate is in turn centrally positioned by and bolted at 68 to the upper part of the cylindrical bearing housing 27 for the drive shaft. Specifically, the housing 27 has secured thereto at its upper end an annular bearing support 70 to which the die plate 66 is bolted in centered relationship. A main bearing 72 of standard type for the shaft journal is mounted within the support 70.
Referring specifically to the carrier mounting for the rotary elements, FIGS. 2 and 3, the carrier 40 consists of a central hub 74 (that is keyed as mentioned above to the upper end of the drive shaft at 42) and a pair of parallel spaced arms 76 and 78 that are integrally secured to the hub and extend equal distances therefrom for diametrically positioning the gear pinions 46 and 48 with respect to the ring die 44. The corresponding ends of the arms at diametrically spaced points on the pinion carrier are provided with aligned holes at 80, 81 and at 82, 83, in which are mounted tightly fitted bushings 84 and 85 for positioning the pinions 46 and 48 respectively. Suitable heavy duty bearings 86 and 88 respectively, FIG. 3, are positioned between the bushings and the bearing surfaces of the corresponding pinions.
In another mode of the invention illustrated by FIGS. 4 to 6, the dry ice pellets are extruded at the ring die generally as described above, except that extrusion is achieved by relatively movable portions of substantially cylindrical surfaces, rather than by meshing gears. To this end, referring first to FIGS. 4 and 5, the inner periphery of the ring die 44a has a generally circular or cylinder-like contour with closely spaced draw holes 45 throughout. For facilitating extrusion flow into the draw holes, the hole openings each have a counter-sink 45a which overlap, so that the die entrance 50a has a hexagonal or honey-comb appearance as indicated in FIG. 5.
The coacting rotary extruder elements constitute cylinders or rolls 46a and 48a that can be mounted within the carrier 40 in the same manner as the pinions 46 and 48. In FIGS. 4 and 5, each roll has at its upper edge gear teeth 47 for meshing with aligned corresponding teeth 49 on thering die, thereby obtaining uniform rotation in relation to carrier rotation. The coacting roll and die surfaces are preferably spaced for slight tolerance, rather than in metal-to-metal contact. The snow as it settles into the die is entrained by the advancing rolls, compressed, and forced into the draw holes for extrusion, generally as described above.
FIG. 6 illustrates a rugged and simple form of roll-type extruder wherein the rolls 46b and 48b are idler-mounted on the carrier for free rotation with respect to the ring die 44b. With this arrangement there is no problem of overstressing gear teeth, and transient load peaks are more easily handled by not forcing rotation of the rolls at the respective draw holes 45b.
In operation, snow or ice may tend to accumulate or ball" on the upper side flat surfaces of the rolls or pinions near the periphery. This is readily prevented by extending at 90 the inner edge of the upper die retaining ring 64 in overhanging relation to the roll or pinion as indicated in FIGS. 1 and 3 for scraping clear such accumulations as the carrier rotates beneath. Also, the tendency of snow from the horn 12 to settle in the hub areas of the pinion carrier rather than outwardly toward the ring die can be at least partly offset by deflecting slightly the longitudinal axis or center line 12 of the horn with respect to the carrier axis of rotation 14.
The well-known tendency of the snow to stick along the inside wall of the snow horn can also be counteracted by advantageous use of the extruder drive means. By way of example, a mechanical horn vibrator operable by the drive shaft may consist of a star-wheel, or as shown, a disc 92 having peripherally spaced pegs 94, secured to the end of the drive shaft. A spring steel strip 96, FIG. 1, secured at 98 to the snow chamber housing 26 extends laterally over the pinion carrier so that the free end of the strip tends to position itself a short distance within the peg circle. The spring strip has a transverse vertical extension 100 with a notched portion 102 at its upper end that is positioned next to the lower edge of the horn. Accordingly, rotation of the disc 92 as the extruder is operated, results in flexing and releasing of the spring strip 96 in snap action that in turn causes the vertical extension 100 to engage the horn in percussion-like manner. The vibration of the horn structure so produced is sufficient to keep it clear of sticking snow.
In an alternative arrangement shown by FIG. 4, the snow from the symmetrically positioned horn is deflected and distributed generally in a radial direction toward the ring die by a cone 104 that is centered beneath the horn and seated on the carrier. For spreading and leveling the deflected snow at the base of the cone for uniform feed into the extruder, a leveler strip 106 is connected to the cylinder 26 at 107 so as to extend above and across the dished inner edge of the retaining ring 64, FIGS. 2 and 3, and the annular region at the die entrance. This region which is open (except for the carrier) therefore receives uniform snow feed as leveling proceeds.
For preventing formation of voids and ensuring settling of accumulated snow in the snow chamber and horn above the extruder, the entire upper assembly unit including the horn and cylinder 26 can be vibrated by mounting an electric vibrator of conventional type on the side wall of housing 38 for example, as indicated at 105, FIGS. 1 and 4, thereby freeing the horn of sticking snow, as well as causing piled-up low mass snow at the bottom of the snow chamber to settle evenly around the base of the cone. This insures more uniform feed by the leveler 106 into the extruder. The unit vibrator 105 may if desired also be used along with the horn vibrator arrangement of FIG. 1.
The remaining mechanical arrangements and structures for a commercial machine are of but general interest for an understanding of the invention and therefore can be described briefly. The motive means for rotating the drive shaft 18 is not limited to any specific arrangement. In the preferred embodiment, an electric motor M vertically mounted at the base of the machine is connected through its shaft pulley 108 and belt-drive transmission 110 to a large diameter drive pulley 112 operatively connected to the lower end of the drive shah. The hub 114 of the drive pulley has a free fit on a centering bushing 116 that in turn is keyed to the lower end of the drive shaft at 1 18.
For avoiding damage under excess load conditions, the drive connection between the power pulley 112 and the drive shaft 18 (at the keyed bushing 116) includes a springloaded clutch 120 of conventional type having a clutch disc 122 splined to the bushing 116 for engagement with the mating clutch surface 123 of the pulley l 12.
Accordingly, a high mechanical ratio can be used between the motor shaft pulley 108 and the extruder shaft for safely producing the required force at the carrier 40 for the snow compressing and ice extruding operations described above. The drive shaft has a second main bearing 124 that is suitably mounted within the cylindrical bearing housing 27 at its lower end. The lower end of the drive shaft may be supported if desired by a vertical thrust bearing (not shown) suitably mounted in a structural steel base on which the main base enclosing housing H is fastened.
Summarizing the advantages of the invention, it is seen that a large quantity of high-density, dry ice pellets can be continuously produced by the rotary extruder described above. There is no operating cycle involved in the sense that a periodic pause is required during production of the ice pellets; also volume production is essentially limited only by the output of the snow horn or other CO snow-making equipment, the physical dimensions of the extruding elements (and drawholes) and the power of the drive motor.
Having set forth the invention in what is considered to be the best embodiment thereof, it will be understood that changes may be made in the system and apparatus as above set forth without departing from the spirit of the invention or exceeding the scope thereof as defined in the following claims.
We claim:
1. A carbon dioxide pellet machine for producing carbon dioxide ice pellets comprising, housing means at least partly defining a snow chamber, carbon dioxide snow generating means at least partly within said snow chamber to direct snow generally vertically downwardly, said snow generating means including nozzle means and means to supply liquid carbon dioxide to said nozzle means under pressure, further means to remove carbon dioxide vapor from said snow chamber, extrusion means at least partly defining the bottom of the snow chamber, said extrusion means including an extruding die formed as a ring, said ring die being horizontally positioned for receiving by vertical gravity feed carbon dioxide snow within the circumscribed ring area said ring die having draw holes extending therethrough around the ring periphery, rotary extruder elements mounted for planetary motion within the ring die for successive traversing of the die draw holes, and power means for driving the rotary elements around the inner periphery of the extruding die for causing snow settling within the ring area to be entrained and compressed between the rotary elements and die, and extruded through the draw holes as ice pellets.
2. An ice pellet machine as specified in claim 1 wherein the extruder elements are rotatably mounted at diametrically opposite positions on carrier means that in turn, is pivoted for movement about the center of the ring die and connected to the power means.
3. An ice pellet machine as specified in claim 2 wherein the die is formed as an internal ring gear with the draw hole openings extending from the gear teeth side of the die, and the extruder elements are gear pinions that rotate about the ring gear center in planetary motion and mesh with the die teeth for entraining and extruding snow at the draw holes.
4. An ice pellet machine as specified in claim 3 wherein gear teeth of the extruding die have draw holes that extend through the centers respectively of the teeth.
5. An ice pellet machine as specified in claim 3 wherein each tooth pitch throughout the periphery of the ring gear spans at least two peripherally spaced draw holes.
6. An ice pellet machine as specified in claim 5 wherein one draw hole of each tooth pitch extends from the top of the corresponding tooth to the exterior periphery of the ring gear, and the other peripherally spaced draw hole extends from the foot line of the tooth through the ring gear, whereby a snow charge carried between two adjacent pinion teeth is delivered to the first-named draw hole for extrusion therethrough and a following snow charge for the other draw hole is forced into the space between the corresponding die teeth by an adjacent pinion tooth.
7. An ice pellet machine as specified in claim 2 wherein the extruder elements are cylinder-like rolls that successively traverse the draw holes at the inner periphery of the ring die.
8. An ice pellet machine as specified in claim 7 wherein the rolls have gear teeth apart from the roll extruder surfaces, that engage corresponding teeth at the inner periphery of the ring die for causing positive rotation of the rolls in synchronism with the rotation of the carrier.
9. An ice pellet machine as specified in claim 7 wherein the rolls are mounted for free rotation.
10. An ice pellet machine as specified in claim 1 wherein liquid carbon dioxide is continuously flashed within a snow horn into said snow chamber, the horn having its exhaust opening opposite and over the extruding die for deposit of snow within the circumscribed ring area of the die.
1 1. An ice pellet machine as specified in claim 10 wherein a deflector is located between the horn exhaust and central ring area for radially directing the snow toward the ring die.
12. An ice pellet machine as specified in claim 11 wherein the deflector is a cone having its apex centrally of the horn exhaust and its base over the central ring area.
13. An ice pellet machine as specified in claim 10 wherein the snow horn and extruding die are mounted on common supporting structure and vibrator means is operatively connected to the structure for loosening collected snow within the horn and above the ring die area.
14. An ice pellet machine as specified in claim 10 wherein the horn is engaged by a vibrator operated by the power means, the vibrator including a percussion element for successively engaging the horn for freeing snow sticking to the inner surface thereof.
15. An ice pellet machine as specified in claim 10 wherein the longitudinal axis of the snow horn is deflected by a small angle from the projected axis of rotation of the extruder means for eccentric deposition of snow with respect to the extruder axis.
16. An ice pellet machine as specified in claim 10 wherein a flat ring dished at its inner periphery is mounted above and closely overhangs the inner side of the ring die and the traversing rotary extruder elements for guiding snow thereto, and a radially positioned snow leveler overhangs the dished ring.
17. An ice pellet machine as specified in claim 1, further including electrically powered means to prevent the sticking and accumulation of snow within the snow chamber.
18. An ice pellet machine as specified in claim 10 wherein the liquid carbon dioxide is directed through precooling coils surrounding the snow chamber prior to flashing in the snow horn, and excess carbon dioxide gas in the snow chamber is vented from the chamber for passing through precooling coils also surrounding the chamber.
19. A dry ice pellet machine comprising, housing meansat least partly defining a snow chamber, carbon dioxide snow generating means at least partly within said chamber to direct snow into an extrusion means, said snow generating means including noule means and means to supply liquid carbon dioxide to said nozzle means under pressure, further means to remove carbon dioxide vapor from said snow chamber, said extrusion means at least partly defining the lower part of the snow chamber, said extrusion means including an annular extruding die positioned to receive the descending snow particles within its annular extent, said die having draw holes extending therethrough around the die periphery, rotary extruder elements mounted on a carrier for planetary motion within the annular die for successive traversing of the die draw holes, and power means for rotating the carrier for driving the rotary elements around the inner periphery of the extruding die for causing snow settling within the die area to be entrained and compressed between the rotary elements and die and extruded through the draw holes as ice pellets.
20. A dry ice pellet machine as defined in claim 19 wherein said snow generating means further includes a snow horn, and electrically powered means to counteract the tendency of the carbon dioxide snow to stick to the interior of the snow horn.
21. A carbon dioxide pellet machine for producing carbon dioxide ice pellets comprising, housing means at least partly defining a snow chamber, a frusto conical snow horn mounted in said chamber and being substantially vertically arranged with its wider end at the bottom, nozzle means at the upper end of the horn, means'to supply liquid carbon dioxide to said nozzle means, means to remove carbon dioxide vapor from said chamber, extrusion means below said s now horn to receive the snow generated therein, said extrusion means including an extrusion ring die having an inner diameter greater than the diameter of the wider end of the snow horn so that the snow is deposited within the ring die, said ring die having draw holes extending therethrough around the ring periphery, extruder elements mounted within the ring die for successive traversing of the die draw holes, power means for driving the extruder elements for causing snow to be compressed by the extruder elements and extruded through the draw holes as ice pellets.
22. A pellet machine as set forth in claim 21 further including electrically powered means to free the snow horn from sticking snow.
i i l I

Claims (21)

  1. 2. An ice pellet machine as specified in claim 1 wherein the extruder elements are rotatably mounted at diametrically opposite positions on carrier means that in turn, is pivoted for movement about the center of the ring die and connected to the power means.
  2. 3. An ice pellet machine as specified in claim 2 wherein the die is formed as an internal ring gear with the draw hole openings extending from the gear teeth side of the die, and the extruder elements are gear pinions that rotate about the ring gear center in planetary motion and mesh with the die teeth for entraining and extruding snow at the draw holes.
  3. 4. An ice pellet machine as specified in claim 3 wherein gear teeth of the extruding die have draw holes that extend through the centers respectively of the teeth.
  4. 5. An ice pellet machine as specified in claim 3 wherein each tooth pitch throughout the periphery of the ring gear spans at least two peripherally spaced draw holes.
  5. 6. An ice pellet machine as specified in claim 5 wherein one draw hole of each tooth pitch extends from the top of the corresponding tooth to the exterior periphery of the ring gear, and the other peripherally spaced draw hole extends from the foot line of the tooth through the ring gear, whereby a snow charge carried between two adjacent pinion teeth is delivered to the first-named draw hole for extrusion therethrough and a following snow charge for the other draw hole is forced into the space between the corresponding die teeth by an adjacent pinion tooth.
  6. 7. An ice pellet machine as specified in claim 2 wherein the extruder elements are cylinder-like rolls that successively traverse the draw holes at the inner periphery of the ring die.
  7. 8. An ice pellet machine as specified in claim 7 wherein the rolls have gear teeth apart from the roll extruder surfaces, that engage corresponding teeth at the inner periphery of the ring die for causing positive rotation of the rolls in synchronism with the rotation of the carrier.
  8. 9. An ice pellet machine as specified in claim 7 wherein the rolls are mounted for free rotation.
  9. 10. An ice pellet machine as specified in claim 1 wherein liquid carbon dioxide is continuously flashed within a snow horn into said snow chamber, the horn having its exhaust opening opposite and over the extruding die for deposit of snow within the circumscribed ring area of the die.
  10. 11. An ice pellet machine as specified in claim 10 wherein a deflector is located between the horn exhaust and central ring area for radially directing the snow toward the ring die.
  11. 12. An ice pellet machine as specified in claim 11 wherein the deflector is a cone having its apex centrally of the horn exhaust and its base over the central ring area.
  12. 13. An ice pellet machine as specified in claim 10 wherein the snow horn and extruding die are mounted on common supporting structure and vibrator means is operatively connected to the structure for loosening collected snow within the horn and above the ring die area.
  13. 14. An ice pellet machine as specified in claim 10 wherein the horn is engaged by a vibrator operated by the power means, the vibrator including a percussion element for successively engaging the horn for freeing snow sticking to the inner surface thereof.
  14. 15. An ice pellet machine as specified in claim 10 wherein the longitudinal axis of the snow horn is deflected by a small angle from the projected axis of rotation of the extruder means for eccentric deposition of snow with respect to the extruder axis.
  15. 16. An ice pellet machine as specified in claim 10 wherein a flat ring dished at its inner periphery is mounted above and closely overhangs the inner side of the ring die and the traversing rotary extruder elements for guiding snow thereto, and a radially positioned snow leveler overhangs the dished ring.
  16. 17. An ice pellet machine as specified in claim 1, further including electrically powered means to prevent the sticking and accumulation of snow within the snow chamber.
  17. 18. An ice pellet machine as specified in claim 10 wherein the liquid carbon dioxide is directed through precooling coils surrounding the snow chamber prior to flashing in the snow horn, and excess carbon dioxide gas in the snow chamber is vented from the chamber for passing through precooling coils also surrounding the chamber.
  18. 19. A dry ice pellet machine comprising, housing means at least partly defining a snow chamber, carbon dioxide snow generating means at least partly within said chamber to direct snow into an extrusion means, said snow generating means including nozzle means and means to supply liquid carbon dioxide to said nozzle means under pressure, further means to remove carbon dioxide vapor from said snow chamber, said extrusion means at least partly defining the lower part of the snow chamber, said extrusion means including an annular extruding die positioned to receive the descending snow particles within its annular extent, said die having draw holes extending therethrough around the die periphery, rotary extruder elements mounted on a carrier for planetary motion within the annular die for successive traversing of the die draw holes, and power means for rotating the carrier for driving the rotary elements around the inner periphery of the extruding die for causing snow settling within the die area to be entrained and compressed between the rotary elements and die and extruded through the draw holes as ice pellets.
  19. 20. A dry ice pellet machine as defined in claim 19 wherein said snow generating means further includes a snow horn, and electrically powered means to counteract the tendency of the carbon dioxide snow to stick to the interior of the snow horn.
  20. 21. A carbon dioxide pellet machine for producing carbon dioxide ice pellets comprising, housing means at least partly defining a snow chamber, a frusto conical snow horn mounted in said chamber and being substantially vertically arranged with its wider end at the bottom, nozzle means at the upper end of the horn, means to supply liquid carbon dioxide to said nozzle means, means to remove carbon dioxide vapor from said chamber, extrusion means below said snow horn to receive the snow generated therein, said extrusion means including an extrusion ring die having an inner diameter greater than the diameter of the wider end of the snow horn so that the snow is deposited within the ring die, said ring die having draw holes extending therethrough around the ring periphery, extruder elements mounted within the ring die for successive traversing of the die draw holes, power means for driving the extruder elements for causing snow to be compressed by the extruder elements and extruded through the draw holes as ice pellets.
  21. 22. A pellet machine as set forth in claim 21 further including electrically powered means to free the snow horn from sticking snow.
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US4033736A (en) * 1974-10-17 1977-07-05 Chemetron Corporation Continuous method for making rod-like solid carbon dioxide extrusions
US4453908A (en) * 1983-04-21 1984-06-12 California Pellet Mill Company Pellet mill void space filler
US4727687A (en) * 1984-12-14 1988-03-01 Cryoblast, Inc. Extrusion arrangement for a cryogenic cleaning apparatus
US5123207A (en) * 1990-10-30 1992-06-23 Tti Engineering Inc. Mobile co2 blasting decontamination system
US5203794A (en) * 1991-06-14 1993-04-20 Alpheus Cleaning Technologies Corp. Ice blasting apparatus
US5249426A (en) * 1992-06-02 1993-10-05 Alpheus Cleaning Technologies Corp. Apparatus for making and delivering sublimable pellets
US5666821A (en) * 1993-04-29 1997-09-16 Lockheed Martin Energy Systems, Inc. Method for producing pellets for use in a cryoblasting process
US5426948A (en) * 1994-09-26 1995-06-27 Hyde, Jr.; Charles M. Multiform solid carbon dioxide extruder
US6240743B1 (en) 1999-11-08 2001-06-05 Russel G. Allen, Jr. Gas venting device for dry ice pelletizer and methods for retrofitting same onto existing dry ice pelletizers
US20040035146A1 (en) * 2000-09-05 2004-02-26 Christian Dannings Pellet press for dry ice
US6986265B2 (en) * 2000-09-05 2006-01-17 Cold Blasting Aps Pellet press for dry ice
US20050092017A1 (en) * 2003-11-03 2005-05-05 Becker James R. Dry ice block extruder
US7021081B2 (en) 2003-11-03 2006-04-04 Airgas Dry Ice Dry ice block extruder
US20090093196A1 (en) * 2005-03-11 2009-04-09 Dressman Richard K Particle Blast System with Synchronized Feeder and Particle Generator
US20080296797A1 (en) * 2007-05-15 2008-12-04 Cold Jet Llc Particle blasting method and apparatus therefor
US9095956B2 (en) 2007-05-15 2015-08-04 Cold Jet Llc Method and apparatus for forming carbon dioxide particles into a block
EP2002968A3 (en) * 2007-06-15 2010-11-10 Guido Pusch Device for manufacturing burnable pellets from renewable resources
US20090110766A1 (en) * 2007-10-25 2009-04-30 Cpm Acquisition Corporation Coupling for Pelleting Mill
US8187057B2 (en) 2009-01-05 2012-05-29 Cold Jet Llc Blast nozzle with blast media fragmenter
US20100170965A1 (en) * 2009-01-05 2010-07-08 Cold Jet Llc Blast Nozzle with Blast Media Fragmenter
WO2012022735A1 (en) 2010-08-16 2012-02-23 Desisa Gmbh Device and method for dispensing dry ice snow
EP2420353A1 (en) 2010-08-16 2012-02-22 desisa GmbH Device and method for dispensing dry ice snow
US9975216B2 (en) 2010-08-16 2018-05-22 Desisa Gmbh Device and method for dispensing dry ice snow
CN102582108A (en) * 2012-03-08 2012-07-18 广州市德寅生物科技有限公司 Biomass fuel forming machine
EP2727715B1 (en) 2012-11-06 2022-03-02 Franz Blieninger Pellet press with device for cutting to length of biogenic pellets containing fibres
EP3369561B1 (en) 2012-11-06 2020-04-15 Franz Blieninger Pellet press with device for cutting to length of pellets containing biogenic fibres and method for producing said pellets
US20150166350A1 (en) * 2013-10-16 2015-06-18 Cold Jet, Llc Method and apparatus for forming solid carbon dioxide
US9649745B2 (en) * 2013-11-29 2017-05-16 Alfred Kärcher Gmbh & Co. Kg Apparatus for producing CO2 pellets from CO2 snow and cleaning device
WO2015079022A1 (en) * 2013-11-29 2015-06-04 Alfred Kärcher Gmbh & Co. Kg Apparatus for producing co2 pellets from co2 snow and cleaning device
CN105848828A (en) * 2013-11-29 2016-08-10 阿尔弗雷德·凯驰两合公司 Apparatus for producing co2 pellets from co2 snow and cleaning device
CN105848828B (en) * 2013-11-29 2018-09-14 阿尔弗雷德·凯驰两合公司 Equipment and cleaning device for generating CO2 spherolites from CO2 snowflakes
US20160271755A1 (en) * 2013-11-29 2016-09-22 Alfred Kärcher Gmbh & Co. Kg Apparatus for producing co2 pellets from co2 snow and cleaning device
US9931639B2 (en) 2014-01-16 2018-04-03 Cold Jet, Llc Blast media fragmenter
CN104309157B (en) * 2014-05-02 2016-08-24 萧钠 Combined type forming machine for straw
CN104309157A (en) * 2014-05-02 2015-01-28 萧钠 Composite straw forming machine
US11001500B2 (en) 2015-06-25 2021-05-11 Irbis Technology LLC Method, apparatus and system for producing granulated solid carbon dioxide
US20190301679A1 (en) * 2018-03-27 2019-10-03 TOKITAE LLC, a limited liability company of the State of Delaware Dry ice compressor device
CN110303714A (en) * 2019-07-04 2019-10-08 杭州万知科技有限公司 A kind of Internet of Things manufacture system of biomass fuel briquetting
CN110303715A (en) * 2019-07-04 2019-10-08 杭州万知科技有限公司 A kind of production equipment of biomass fuel briquetting
WO2024181862A1 (en) 2023-02-28 2024-09-06 Universiteit Twente Dry ice
NL2034234B1 (en) * 2023-02-28 2024-09-09 Univ Twente Dry ice

Also Published As

Publication number Publication date
JPS5384643U (en) 1978-07-12
JPS5436126Y2 (en) 1979-11-01
GB1301783A (en) 1973-01-04
FR2078442A5 (en) 1971-11-05
DE2106477C3 (en) 1980-06-04
DE2106477B2 (en) 1979-09-13
DE2106477A1 (en) 1971-08-19
CA950615A (en) 1974-07-09
ZA71749B (en) 1972-09-27

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