SE441782B - ISSUER FOR THE MANUFACTURING OF ISBITS OR CUBES - Google Patents

Description

7813313-9 from the chamber to engage a crushing head, which breaks the ice column into ice cubes or ice cubes. This type of ice making machine is described in US 3,662,564, 3,702,543 and 3,654,770.

The invention relates to an ice apparatus comprising an ice flake manufacturing mechanism with an outlet part for discharging ice flakes, which mechanism comprises a cooling chamber and a rotatable extruding screw, an extruding device with an extruding body, which forms a circular chamber with a truncated cone-shaped part inlet in the circular part of the chamber; the ice conducting means for transferring ice flakes from the ice flake outlet to the inlet body inlet; an ice-squeezing feed screw rotatably mounted in the chamber, the feed screw having a helical cone-shaped feed blade for feeding ice, the feed blade having substantially the same diameter and length as the corresponding chamber section; an outlet opening which extends parallel to the axis of rotation of the screw and is located at the narrow end of the chamber. The object of the invention is to provide a new and improved apparatus for producing ice in the form of cubes and the like. and this has been achieved with an ice apparatus of the above kind in that the body of the auger and the wall of the chamber between them form an annular space with progressively decreasing radial extent, in which space passing ice flakes are dewatered and compressed into a relatively solid mass of ice and passed out through the outlet opening. the inlet is arranged substantially perpendicular to the longitudinal axis of the chamber and with its central line offset in the lateral direction relative to the axis of rotation of the auger and that the blades of the auger are formed with a plurality of axially and circumferentially spaced grooves at the periphery of the blade. a certain angle along the blade. 7813513-9 Other features of the invention appear from the subclaims.

The invention will be explained in more detail below with reference to the accompanying drawings, in which Fig. 1 schematically shows the ice machine according to the invention with parts of the ice flake generating mechanism and the ice storage container broken for illustrative purpose. Fig. 2 is a partially cut-away side view on a larger scale of the ice-squeezing mechanism included in the system of Fig. 1. Fig. 3 shows on a larger scale a section along the line 3-3 in Fig. 2, and Fig. 4 shows a section along line 4-4 in Fig. 2. Fig. 5 is a side view of the ice compressing or compacting auger included in the ice squeezing mechanism of the invention. Fig. 6 is a side view of the feed screw according to Fig. 5 in the direction of the arrow 6 in Fig. 5.

Fig. 7 shows a cross section of the crushing head, which is included in the squeezing mechanism according to the invention, and Fig. 8 is an end view of the crushing head according to Fig. 7 in the direction of the arrow 8.

Fig. 9 is a sectional view taken along line 9-9 of Fig. 3.

Fig. 1 of the drawings shows an ice apparatus 10 according to a suitable embodiment of the invention and this consists of an ice flake producing machine 12, which is fed with water, which is to be frozen, through an inlet line 14. The machine is operated together with a cooling system 16, of which said water is frozen and transferred by means of a suitable ice flake feeding line 18 to an ice squeezing mechanism, which is constructed according to the invention and which compresses or compresses the ice to form separate ice cubes or ice cubes, which are fed through a line 22 to a container or storage chamber, etc. which has been denoted by 24 and which will be described in more detail below. 7813313-9 As an example it can be mentioned that the ice flake machine 12 comprises a cylindrical freezing housing 26, in which a rotating feed screw 28 has been arranged, which is rotated in a selected manner by means of a drive motor 30, which is connected to the feed screw 28 by a gear mechanism 32. through a cooling line 34 to an annular evaporation chamber 36, which partially surrounds the freezer housing 26 and causes water fed through the line 14 to freeze around the inner circumference of the housing 26. The coolant is returned to the system 16 through a suitable cooling line 38, which is connected to an ordinary cooling compressor 40, which in turn is connected through the cooling line 41 to an associated cooling capacitor 42. In a well-known manner, the operation of the feed screw 28 causes a shear of ice in the form of flakes from the inside of the housing 26. and these flakes are fed upwards to the line 18, from where the ice flakes are fed to the squeezing mechanism 20, which will be described in more detail below.

As shown in Fig. 1, the squeezing mechanism 20 comprises e.g. a support structure 44, which comprises a base part 46 and a vertical part 48, which later operatively and suitably adjustably supports a suitable drive motor 50, which is driven by means of a drive belt 52 to a reduction gear 54, which is mounted on the base part 46.

The unit 54 comprises a suitable housing which effectively receives the reduction shaft (not shown) to effect rotation of the output shaft 58 corresponding to the driving movement of the belt 52.

The squeezing mechanism 20 shown in Fig. 3 comprises an elongate squeezing housing 60, which is arranged substantially coaxially with the axis of rotation 58 and which comprises a central part 62 with outwardly extending flanges 7813313-9 64, 66, which are formed in one piece with its opposite ends. The housing 60 also includes an integrating ice inlet portion 68 extending upwardly from its center portion 62, and the inlet portion 68 forms an inlet 70 which can be connected to the conduit 18 when suitably operatively connected to the inlet portion 68, whereby ice flakes are transmitted. from the conduit 18 through the bore 70 to the interior of a low-extruded extruder chamber 72 formed in the interior of the housing 60. According to a feature of the invention, the axis of the through hole 70 is laterally offset a distance D (see Fig. 9) from the longitudinal axis of the ice extruder chamber 72 for reasons, which will be explained in more detail below.

As most clearly seen in Fig. 3, the housing 60 comprises a cylindrical part or part with a uniform diameter 74 at the end, which is closer to the unit 54 and which also comprises a part 76 shaped like a truncated cone or tapered at one end near the flange part 66. Means in the form of a plurality of longitudinally extending, circumferentially spaced reinforcing flaps or strips 78 are suitably formed around the portion 76 to improve the structural integrity of the housing 60.

The housing 60 also includes an outlet portion 80 which is disposed on the opposite side to the flange 66 from the portion 76 and it forms an ice extruding opening 82 which preferably has a square cross-section and comprises spaced, parallel sides 84 and 86 and spaced parallel upper and lower surfaces 88 and 90. The outlet opening 82 is arranged to be connected to the interior of the extrusion chamber 72, which consists of a cylindrical part 92 and the part 94 formed as a truncated cone, which are located in the part 74 and 90, respectively. the portion 76 of the housing 60. A plurality of longitudinally extending, circumferentially spaced, and radially projecting grooves 96 are formed within the inner circumference of the chamber 72, which grooves 96 serve as guide means for guiding the ice flakes when the ice is compressed and compressed. during its displacement towards and through the outlet opening 82. Within the lower side of the housing 60 a suitable outlet opening 98 has been arranged, which can be connected to a suitable pipe or the like with the outlet of the system or elsewhere, so that water, which is squeezed out of the ice flake product below the blackmail, can be removed. The housing 60 is arranged to be fixedly connected by means of a plurality of suitable fastening elements 100, e.g. screws, bolts or the like, which extend through suitable openings in the flange 64 and through the center of located openings in the mounting pad 102 and are suitably attached to the front surface of the housing 66, whereby the housing 60 is fixedly mounted on and extends from the housing 66, in the manner best seen in FIG. 2. In a suitable embodiment of the invention, the housing 60 has been made by a precision casting method, which has been found to be preferable, since it thereby obtains a relatively inexpensive, high quality construction.

It should be noted, however, that many different manufacturing methods can be used in the context of the invention.

The feed screw 104 comprises a body formed or tapered substantially as a truncated cone with a larger diameter end portion and a smaller diameter end portion and is arranged coaxially in the chamber 72.

As best seen in Figures 2-5, an ice extruding feed screw is rotatably mounted in the interior of the chamber 72, which as a unit is designated 104 and which is constructed in accordance with the present invention.

With the body 106 integrating is formed a substantially cylindrical shaft or support part 108, which is formed in an internally threaded bag bore 110, which is arranged to be screwed together with the outer end of the output shaft 58 to rotate in accordance therewith.

As shown in Fig. 3, the shaft 58 cooperates with the shaft part 108 to support the feed screw 104 in the chamber 72 in a lever-like manner. The feed body 106 is also formed with a spiral wing or a feed blade, which as unit is designated 112 and which extends spiral over the entire length of the conical part of the body 104.

As shown in Fig. 5, the profile shape of the feed blade 112 is limited in part by an imaginary cylindrical surface 114, the axis of which coincides with the axis of rotation of the auger 104 and also by an imaginary surface 116 shaped like a truncated cone, the axis of which is also coaxial with the auger 104. shoulder. As can be seen from a comparison between Figures 3 and 4, the imaginary surfaces 114 and 116 substantially correspond to the inner shape of the portions 74 and 76 of the housing 60. In a suitable construction, the tapered surface 116, which is conceived as a truncated cone, is larger than the taper at the root of the feed body 106, i.e. greater than the taper of the conical surface of the body 106. A suitable construction is indicated in Fig. 5, where the taper of the surface 16 amounts to about 250 while the taper at the root of the feed body 106 is about 16 °.

According to one of the features of the invention, the outer peripheral edge of a part of the feed blade 112, which is delimited by an imaginary cylindrical surface 114, is formed with a plurality of grooves, which as a unit are denoted by 118. Each of the grooves is delimited by a larger and a smaller area 120 resp. 122, which are arranged substantially 90 ° offset from each other and in a suitable embodiment of the invention the blade 112 has been formed with eight such grooves, which along the circumference and axially separated from each other along the blade 112 by about 60 °, the grooves 118 are intended 7813313-9 to function for efficient feeding of the ice flakes inwardly through the inlet 70, after which the ice is packed into high quality ice.

At the outlet end of the housing 60, i.e. according to Figs. 2 and 3, the right end of the housing 60 has been fitted with a crushing head, which as a unit is denoted by 124. The crushing head 124 consists of a body 126, which is formed with a substantially radially outwardly extending flange 128, which is arranged to be fastened by means of suitable screws, bolts 130 or the like to the flange part 66 of the housing 60.

The interior of the body 126 of the crushing head is formed with a longitudinally extending outlet, which as a unit is designated 132, and its inlet end 134 is slightly enlarged and arranged to enclose the projecting part 80 on the housing 60, which is most clearly shown in fig. 3 and 7. The outlet end of the passage 132 forms an outlet opening 136 »which is bounded by vertically extending, separated, parallel side walls 138, 140 and by horizontally extending, separated upper and lower walls 142, 144. As can be seen most clearly from Fig. 3 tapers the inner ends of the side walls 139, 140 as most clearly shown at 146, 148, while the upper wall 142 is formed with a sloping surface forming a crushing ramp 150, which operates in the manner described below by assisting in the crushing of the solid bar or pillar of ice, which is produced as the ice flakes are pressed through the outlet opening 82, into ice cubes or ice cubes of predetermined length, which t shall be described in connection with the explanation of the entire operation according to the invention.

As already mentioned, the ice cubes or ice cubes produced by the ice squeezing mechanism 20 are fed through a suitable conduit 22 to a remote location, e.g. the already mentioned storage container or dispensing device, which is schematically indicated and 7813313-9 denoted by 24. The inlet end of the conduit 22 is arranged to be attached to the outlet end of the crushing head 124 by means of a pair of holding brackets, which are shown in Fig. 3 and which have bracket 152 comprises a support arm 154 with an end part 156 at one end, which is fixed by means of said screws, bolts 130 or the like at the crushing head 124. The opposite or outer end of the brackets 152 comprises arcuate clamping parts 158, which are arranged to clamp the end of the conduit 22 at the outlet end of the crushing head 124 in such a way that inadvertent detachment of the conduit 22 from the crushing head 124 is prevented even under the pressure conditions which arise during the squeezing out of the ice.

When operating the system 10 and assuming that the housing 26 in the ice maker 12 is fed with a suitable amount of water through the line 14 and that the cooling system 15 can be operated to freeze this water around the inner circumference of the freezing housing 26, operation of the motor 30 will result in a rotation of the feed screw 28 so that ice flakes are fed from the upper end of the housing 26 into the lead_18. This ice flake product is fed through the conduit 18 into the bore 70 in the extruder housing 60, from which this ice product is introduced into the interior of the extruder chamber 72. Assuming that the drive motor 50 is fed to effect drive movement of the belt 52 and the drive shaft 58 is brought to extrude the screw 54 to rotate in the interior of the chamber 72. Such a rotation of the feed screw 104 causes the ice flakes to be compressed and compressed while displacing longitudinally along the interior of the chamber 72 and pressed axially out through the outlet opening 82. Thanks to the square the cross-section of the opening 82, the ice bar or ice column squeezed thereby will have a corresponding cross-section. When this rod or pillar is discharged through the opening 82, it engages the crushing ramp 150 in the interior of the crushing head 124, which causes the ice pillar to break into separate ice cubes or ice cubes of substantially uniform length, and thanks to this uniform, predetermined cross-section of this ice, it becomes possible to feed the ice cubes through the conduit 22 to a remote location, e.g. an ice container in a dispenser 24, without the ice accumulating in the conduit 22. In a suitable embodiment of the invention, the shape and cross section of the conduit are chosen so that its diameter is only slightly larger than the diagonal distance across the substantially square cross-sections of the ice cubes, which means that the transport of the ice cubes is facilitated through the line 22 only under the influence of the force generated by squeezing further ice through the opening 82. The line 22 may consist of a flexible hose, e.g. a suitable rubber or plastic hose with the required sanitary properties, and it should be noted that the cross-sectional shape of the conduit 22 is not critical provided that its dimensions adhere closely to the dimensions of the ice transported through the conduit. It should be pointed out that one of the essential advances and advantages of the invention is to be seen in the fact that the so-called the ice cubes thus produced have essentially the same shape both at the inlet and at the outlet of the conduit 22, which is achieved thanks to the fact that the ice flakes are compressed and formed in advance into separate particles, with uniform cross-sectional shapes, before the ice is introduced. in the conduit, so that it does not disintegrate under the influence of the compression force exerted during its passage through the squeezing mechanism 20 to the storage container 24 or the like.

Another important feature of the invention is to see therein that ice cubes of very high quality are obtained, the term "high quality" meaning that the ice is substantially free of entrapped bubbles, impurities and minerals as well as on excess water, which is all squeezed out out of the ice, as it is compressed and compressed during its movement towards and through the ice outlet opening 82.

As already mentioned, both excess water and any minerals or impurities therein will be removed from the chamber through the outlet opening 98.

Another important feature of the invention is to see therein that the laterally offset inlet opening 82 and the many grooves 118 cooperate to facilitate the feeding of the ice flakes into the interior of the squeezing chamber 72 relative to prior art ice squeezing devices. This characteristic, together with the arrangement of the many circumferentially spaced, longitudinally extending grooves and the soft deformation of the extrusion chamber 72, when its circumference ends at the outlet opening 82, results in the production of said high quality ice product at slightly less pressure than at previous pressures. known constructions.

Another feature of the invention is that an equal volume of ice cubes can be produced by means of the invention while consuming a considerably smaller amount of energy than with ordinary equipment for producing ice cubes. Accordingly, by means of the invention, not only an agent for the production of ice cubes of very high quality has been obtained, but also the production of ice products has been made possible at considerably lower operating costs for the ice machine.

The invention is not limited to the embodiments shown and described, but many modifications are known within the scope of the appended claims.

Claims (6)

7813313-9 12 P A T E N T K R A V An ice apparatus, comprising an ice flake producing mechanism (12) having an outlet portion for discharging ice flakes, the mechanism comprising a cooling chamber and a rotatable extruding screw (28), an extruding device (20) having an extruding body, which forms a circular chamber (72) having a truncated cone portion (76) and having an inlet (70) in the circular portion (74) of the chamber; ice conducting means (18) for transferring ice flakes from the ice flake outlet to the extruder body inlet (70); ); an ice-squeezing feed screw (104) rotatably mounted in the chamber (72), the feed screw (104) having a helical cone-shaped feed blade (112) for feeding ice, the feed blade (112) having substantially the same diameter meters and length as the corresponding chamber section; an outlet opening (82) extending parallel to the axis of rotation of the screw (104) and located at the narrow end of the chamber (72), characterized in that the body of the feed screw (106) and the wall of the chamber (72) therebetween form an annular space with progressively decreasing radial extent, in which space passing ice flakes are dewatered and compressed into a relatively solid mass of ice and carried out through the outlet opening (82), and the inlet (70) is arranged substantially perpendicular to the longitudinal axis of the chamber (72). and with its center line offset in the lateral direction relative to the axis of rotation of the auger (104) and that the blade (112) of the auger (104) is formed with a plurality of axially and circumferentially spaced grooves (118) at the periphery of the blade, which grooves are spaced a certain angle along the blade (112). Apparatus according to claim 1, characterized in that means are provided at the largest diameter of the chamber for forming a lever-like support for the auger (104). 7813313-9 15 Apparatus according to claim 1, characterized in that the axis of rotation of the auger (104) is substantially horizontal and that a crusher element (124) is arranged outside the outlet, which is arranged to break through ice passing through the outlet into separate ice cubes with essentially uniform cross-sectional shape. Apparatus according to any one of the preceding claims, characterized in that the grooves (118) of the auger are spaced apart 60 ° (1 °). Apparatus according to claim 1 or 2, characterized in that the degree of tapering of the body of the feed screw (104) formed as a truncated cone differs from the degree of tapering of an imaginary, truncated cone surface (116) for limiting the squeezing bead (112), the degree of tapering of the imaginary, truncated cone-shaped surface being greater than the degree of tapering of the body (104). Apparatus according to any one of the preceding claims, characterized in that the outlet opening (82) is arranged substantially axially opposite the axis of rotation of the feed screw (104) and that the height is formed with a forearm extending in the longitudinal direction, along the circumference separate grooves for controlled movement of the ice as it is fed from the inlet (70) to the outlet opening (82).