SE456526B - ICE MACHINE WITH FEED SCREW FOR MANUFACTURING ISBITS - Google Patents

Description

456 526 2 compressed and packed together and water removed, is certainly much more efficient than the conventional ice cube making equipment described above, but so far this type of equipment has only been able to produce ice of a quality inferior to that obtained with the ice cube type. When producing ice cubes or ice cubes of various shapes, a definitive distinction is made between ice cubes of the type produced with the conventional ice machines mentioned at the outset and ice in the form of flakes, which are formed under pressure, since the first type of ice is hard, clear and regular in its nature, ice of the type flakes in the form of irregular ice cubes, on the other hand, is not at all as hard or clear as the ice produced with the type of equipment that forms ice cubes.

The present invention relates to a new and improved ice machine of the type in which ice is formed in the form of flakes but in which the disadvantages which have been associated with previous machines of similar type have been eliminated and in which ice of very high quality is produced and in pieces of relatively uniform size in contrast to the irregular ice cubes of low quality which have hitherto been obtained with machines of similar type. To achieve this, the ice machine according to the invention is characterized by means for generating ice bodies and consisting of a substantially cylindrical ice formation chamber, and the ice body generating means comprises means for feeding coolant substantially in the vicinity of said chamber and means for feeding water into the interior of the chamber, so that the proximity of the coolant in the chamber causes said water to freeze into ice against the interior of the chamber, that said ice body has a substantially cylindrical cross-section and radial inner and outer sides, that a feed screw is movably arranged in the interior of the chamber to displace the frozen water from the chamber to form said ice body therein and to cause the ice body to be displaced towards and into engagement with an ice discharge means, which has substantially axially extending ice discharge openings, which openings are arranged immediately above the ice body, so that a part of the ice body is displaced through the openings upon upward displacement of said ice body, and the outlet openings have a dimension which, measured radially in the chamber, is greater than the radial thickness of the ice body, such that the cross-section of said body, which is displaced through the opening, has at least one side spaced from the wall of the opening to form a flow passage through which unfrozen water in the body can flow through the opening back into the ice-producing means.

Further features of the ice machine according to the invention are apparent from the subclaims.

The invention and the advantages and features associated with it will be described in more detail below with reference to the accompanying drawings, in which Fig. 1 is an enlarged section through an ice machine according to the present invention, Fig. 2 is a bottom view of the ice dispensing member included in the ice machine shown in Fig. 1, Fig. 3 is a larger scale partial section along line 3-3 in Fig. 2, Fig. 4 is a partial cross-section through a part of the ice feeder screw and an ice dispensing opening connected thereto, Fig. 5 is a partial section along line 5-5 in Fig. 4, and Fig. 6 is a perspective view of an ice cube produced in the ice machine according to the present invention.

As can be seen from the drawings and particularly from Fig. 1, the ice machine 10 according to the present invention, which is of the type provided with a feeding screw, consists of the following main parts, namely an elongated, hollow, cylindrical or tubular container 12, in which a screw member in the form of an elongated feeding screw 14 is rotatably arranged.

The feed screw 14 is formed with an upper and a lower part 16 and 18 respectively of smaller diameter than the screw, which parts are rotatably mounted, as indicated at 20 and 22 in Fig. 1. The feed screw 14 has an elongated, generally cylindrical central part 24, which is formed with a continuous, helical flange or screw thread 26, which forms a helical edge 28 for scraping off ice and which is located closely adjacent to the inside of the tubular container 12. The outer circumferential surface of the feed screw part 24, i.e. the core diameter, and the inside of the container 12 form between them an ice formation chamber, around which a cooling coil 32 is arranged. The cooling coil 32 is surrounded by a jacket or casing 34, which in turn is located inside a layer of a suitable heat-insulating material or the like, which as a unit has been designated by 36. In a well-known manner, water required for ice production is fed into the ice formation chamber 30 through suitable water lines (not shown), after which, during operation of a cooling system connected to the machine, coolant will flow through the cooling coil 32, whereby a thin layer of ice is continuously formed around the entire tubular container 12 on its inner circumferential surface or inside. Upon rotation of the feed screw 14 by means of any suitable drive motor or similar drive means (not shown), which is drivably connected to the feed screw 14 via a drive shaft 38, the ice layer will be moved axially upward by the helical flange or ramp 26, whereby the ice is given the shape of a generally cylindrical or tubular ice body with a radial thickness or size corresponding to the radial space between the inner circumferential surface of the container 12 and the core diameter of the feed screw.

The cylindrical ice body, which in Figs. 4 and 5 has been designated by I, is moved upwards in the chamber 30 by the action of the rotating feed screw flange 26, whereby the uppermost part of the ice body 1 is subjected to a compacting and forming process, which results in the ice being formed into separate ice cubes or pieces of ice, one of which is shown in Fig. 6, in the manner to be described in more detail below.

Adjacent to the upper end of the cylindrical container 12 is an annular mounting flange 40, which is formed with a number of internally threaded openings 42. The mounting flange 40 has the function of effectively supporting an ice pressing and ice dividing member, which as a unit has been designated by 44 and is placed at the upper end of the container 12. In detail, the member 44 consists of a generally cylindrical body 46 with a radially outwardly directed mounting flange 48, which is formed in one piece with the lower end of the member and is arranged to be mounted on top of the flange 40 in the manner best shown in Fig. 1. The cylindrical body 46 is further provided with an upper fastening flange 50 and the two flanges 48 and 50 are formed with bores 52 for fastening bolts 54 or similar members, with the aid of which the ice pressing member 44 can be fastened to the flange 40. Directly on top of the member 44 is placed an elbow-shaped ice feeder pipe 56, which is provided with a mounting flange or the like 58, in which openings 60 have been received for fastening bolts 62 or the like, with the aid of which the feeder pipe 56 can be effectively fastened to the upper end of the ice pressing and ice dividing member 44.

As the cylindrical ice body I is forced upward by the rotating feed screw 14, it is subjected to the compacting or pressing action of the means 44, whereby ice cubes of relatively uniform size and of high quality are formed, and these ice cubes are moved upwardly and into the elbow-shaped feed tube 56 and along a discharge path 64, after which the ice can be transferred to a storage location, located either adjacent to or separate from the machine 10. The above-described mounting arrangements for the elbow tube 56 for connecting it to the means 44 indicate only one of several suitable ways of securing the feed tube 56 in this operative position, but other mounting arrangements are of course also possible within the scope of the invention. Thus, for example, the elbow tube 56 may be rotatably or adjustably secured to the top of the means 44 in such a way that it can be easily and conveniently positioned in various ways, depending on the intended installation. It should also be emphasized that suitable sealing means, for example in the form of O-rings or the like, can be arranged adjacent to opposing surfaces of the member 44 and the flange 40 and/or elbow 56 connected thereto, as shown in the drawings, to prevent water leakage in a known manner.

The ice pressing and dividing member 44 has a central portion 66, the underside of which is formed with an annular blind bore or cavity 68.

As is most clearly seen in Fig. 1, a suitable anti-friction bearing means, designated as a unit by 70, is arranged in the bore 68 to rotatably support the smaller diameter upper end portion 16 of the feed screw 14.

Radially outwardly from the central portion 66 of the member 44 is disposed an intermediate portion, which as a unit is designated 72 and is located substantially axially directly above the ice-making chamber 30. According to the present invention, the portion 72 is formed with a plurality of circumferentially spaced and axially extending ice discharge openings extending from the underside of the member 44, i.e. the side of the member 44 facing the ice formation chamber 30 to the open upper side of the member 44, as best seen in FIG. 1. All of the openings 74 are identical in size and shape and are arranged so that the center axis of each opening 74 is located along an imaginary circle, the center of which is coaxial with the geometric axis of the feed screw 14 and the container 12 and the diameter of which is larger than the core diameter of the feed screw 14 but smaller than the inner diameter of the container 12. According to one embodiment of the present invention, the diameter of this imaginary circle, designated by the letter C in FIG. 5, is such that the center of each opening 74 will be located radially between, i.e. halfway between or equidistant from the core diameter of the feed screw 14 and the inner wall of the container 12.

As best seen in FIGS. 3-5, each discharge opening 74 has an upper cylindrical portion 76 and a lower tapered portion 78 in the form of a truncated cone. The portions 76, 78 of the openings 74 are coaxial, as can be seen in the drawings. As shown in FIG. 3, the ice discharge openings 74 are spaced apart in the circumferential direction such that their tapered lower portions define downwardly directed converging surfaces 80 and 82 between each pair of adjacent openings 74, the surfaces 80 and 82 radiating together into a generally radially disposed ice cutting edge 84 between each pair of adjacent openings 74, with the edges 84 located in a radial plane defining the upper axial end of the ice formation chamber 30 and in the same plane as the underside of the ice pressing and breaking means 44. According to one embodiment of the invention, the lower tapered portions 78 of the discharge openings 74 are formed by an angle with the geometric axes of the openings 74 of between 15 and 25°, preferably about 20°. According to In one embodiment of the invention, the desired high ice quality is obtained when the diameter of the openings 74, and especially the diameter of their upper parts 76, is in a certain ratio to the radial thickness of the ice body I or in other words to the radial distance between the core diameter of the feed screw 14 and the inner diameter of the container 12. More specifically, the diameter of the upper part 76 of each opening 74 should suitably amount to about 1.2 times the radial thickness of the ice cylinder I or the radius of the inside of the container 12 minus the core diameter of the feed screw 14. According to a suitable embodiment of the invention, the ice pressing means or breaking means 44 is formed with 16 ice discharge openings 74 arranged at equal distances from each other in the circumferential direction, which are located along the circle C, which has a diameter of 67 mm, the diameter of the upper parts 76 of the openings 74 being 11 mm and the diameter at the very bottom of the lowermost parts 78 being 14 mm, and the lower parts 78 tapering 200 (included angle) and the ice cylinder having a radial thickness of 8 mm.

According to the present invention, when the cylindrical ice body I is forced upwardly toward and into engagement with the underside of the member 44 under the action of the feed screw 14, the upper end of the ice body is divided into equal segments or bars by the edges 84 between adjacent discharge openings 74. These segments or bars are forced vertically upwardly by the upwardly moving ice cylinder, the ice being compressed so that the bars retain their shape as they are forced upwardly through the openings 74 and into the space immediately above them. As can be seen from Fig. 1, a substantially radially inwardly and upwardly inclined ramp or surface 90 is formed around the inside of the upper part of the member 44, which is substantially directly above the upper parts 76 of the openings 74, so that the ice bars which are pressed out of the upper end of the openings 74 will abut against the ramp 90 and thereby break off or disintegrate into ice cubes of substantially equal lengths and will then be fed forward along the conveyor path 64 by subsequent, newly formed ice cubes to an ice storage (not shown).

As a result of the diameter of the upper portions 76 of the openings being slightly larger than the radial thickness of the cylindrical ice body I, as can be seen from Figs. 4 and 5, the ice bars formed by the ice advancing through the openings 74 will have portions on their radially inner and outer sides which are spaced from the adjacent peripheral wall of the openings 74. The spaces thus defined form water flow channels for excess water in the ice body. During the compaction and pressing process which takes place when the ice body is forced upward through the openings 74, this water can therefore flow downwards, back into the ice formation chamber 30, where it can be used as ice formation water. Thanks to these flow passages, considerably larger amounts of water can leave the ice bars than has been possible with previously known ice machines, with the result that the quality of the ice produced with ice machines according to the present invention is noticeably higher than what has hitherto been achieved with known equipment. The quality of the ice produced with the ice machine according to the present invention is of the order of 80-85%, while the quality of previous machines producing ice in the form of flakes is 60-65%. With the machine according to the present invention, ice of very high quality can thus be produced without the disadvantages associated with standard machines of the known type.

In addition to the above-described advantages of the ice machine according to the invention in producing high quality ice cubes or ice pieces, the invention is also advantageous from the point of view that radial load on the bearing of the feed screw is reduced to a minimum by bringing the cylindrical ice body I upward through the discharge openings 74 in contrast to the lateral discharge devices with which previously known ice machines are equipped. Furthermore, since the feed pipe 56 can be selectively rotatably attached to the upper end of the ice machine 10, the machine can be installed anywhere. Furthermore, since the ice pressing and ice crushing means 44 consists of a single separate part, it becomes easy to replace and exchange it for inspection and repair or for changing the size of the ice cubes produced.

The invention has been described above with reference to one embodiment, but of course many modifications and changes to individual parts are possible within the scope of the following patent claims.

Claims (9)

q '456 526 P A T E N T K R A V Ice machine for producing compact ice bodies of high quality and relatively uniform size, characterized by means (12) for generating ice bodies (7) and consisting of a substantially cylindrical ice-forming chamber (30), together with the means producing ice bodies (I) comprises means (32) for feeding coolant substantially in the vicinity of said chamber (30) and means for feeding water into the interior of the chamber (30), so that the proximity of the coolant in the chamber (30) causes said water freezes to ice against the inside of the chamber (30), that said ice body (I) has a substantially cylindrical cross-section and with radially inner and outer sides, that a feed screw (14) is movably arranged in the interior of the chamber (30) to displace it. freezing the water from the chamber (30) to form said ice body therein and to cause the ice body (I) to be displaced towards and into engagement with an ice discharge means (44) having substantially axially extending ice discharge openings (74) which open ( 74 ) are arranged immediately above the ice body, so that a part of the ice body (I) is displaced through the openings (74) when displaced upwards of said ice body (I), and the outlet openings (74) have a dimension which, measured radially in the chamber (30), is greater than the radial thickness of the ice body (I), so that the cross-section of said body (I), which is displaced through the opening (74), has at least one side spaced from the wall of the opening (74) to form a flow passage, through which unfrozen water in the body can flow through the opening (74) back into the ice-producing means (12). Ice machine according to claim 1, characterized in that the radial dimension of the outlet opening is larger than the radial thickness of the substantially cylindrical ice body. Ice machine according to claim 1, characterized in that the ice discharge opening (74) is circular and has a diameter greater than the height of the ice body (I). 456 526 »D- Ice machine according to one of the preceding claims, characterized in that the diameter of the discharge openings (74) is larger than the radial dimension between the inner diameter of the container (12) and the core diameter of the feed screw (14). Ice machine according to one of the preceding claims, characterized in that the ice discharge means (44) is formed with several circumferentially spaced and axially extending discharge openings (74), the geometric axes of which are located along an imaginary circle, whose center point is coaxial with the geometric axis of the auger (14) and whose diameter exceeds the core diameter of the auger (14) but is smaller than the inner diameter of the container: (12). Ice machine according to claim 5, characterized by a radially inwardly and upwardly inclined ice disintegration ramp (90), which is arranged above the openings (74) to force the ice fed upwards through the openings to be bent inwards and divided into ice cubes of substantially uniform size. Ice machine according to one of the preceding claims, characterized in that the ice discharge openings (74) consist of an upper cylindrical part (76) of uniform diameter and a lower, tapered part (78) in the form of a truncated cone. . Ice machine according to claim 7, characterized in that the discharge openings (74) taper at an angle of about 200. Ice machine according to claim 8, characterized in that the diameter of the upper part (76) of the discharge openings (74) is about 1.2 times the radial distance between the inner diameter of the container (12) and the core diameter of the feed screw (12). // »