NO300187B1 - bottle cooler - Google Patents

Description

This invention relates to a cooling counter for bottles, cans and similar containers, preferably containing beverages - a so-called bottle cooler - where the bottles etc. are offered for sale while they are continuously cooled by means of cold air which is caused to pass a cooling machine and to circulate around the bottles etc, and where the bottle cooler comprises an annular space which forms a filling part and storage for the bottles etc, and where immediately below the annular space there is a bottle withdrawal point which is bounded downwards by a bottle support shelf, on which the bottles etc are presented for sale, which annular space has an extent that is at least approximately corresponds to 3 60° about a central, vertical axis, which bottle outlet is accessible from the outside from preferably all sides.

A cooling counter/bottle cooler of the type indicated at the outset is shown and described in NO patent application no. 940486. A major advantage of this bottle cooler is that the bottles are accessible from all sides, 360° about a central, vertical axis.

With bottle coolers of this kind, however, it has been shown

to be a problem related to the design and extent of said annulus in the horizontal plane: After the customers have started to remove bottles from the withdrawal point at a filled bottle cooler's annulus, the remaining bottles, above the withdrawal point, i.e. in the annulus/bottle receiving chamber, will have an inclination to form "bridges", as the bottles, which are somewhat wedge-shaped, wedge into each other and lock in a

entangled state in the bottle cooler's annular bearing.

When bottles are removed from the bottle cooler's storage, which is formed by the annulus, so that the bridge(s) are broken, the result is often that a larger number of bottles simultaneously fall into the underlying outlet. This often happens by free fall and to the great consternation of the customers. A bottle of carbonated drink that has made such a free fall in the bottle cooler will easily "fizz" over if it is opened immediately or after a relatively short time thereafter.

The main purpose of the present invention has been to counteract the construction of unwanted "bottle bridges" in the annulus of bottle coolers. Hereby, the invention is based on the idea of limiting the extent of the annular space in the horizontal direction at least in the annular space, but preferably also in the bottle withdrawal point.

For this purpose, a cooling counter/bottle cooler designed in accordance with the introductory section is distinguished by the features stated in the characterizing part of patent claim 1.

An important, but subordinate purpose of the present invention is to dampen the movement/fall of the bottles from the annulus to the underlying bottle outlet.

The common denominator of these objectives is to ensure bottle movement from the annulus to the underlying bottle outlet in as gentle and controlled a manner as possible.

Subordinate features of the invention are apparent from subsequent subclaims.

Broadly speaking, the invention is based on the fact that in any case the annular space, possibly also the underlying bottle outlet, is divided by means of at least one upright dividing wall.

Depending on the size and design of the bottle cooler, in particular the outer diameter of the annular space, two, three or four such upright partitions can be arranged, which are preferably placed at the same angular distance.

By dividing up the annular space, possibly also the outlet point for bottles accessible to all sides by means of said partitions, the resulting separate spaces become so small that the bottles can hardly form "bridges".

The upright partition(s) have, in addition to their primary function, the function of stiffening and supporting the bottle cooler's construction.

In order to dampen the falling movement of the bottles from the annulus, in the annulus according to the invention there can be arranged approximately horizontally protruding, flexible damping means which preferably have the form of several separate damping elements which are placed in a ring shape. The upper surface of these flexible damping elements can slope slightly downwards in a direction radially outwards from a central pipe, which such bottle coolers are normally provided with and which in this case forms a mount for dampers and partitions.

Design examples of bottle coolers/refrigerators according to the invention are explained in more detail below with reference to the drawings, where: Fig. 1 shows a bottle cooler equipped with partitions according to the invention seen from the outside, from one side; Fig. 2 shows a sectional view along the line II-II in fig. 1; Fig. 3 shows a bottle cooler equipped with dampers for bottle fall/movement and partitions according to the invention; Fig. 4 shows a sectional view along the line IV-IV in fig. 3; Fig. 5 shows a vertical section through a somewhat differently designed bottle cooler, equipped with partitions according to the invention; Fig. 6 shows a sectional view along the line VI-VI in fig. 5; Fig. 7 corresponds to fig. 5, but shows the bottle cooler equipped with bottle drop/movement damping means - bottle dampers - but no partitions. By not combining fig. 5 and 7

these become more illustrative than if both partitions and bottle dampers were drawn in one figure;

Fig. 8 is a sectional view along the line VIII-VIII in fig. 7.

In the embodiment according to fig. 1-4, a bottle cooler or cooling counter for bottles/cans comprises a central, upwardly open square tube 1 with a lower, upwardly tapering truncated pyramidal portion 1<1>. Above its upper part, the pipe 1 is surrounded by a concentric mantle 2 which at the top carries a cap 3, which can be removed to enable the filling of the annulus 4 between the mantle 2 and the pipe 1 with bottles not shown, which are intended to end up in one to all edges accessible bottle outlet 5 which lies immediately below the ring space 4 and is bounded downwards by a bottle support shelf 6.

A cooling machine (not shown in Fig. 1-4) is placed in the bottle cooler which cools air which is circulated by a fan not shown, preferably up through the pipe 1 and down into the annular space 4 as well as out over the bottles in the annular space 4 and in the outlet point 5 for bottles.

In order not to run the risk of the bottles getting wedged and being stuck to each other in the annular space 4, according to the invention, upright partitions 7 are arranged, see in particular fig. 2 and 4. By limiting the physical extent of the annular space 4 in the horizontal direction, the divided, separate spaces will have such a small horizontal extent that the bottles are prevented from forming "bridges". This avoids the disadvantages mentioned at the beginning.

An additional effect of the partition(s) is its/their stiffening and supporting effect on the bottle cooler's construction.

In order to dampen the falling or sliding movement of the bottles in the annular space 4 respectively along the outside of the pipe 1 or the inside of the mantle 2, according to the invention, one or more flexible damping means 8, 9, which are shown in fig. 3 and 4, but which in principle is intended to also be used in combination with the partition(s) 7 in fig. 1 and 2.

Each flexible damping member 8, 9 consists of cantilevered tabs 8' which are attached to the tube 1 at the inner end, but which are otherwise free-supporting, elastically yielding and bendable. Such damping tabs 8' are arranged in ring form to form respective annular damping means 8, 9. The overlying ring-shaped, flexible damping means 8 can advantageously have a larger diameter than the underlying damping means 9.

The damping members 8, 9 could, in principle, have been designed for attachment to the inside of the jacket 2 instead of to the outside of the tube 1. The main thing is that the damping means are flexible and project into the bottles' path of fall/movement in the annular space 4, where the bottles come into contact with the damping means 8, 9 and bend them elastically down and are damped, before the bottles continue their movement down towards the outlet point 5. The movement of the bottles becomes thereby controlled without free fall or uncontrolled movement of bottles into the withdrawal point.

In fig. 5 - 8 the invention is illustrated in connection with

another embodiment of the bottle cooler. Partition walls 7 and bottle dampers 8 and 9 are also denoted here with the same reference numbers as in fig. 1-4.

The bottle cooler according to fig. 5-7 also includes a central, upwardly directed pipe 1 with a conical, upwardly tapering lower part 1<1> with an inner vaulted wall which is perforated to allow cooling air to pass through, from the outside into the bottle cooler's cooling machine. The pipe 1 has an underlying extension pipe 10 with a lower extension 11.

In the interior of the bottle cooler, which is surrounded by a double-walled subframe 12, the cooling machine and the air circulation device are arranged. The reference numeral 13 thereby denotes a fan for transporting cooled air upwards through the pipe 1, which at the top has radial openings 1" and is enclosed by a cap 3. The cap 3 is divided at 14, the upper part 3' being removable for filling bottles in the lower cap part 3", which thereby forms a bottle receiving chamber or storage, from which the bottles via the damping means 8 and 9 slide down into the outlet 5, which is bounded downwards by the bottle support shelf 6, which in this embodiment is ring-shaped and slopes upwards in a radially outward direction. The perforated part 1' of the tube 1 forms a 360° lateral support surface for the bottles.

Inside the chassis 12, there is also arranged an evaporator 14 which forms part of said cooling machine, which also, under a horizontal plate 15, includes an air-cooled condenser 16 with associated fan 17 and a compressor 18. Just below the condenser 16, fan 17 and compressor 18 a horizontal heating plate 19 is mounted for evaporation of condensate, which is supplied via a central, vertical pipe 20 through the horizontal plate 15.

It appears from fig. 5 how the three partitions 7 with 120° angular distance stiffen and support the bottle cooler construction. In fig. 5 and 6, damping means 8 and 9 are not shown for the sake of clarity.

The lower ring/sleeve-shaped cap part 3" is stationary in relation to the central tube 1 and is attached to this via spokes 21 and a ring 22 as well as by its lower edge resting with a sleeve-shaped, lower end part 3a on a radial forward

firing part 7<1> of the partitions 7.

The upper cap part 3' is displaceable along the central tube

1 via spokes 23 and a guide sleeve 24.

In fig. 7 and 8 which correspond to fig. 5 and 6, the bottle damping means 8 and 9 according to fig. 3 and 4 signed,

but, on the other hand, not the partitions 7, for previously stated reasons.

In the figures, the partition walls 7 extend over the combined height extent of the main height of the annular space 4 and the height of the bottle outlet 5. A satisfactory effect will be achieved by providing only the annulus 4 with one or more partitions. One bottle damping means, for example 8, is often sufficiently effective to be able to perform the damping of the bottle movement alone; or two or more dampening devices 8,9 can be arranged.

Air is cooled in the cooling machine 14, 16, 17, 18 and brought to

to flow upwards through the tube 10,1 where the air flows out of the upper radial openings 1" and passes downwards through the annulus 4 which is delimited between the tube 1 and the mantle 2 and below it passes along the bottles in the annulus 4 and outlet point 5 and absorbs heat from the bottles, after which the air passes through the perforations of the side support part l' into the interior of the bottle cooler, to be cooled again in said cooling machine 14, 16, 17, 18 and so on, for continuous cooling of the bottles.

Claims (8)

1. Refrigerated counter for bottles, cans and similar containers, preferably containing beverages, a so-called bottle cooler, where the bottles etc. are offered for sale while they are continuously cooled by means of cold air repeatedly passed through a cooling machine (14, 16, 17 , 18) and to circulate around the bottles etc, and where the cooling counter/bottle cooler comprises an upright tube (1,1') which preferably carries cooled air and is enclosed by a mantle (2) and/or a cap (3), so that between the pipe (1,1') and the mantle/cap (2/3) an annular space (4) is formed for filling and storing bottles etc., with an underlying, horizontally open outlet (5) where the bottles etc. lie visible for sale, and are preferably accessible from all sides, receive bottles from the overlying annulus (4) as bottles etc. are removed from the withdrawal point (5), characterized in that at least one upright partition is arranged in said annulus (4) (7), which may possibly str do not dig into the underlying outlet (5) for bottles etc. 2. Refrigerated counter/bottle cooler as specified in claim 1, characterized in that two or more partitions (7) are arranged which are placed at equal angular distances around said pipe (1,1*). 3. Refrigerator/bottle cooler as specified in claim 1 or 2, characterized in that the partition(s) (7) is attached to said pipe (1,1') and possibly also to said mantle/cap (2/3). 4. Cooling counter/bottle cooler as specified in one or more of the preceding claims, characterized in that the partition(s) (7) at its lower end part is shaped complementary to the conical lower part (l<1>) of said pipe (1) , and to an outwardly obliquely upwardly directed, ring-shaped support shelf (6) for the bottles etc. and which delimits the mentioned outlet point (5) downwards, the dividing wall(s) (7) with their opposite edges being shaped, stiffening and supporting against said perforated, conical part (1') of the tube (1) and against said bottle support shelf (6). 5. Refrigerator counter/bottle cooler as specified in claim 4, characterized in that the partition(s) (7) at its outward-facing edge, a little above its lower end, has an outward-facing projection (7') which engages in a shaped, stiffening and repelling manner a downwardly open, sleeve-shaped end part (3a) of said mantle/hood (2/3). 6. Refrigerator/bottle cooler as specified in any of the preceding claims, characterized in that at least one flexible damping member (8, 9) is arranged in the annular space (4) which projects transversely into the annular space (4) and is designed to dampen and slow the downward falling/sliding movements of the bottles. 7. Refrigerator/bottle cooler as stated in claim 6, characterized in that the damping member or each damping member (8, 9) consists of a number of tabs (8', 9') which are assembled in a ring shape, attached to said pipe (1) and directed gently sloping downwards. 8. Refrigerator counter/bottle cooler as specified in claim 6 or 7, characterized in that two or more damping means (8, 9) are arranged which are located at different levels, and that an overlying damping means (8) has a larger transverse dimension than an underlying damping member (9).