• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    IMPROVEMENTS IN OR CONCERNING COOLING. The present invention relates to improvements in or relating to cooling. Applicants describe a cooling apparatus comprising a cavity for receiving a product to be cooled. The apparatus comprises a rotating means for rotating a product received in the cavity and a liquid for cooling supply means for supplying a liquid for cooling in the cavity. The apparatus further comprises means for applying additional movement to the cavity.
    公开号:BR112012023876B1
    申请号:R112012023876-0
    申请日:2011-03-17
    公开日:2021-04-20
    发明作者:Vartan Grigorian
    申请人:Enviro-Cool Uk Limited;
    IPC主号:
    专利说明:

    [001] The present invention relates to improvements in or relating to cooling.
    [002] In catering, retail and entertainment sectors, various forms of vending devices are used to keep products refrigerated. For cold beverages these devices form two typical groups - commercial beverage coolers and cold beverage vending machines. The two types of device are essentially large glass front coolers with hinged or sliding doors in the case of the first group (for manual dispensing) or a dispensing mechanism in the case of the second. They pre-cool and store ready-to-purchase beverages. In many cases, beverages are kept at low temperatures for long periods before they are eventually purchased. As a result, considerable energy is potentially used unnecessarily. Compounding the problem, both types of devices operate inefficiently. In use, beverage coolers in the first group experience substantial loss of cold air every time the large door is opened. Vending machines must provide easy passage to the vending tray where the item is picked up by the user, resulting in poor sealing. Cooling systems generally have a requirement to be exerted through background operating cycles to maintain efficiency, however this uses additional energy not directly contributing to the cooling of the content.
    [003] It is also known that many beverage retailers store beverages in refrigerated cabinets with an open front for easy access and product visibility. These cases obviously suffer even greater energy waste.
    [004] The net result is a high level of wasted electrical energy used keeping beverages in a long-lasting cold state ready for purchase, regardless of when it may occur.
    [005] Energy waste is not confined to associated locations that have vending machines. Many small corner stores, gas stations and coffee shops have beverage refrigeration cabinets. For these operators, electricity costs will represent a high proportion of their operational overhead. Waste of energy is not the only issue. Since refrigeration systems generate heat, often the waste heat energy by-product from the refrigeration system causes undesirable heating of the area located around the machines. This creates an inconsistency in which users must drink their beverages satisfactorily chilled in unsatisfactorily hot areas.
    [006] Cooling speed is also an issue, particularly in establishments having a high turnover of beverages, such as at special events - concerts, sporting events and so on. Often in the event state, beverages are adequately cooled by having been in refrigerators for several hours. However, after the event is taking place, the volume of beverages being sold exceeds the capacity of the coolers to chill additional beverages. Drinks should then be sold only partially chilled or not chilled.
    [007] The present invention seeks to address these problems by providing a device that allows cooling beverages on demand. The device can be a standalone device or it can be incorporated into a vending machine.
    [008] The applicant's previous application, WO2011/012902, describes a cooling apparatus comprising a cavity for receiving a product to be cooled. The apparatus comprises rotation means for rotating a product received in the cavity and cooling fluid supply means for supplying a cooling fluid to the cavity. The reader should refer to that publication for additional background. The rotation means is adapted to provide pulsed or non-continuous rotation for a predetermined period.
    [009] Applicants have developed an apparatus comprising a cavity for receiving a can or other container for a beverage to be cooled. The cavity includes a motor driven turntable to allow the can to be rotated at speed and also includes means to retain the can in position on the turntable while allowing rotation. The apparatus also includes a supply means for a coolant. The cavity itself can be rotated or the container can be rotated in the cavity.
    [010] Sealed can cooling equipment was manufactured to utilize a salt water solution that is chilled to approximately -16°C, in a cooling tank with a rotary agitator to reduce salt solidification. A diaphragm pump was used to fill the cooling vessel, at a rate of up to 5 litres/min. the cooling vessel is designed to accept a standard can, which can be rotated at 12 Hz/720 rpm. Pump flow rate and can rotational speed are controllable. Real-time beverage cooling rates were recorded.
    [011] Applicants have determined that, during rotation of a can, a forced vertex develops whose depth within the can depends on the speed of rotation. Forced convection occurs and creates artificially induced convection currents within the can. When the rotation is then stopped, a falling or free vertex forms and natural convection occurs, promoting mixing of the can contents, but without incorporation of air bubbles that could lead to excessive nucleation and effervescence.
    [012] However, in a static can without this ice slurry apex, colder beverages being denser, sink to the base of the can. Mixing the contents of the can is very poor leading to poor thermal uniformity, and also leading, in many cases, to formation of ice or “ice paste”. In the applicants' previous work, they determined that pulsed or intermittent rotation overcame this problem. However, it introduces delays in cooling as the beverage container is slowed down and brought back up to speed.
    [013] The present invention seeks to provide additional improved cooling rates.
    [014] In its broadest sense, the present invention provides a cooling device to cool a product characterized by the fact that the device is adapted to apply movement to the product at least approximately two geometric axes of freedom.
    [015] Therefore, the present invention provides a cooling device that comprises a cavity for receiving a product to be cooled. The apparatus comprises rotation means for rotating a product received in the cavity and a refrigerant supply means for supplying a refrigerant in the cavity. The apparatus further comprises means for applying additional movement to the cavity.
    [016] In a modality, the supplementary movement is a linear movement. Preferably, the linear motion is reciprocating motion.
    [017] Preferably, the reciprocating motion is at a rate of at least 50 swings per minute, more preferably at least 80 swings per minute, even more preferably at least 100 swings per minute. Advantageously, the reciprocating motion is at a rate of approximately 120 oscillations per minute.
    [018] In an alternative embodiment, the rotation means is adapted to rotate the product around two parallel non-coincident geometric axes. Preferably, one of the geometric axes is a geometric axis of the product.
    [019] Preferably, the rotation means is adapted to rotate the product at a rotational speed of 90 turns per minute or more, more preferably at least about 180 turns per minute, even more preferably at least about 360 turns per minute.
    [020] Optionally, the rotation means is adapted to rotate a product in the cavity. Alternatively, the rotation means is adapted to rotate the cavity.
    [021] Preferably, the refrigerant is a coolant and the coolant supply means is adapted to provide a flow of coolant to the cavity.
    [022] Preferably, the cooling fluid is supplied to the cavity at a temperature of -10°C or less, more preferably -14°C or less, even more preferably -16°C or less.
    [023] In certain embodiments, the apparatus comprises a plurality of cavities as defined above.
    [024] In typical embodiments, the apparatus is incorporated into a vending apparatus and the vending apparatus further comprises insertion and removal means for inserting the product to be cooled into the cavity and removing the cooled product therefrom.
    [025] Preferably, the vending apparatus further comprises storage means for storing a product or range of products and selection means for selecting a product from the storage means for insertion into the cavity.
    [026] The above and other aspects of the present invention will now be described in further detail, by way of example only, with reference to the accompanying drawings, in which Figure 1 is a perspective view of a first embodiment of an apparatus according to present invention; Figure 2 is a graph showing cooling rates obtained in various experiments of the apparatus of Figure 1; and Figure 3 is a schematic plan view of a second embodiment of an apparatus in accordance with the present invention.
    [027] In its crudest form, the coolant is simply poured into the cavity and then removed at the end of the cooling process. In preferred embodiments, a flow of coolant through the apparatus is provided.
    [028] Figure 1 shows the equipment 10 comprising a cavity 11 for receiving the beverage container mounted on a table 12. The cavity 11 is rotatable by means of an electric motor 13 mounted under the table 12. The table 12 is moved alternately by being slidably mounted on a pair of parallel tracks 14 and induced to move alternately by means of a cam arrangement comprising an eccentrically mounted link rod 15 driven by an additional motor 16. The link rod 15 is adjustable to provide a variable stroke range from 5 to 25 mm. Alternative arrangements will be evident to the person skilled in the art, including gear arrangements to allow for the use of a single engine. Therefore, the apparatus can apply a movement to a beverage container placed in the cavity 11 approximately two degrees of freedom - a rotational movement about the rotational geometric axis of the cavity 11 and a linear movement about the reciprocal direction of movement of the table 12.
    [029] The cooling rates obtained for a 330 ml aluminum can at room temperature are shown in figure 2. The rotational speed in all three cases was 350 revolutions per minute. The reciprocal movement was at a rate of 120 turns per minute with a single stroke length of 18.5 mm (equivalent to a movement of 74 mm/sec). The coolant temperature was -14.5°C flowing through cavity 11 at a rate of 5.25 l/min. the effective cavity volume was 650 ml, equaling an approximately 20mm coolant jacket around a standard diameter canister.
    [030] As a control, the cooling rate obtainable by the apparatus of WO2011/012902 (rotated rotation only without linear movement) is shown as line (i), showing cooling from an exemplary ambient temperature of 22°C to 4°C just above 70 seconds. In comparison, the device in Figure 1 achieved cooling to 4°C in 54 seconds (row iii) and 58 seconds (row ii), an improvement of 18-23%.
    [031] It is suggested that the apparatus leads (at least in an idealized assembly) to the development of a Rankine vertex in the beverage container. Visual observation in a transparent cavity 11 and transparent beverage container confirms this to be the case.
    [032] Other techniques for generating a Rankine vertex or a Rankine-like vertex are possible, including epicyclic rotation, single-plane shaking, and multiple-plane shaking; by introducing asymmetry in the container, for example, by a localized notch, rotation outside the geometric axis or rotation of the container perpendicular to its geometric axis; introducing a shock wave into the container during rotation; or introducing a centripetal force, for example.
    [033] In essence, a vertex like a Rankine-like vertex results in a tangential velocity that is not equal to the angular velocity multiplied by the radius through the entire radius. As a result the drink does not behave like a sold dough - shear is present and mixing occurs.
    [034] In typical embodiments, the device is incorporated into a vending device and further comprises insertion and removal means to insert the product to be cooled in the cavity and remove the cooled product therefrom.
    [035] Preferably, the vending apparatus further comprises storage means for storing a product or range of products and selection means for selecting a product from the storage means for insertion into the cavity.
    [036] The vending apparatus will typically also include payment collection apparatus such as a coin operated mechanism or a card reading apparatus to discount a charge from a card.
    [037] The beverage container of figure 3 shows such an arrangement in which the container is rotated in an epicyclic mode. That is, the apparatus includes primary rotation means for rotating the container, such as a can 20, about its own axis 21 and secondary rotation means for rotating the can axis about a parallel non-parallel secondary axis. coincident 22. Such a rotational arrangement provides greater agitation of the beverage itself, thereby reducing temperature gradients with the container.
    [038] Convective heat transfer is largely governed by the fluid flow regime in the boundary layer. Increasing the velocity gradient in the boundary layer will increase convective heat transfer. While the Reynolds number is a key parameter that governs whether the boundary layer is laminar or turbulent, it can transition due to surface texture or roughness and the local pressure gradient. The more complex movement of the container and coolant provided by this arrangement gives more degrees of freedom to control the thickness and velocity gradient in the boundary layer. This allows the device to maximize convective heat transfer while eliminating ice slurry or ice formation that hampered previous attempts to achieve rapid cooling.
    [039] The present invention also seeks to provide a vending machine that incorporates the device described above. In a conventional vending machine, the entire storage cavity must be insulated, but insulation for a cavity that holds perhaps 400 cans can typically only be achieved using foam or insulating mats or other materials that trap air to prevent heat transfer. These materials are relatively inefficient thermal insulators.
    [040] In addition to providing a vending machine that freezes beverages exclusively on demand, the present invention provides a vending machine in which most cans or other beverage containers are storable at room temperature and only a small number, perhaps 16 or approximately, they are storable at a drinking or reduced temperature.
    [041] As a result, the cavity in which the reduced temperature containers are stored can be insulated by more effective means such as vacuum insulation panels. The cooling apparatus is provided between the ambient storage cavity and the chilled storage cavity.
    [042] The use of two storage zones significantly reduces overall energy consumption and will also reduce the energy rating required for the blast chiller.
    [043] Additional low-level refrigeration for the refrigerated storage cavity can be provided to maintain the correct temperature, but the energy consumption to maintain the temperature in a small vacuum insulated capacity cavity is substantially lower than in machines conventional ones.
    权利要求:
    Claims (7)
    [0001]
    1. Cooling apparatus comprising a cavity for receiving a product (20) to be cooled; rotating means for rotating the product received in the cavity and refrigerant supply means for supplying a refrigerant to the cavity; CHARACTERIZED by the fact that the rotation means is adapted to rotate the product (20) about two parallel non-coincident axes (21, 22); and wherein one of the axes (21) is a product axis.
    [0002]
    2. Cooling apparatus according to claim 1, CHARACTERIZED by the fact that the rotation means is adapted to rotate the product (20) at a rotational speed of 90 revolutions per minute or more, more preferably at least about 180 revolutions per minute, even more preferably at least about 360 revolutions per minute.
    [0003]
    3. Cooling apparatus according to claim 1 or 2, CHARACTERIZED by the fact that the coolant is a coolant and the coolant supply means is adapted to provide a flow of coolant to the cavity.
    [0004]
    4. Cooling apparatus according to any one of claims 1 to 3, CHARACTERIZED by the fact that the cooling fluid is supplied to the cavity at a temperature of -10°C or less, more preferably -14°C or less , even more preferably -16°C or less.
    [0005]
    5. Cooling apparatus according to any one of claims 1 to 4, CHARACTERIZED by the fact that the rotation means is adapted to provide a pulsed or non-continuous rotation for a predetermined period.
    [0006]
    6. Vending apparatus, CHARACTERIZED in that it comprises a cooling apparatus as defined in any one of claims 1 to 5, and further comprising an insertion and removal means for inserting the product (20) to be cooled in the cavity and removing the product cooled from it.
    [0007]
    7. Vending apparatus according to claim 6, CHARACTERIZED by the fact that it further comprises a storage means for storing a product (20) or range of products and a selection means for selecting a product (20) from the storage medium for insertion into the cavity.
    类似技术:
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    同族专利:
    公开号 | 公开日
    US20130180280A1|2013-07-18|
    HK1162655A1|2012-08-31|
    KR20130004498A|2013-01-10|
    SI2547970T1|2015-12-31|
    ZA201206914B|2014-03-26|
    PL2547970T3|2016-01-29|
    AP3598A|2016-02-22|
    GB201104467D0|2011-04-27|
    WO2011114158A2|2011-09-22|
    NZ602376A|2014-04-30|
    WO2011114158A3|2011-11-10|
    EP2547970A2|2013-01-23|
    CN102869934B|2014-10-08|
    AP2012006474A0|2012-10-31|
    JP2013540248A|2013-10-31|
    CN102869934A|2013-01-09|
    GB2479435B|2012-11-28|
    AU2011228841B2|2014-01-16|
    CA2792728A1|2011-09-22|
    MX2012010638A|2012-11-29|
    ES2551410T3|2015-11-18|
    GB2479435A|2011-10-12|
    DK2547970T3|2015-11-02|
    AU2011228841A1|2012-10-04|
    EP2547970B1|2015-08-12|
    HRP20151211T1|2015-12-18|
    PT2547970E|2015-11-13|
    BR112012023876A2|2016-08-02|
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    法律状态:
    2019-01-08| B06F| Objections, documents and/or translations needed after an examination request according [chapter 6.6 patent gazette]|
    2019-11-05| B06U| Preliminary requirement: requests with searches performed by other patent offices: procedure suspended [chapter 6.21 patent gazette]|
    2020-09-08| B06A| Patent application procedure suspended [chapter 6.1 patent gazette]|
    2021-02-17| B09A| Decision: intention to grant [chapter 9.1 patent gazette]|
    2021-04-20| B16A| Patent or certificate of addition of invention granted [chapter 16.1 patent gazette]|Free format text: PRAZO DE VALIDADE: 10 (DEZ) ANOS CONTADOS A PARTIR DE 20/04/2021, OBSERVADAS AS CONDICOES LEGAIS. |
    优先权:
    申请号 | 申请日 | 专利标题
    GB1004453.5|2010-03-17|
    GBGB1004453.5A|GB201004453D0|2009-07-30|2010-03-17|Improvements in or relating to cooling|
    PCT/GB2011/050526|WO2011114158A2|2010-03-17|2011-03-17|Improvements in or relating to cooling|
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