The present invention relates to a method and a system for volumetric measurement of beverage in a beverage dispensing system.
Conventional beverage dispensing systems intended for professional or private use such as e.g. the DraughtMaster™ system produced by the applicant company are described in e.g. WO2007/019848, WO2007/019849, WO2007/019850, WO2007/019851 and WO2007/019853, Such beverage dispensing systems are used to store and dispense mainly carbonated beverages such as beer. Using a beverage dispensing system for storing and dispensing beverage provides many advantages compared to using cans or bottles. Most commercial beverage dispensing systems include a tapping system for a simple dispensing of the beverage into a beverage glass and a cooling system for keeping the beverage at a constant and correct low temperature.
For hygienic reasons all parts contacting the beverage must be handled in a sterile way to avoid dirt and bacteria to enter the beverage. Bacterial growth within the beverage will significantly reduce the flavour of the beverage and will pose a serious health problem for anyone drinking the beverage. Therefore, in most modern beverage dispensing systems the beverage container, the dispensing line connected thereto and the tapping valve are for single use only. In this way the beverage will be kept away from any possible contaminants during storage and dispensing. To ensure that the sterility of the parts contacting the beverage is maintained, it is therefore not allowed to disassemble the parts contacting the beverage, i.e. disconnecting the dispensing line from the container or the tapping valve from the tapping line. Such disconnections would compromise the sterile environment of the beverage.
Some beverage dispensing systems, such as the above mentioned DraughtMaster™ system, use a lightweight, collapsible and disposable beverage container or keg for accommodating the beverage and a pressurizing system for allowing the beverage flow from the container to the tapping system. The collapsible beverage container is typically made of thin and flexible plastic material and may even be in the form of a plastic bag. Typical volumes of beverage included in the beverage container are between 5-10 litres for systems intended for private users and between 10-50 litres for systems intended for professional users such as bars and restaurants. Even larger containers, such as tanks of 1000 litres or more may be used for professional users having a very large turnover of beverage, such as for arenas, stadiums or the like. The head space of the beverage container is either very small or non-existent. The filled beverage container is accommodated in an inner volume of a pressure chamber of the beverage dispensing system.
Before a user may start beverage dispensing operations, the pre-filled collapsible container must be installed into the pressure chamber of the beverage dispensing system. The pressure chamber is thereby opened and the beverage container installed therein, whereafter the pressure space is sealed and pressurized. The pressure in the pressure chamber prevents any major loss of carbonization of the beverage and allows the beverage to be propelled to the tapping system via a tapping line by compressing the beverage container. When the beverage container is empty it has collapsed and may be removed from the inner volume by opening the pressure chamber.
A drawback of the above-mentioned beverage dispensing system is that the beverage container normally cannot be inspected without difficulty after installation due to the pressurized inner volume. An inspection can only be carried out after first releasing the pressure inside the pressure chamber. Typically, a beverage container remains up to several weeks inside the pressure chamber and during this time the beverage dispensing system may be used by many people. Therefore, the user wishing to dispense beverage cannot easily determine the remaining amount of beverage in the beverage dispensing system. In contrast, it is very simple for a user to determine the remaining amount of beverage in a bottle or can by either estimating the weight of the beverage in the container or alternatively performing a visual inspection.
A user wishing to perform a series of beverage dispensing operations, e.g. to fill several beverage glasses with beverage for a group of people, may occasionally be operating a beverage dispensing system having an insufficient amount of beverage remaining in the beverage container. The user may therefore occasionally have to interrupt beverage dispensing when the beverage container is empty. Such interruptions are very annoying, especially in case only a few members of the group have been served. If the user were able to have at least an estimate of the remaining beverage, the user might want to use another beverage dispensing system or arrange for a new cool beverage container to be installed in the beverage dispensing system before initiating the beverage dispensing operations. Therefore technologies are needed for estimating the amount of beverage remaining in the beverage container without the need of performing an estimation of the weight or a visual inspection.
One way of determining the volume of the remaining beverage in the collapsible container would be to measure and store the volume of the out-flowing beverage of a beverage container having a predetermined volume. However, not all beverage containers have a predetermined volume, e g when a beverage container from which some beverage has already been dispensed is installed in the beverage dispensing system. Further, as carbonated beverage, such as beer, generates at least some amount of foam during dispensing, foam may already be generated in the dispensing line leading from the beverage container to the tapping system. Such foam causes the volume of beverage to expand and Renders the flow measurements to be less accurate. This may lead the user to believe that less beverage is remaining in the beverage container. Furthermore, measuring the outflow of beverage is undesired since this would necessitate mechanical parts contacting the beverage. Typically, for hygienic reasons all parts contacting the beverage in modern beverage dispensing systems are replaceable and of single use only. This would require the measurement system to be replaceable and thus very expensive.
In the prior art several approaches have been made for measuring the beverage remaining in the beverage container. Some techniques are based on the position of a dispensing valve or beverage tap. One example of an apparatus utilizing the position of the valve or tap to calculate remaining content is described in U.S. Pat. No. 4,225,057 A, which apparatus uses position detecting means coupled to a beverage outlet to detect a movement between an open and a closed position of the outlet. A predetermined flow rate through the outlet allows the calculation of the total amount of fluid passing. Alternatively, as described in U.S. Pat. No. 5,511,694, a calculation of the time during which the handle has been in an open position is used to calculate the remaining volume, which is then shown on a display.
A refined solution is disclosed in US 2008/0071424 which describes a fluid flow measuring system based on a positional flow sensing device coupled to a control valve dispensing mechanism for converting positional information to flow volume using transfer functions based on pressure, line diameter, etc. A compact solution is disclosed in U.S. Pat. No. 7,096,617 B2 in which a tap handle is illuminated by a light source. A motion sensor in the tap handle starts a timer when the tap is moved, which, after reaching a predetermined time, interrupts electrical power to the light source, indicating that the keg is almost empty. In addition to the above documents, references were found which calculate the remaining volume based on actions of other elements of a dispensing device, such as U.S. Pat. No. 7,337,920 B2 which uses a stepping motor to dispense a flavoring fluid, the number of dispenses and the volume of each dispense being used to calculate a remaining volume. Another example is EP 1 218 286 131 in which a volume counter and a memory are mounted on a keg, the amount tapped being used to indicate when a keg is nearly empty.
A number of prior art technologies use the pressure to measure the content of a keg, U.S. Pat. No. 3,311,267 A discloses a sight tube connected to the beer tap line and the headspace, thus allowing the level of beer in the container to be read. Further documents describing technologies which are utilizing the pressure difference between the beverage in the container and the headspace gas are: GB 1 223 848 A, U.S. Pat. No. 3,956,934 A, GB 1 577 499 A, GB 2 077 432 A, GB 2 099 584 A, EP 2 065 685 A2, US 2009/0165477 A1. In addition, a method for measuring the volume of a malted beverage packed in a bag in a large tank is disclosed in EP 0 791 810 A2 in which a detachable pipe bend in the bag has a pressure difference sensor. A further reference disclosing a gauge tube is EP 2 041 525 A1 in which the gauge tube is pressurized to the same pressure as the liquid in the container. A variant on differential pressure techniques for determining the liquid level in a container is disclosed in GB 2 192 989 A in which gas is forced into a spear having an opening at the bottom of the keg. When bubbles start to rise from the opening, the difference in pressure between the supplied gas and the headspace of the keg indicates the level of beverage. A similar technique is described in published GB 2 094 474. Pressure may also be used to measure flow, as described in EP 0 414 156 A2 in which a flow meter includes a line segment of known length, size and material, providing a measurable pressure difference owing to the drag therein. In WO 2004/050537 A2 a technology is described in which the remaining volume of beverage in the beverage container is determined by using the time rate of change of pressure rise in the keg subsequent to a normal dispense cycle. However, this will require a constant rate of gas filling, which may be difficult to obtain by using standard hardware. Pressure fluctuations within the system may also introduce errors in the mathematical determination of the time rate of change of pressure rise.
Yet further prior art technologies determine the volume of the beverage flowing out of the beverage container indirectly by measuring in-flowing gas which substitutes the out-flowing beverage. In this way the problems associated with the direct measuring of the beverage flowing out of the beverage container is avoided. The in-flow of pressuring gas into a container is measured in the technology presented in EP 2 053 014 A1. The remaining amount of the beverage in the beverage container is thereby calculated based on the flow rate of the gas. The drawback of such indirect measurement methods is the possibility of cumulative systematic errors which may significantly affect the end result, i.e. the determination of the volume of beverage in a near empty beverage container. A similar technique for a bottle is described in EP 2 091 858 A1 where a pourer spout has an airflow measurement unit for measuring the inflow of air into a container on which the spout is mounted, and thereby the dispensed volume may be determined.
Further prior art references use the weight of a beverage container to determine the remaining contents. One example has been described in DE 35 11 224 in which a device for registering the liquid content from beverage containers comprises sensors for the container weight. Further references are U.S. Pat. No. 5,837,944 A, GB 2 354 080 A and U.S. Pat. No. 7,255,003 B2.Weight measurements have also been used to dispense a predetermined weight of beverage by monitoring the reduced weight of a supply keg as described in U.S. Pat. No. 5,007,560 A.
Further, temperature-sensitive liquid crystals have been used to detect the liquid level in a container. In U.S. Pat. No. 5894089A a technology is disclosed in which an indicator for detecting a liquid level is described, comprising a vessel having a thermo-sensitive tape wherein during use a hot or cold fluid is poured into the vessel whereby the vessel is pressed against the wall of a container, providing a colour change at the level of liquid in the container. The colour change is caused by the differing heat transport properties of the headspace and the liquid in the container. Further references include U.S. Pat. No. 6,260,414 B1, U.S. Pat. No. 6,925,872 B2 and U.S. Pat. No. 7,302,846 B2. An alternative technique is described in EP 1 009 978 A1 in which a handheld device includes temperature-sensitive means for determining the level of a fluid in a container, further including a microprocessor for calculating the amount of fluid in the container.
Further, electrodes have been used to detect a liquid level, one reference being GB 2 170 602 A, in which the level of a liquid in a vessel is measured using the capacitance between first and second electrical conductors positioned at first and second levels, the capacitance varying with the liquid level. Current flowing between-two detectors may also be used to determine whether the detectors are covered by a liquid, as is described in U.S. Pat. No. 4,732,297 A.
Further, light has been used to detect a liquid level in a container. GB 2 273 560 A describes a liquid detection apparatus having a photoelectric sensor for determining when the level of liquid has decreased below a predetermined level. The difference in refractive index between the liquid and the gas in the headspace affects the internal reflection in the sensor. The flow of liquid may also be detected by light as described in U.S. Pat. No. 6,819,250 B2 in which a liquid sensor comprises a light transmitting tubular body through which liquid flows, and a photo sensor mounted on the body senses the presence or absence of liquid flowing through the tubular body. Cameras have been used in beverage filling machines as described in EP 0 613 854 131 in which liquid levels are determined using video cameras. JP 2007-278778 discloses an apparatus for inspecting liquid filled containers where the liquid level is detected by detecting X-ray light passed through the container. However, the above methods are difficult to use in combination with collapsible containers due to the unpredictable deformation of such containers during dispensing.
Ultrasound is proposed to be used for determining liquid level in EP 1 506 523, disclosing a technology in which a wireless communication device placed within a valve device of a beverage container may communicate with additional sensors to determine a liquid level through measuring the resonance of a fill tube within the container, using a piezo-electric actuator. Further, JP 2005-274204 A discloses a measuring conduit using two ultrasonic oscillators to measure the time delay of ultrasonic waves in a flow of beer to determine the flow of beer.
U.S. Pat. No. 5,909,825 defines a beverage dispensing system using first and second containers, each having a float sensor to indicate the liquid level within the respective container. Further, GB 2 263 687 A discloses a flow meter having an element which is rotatable by a flow of beer. US20050194399A1 discloses a beverage dispensing system measuring beer flow by volume. The flow sensor uses a turbine and IR light to achieve a flow signal. All of the above technologies require substantial modifications to the existing beverage dispensing system.
All the above US patent documents are hereby incorporated by reference.
It is therefore an object of the present invention to provide technologies for the accurate measuring of the remaining volume of beverage in a beverage dispensing system. It is a further object of the present invention to provide technologies for the accurate measuring of the remaining volume without the need of any substantial modifications to the existing system, such as requiring excessive additional hardware. It is yet a further object of the present invention to provide technologies for the accurate measuring of the remaining volume, which technologies do not suffer from any systematic cumulative errors or similar mathematical errors.
The above object together with numerous other objects, advantages and features which will be evident from the below detailed description of the present invention is in accordance with a first aspect of the present invention obtained by a method for determining a volume of beverage, preferably being a carbonated beverage such as beer or soft drink, being included in a collapsible beverage container, the method comprising providing a beverage dispensing system, the beverage dispensing system including:
The collapsible container should be of a type deforming during beverage dispensing operations. The amount of beverage in the beverage container is at all times defined by essentially the volume of the beverage container itself, and when empty the beverage container will be completely collapsed or flat. The pressure chamber should be rigid, i.e. it should be capable of withstanding a pressure of at least a few bar above atmospheric pressure without bulging or deforming. The residual volume, being the inner volume of the pressure chamber subtracted by the beverage volume, should be rather small when a new full beverage container is introduced in the pressure chamber, such as 5%-50%, preferably 10%-20%, of the initial volume of beverage. The pressurization system may be a pump or compressor capable of introducing a pre-determined volume of atmospheric gas into the pressure chamber, independently of the pressure therein. Preferred pressurization systems include reciprocating piston pumps. The pressure sensor may e.g. be an electronic sensor or pressure switch for determining pressures around atmospheric pressure. The pressure outside the beverage dispensing system may be considered to be 1 atm or 1 bar. The low pressure value and the high pressure value may be chosen arbitrarily. However, the low pressure value may preferably be sufficiently high for allowing proper beverage dispensing, while the high pressure value may preferably be sufficiently low for not to generate excessive foaming of the dispensed beverage.
When the pressure in the inner volume has decreased below the low pressure value, irrespective of whether the decrease of pressure is the result of gas leakage from the inner volume or the result of beverage dispensing operations, the pressurization system is activated to restore the high pressure. It is contemplated that some beverage dispensing systems may allow a lower pressure before activating the pressurization system, e.g. the pressurization system may not be activated before the beverage dispensing operation has been interrupted. The volume of gas being supplied to the inner volume may be determined by the pressurization system. The volume of the residual volume may be determined as the volume of gas being supplied to the inner volume divided by the difference between the high pressure value and the low pressure value. The volume of remaining beverage in the flexible container at a given time may be determined by subtracting the inner volume from the residual volume. It is contemplated that the walls of the container are thin and thus do not influence the measurement results. A control unit of the beverage dispensing system may be used for performing the calculations. The control unit which performs the calculations may include a microprocessor. The present method is preferably used during non-beverage dispensing, i.e. the pressurization system is activated during non-beverage dispensing. The method may also be used during beverage dispensing when the volume of beverage dispensed per second is substantially smaller than the volume of pressurized gas introduced into the residual volume per second by the pressurization system. The present method is measuring the remaining volume of beverage in the beverage container as an absolute volume measurement without relying on any previous measurement.
According to a further embodiment of the method, the method further includes the steps of:
According to a further embodiment of the method, the method further includes the steps of:
According to a further embodiment of the method, the method further includes the steps of:
The present method may be used during beverage dispensing while the pressurization system is activated and is preferably used during dispensing when the volume of beverage dispensed per second is substantially equal to or larger than the amount of pressurized gas introduced into the residual volume per second by the pressurization system. The first pressure value may correspond to the high pressure value and the second pressure value may correspond to the low pressure value. Alternatively, the first and second pressure value may be equal. The present method uses a previous measurement of the remaining beverage volume, and thus cumulative errors may be introduced into the calculation. As soon as the beverage dispensing operations are finished, the remaining beverage in the beverage container may be determined according to the absolute volume measurement method mentioned above in order to avoid cumulative errors.
According to a further embodiment of the method, the method further includes the steps of:
According to a further embodiment of the method, the pressurization system performs a number of operating cycles, each operating cycle comprising the steps of:
According to a further embodiment of the method, the number of operating cycles is determined by measuring the time during which the operating cycles are performed, or, alternatively, wherein the pressurization system is driven by an electrical motor and the number of operating cycles is determined by measuring the number of revolutions of the electrical motor during which the operating cycles are performed, or, yet alternatively, wherein the number of operating cycles is determined by measuring the number of pressure fluctuations occurring within the inner volume when the pressurization system is activated. In case the pressurization system is capable of supplying the same volume of air over time independent of the pressure of the inner volume and independent of the external conditions, and the drive mechanism of the pressurization system reaches the nominal working speed quickly and does not suffer from any significant start-up delay, the number of operations may be determined by the time during which the pressurization system is activated. Alternatively, the number of revolutions of an electrical motor or a flywheel connected thereto may be monitored by the use of an electrical contact or photocell or the like. Yet alternatively, the electronic sensor or pressure switch used for measuring the pressure of the inner volume may be used, since every stroke of the pressurization system yields a pressure wave into the inner chamber. By measuring the number of pressure waves, an estimate of the number of cycles can be made.
According to a further embodiment of the method, the measure of the volume of beverage is determined to be equal to the inner volume subtracted the specific volume divided by the difference between the high pressure value and the low pressure value. In case the ideal gas law is used and the temperature difference between the inside and outside of the inner volume is neglected, the above formula may be used to calculate the volume of the beverage remaining in the beverage container.
According to a further embodiment of the method, the beverage dispensing system further includes a pressure sensor for determining an outside pressure value outside the pressure chamber and/or a temperature sensor for determining an outside temperature value outside the pressure chamber, the outside pressure value and/or the outside temperature value being used for establishing the measure of the volume of beverage. The pressure decrease due to the lower temperature of the pressure chamber may be determined by monitoring the temperature outside and inside the inner volume.
According to a further embodiment of the method, the low pressure value is in the order of 1.6 bar and the high pressure value is in the order of 1.8 bar absolute pressure. The above values are typical values for achieving a good flow of beverage while avoiding excessive foaming.
According to a further embodiment of the method, the method further includes the step of presenting a visual indication being visible from the outside of the beverage dispensing system of the measure of the volume of beverage included in the collapsible beverage container, the visual indication indicating whether the measure of the volume of beverage included in the collapsible beverage container is above or below a predetermined volume value, preferably at least two predetermined volume values, such as the volume of beverage being above ¾ of the inner volume, above ½ of the inner volume and above ¼ of the inner volume, most preferably the visual indication being a continuous indication of the measure of the volume of beverage included in the collapsible beverage container, such as a gauge. Preferably, some visual indication is given about the amount of remaining beverage. The indication may e.g. be an analogue or digital gauge, one or more lights or the like.
According to a further embodiment of the method, the method further includes a linear compensation for wear and tear of the pressure device by monitoring the total time of operation of the pressurization system. The applicant has found that the wear and tear causes a leakage of the pressurization system which is essentially linear with respect to the time of operation of the beverage dispensing system. The calculation unit may compensate for such leakage of the pressurization system.
The above object together with numerous other objects, advantages and features which will be evident from the below detailed description of the present invention is in accordance with a second aspect of the present invention obtained by a beverage dispensing system comprising:
According to a further embodiment of the method, the pressurization system includes a housing, a reciprocating piston operating within the housing and a one-way valve, each operating cycle including a forward and a subsequent backward stroke of the piston, the specific volume being equal to the volume covered by each stroke of the piston, or alternatively, wherein the pressurization system includes a housing and a rotating member operating within the housing, each operating cycle including a 360 degree rotation of the rotating member, the specific volume being equal to the volume covered by the rotating member during the 360 degree rotation. The pressurization system may thus comprise pumps and compressors both of a reciprocating piston type and of a capsule type.
According to a further embodiment of the method, the inner volume is in the range of 5 litres to 50 litres, such as between 5-10 litres, 10-20 litres, 20-30 litres, 30-40 litres or 40-50 litres. Typical volumes of private systems are between 5-10 litres and of professional systems between 10-50 litres.
According to a further embodiment of the method, the pressure in the inner space during dispensing remains lower or equal to the low pressure value, preferably within the range of 1.3 and 1.6 bar, such as within the range 1.4 and 1.5 bar. It is contemplated that the pressure may be allowed to decrease to a value being lower that the low pressure value.
The dispensing line 30 transports the beverage 18 from the inside of the beverage container 16 to a tapping valve 38 located outside the inner volume 14. The tapping valve 38 is controlled by a tapping handle 40. The tapping valve 38 controls the flow of beverage 18 to the outside of the housing 12. The housing 12 further comprises a pressurization system 42, which may be a pump or a compressor. The pressurization system 42, which will be described in more detail in connection with
The control unit 48 is connected to the electronic sensor or pressure switch 46 and the pressurization system 42. The control unit 48 receives information about the pressure inside the inner volume 14 and starts the pressurization of the inner volume 14 in case the pressure in the inner volume 14 is below a predetermined minimum dispensing pressure, such as e.g. 1.4 bar or 1.6 bar absolute pressure. The control unit 48 further receives information about whether or not a beverage container 16 is installed in the inner volume 14 and whether or not the housing 12 is pivoted into its open position, or if it is closed and sealed onto the base unit 34. In case no beverage container is installed into the inner volume 14 or in case the housing 12 is pivoted into its open position, the inner volume 14 cannot be pressurized. Preferably, the control unit 48 also receives information whether or not the tapping handle 40 is in its vertical, non-dispensing orientation. In case the tapping handle is shifted to its horizontal, beverage-dispensing orientation, i.e. allowing beverage to flow out, the volumetric measurement will be influenced, and thus it is preferred that the inner volume is pressurized while the tapping handle 40 is in its vertical orientation, i.e. preventing beverage from flowing out. In alternative embodiments it may be actively prevented to swing the tapping handle 40 when the pressurization system 42 is activated.
In the present view some more details of the pressurization system 42 are shown in the close-up part of the figure. The pressurization system 42 comprises an inner cylindrical cavity 50 in which a piston 52 is reciprocating. The piston 52 and the inner surface of the cylindrical cavity 50 form a tight fit. The piston is connected to a flywheel 54 which is driven by an electrical motor (not shown). The electrical motor is preferably connected to a mains electrical outlet. The electrical motor is controlled by the control unit 48. When the pressure in the inner volume 14 decreases below the minimum dispensing pressure, the electrical motor (not shown) is activated to turn the flywheel as shown by the arrows. Each turn of the flywheel constitutes an operational cycle of the pressurization system 42 in which the piston travels from a top position a specific length L downwardly to a bottom position adjacent the bottom of the inner cavity 50 and again the same distance L upwardly to the top position. The words bottom, top, upwardly and downwardly should be interpreted in the context of the figure. It is contemplated that a pressurization system as shown in
V
spec
→A
spec
·L
spec
wherein Aspec is the area of the piston and Lspec is the length between the top position of the piston and the bottom position of the piston. A volumetric measurement is performed each time the pressure is increased from 1.6 bar in the pressure chamber to 1.8 bar in the pressure chamber as further described below.
The flywheel 54 is connected to the control unit 48. The control unit 48 thereby receives information about the number of operational cycles performed by the pressurization system 42. During pressurization of the inner volume 14, the number of operating cycles required to increase the pressure from the low pressure value=1.6 bar to the high pressure value=1.8 bar is stored in the calculation unit 48. Since beverage is a liquid and consequently substantially non-compressible, and the outside pressure is determined to be one bar, the total volume of beverage Vbev remaining in the beverage container may be calculated according to the ideal gas law as:
wherein Vin is the volume of the inner volume, Vspec of atmospheric pressure introduced by each operational cycle, nop is the number of operation cycles performed between reaching plow=1.6 bar in the pressure chamber and reaching phigh=1.8 bar in the pressure chamber. The measurement is absolute, i.e. it is thus not necessary to know the initial volume of beverage in the beverage container 16 before installing it into the inner volume 14. It is understood that the volume of air of atmospheric pressure vspec will compress as it is entering the inner volume 14, which typically has a higher pressure compared to the outside of the inner volume 14.
It should be noted that in case the re-pressurization of the inner volume 14 is performed quickly in relation to the dispensing of beverage, i.e. if the volume of pressurized air introduced per second by the pressurization system is large compared to the volume of beverage dispensed per second, re-pressurization and volumetric measurements may be performed irrespective of beverage dispensing. However, in case the re-pressurization is comparable to or slower than the dispensing of beverage, i.e. if the volume of pressurized air introduced per second by the pressurization system is less than or substantially equal to the volume of beverage dispensed per second, the beverage dispensing will influence the volumetric measurement.
In the present embodiment, the number of operating cycles is determined by the number of turns of the flywheel 54. The number of turns may be determined e.g. by the use of electrical contacts, photocells etc. Other alternative ways of determining the number of operating cycles include determining the number of turns of the electrical motor, determining the number of strokes of the piston 52 and determining the number of pressure pulses received at the electronic sensor or pressure switch 46.
In the present embodiment, it is assumed that the temperature inside the inner volume 14 is kept at a constant low temperature of about 5 degrees C. In the formulas presented here, the temperature effect causing a reduced pressure when the temperature is reduced at constant volume has been neglected. The cooling of the outside air, presumably at room temperature, will cause a measurement error of a few percent. The calculation unit may compensate for this error for a more precise volumetric measurement.
It is contemplated that the above method may be used in reverse in order to dispense a predetermined volume of beverage instead of measuring the volume of beverage remaining.
wherein the first term Vbev
represents the increase of the air volume in the pressure chamber during dispensing and non-operation of the pressurization system 42, and the third term
represents the volume of the dispensed beverage during dispensing and pressure held constant by the pressurization system 42. The calculation according to the above-mentioned formula may be used e.g. in case the tapping handle 40 is swung during re-pressurization or in the event that the pressure inside the pressure chamber falls below 1.6 bar, e.g. 1.4 bar. The above method has the drawback that the result depends on the previously determined volume of the beverage container, i.e. cumulative errors may occur. After the dispensing operation is finished, an absolute measurement as described above in connection with
It is understood that a relative measurement of the volume of remaining beverage as described above may also be performed when the tapping valve 38 is in the non-beverage dispensing position as a complement to the absolute volume measurement. It should however be remembered that the relative measurement as described here does not take into account the effect of leakage of air from the pressure chamber.
The pressurization system is provided with a counter for determining the number of operating cycles or revolutions. The tables show the number of operating cycles (r=revolutions), the measured volume of air introduced into the inner volume (litre m=measured value), the calculated volume of air introduced into the inner volume (litre c=calculated value) and the difference (diff) between measured value and calculated value. The plot shows the number of operational cycles of the pressurization system as a function of the volume of air (in litre). The points represent experimental results and the line is a curve which has been linearly fitted to the experimental results. From the plot it can be seen that the relationship between the number of operational cycles of the pressurization system and the volume of air introduced into the inner volume of the beverage dispensing system is substantially linear. It has thereby been found out that each revolution of the pressurization system introduced 0.275 ml of air of atmospheric pressure into the inner space. The experiment has been performed using a 20 litre beverage container while tapping approximately 2 litre of beverage.
Although the present invention has been described above with reference to specific embodiments of the method for determining a volume of beverage and also specific embodiments of the beverage dispensing system, it is of course contemplated that numerous modifications may be deduced by a person having ordinary skill in the art of beverage dispensing. For instance, the housing and the flexible container may be replaced by a bag-in-keg or bag-in-container including a rigid outer container and a flexible inner bag. The inner space is thereby established between the outer container and the inner bag. Similar kegs have been produced and sold by various companies which are active within the field of beverage dispensing. Other variants of the above technology exist, such as a metallic can or container with an internal plastic bag, or even an inner flexible metallic bag. Further, the container may or may not include an ascending pipe, and the container may be used in an horizontal, vertical, sloped or upside down orientation when being tapped.
Such modifications, which are readily deducible by the skilled person, are to be construed as part of the present invention as defined in the appending claims.
Number | Date | Country | Kind |
---|---|---|---|
10170294.2 | Jul 2010 | EP | regional |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2011/062534 | 7/21/2011 | WO | 00 | 12/13/2012 |