Patent Description:
Beverage dispensing systems are known from, for example, <CIT> and <CIT>. Over the last decades the dispensing systems have been designed for enhancing the taste experience of the beverage by, for instance, avoiding contamination of dispensing lines and other measures. However, the beverage dispensing systems have become more specialised and thereby as a consequence bulkier.

It is an object of the present invention to wholly or partly overcome the above disadvantages and drawbacks of the prior art. More specifically, it is an object to provide an improved beverage dispensing system having a flexible design without jeopardising the quality of the beverage to be dispensed and at the same time minimising the footprint of the system.

The above objects, together with numerous other objects, advantages and features, which will become evident from the below description, are accomplished by a solution in accordance with the present invention by a beverage dispensing system according to appended claim <NUM>.

Hereby a flexible beverage dispensing system is obtained, wherein the cabinet may be used for other purposes as the cooling module may be detached easily from the cabinet. In addition, by applying the evaporator as a cooling jacket and using predominantly conductive heat transfer, it has the advantage that a standard cabinet may be used as housing for the beverage dispensing system without the need for insulated cooling chambers. Furthermore, a compact beverage dispensing system is obtained which do not occupy much room.

Furthermore, the evaporator may be a roll bond evaporator having one or more cooling agent channel(s) distributed along the extension of the evaporator. Hereby a flexible evaporator is obtained which may be formed according to the intended beverage container.

Moreover, the evaporator may have a cover made of polymeric material. Hereby easy cleaning of the evaporator and uniformly distributed low temperature of the evaporator surface is obtained. Additionally, the surface temperature on the polymeric cover is such that it prevents ice formation inside the beverage container and compensate for water anomaly at <NUM> degrees Celsius.

Advantageously, the components being connected with each other to form a single unit, which will facilitate attaching and detaching the cooling module in or from the inside of the cabinet.

In addition, the condensing unit and the control unit may be arranged inside a compartment. Preferably the compartment is liquid-tight so that the condensing unit and electronics may be protected from any beverage spill from the beverage container and/or condense from the evaporator, if any.

Furthermore, the cabinet may be an aircraft cabin service trolley, which ensures minimum footprint of the beverage dispensing system and maximum mobility. Also, by using an aircraft cabin service trolley, a new design for beverage dispensing systems have been obtained which is appealing to many, since the aircraft cabin service trolley is well known to many. However, due to the size of the aircraft cabin service trolleys the inventors have had to fully redesign especially the position of the different components of the cooling module.

To provide mobility of the beverage dispensing system, the cabinet may have wheels arranged below the bottom face.

Furthermore, the top face may have an opening, the tapping head is arranged opposite the opening.

For further providing flexibility to the beverage dispensing system the tapping head is detachable connected with the cabinet, so that it may be dismounted in periods where the beverage dispensing system is not in use.

The tapping head comprises a tower having an interior channel wherein the dispensing line can be guided from the beverage container to the tapping head.

The interior channel may have a size enabling the dispensing line to be guided through the interior channel, either from the tapping head or from the cabinet. This is especially advantageous in circumstances where the dispensing line is a one-way dispensing line which shall be replaced each time the beverage container is replaced. For instance, the beverage dispensing concept sold under the tradename FlexiDraft™ may be used together with the present invention.

Moreover, the tapping head may be connected with a plate, which plate may be arranged on the top face of the cabinet. This may also enhance the flexibility of the beverage dispensing system, while providing a support face and thereby stability to the tapping head. A further advantage is that the top face of the cabinet not necessarily needs to be reinforced. The plate may also have recesses to for instance a drip tray. Also, the plate may have substantially the same width as the cabinet.

The base plate may comprise one or more gaskets arranged around the edges of the base plate for increasing overall cabinet tightness.

Also, a plurality of fastening means may be arranged at the top face, the fastening means are configured to maintain the plate in position on the top face. Hereby is obtained a simple and flexible way to secure the plate, and thereby the tapping head to the top face of the cabinet.

Furthermore, the cabinet has internal walls, at least two opposite internal walls have a plurality of brackets arranged with a mutual distance from the bottom face to the top face.

In addition, the plate and the tapping head may be arranged inside the cabinet when not in use, wherein the plate is resting on two opposite brackets.

The plate and tapping head may be inverted before being arranged inside the cabinet. Hereby the beverage dispensing system may be stored away when not in use in an easy manner, and at the same time ensuring that all the different components are protected inside the cabinet.

The beverage container may be made of metal or a polymeric material.

Advantageously, the cooling jacket may cover more than <NUM>% of the outer face of the beverage container, preferably more than <NUM>% of the outer face. Hereby the cooling capabilities of the cooling module is enhanced.

Moreover, the cooling jacket may have a form as a U or Ω when seen from a top view.

Furthermore, tensioning means may be arranged in connection with the cooling jacket, the tensioning means is/are configured to tightening the cooling jacket around the beverage container so that it is ensured that the cooling jacket is in good contact with the outer face of the beverage container so that the intended cooling of the beverage is obtained. Additionally, by using the tensioning means the beverage container is secured properly inside the cabinet.

The height of the cabinet may be at least substantially twice as large as the width of the cabinet.

Also, the height of the cabinet may be approximately <NUM> and the width of the cabinet is approximately <NUM>, which the standard measurements of an aircraft cabin service trolley.

In addition, the gas cylinder may be arranged in connection with the door.

Moreover, a gas regulator may be connected with the gas cylinder.

Furthermore, the cooling jacket may have a cooling face facing the outer face of the beverage container, a plurality of blocks is arranged on the cooling face so that thermal contact resistance between the beverage container and the cooling jacket of the evaporator is low. In addition, a gap between the cooling jacket of the evaporator and the beverage container are reduced.

The blocks may be made of metal, preferably aluminium.

Also, the blocks may be distributed so as to cover a major part of the cooling face.

In addition, a fan may be arranged inside the cabinet for providing airflow inside the cabinet.

A gasket strip may be arranged in connection with a door frame of the cabinet to increase cabinet tightness. Due to relatively high cabinet temperature, condensation on the door and the walls of the cabinet is avoided.

The base plate may substantially divide the cooling module with an insulated frame to avoid air circulation below the base plate.

The invention and its many advantages will be described in more detail below with reference to the accompanying schematic drawings, which for the purpose of illustration show some non-limiting embodiments and in which.

<FIG> shows a beverage dispensing system <NUM> according to the present invention. The beverage dispensing system comprises a substantially closed cabinet <NUM> having a height, a width and a depth and a door <NUM> for providing access to an interior <NUM> of the cabinet <NUM>. The cabinet <NUM> has a top face <NUM> and a bottom face <NUM>. In the present embodiment the cabinet <NUM> is an aircraft cabin service trolley, which ensures minimum footprint of the beverage dispensing system and maximum mobility. Also, by using an aircraft cabin service trolley a new design for beverage dispensing systems have been obtained which is appealing to many, since the aircraft cabin service trolley is well known to many. However, due to the size of the aircraft cabin service trolleys, the inventors have had to fully redesign especially the position of the different components of the cooling module, which will be described further below. The present invention will be described and shown in an embodiment wherein the cabinet is the aircraft cabin service trolley however, the cabinet may have other forms and designs.

The beverage dispensing system also comprises a beverage container (not shown) having a cylindric form and an outer face, the beverage container containing a beverage to be dispensed. Furthermore, a dispense head (not shown) may be coupled to the beverage container, and a dispensing line (not shown) extending from the dispense head to a tapping head <NUM>. The dispensing line is configured to lead the beverage from the beverage container to the tapping head for dispensing, the tapping head <NUM> is arranged on the top face <NUM> of the cabinet <NUM>.

Furthermore, a gas cylinder <NUM> having a gas, is fluidly connected with the dispense head for propelling the beverage out of the beverage container when the tapping head <NUM> is opened for dispensing.

The beverage dispensing system also comprises a cooling module <NUM> being detachable arranged inside the cabinet <NUM>, the cooling module <NUM> being configured to cool the beverage contained in the beverage container. The cooling module <NUM> will be described further below.

For providing mobility to the beverage dispensing system <NUM>, the cabinet <NUM> may have wheels <NUM> arranged below the bottom face <NUM>.

Furthermore, the top face <NUM> may have an opening (not shown), the tapping head <NUM> is arranged opposite the opening. The dispensing line may extend from the interior of the cabinet up in the tapping head <NUM>.

For further providing flexibility to the beverage dispensing system <NUM> the tapping head <NUM> may be detachable connected with the cabinet <NUM>, so that it may be dismounted in periods where the beverage dispensing system <NUM> not is in use. This will further be described below in connection with <FIG>.

The tapping head <NUM> may comprise a tower <NUM> having an interior channel (not shown) wherein the dispensing line can be guided from the beverage container to the tapping head <NUM>.

The interior channel may have a size enabling the dispensing line to be guided through the interior channel, either from the tapping head or from the cabinet. This is especially advantageous in circumstances where the dispensing line is a one-way dispensing line which shall be replaced each time the beverage container is replaced. For instance, the beverage dispensing concept sold under the tradename FlexiDraft™ may be used together with the present invention. <CIT> is incorporated by reference.

The tapping head <NUM> is connected with a plate <NUM>, which plate <NUM> is arranged on the top face <NUM> of the cabinet <NUM>. This may also enhance the flexibility of the beverage dispensing system <NUM>, while providing a support face and thereby stability to the tapping head <NUM>. A further advantage is that the top face <NUM> of the cabinet not necessarily needs to be reinforced. The plate may be also have recesses to for instance a drip tray <NUM>. Also, the plate <NUM> may have substantially the same width as the cabinet.

In <FIG> the beverage dispensing system <NUM> is shown in a front view with the door <NUM> open. The cabinet <NUM> having a height H and a width W as well as a depth D (shown in <FIG>). The height H of the cabinet <NUM> may be at least substantially twice as large as the width W of the cabinet <NUM> as shown in <FIG>.

Also, the height H of the cabinet may be approximately <NUM> and the width W of the cabinet is approximately <NUM>, which the standard measurement of an aircraft cabin service trolley.

As shown in <FIG> the cabinet <NUM> has internal walls <NUM>, at least two opposite internal walls <NUM> have a plurality of brackets <NUM> arranged with a mutual distance from the bottom face <NUM> to the top face <NUM>.

In the present embodiment the gas cylinder <NUM> is arranged in connection with the door <NUM>. The gas cylinder <NUM> is connected with a gas regulator <NUM> being configured to provide the intended gas pressure to the beverage container for propelling the beverage out of the beverage container.

In <FIG> the beverage dispensing system <NUM> is shown in a side view.

In <FIG> the beverage dispensing system <NUM> is shown in a top view.

<FIG> show the cooling module <NUM>. In <FIG> the cooling module <NUM> is shown in perspective. In <FIG> the cooling module <NUM> is shown in a top view. In <FIG> the cooling module <NUM> is shown in a front view and <FIG> is a side view of the cooling module <NUM>. The cooling module <NUM> comprises the following components an evaporator <NUM> formed as a cooling jacket <NUM>, the cooling jacket <NUM> is configured to partly encircle the beverage container (not shown) and being in contact with the outer face of the beverage container for cooling the beverage. The outer face is the lateral face of the beverage container.

The cooling module <NUM> also comprises a base plate <NUM> whereupon the beverage container is to be arranged and a temperature sensor <NUM> being arranged to be in contact with the outer face of the beverage container, the temperature sensor <NUM> being operatively connected with a control device <NUM>. Risk of beverage freezing is mitigated by using a temperature control that has as input signal from the temperature sensor which is in direct contact with the beverage container. The temperature control has embedded parameters that together with the system design allow tuning in such a way that that the beverage will not freeze.

Furthermore, the cooling module comprises a condensing unit <NUM> comprising a compressor <NUM>, a condenser <NUM> and an expansion device (not shown), the condensing unit <NUM> is configured to cool a cooling agent, and to circulate the cooling agent for cooling the cooling jacket <NUM>. The condensing unit <NUM> and the control device <NUM> are arranged below the base plate.

Hereby a flexible beverage dispensing system <NUM> is obtained, wherein the cabinet <NUM> may be used for other purposes as the cooling module <NUM> may be detached easily from the cabinet <NUM>. In addition, by applying the evaporator <NUM> as a cooling jacket and using predominantly conductive heat transfer it has the advantage that a standard cabinet may be used as housing for the beverage dispensing system <NUM> without the need for insulated cooling chambers.

Furthermore, the evaporator <NUM> may be a roll bond evaporator having one or more cooling agent channel(s) distributed along the extension of the evaporator <NUM>. Hereby a flexible evaporator <NUM> is obtained which may be formed according to the intended beverage container.

Moreover, the evaporator <NUM> may have a cover made of polymeric material. Hereby easy cleaning of the evaporator <NUM> and uniform distributed low temperature of the evaporator surface is obtained. Additionally, the temperature on the polymeric cover is such that it prevents ice formation inside the beverage container and compensate for water anomaly at <NUM> degrees Celsius.

Advantageously, the components of the cooling module <NUM> being connected with each other to form a single unit will facilitate attaching and detaching the cooling module <NUM> in or from the inside of the cabinet.

In addition, the condensing unit <NUM> and the control unit <NUM> may be arranged inside a compartment <NUM>. Preferably the compartment <NUM> is liquid-tight so that the condensing unit <NUM> and electronics in form of the control unit may be protected from any beverage spill from the beverage container and/or condense from the evaporator <NUM>, if any.

The base plate <NUM> may be arranged with a small inclination, preferably below <NUM> degrees so that if any liquid is ending up on the base plate it may be directed in a condense tray <NUM> located inside the condensing unit. The condense tray <NUM> is shown in <FIG>.

In addition, the base plate has an edge around the perimeter of the base plate. One or more gaskets may be arranged at the edge for increasing cabinet tightness by avoiding fluid communication between an evaporator space and a condensing unit space.

Advantageously, the cooling jacket <NUM> may cover more than <NUM>% of the outer face of the beverage container, preferably more than <NUM>% of the outer face. Hereby the cooling capabilities of the cooling module <NUM> is enhanced.

Moreover, the cooling jacket <NUM> may have a form as a U or Ω when seen from a top view as shown in <FIG>.

Furthermore, the cooling jacket <NUM> may have a cooling face <NUM> facing the outer face of the beverage container, a plurality of blocks <NUM> is arranged on the cooling face <NUM> so that thermal contact resistance between the beverage container and the cooling jacket <NUM> of the evaporator <NUM> is low. In addition, a gap between the cooling jacket <NUM> of the evaporator <NUM> and the beverage container is reduced.

The blocks <NUM> may be made of metal, preferably aluminium.

Also, the blocks <NUM> may be distributed so as to cover a major part of the cooling face <NUM>.

In addition, a gasket strip may be arranged in connection with a door frame of the cabinet to increase cabinet tightness. Due to relatively high cabinet temperature, condensation on the door and the walls of the cabinet is avoided.

The base plate <NUM> may substantially divide the cooling module <NUM> with an insulated frame to avoid air circulation below the base plate <NUM>.

In <FIG> a beverage container <NUM> is arranged inside the cabinet <NUM> of the beverage dispensing system <NUM>. The beverage container <NUM> is placed on the base plate <NUM> and is encircled by the evaporator.

Furthermore, tensioning means <NUM> is/are arranged in connection with the cooling jacket, the tensioning means <NUM> is/are configured to tightening the cooling jacket around the beverage container <NUM> as seen in <FIG> so that it is ensured that the cooling jacket is in good contact with the outer face <NUM> of the beverage container <NUM> so that the intended cooling of the beverage is obtained. Additionally, by using the tensioning means <NUM> the beverage container is secured properly inside the cabinet. The tensioning means <NUM> are in the present embodiment a strap in each end being connected with the cooling jacket.

The beverage container <NUM> may be made of metal or a polymeric material.

In <FIG> the beverage container system <NUM> is shown with the door <NUM> closed. As mentioned above, the plate <NUM> is arranged on the top face of the cabinet <NUM>. A plurality of fastening means <NUM> is arranged at the top face, the fastening means <NUM> are configured to maintain the plate <NUM> in position on the top face. Hereby a simple and flexible way to secure the plate <NUM> is obtained and thereby the tapping head <NUM> to the top face of the cabinet.

In <FIG> and <FIG> the cabinet <NUM> is shown in a storage position meaning the tapping head has been demounted from the cabinet <NUM>. In <FIG> the door <NUM> is closed so that the interior of the cabinet <NUM> is closed too.

In <FIG> the door <NUM> is open whereby it is possible to see the plate <NUM> and the tapping head <NUM> arranged inside the cabinet <NUM> when not in use. The plate <NUM> is resting on two opposite brackets <NUM>.

In the present embodiment, the plate <NUM> and tapping head <NUM> have been inverted before being arranged inside the cabinet <NUM>. Hereby the beverage dispensing system <NUM> may be stored away when not in use in an easy manner and at the same time ensuring that all the different components are protected inside the cabinet. Hence, when not in use the tapping head and plate are fitted inside the cabinet. The advantage is that the cabinet in the design as an aircraft cabin service trolley appears to be only a trolley and not a beverage dispensing system.

<FIG> shows a cross-sectional view of a beverage container <NUM> having an extractor tube <NUM> or spear arranged in a collar <NUM> of the beverage container <NUM> and a dispense head <NUM> coupled to the extractor tube <NUM>. The extractor tubes and dispense heads are well known as well as their function, hence it will not be described in detail here. The dispense head <NUM> has a gas inlet <NUM> which is fluidly connected with the gas cylinder (not shown). Furthermore, the dispensing line <NUM> is fluidly connected with the dispense head <NUM>. In the present embodiment the dispensing line <NUM> comprises a probe <NUM> which may be inserted into a bore in the dispense head <NUM>. The probe is used to activate a double valve of the extractor tube. The probe and the dispensing line are in the present embodiment configured to be replaced each time the beverage container is replaced. Hence both the probe and the dispensing line may be made of polymeric materials and may be disposed after use.

<FIG> shows an embodiment of a dispense head <NUM> coupled to an extractor tube <NUM>, the dispensing line <NUM> is connected with the dispense head <NUM> as mentioned above. Since many different systems of beverage containers, extractor tubes/spears, and thereby also dispense heads to be coupled to the extractor tubes exist, the present invention may be used with any of the known systems, and they will consequently not be described any further here. The embodiment shown in <FIG> is only one example of the dispense head which may be used in connection with the present invention.

<FIG> shows the beverage dispensing system <NUM> of <FIG> with a beverage container <NUM> arranged inside the cabinet <NUM>. The beverage dispensing system <NUM> is shown in a front view.

As mentioned above, the beverage dispensing system <NUM> comprises a beverage container <NUM> having a cylindric form and an outer face <NUM>, the beverage container <NUM> containing a beverage to be dispensed. Furthermore, a dispense head <NUM> is coupled to the beverage container <NUM>, and a dispensing line <NUM> is extending from the dispense head <NUM> to a tapping head <NUM>. The tapping head <NUM> comprises a tower <NUM> which in <FIG> has a cut out so that the dispensing line <NUM> placed in the interior channel <NUM> is shown.

The dispensing line <NUM> is configured to lead the beverage from the beverage container <NUM> to the tapping head <NUM> for dispensing, the tapping head <NUM> is arranged on the top face of the cabinet <NUM>. The tapping head <NUM> comprises a tapping handle <NUM> for opening and closing the dispensing of beverage of the spout <NUM>.

Furthermore, a gas cylinder <NUM> having a gas, is fluidly connected with the dispense head <NUM> for propelling the beverage out of the beverage container <NUM> when the tapping head <NUM> is opened for dispensing.

The beverage dispensing system also comprises a cooling module <NUM> being detachable arranged inside the cabinet <NUM>, the cooling module <NUM> being configured to cool the beverage contained in the beverage container.

Even though the present invention has been described in connection with one cooling module inserted into one cabinet, several cooling modules may be arranged inside a cabinet whereby it is possible to cool a number of beverage containers in the same cabinet with the different beverage containers having different intended dispensing temperatures. Hence by the cooling modules it would be possible to cool different beverage containers, and thereby the beverages in them, independently of each other.

Claim 1:
A beverage dispensing system (<NUM>), comprising
a substantially closed cabinet (<NUM>) having a height H, a width W and a depth D and a door (<NUM>) for providing access to an interior (<NUM>) of the cabinet (<NUM>), the cabinet has a top face (<NUM>) and a bottom face (<NUM>),
a beverage container (<NUM>) having a cylindric form and an outer face (<NUM>), the beverage container containing a beverage to be dispensed,
a dispense head (<NUM>) to be coupled to the beverage container, and a dispensing line (<NUM>) extending from the dispense head to a tapping head (<NUM>), the dispensing line is configured to lead the beverage from the beverage container to the tapping head for dispensing, the tapping head is arranged on the top face (<NUM>) of the cabinet,
a gas cylinder (<NUM>) having a gas, is fluidly connected with the dispense head for propelling the beverage out of the beverage container when the tapping head is opened for dispensing,
wherein a cooling module (<NUM>) is detachable arranged inside the cabinet (<NUM>), the cooling module (<NUM>) being configured to cool the beverage contained in the beverage container, the cooling module comprises the following components
- an evaporator (<NUM>) formed as a cooling jacket (<NUM>), the cooling jacket is configured to partly encircle the beverage container and being in contact with the outer face (<NUM>) of the beverage container for cooling the beverage,
- a base plate (<NUM>) whereupon the beverage container is to be arranged,
- a temperature sensor (<NUM>) being arranged to be in contact with the outer face of the beverage container, the temperature sensor being operatively connected with a control device (<NUM>), and
- a condensing unit (<NUM>) comprising a compressor (<NUM>), a condenser (<NUM>) and an expansion device, the condensing unit (<NUM>) is configured to decrease a temperature of a cooling agent, and to circulate the cooling agent for cooling the cooling jacket (<NUM>), the condensing unit (<NUM>) and the control device (<NUM>) is arranged below the base plate (<NUM>),
wherein tapping head (<NUM>) is detachable connected with the cabinet (<NUM>) and comprises a tower (<NUM>) having an interior channel in which the dispensing line can be guided from the beverage container to the tapping head.