The disclosure relates to beverage brewing systems and in particular brewing systems which use a charge of brewing substance for use in pressurized brewing. Such pressurized brewing is often referred to as “espresso” brewing. Espresso brewing uses a relatively small charge of relatively finely ground coffee or other brewing substance for use in a confined brewing chamber. The brewing substance is compacted to a desired degree and then infused with pressurized water. Compaction of the brewing substance and infusion with the pressurized brewing water requires a sealed brewing chamber to facilitate proper brewing.
The beverage product produced in an espresso brewing process is referred to as “espresso.” Espresso tends to be a thicker beverage compared to drip, French press, cone, or other unpressurized brewing processes. Espresso tends to have a higher percentage of solubles and particulate matter and tends to be relatively viscous or “syrupy.” A variety of espresso brewing machines are available ranging from manual, semi-automatic, to fully automatic. In a manual process an operator grinds a quantity of coffee beans for use in the process. The ground coffee is loaded into a holder device often referred to as a “portafilter.” The portafilter is attached to a pressurized water dispensing head of the brewer. In this manner the ground coffee is contained in a closed, sealed space for brewing. The brewer is activated to controllably deliver pressurized brewing water to the coffee contained in the portafilter. The operator controls the machine for a selected period of time to produce a quantity of espresso beverage.
Fully automatic machines may include a control interface which allows a user to select a type of bean, quantity of espresso to be produced, and perhaps other characteristics. The fully automatic machine includes bean hoppers which may automatically deliver beans to a grinder and then dispense the ground coffee into a brewing chamber. Infusion with heated, pressurized water is automatically controlled by the machine after activation by the operator. At the conclusion of the brewing process a puck of spent, drained but moist, brewing substance is automatically removed from the brewing chamber and passed to a waste collection container for subsequent removal.
In some situations it may be useful to provide an alternative structure for brewing beverage. The alternative structure may be of a larger volume or may include other enhancements. As such it may be desirable to provide a modular assembly which allows the extraction assembly to be removed from one brewer and replaced with a different extraction assembly.
For example, it may be beneficial to initially place a brewer which satisfies various criteria including cost, production volume and reliability. At some point during the life of the system the extraction assembly could be removed and replaced with the extraction assembly which can be mounted in the same position of the machine and coupled to the same water, electrical or other connections. In other words, the new extraction assembly can be substituted for the prior extraction assembly. The prior assembly might be removed for repair purposes, or in order to upgrade the machine.
It may also be desirable to provide a brewer which includes a heating element in close proximity to a chamber which receives grounds for brewing. In this regard, heat can be brought directly to the area in which the coffee is brewed to help maintain a more consistent, tighter tolerance temperature and faster recovery between brew cycles. Temperature affects extraction process and having a preheated brew chamber helps in optimizing extraction process.
Also, it may be desirable to provide various parts that are replaceable, such as wear parts. In this regard, while it is routine to replace items such as gaskets and bushings, it would be desirable to provide a replaceable structure for the brew chamber itself so that the chamber may be removed since it can be a wear part as a result of piston operation against the chamber.
The present disclosure includes an extraction assembly for use in an automatic espresso brewer. The extraction assembly includes components and methods for controllably extracting espresso beverage from a quantity of brewing substance. The components, assemblies and methods facilitate improved control and operation of the extraction assembly and improve the reliability of the extraction assembly. Generally, the brewing substance is compacted between a pair of opposing pistons. The pair of pistons operates relative to a brew chamber for use in the espresso extraction process. The pistons provide compacting force and boundaries within the chamber and facilitate removal of a spent brewing substance puck at the end of the brewing cycle. An alternative extraction assembly or structure for brewing beverage is provided which may include a larger brew volume, enhanced structures, and removable replacement components. The alternative new extraction assembly can be substituted for the prior extraction assembly. Also provided is a heating element in close proximity to the brew chamber. Heat from the heating element can be brought directly to the area in which the coffee is brewed to help maintain a more consistent, tighter tolerance temperature and faster recovery between brew cycles.
The present disclosure will be described hereafter with reference to the attached drawings which are given as a non-limiting example only, in which:
The exemplification set out herein illustrates embodiments of the disclosure that is not to be construed as limiting the scope of the disclosure in any manner. Additional features of the present disclosure will become apparent to those skilled in the art upon consideration of the following detailed description of illustrative embodiments exemplifying the best mode of carrying out the disclosure as presently perceived.
While the present disclosure may be susceptible to embodiment in different forms, there is shown in the drawings, and herein will be described in detail, embodiments with the understanding that the present description is to be considered an exemplification of the principles of the disclosure and is not intended to be exhaustive or to limit the disclosure to the details of construction and the arrangements of components set forth in the following description or illustrated in the drawings.
A general diagrammatic illustration of an extractor assembly 30 is shown in
The frame 34 includes the upper and lower beams 64, 66 and a column 72. A lead screw 74 of the drive mechanism 42 is attached to the upper and lower beams 64, 66. While the lead screw 74 may be more appropriately defined as part of the drive mechanism, it also provides a structural component and is attached to other components of the frame 34.
The drive mechanism 42 includes the lead screw 74 and a controllable drive motor 80. The drive motor is mechanically coupled by way of a transfer assembly 82 such as a pulley and belt combination. Operation of the motor 80 and the transfer assembly 82 operates a correspondingly attached to the drive interface 84. The drive interface 84 is driven by the transfer assembly 82 and is provided with threads which correspond to the thread structure of the lead screw 74. Transfer of energy from the motor 80 to the drive interface 84 causes relative motion of the frame 34 to which the drive mechanism 42 is attached along the lead screw 74.
A controller 90 is coupled to the drive motor 80 over line 92. A limit detector 94 in the form of a limit switch or other switch device positioned proximate a portion of the movable frame such as a detection plate 95 is coupled to the controller 90 over line 96. The limit switch detects an upper limit 98. Such limits may be in the form of structural features such as bumps or the protrusions or may be indicia 99, gaps, colors, or magnetic strips or other devices which can be used to detect various limits, the sensor 94 along with the flow meter helps in detecting the lower limit 100 of the frame travel. The combination of the limits switch 94 and the sensor and flow meter detecting the upper and lower limits 98, 100 is intended to be broadly interpreted. These limits provide upper and lower boundaries which will be detected and communicated to the controller 90 to limit travel of the movable frame 34 and corresponding components upwardly and downwardly relative to the carriage and the adjustment screw driving therethrough. The location of the limit switch 94 may be varied for the best results.
A heated water system 106 controllably provides heated water to the extraction assembly 30. The heated water system is controlled, at least in part by being coupled to the controller 90 over line 108. The heated water system 106 is generally known in the art and may provide a variety of controllable features to control the amount of water dispensed, the timing of water dispensing, the temperature of water dispensed, the pressure of the water dispensed, and other features. A dispense line 110 is coupled to and communicates with the heated water system 106 to deliver water from the heated water system 106 to the brew chamber 46.
It should be noted that the present disclosure may refer to coffee an espresso in reference to beverage making substance throughout the description in the interest of clarity and simplicity. It will be understood, however, that any form of beverage making substance may be used to produce a beverage and the term coffee or beverage making substance is intended to be broadly interpreted. This broad interpretation is also intended to include, but is not limited to, beverage substances including but not limited to, coffee, tea, herbs, botanicals, liquid beverage concentrate, ground, pulverized, rough cut, whole, powdered beverage concentrate, flaked, granular, freeze dried or other forms of materials including, but not limited to, liquid, gel, crystal or obtain a beverage or other food product or any other forms of beverage substance or food products.
Terms including beverage, brewed, brewing, brewing substance, brewed liquid, and brewed beverage as may be used herein are intended to be broadly defined as including, but not limited to, the brewing of coffee, tea, and any other beverages. This broad interpretation is also intended to include, but is not limited to, any process of dispensing, infusing, steeping, aerating, reconstituting, diluting, dissolving, saturating or passing a liquid through or otherwise mixing or combining a beverage substance with a liquid such as water without limitation to the temperature of such liquid unless specified. While a heated liquid is referred to herein it should be understood that reference to temperature is provided by way of illustration and not limitation and should be broadly interpreted. It should be understood that a beverage may be made to accommodate a recipe using heated, unheated, chilled or liquid within any range of temperature. Also, the volume or quantity of the beverage making substance used in the system or the beverage produced by the system is intended to be broadly interpreted and not limited to that as specifically disclosed and includes serving sizes ranging from single cup to multiple cup containers or low volume shots.
With further reference to
As shown, the second piston 56 is positioned in a lower portion 120 of the brew chamber. A shoulder 122 is positioned on the lower portion 120 of the brew chamber so as to provide an interface between the second piston 56 to limit travel of the piston downwardly through the brew chamber. A stem 124 of the second piston extends downwardly through an opening 126 in the bottom of the brew chamber defined by the shoulder 122. A sealing gasket 128 is provided between the shoulder and piston so as to prevent leakage there between. Beverage brewing substance 114 dispensed into a cavity 130 defined by the inside surface 132 of the walls 134 of the chamber 46 rests on the upper face 140 of the second piston 56. In the position shown in
Progressing to
With reference to
Compression of the gasket 150 does not occur during the initial movement of the piston 52 into the chamber 46 helping to reduce wear on the gasket and prolong its life. In this regard, a pair of first and second springs 174 and 172 are carried on a shaft 170 of the piston. When the piston 52 is first introduced into the brew chamber by movement of the frame 34, the springs 174, 172 are relaxed and not compressed. As such, there is generally nominal force of the first spring 174 against the sleeve 156. As such, there is little if any compression of the gasket 150 outwardly from the annular channel 152. There is nominal engagement between the gasket 150 and the inside surface 132 of the walls 134 of the brew chamber. This facilitates improved wear characteristics and operation of the extraction assembly. While there may be some engagement between the gasket 150 and the inside surface 132 of the cavity 130, this merely provides a wiping function which may provide improved sealing when the gasket 150 is compressed.
Further movement of the carriage upwardly causes the slight compression of the second spring 172, having a lower spring constant, to initially start to compress as the face 142 of the piston contact the brewing substance. This tends to create a “soft seal” slightly compressing the o-ring. This results in an initial compaction force or packing pressure on the brewing substance. This soft seal and initial packing pressure allows the grains in the ground brewing substance to shift and position to provide some degree of uniformity in the distribution and compaction of the brewing substance.
Continued movement of the frame down along the lead screw causes further compaction and compression of the first spring 174. Compression of the first spring 174 creates forces against the sleeve which further compresses the gasket 150 which causes the gasket to bulge outwardly against the inside surface of the brew chamber and creates a tighter seal. A packing pressure of approximately 40-50 pounds may be used for the compaction of the brewing substance 114. The spring constant associated with each of the two springs 174, 172 can be specified so that desired compaction force against the brewing substance is achieved. Once the frame 34 is moved downwardly to fully engage the first piston 52 to a predetermined packing pressure, water can be dispensed in to the chamber under pressure to start the extraction process.
A sensor or detector 200 is provided on the extraction assembly to detect the conditions of the assembly during the brewing process. In this regard, the sensor 200 can be used to detect a variety of conditions associated with the compaction process just described. The sensor can be provided in a variety of embodiments such as optical, physical pressure detecting, relative movement, proximity, or other types of detectors. Also, the sensor may be positioned in one of several positions or multiple sensors may be used to provide difference sensing parameters or multiple sensing parameters to provide redundancy.
As shown in the Figures, a proximity detector 200 is carried on the frame. The proximity detector detects the relative motion of the first piston 52. The proximity detector is coupled to the controller over line 202. Once a predetermined condition is achieved, the proximity detector 200 detects this condition and communicates the information to the controller. The controller then stops further operation of the drive motor 80 thereby stopping movement of the carriage 38. Ceasing operation of the motor 80 ceases movement of the frame 34 thereby creating a stopped or parked condition. The stopped position of the frame provides a relatively stable position for the brewing process. The sensor 200 (or multiple sensors) may be used to continue to monitor the condition throughout the brewing process. In this regard, if brewing substance shifts during the brewing process the change in compacting force can be detected and the motor 80 can be operated to adjust the frame appropriately. Continued monitoring may be used to improve the quality and continuity of the brewing process including the potential for shifting or change of the brewing substance or other brewing conditions.
Once the brewing substance 114 appropriately compacted in the brew chamber 46 between the first and second pistons heated water can be introduced through the inlet lines 220. Heated water enters through the second piston 56. A filter structure 222 (see
The flow meter count is monitored to determine the end of the brew cycle. This signal of the brew cycle completion allows the frame to change direction of movement along the lead screw 74. As the frame 34 moves upwardly, the reverse of the compaction cycle occurs with regard to the first piston 52. The pressure is relieved from the springs 174, 172 ultimately allowing decompression of the gasket 150. The decompressed gasket allows the first piston to smoothly disengage from the inside surface 132 of the brew chamber.
As the frame progressively moves downwardly, the stem 124 of the second piston 56 disengages the lower beam 66 of the frame 34. As the frame continues to travel upwardly, the shaft 124 bottoms out against the recess 240 causing the piston head to disengage from the shoulder 122. Further upward movement of the frame 34 causes relative motion of the piston 56 in the cavity 130 to move the spent brewing substance or “puck” 246 upwardly towards the mouth 116 of the chamber 46. The puck in this condition is a somewhat moist relatively drained form of brewing substance. Some moisture allows the puck of material to retain the puck-like shape which facilitates convenience handling. As shown in
At this point, reference is made to the enlarged view of
In use, the extraction assembly 30 starts as shown in a position in
At a predetermined level of compaction force, the sensor 200 communicates with the controller 90 to stop operation of the motor 80 thereby stopping movement and compression or compaction of the brewing substance 114. After the sensor indicates that the compaction is at a predetermined level and movement of the frame 34 should stop, the heated water system 106 is controlled to dispense water through line 110 to the chamber 46.
As an additional matter, the chamber 46 can be provided with a heating element 300 which can be coupled to the controller 90 over line 302. The heating element 300 can be wrapped on the outside of the chamber, embedded in the chamber or otherwise associated with the chamber so as to provide controllable heating energy if needed to the material of the chamber wall 134. The ability to provide controlled heat to the chamber helps to maintain the temperature of the brewing process and prevent dissipation of the heat from the heated water. Controlled heating may be useful to help maintain a predetermined preferred brewing temperature. If the characteristics of chamber 46 are such that heat energy in the water would transfer to the wall material 134, it may reduce the temperature of the water to an undesired level thereby altering the expected brewing characteristics. As a result, additional heat can be controllably provided to maintain the chamber wall 134 at a desired temperature to prevent this heat transfer.
As the water flows through line 110 into the cavity 130 filled by the compressed brewing substance 114, a brewing process occurs often referred to as “espresso brewing”. The espresso beverage is filtered through the filter structure carried on the first piston 52 and flows through the drain passages for dispensing from the dispense line 230.
In the upwardly most or “home position”, a limit switch or sensor 94 operates (see
The alternate embodiments shown in
The extractor assembly 30a as shown in
As and additional benefit of the enhanced brewing chamber structures, the combined structures reduce the overall stress on each individual structure thereby enhancing the reliability and life of the structure. Additional torque may be applied to the enhanced structure which allows for more precise tuning of the compacting forces applied by the pistons in the brew chamber. As noted above, the use of multiple shafts and lead screws reduces deflection of the structure by more evenly distributing the forces and providing enhanced balance to the overall structure. The more equally distributed forces also provides an opportunity to prolong the life of the motors, actuators, bearings, belts, bushings and other components associated with the drive system. Additionally, the distributed forces and lead screw operations helps to more precisely align the piston as it travels through the chamber resulting in further piston and chamber life.
It should be noted that the overall construction and arrangement of the enlarged brew chamber version as shown in
With further reference to
As further shown in
Further, an insulating structure 430 is retained around the sleeve 420 to enhance the use of heat energy created by the heating element to direct it towards the brew chamber. This further enhances the heating efficiency of this system and helps maintain a consistent temperature of the brew chamber throughout numerous brewing cycles.
The heating component is provided in the preferred embodiment in the form of a positive thermal coefficient ceramic heater or PTC heater. The PTC element is useful since it has a generally highly nonlinear thermal response and becomes resistant above a threshold temperature which depends on the composition of the materials in the PTC heater. The PTC element does not require a thermostat because it effectively is self regulating due to the described properties. The PTC component provides more reliably controlled heating to the chamber.
Localized heating of the brew area rather than heating the entire block helps to reduce the energy of keeping the brew chamber at a predetermined temperature. Further, this localized heating also prevents overheating of the other components in the system such as the, puck removing arm. Moreover, when the brewer is in a start up mode it takes less time for the heating element which is placed in close proximity to the brew chamber to bring the brew chamber up to a predetermined brewing temperature than if the entire block needs to be heated. As a result of providing a removable heating component 300a in the sleeve 420 the component 300a can be removed to help reduce the temperature of the block more quickly when servicing the brewer.
While the present disclosure may be susceptible to embodiment in different forms, there is shown in the drawings, and herein will be described in detail, embodiments with the understanding that the present description is to be considered an exemplification of the principles of the disclosure and is not intended to be exhaustive or to limit the disclosure to the details of construction and the arrangements of components set forth in the following description or illustrated in the drawings.
While this disclosure has been described as having an exemplary embodiment, this application is intended to cover any variations, uses, or adaptations using its general principles. It is envisioned that those skilled in the art may devise various modifications and equivalents without departing from the spirit and scope of the disclosure as recited in the following claims. Further, this application is intended to cover such departures from the present disclosure as come within the known or customary practice within the art to which it pertains.
This application is a U.S. nationalization under 35 U.S.C. § 371 of International Application No. PCT/US2013/022682, filed Jan. 23, 2013, which claims the benefit of priority under 35 U.S.C. § 119(e) to U.S. Provisional Patent Application No. 61/590,231, filed Jan. 24, 2012. The disclosures set forth in the referenced applications are incorporated herein by reference in their entireties.
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PCT/US2013/022682 | 1/23/2013 | WO | 00 |
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WO2013/116056 | 8/8/2013 | WO | A |
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