Abstract:
A motorized beverage machine ( 1 ) has a brewing unit ( 2 ) that comprises a first assembly ( 13 ) and a second assembly ( 14 ) cooperating together, each assembly ( 13,14 ) delimiting part of a brewing chamber ( 29 ) for containing an ingredient capsule ( 30 ). At least one of these assemblies ( 14 ) is: movable away from the cooperating assembly ( 13 ) into an open position within such machine for forming between said assemblies a passage ( 31 ) for inserting into and/or removing from the brewing unit the ingredient capsule ( 30 ); and movable to the cooperating assembly into a closed position for forming the brewing chamber ( 29 ). The machine comprises activation means including: a motor for driving the movable assembly between the open and closed positions and transmission means for transmitting the drive action of the motor to the movable assembly; water supply means for supplying heated water to brewing chamber; control means for controlling the drive action of the motor comprising means for measuring at least one electrical parameter representative of the motor power consumption and for comparing the evolution of said measured parameter as a function of time during the transfer of the assembly from the open to the closed position to a set reference and means for providing an input to at least one of the activation means as a result of the compared evolution of the measured parameter to the set reference.

Description:
FIELD OF THE INVENTION 
       [0001]    The present invention relates to a beverage machine for the preparation of a beverage from an ingredient capsule. More particularly, the machine has a motorized brewing unit and a control for closing the brewing unit in a convenient and safe manner. 
         [0002]    For the purpose of the present description, a “beverage” is meant to include any human-consumable liquid substance, such as tea, coffee, hot or cold chocolate, milk, soup, baby food, etc. . . . A “capsule” is meant to include any pre-portioned beverage ingredient, such as a flavouring ingredient, within an enclosing packaging of any material, in particular an airtight packaging, e.g. plastic, aluminium, recyclable and/or biodegradable packagings, and of any shape and structure, including soft pods or rigid cartridges containing the ingredient. 
       TECHNICAL BACKGROUND 
       [0003]    Certain beverage preparation machines use capsules containing ingredients to be extracted or to be dissolved and/or ingredients that are stored and dosed automatically in the machine or else are added at the time of preparation of the drink. Some beverage machines possess filling means that include a pump for liquid, usually water, which pumps the liquid from a source of water that is cold or indeed heated through heating means, e.g. a thermoblock or the like. 
         [0004]    Especially in the field of coffee preparation, machines have been widely developed in which a capsule containing beverage ingredients is inserted in a brewing device. The brewing device is tightly closed about the capsule, water is injected at the first face of the capsule, the beverage is produced in the closed volume of the capsule and a brewed beverage can be drained from a second face of the capsule and collected into a receptacle such as a cup or glass. 
         [0005]    Brewing devices have been developed to facilitate insertion of a “fresh” capsule and removal of the capsule upon use. 
         [0006]    WO 2005/004683 and WO 2007/135136 relate to such brewing devices. The devices comprise a frame, a fixed holding part for the capsule, a movable holding part which is mounted relative to the frame in a sliding relationship, one or two knuckle joint mechanisms that provide a mechanical system which enables to close in a steady and fluid-tight manner the holding parts about the capsule while also resisting to the counter-force acting while re-opening and generated by the internal brewing pressure, and a handle for directly levering the knuckle joint mechanism. Such a device forms a simple assembly enabling insertion of the capsule by vertical fall through a passage in the frame and removal of the used capsule in the same direction as the insertion direction. The handle may serve to cover and uncover the passage for the capsule. The movable parts of the brewing device are actuated manually via the handle. The manual force required to move the movable parts varies during closure and opening of the machine and depends on the dimensional tolerances of the capsules used and the positioning and nature of the capsules as well as the temperature of the brewing unit. 
         [0007]    WO 2009/043630 discloses a beverage preparation machine including a brewing unit having a front part with a passage for inserting a capsule into the brewing unit. The front part is arranged to telescope out of the machine&#39;s housing for uncovering the passage for inserting a capsule into the brewing unit and telescopes into the brewing unit for sliding the passage under the housing and thus covering the passage by the housing. 
         [0008]    From a different approach, the actuation of the movable part of the brewing device may be motorized. EP 1 767 129 relates to a motor-driven extraction module for a capsule-based beverage production device. In this case, the user does not have to provide any manual effort to open or close the brewing device. The brewing device has a capsule insertion passage provided with a safety door assembled to the movable part of the brewing device via a switch for detecting an undesired presence of a finger in the passage during closure and prevent squeezing-injuries by stopping the motor before any finger is caught in the brewing device. 
       SUMMARY OF THE INVENTION 
       [0009]    An object of the invention is to provide a motorized closure function of the brewing unit for providing more convenience in loading and ejection of the ingredient capsule and reducing user&#39;s intervention. Another object is to provide a safe operation by reducing the risk of injuries while using a motorized beverage machine. Another object is to provide added value functionalities such as semi-automatic or automatic brewing, rinsing and/or de-scaling modes. Another object is to control optimal conditions for rinsing and/or de-scaling the machine. 
         [0010]    One or more of these objects are meet by a motorized brewing machine according to the independent claim(s). The dependent claims further provide solutions to these objects and/or additional benefits. 
         [0011]    The invention relates to a motorized machine for preparing and dispensing a beverage and more particularly to a beverage machine having a motorized brewing unit. For instance, the machine is a coffee, tea, chocolate, cacao, milk or soup preparation machine. In particular, the machine is arranged for preparing within a beverage processing module a beverage by passing hot or cold water or another liquid through a capsule containing an ingredient, such as a flavouring ingredient, of the beverage to be prepared, such as ground coffee or tea or chocolate or cacao or milk powder. 
         [0012]    Such beverage preparation typically includes the mixing of a plurality of beverage ingredients, e.g. water and milk powder, and/or the infusion of a beverage ingredient, such as an infusion of ground coffee or tea with water. For instance, a predetermined amount of beverage is formed and dispensed on user-request, which corresponds to a serving. The volume of such a serving may be in the range of 25 to 200 ml, e.g. the volume for filling a cup or mug, depending on the type of beverage. Formed and dispensed beverages may be selected from ristrettos, espressos, lungos, cappuccinos, café latte, americano coffees, teas, etc. . . . In particular, a coffee machine may be configured for dispensing espressos, e.g. an adjustable volume of 20 to 60 ml per serving, and/or for dispensing lungos, e.g. a volume in the range of 70 to 150 ml per serving. 
         [0013]    In particular, the motorized beverage machine has a brewing unit that comprises a first assembly and a second assembly cooperating together, each assembly delimiting part of a brewing chamber for containing an ingredient capsule. At least one of these assemblies is:
       movable away from the cooperating assembly into an open position within the machine for forming between the assemblies a passage for inserting into and/or removing from the brewing unit the ingredient capsule; and   movable to (e.g. towards) the cooperating assembly into a closed position for forming the brewing chamber.       
 
         [0016]    The assemblies are relatively movable to one another. One assembly may be fixed in the machine, e.g. in the main frame or outer housing of the machine, and the other assembly may be movable thereto. Alternatively, both assemblies may be movable in the machine, e.g. in the main frame or outer housing of the machine. 
         [0017]    The machine comprises activation means that include:
       a motor for driving the movable assembly of the brewing unit between the open and closed positions;   a transmission means for transmitting a drive action from the motor to the movable assembly, e.g. one or more transmission gears and/or belts and/or cardans;   water supply means for supplying heated water to the brewing chamber, e.g. a water source with a pump and/or a heater and a control unit such as a PCB with a controller and optional memory device and/or other electronic components (i.e. a PCBA “Printed Circuit Board Assembly”); and   control means for controlling the drive action of the motor, e.g. a control unit such as a PCB with a controller or a PCBA.       
 
         [0022]    In accordance with the invention, the motorized beverage machine comprises means for measuring at least one electrical parameter representative of the motor power consumption and for comparing the evolution of this measured parameter as a function of time during the transfer of the assembly from the open to the closed position to a set reference and means for providing an input to at least one of said activation means as a result of the compared evolution of said measured parameter. 
         [0023]    Hence, the circumstances under which the assemblies are moved to the open and/or closed position can be monitored by monitoring the power consumption of the motor. In particular, the required mechanical output energy of the motor to produce a movement is directly linked to its consumed input energy, e.g. electric energy, can be measured. 
         [0024]    The set reference may be based on a power consumption modelisation and/or an empiric power consumption measure under predetermined conditions, e.g. with or without ingredient capsule in the brewing unit, specific environment of use, etc. . . . The set reference typically includes a tolerance margin to take into account variations that may occur e.g. due to the environment of use and/or manufacturing tolerances and/or handling tolerances. 
         [0025]    For example, the motor is controlled to produce an output movement, e.g. rotation of a rotor, at a predetermined speed and/or to operate at a predetermined input voltage for example at constant voltage. To maintain the predetermined speed and/or voltage, the input powering of the motor can be adjusted in line with the needed output powering, e.g. angular speed and torque (depending on the constraints under which the motor has to operate in a given circumstance). In particular, the power supply of the motor may be arranged to control the motor&#39;s input voltage and the motor can be arranged to draw the required amount of current needed to maintain the input voltage. By measuring the required motor input powering to maintain the desired motor output speed and/or the input voltage, the mechanical constraints exercised against the motor output can be determined. Such constraints may correspond to normal operation of the motorized machine, e.g. opening or closing the brewing unit assemblies with or without a capsule ingredient, or to an abnormal operation, e.g. an interference with an obstacle preventing normal opening or closing, such as a human body part e.g. a finger, caught inbetween the assemblies or inhibiting reopening of the assemblies, e.g. jamming of the brewing unit. In the former case (normal operation), the motorized beverage machine may be configured to allow a corresponding operation, e.g. beverage preparation or cleaning, or to carry it out automatically. In the latter case (abnormal operation), a safety mode may be provided, e.g. to stop closure or reopen the assemblies when an undesired obstacle is caught between the assemblies, or stop the motor when the brewing unit is jammed e.g. to prevent undesired stress in the machine and allow for example manual unjamming by a user and/or service person, as appropriate. 
         [0026]    A safety input is typically provided to the motor when detecting an abnormal variation of the measured parameter relative to the set reference. The variation may be deemed abnormal when the measured parameter:
       exceeds a level that is at least 20% above the set reference, in particular 30 or 40% thereabove such as 50% thereabove; and/or   corresponds to a resistance against closure caused by the presence of an obstacle, in particular a human body part such as a finger, inbetween the assemblies moving towards the closed position and prior to reaching thereof, for example a resistance between the assemblies of the brewing unit in the range from 50 to 200 N, in particular from 75, 100 or 120 to 130 or 150 N.       
 
         [0029]    Providing a reference set that includes a tolerance range, e.g. 20, 30, 40 or even 50% relative to a median or average reference set may be appropriate to take into account normal variations of mechanical effects occurring in the machine, such as variations of a friction coefficient, temperature and humidity as well as manufacturing tolerances. 
         [0030]    The safety input may comprise inverting the motor action to move the movable assembly in open position or reducing or stopping the drive action of the motor. 
         [0031]    The control means can be configured to detect the abnormal variation in comparison to a referential curve representing the normal evolution of the electrical parameter as a function of time corresponding to:
       a mode in which the movable assembly is moved into a closed position with an ingredient capsule inserted in the brewing chamber (hereinafter the “Capsule closure mode”); and/or   a mode in which the movable assembly is moved into a closed position with no capsule inserted in the brewing chamber (hereinafter the “Empty closure mode”).       
 
         [0034]    A water supply mode consisting of supplying heated water to the brewing chamber may be initiated when no abnormal variation of the measured parameter relative to the set reference has been detected and the assembly is in a closed position (“Capsule closure mode or empty closure mode”). The supplying of heated water may involve the circulation, e.g. by using a pump, of water from a source, e.g. a water tank, and/or the heating of water, e.g. continuous or batch heating, to the brewing chamber. The supply of heated water may be controlled, e.g. via one or more temperature sensors, pressure sensors and/or flowmeters, to adjust the heating and flow characteristics of the supplied heated water. 
         [0035]    Optionally, the control means comprise a user-interface to selectively initiate the water supply mode. Hence, water may be circulated to the brewing chamber automatically or upon a user-request via the user-interface. 
         [0036]    The control means may be configured to initiate a brewing mode when the measured parameter matches the referential curve (including a possible tolerance) corresponding to the “capsule closure mode”. 
         [0037]    The control means can be configured to initiate a rinsing and/or de-scaling mode when the measured parameter matches the referential curve corresponding to the “empty closure mode”. In particular, the control means can be configured so that said supplied water is heated at a temperature, such as in the range of 55 to 85° C., lower than the normal brewing temperature, such as in the range of 85 to 98° C. 
         [0038]    At least one measured parameter may represent the current consumption of the motor. 
         [0039]    The transmission means may include a gear assembly. 
         [0040]    The transmission means, in particular a gear assembly, may be configured to provide a transmission ratio of at least 1:100, preferably comprised between 1:200 and 1:300. 
         [0041]    The control means can be free of end position sensors in the open position and/or in the closed position. In this case, the measure of the power consumption by the motor may be used to determine the open position and/or closed position. The measure of the power consumption may be correlated with a time evolution to link the consumption to a time-based expected position of the movable assembly, for instance to distinguish the power consumption resulting from reaching an end position from the power consumption resulting from interference with an intermediate undesired obstacle. 
         [0042]    Alternatively, the control means may include at least one end position sensor, e.g. two end position sensors in particular for detecting the open position and/or the closed position. 
         [0043]    The motorized beverage machine may include an ingredient capsule between the first and second assemblies, the motor being controlled by the control means to move the assemblies from the open position to the closed position to form the brewing chamber to contain the ingredient capsule, the measuring means of the control means being arranged to measure at least one parameter representative of the power consumption of the motor during motion of the assemblies to the closed position with the capsule between the closing assemblies, the comparing means of the control means being arranged to compare the evolution of said measured parameter to the set reference, the input means of the control means being arranged to provide to at least one of said activation means the input resulting from said comparison. 
         [0044]    The control means can be configured to detect any abnormal variation in comparison to a referential curve representing the normal evolution of the electrical parameter as a function of time and to:
       initiate a water supply mode when no abnormal variation of the measured parameter relative to the set reference has been detected and the assembly is in a closed position; and/or   provide a safety input to the motor when an abnormal variation of the measured parameter relative to the set reference is detected.       
 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0047]    The invention will now be described with reference to the schematic drawings, wherein: 
           [0048]      FIG. 1  is a partly schematic and partly perspective view of a beverage machine according to the invention; 
           [0049]      FIG. 2  shows a partial cross-sectional perspective representation of a brewing unit of the beverage machine of  FIG. 1  in open position; 
           [0050]      FIG. 3  shows a partial cross-sectional perspective representation of a closed brewing unit of the beverage machine of  FIG. 1  in an “empty closure mode”; 
           [0051]      FIG. 4  shows a partial cross-sectional perspective representation of a closed brewing unit of the beverage machine of  FIG. 1  in a “capsule closure mode”; and 
           [0052]      FIG. 5  shows a graphic of referential curves of the current absorption of the motor as a function of time in a “capsule closure mode” and in an “empty closure mode”. 
       
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
       [0053]    An exemplary motorized beverage machine  1  according to the invention is illustrated in  FIG. 1 . The machine comprises a brewing unit  2  which is connected to an electric motor  3  which drives transmission means  4  for moving brewing unit  2  from an open to a closed position and/or vice versa. Water supply means  5  are also provided as a part of machine  1 . Such means  5  may include a water reservoir  6 , a water pump  7  and a water heater  8 . Water circulates in a water circuit  9  which is linked to brewing unit  2 . Typically, circuit  9  is in fluid connection with brewing unit  2 . Control means  10  are also provided in machine  1 . Control means  10  include a control unit  11 , sensors (not represented) and a user interface  12 . Control unit  10  includes processor(s), memories and programs enabling to provide appropriate inputs to and receive outputs from the different activation means of the machine in particular, the pump, heater and motor. 
         [0054]    Control means  10  may be connected, e.g. wired or wireless, to user interface  12 , pump  7 , heater  8  and various sensors, such as flow-meters, temperature sensors, pressure sensors, ammeter (e.g. for measuring the current consumption of motor  3 ) such as a Hall sensor. In particular, control means  11  may control electric power switches and/or current and voltage regulators associated with motor  3 , pump  7  and heater  8 . 
         [0055]    As shown in  FIGS. 2 and 3 , brewing unit  2  has a first assembly  13  and a second assembly  14  which are movable relatively one another. 
         [0056]    In the context of the present invention, “assembly” may refer to a single component assembling different functions, e.g. mechanical guiding function, mechanical holding function, mechanical piercing function, flow function, pressure function, etc. . . . , and/or refer to a plurality of components assembling the desired functions. 
         [0057]    For instance, first assembly  13  is a rear injection assembly  13  and includes a capsule cage with injection blades  15 . Front assembly  14  forms a beverage delivery assembly and includes a capsule delivery plate  16 . Front assembly  14  is associated to an outer casing  17  and is movable therewith relatively to rear injection assembly  13  which remains fixed to a frame  18  of machine  1 . Front delivery assembly  14  includes a beverage outlet  19 . 
         [0058]    Front delivery assembly  14  is moved relatively to rear injection assembly  13  by means of motor  3  which drives transmission means  4 . 
         [0059]    In the open position ( FIG. 2 ), a passage  31  is provided between the first and second assemblies  13 , 14  for allowing the insertion of a capsule  30 . The capsule may be positioned in an intermediate position, for example as described in EP 1 646 305 or WO 2009/043630. 
         [0060]    In the closed position ( FIG. 3 ), a brewing chamber  29  is formed. Brewing chamber  29  is occupied at least partially by a capsule  30  in a normally closed position of the brewing unit ( FIG. 4 ). The capsule may be of any type and should simply be compatible with brewing chamber  29  and passage  31  for being handled by the assemblies during closure and opening of the brewing unit. Suitable capsules and brewing chambers are for instance disclosed in EP 0 512 468, EP 0 512 470 and EP 2 068 684. 
         [0061]    Transmission means  4  may include various mechanical systems. Transmission means  4  may have a force transmission ratio from the motor to the assembly of at least 1:50, in particular from 1:100 to 1:300 to 1:500. 
         [0062]    In the embodiment illustrated in  FIGS. 1 to 4 , transmission means  4  includes a gear assembly  20  linked to a cam  22  and cam-follower  23 . For a balanced transmission of the forces on casing  17 , cam  22  comprise a pair of elongated grooves located on each side of casing  17 . Gear assembly  20  comprises a worm drive  21  connected to the motor axle (i.e. to the rotor of motor  3 ). Worm drive  21  operates a large gear  24 , e.g. a spur gear or helical gear, which is fixed to an axle  25  on which sit two lateral smaller gears  26 ,  27 , e.g. spur gears or helical gears or friction gears. The smaller gears  26 ,  27  drives a pair of gear segments  28 , e.g. spur gears or helical gears or friction gears, which moves cam-follower  23  and, by way of consequence, move cam  22  with the casing  17  from the opened to the closed position and vice versa. In the closed position gear segments  28  with cam-followers  23  are positioned such that the brewing pressure is absorbed across the gear segments without it being transmitted to the rest of the drive system, e.g. radially across the gear segments. However, as explained hereafter, the brewing pressure can be absorbed by the drive system by a suitable configuration. 
         [0063]    The gear ratio between worm drive  21  and large gear  24  may be in the range of 1:25 to 1:100, such as 1:50 to 1:80. The gear ratio between small gear  27  and gear segment  28  can be in the range of 1:3 to 1:10, in particular in the range of 1:5 to 1:8. 
         [0064]    For instance, the use of a worm drive  21  in transmission  4  can make this transmission unidirectional. In other words, force and movement can only be transmitted from motor  3  to transmission  4  and not vice versa, worm drive  21  acting as a stop in the opposite direction. Hence, no further stop means is needed to maintain the assemblies in a given position. It is sufficient to interrupt the powering of motor  3  to secure assemblies  13 , 14  in a given position, in particular in the closed or open position. 
         [0065]    In a possible solution, both open and closed end positions are geometrically made as “hard stops” with no end switches or sensors. 
         [0066]    The input for the motor control may involve the user-interface, the current absorption of the motor and a timer of the control unit. 
         [0067]    As illustrated in  FIG. 5 , two different typical curves  40 , 41  can be detected over time, e.g. by measuring the power consumption of motor  3 , for example by measuring the current consumption of motor  3 , in particular when motor  3  is a DC motor, e.g. operated at generally constant voltage. 
         [0068]    Curve  40  represents the evolution over time of the current consumption of motor  3  in the “capsule closure mode”. The closed state of brewing unit  2  in the capsule closure mode is represented in  FIG. 4  with a capsule  30  enclosed in the closed brewing chamber. 
         [0069]    Curve  41  represents the evolution of the current consumption of motor  3  in the “empty closure mode”. The closed state of brewing unit  2  in the empty closure mode is represented in  FIG. 3 . 
         [0070]    Hence, curves  40 , 41  correspond to a closure movement of assemblies  13 , 14  of brewing unit  2 . Likewise, curves can be determined for the opening movements, e.g. with and without capsule  30  inbetween assemblies  13 , 14 . Such opening curves can be used as a reference set to detect possible disturbances of an opening movement of assemblies  13 , 14 , e.g. jamming of a human body part such as a finger between a housing of the machine and a therein movable assembly of brewing unit  2 . 
         [0071]    Control unit  10  of machine  1  is configured for comparing the variation of the actual current consumption to referential curves  40  and  41  depending on the relevant mode the brewing unit is engaged in. Such configuration is obtained by software. 
         [0072]    If a capsule  30  is inserted in brewing unit  2 , and no abnormal variation of the current absorption is detected in comparison to curve  40 , e.g. no variation exceeding 20% of the typical current consumption curve  40 , a brewing cycle can be initiated. The start of brewing cycle can be triggered by a command or request on the user&#39;s interface  12 . Alternatively, the start of the brewing cycle can be triggered automatically by the reaching of the closed position. 
         [0073]    If no capsule is inserted into brewing chamber  2  and no abnormal variation of the variation of the current absorption is detected in comparison to curve  41 , a rinsing and/or de-scaling mode with reduced temperature to allow optimal de-scaling and/or save energy is initiated in the closed position ( FIG. 3 ). The start of rinsing and/or de-scaling cycle can also be triggered by a command or request on the user&#39;s interface  12 . Alternatively, the start of the rinsing and/or de-scaling cycle can be triggered automatically by the reaching of the closed position. If no capsule is inserted into brewing chamber  2  and no abnormal variation of the variation of the current absorption is detected in comparison to curve  41 , a cup-preheating mode may be initiated that involves the dispensing of heated water into a user-cup for preheating thereof prior to preparing and dispensing a beverage. Preheating of the cup may be carried out at beverage preparation temperature or at a reduced temperature. 
         [0074]    More specifically, curve  40  illustrating an exemplary evolution of current consumption over time by motor  3  when a capsule  30  is inserted into brewing unit  2 , includes various phases: 
         [0075]    An initial portion  401 , i.e. a sharp increase of current consumption reflects the start of motion of the movable assembly, in particular the power consumption needed to overcome the static friction forces. A second portion  402 , starts at a level slightly below the top of portion  401  (the dynamic friction forces being lower than the static friction forces) and increases slowly. This portion illustrates the increasing resistance caused by a capsule  30  progressively entering brewing chamber  29  during closure. A maximum  403  is reached when capsule  30  is forced out of an intermediate position in which it is supported by stop members, e.g. as explained in EP 2 103 236. Thereafter, the current consumption drops slightly until it reaches a minimum  404 . The current consumption  405 , 406 , 407  increases due to the deformation and progressive piercing of capsule  30  by blades  15  during closure. The more or less flat portion  408  represents the final approach of the assemblies. The current increase  409  reflects the power needed to stress a biasing spring (not shown) for a play take-up between the assemblies in the closed position. Once the current consumption reaches maximum  410 , the maximum power is consumed by motor  3  which indicates that the motor  3  is blocked: the assemblies are in their closed position. 
         [0076]    Curve  41  illustrating an exemplary evolution of current consumption over time by motor  3  when no capsule is inserted into brewing unit  2 , includes various phases: 
         [0077]    Portion  411  corresponds to portion  401 , i.e. the movable assembly is put in motion. Once the assembly is motion, portions  412 , 413  and  414  illustrate essentially the force distribution of the rotating cam-follower  23  moving in the straight grooves  22  and assembly  13  moving generally perpendicularly to the direction of grooves  22 . Portion  416 , 417  illustrate the power consumption increase due to stressing the biasing spring. Like above, once the current consumption reaches maximum  417 , the maximum power is consumed by motor  3  which indicates that the resistance against motor  3  is complete: the assemblies are in their closed position. 
         [0078]    As illustrated in  FIG. 5  by way of example, the time needed for closing the assemblies when no capsule is inserted into brewing unit  2 , is slightly shorter, approx 0.5 sec, than when motor  3  has to overcome additional forces caused by the presence of a capsule  3 . Overall, closure can be achieved within 2 or 2.5 sec, as illustrated with this particular embodiment of the invention. 
         [0079]    The time needed for opening of closing the assemblies of a brewing unit may typically be in the range of 1 to 10 seconds. 
         [0080]    When the measure of the current absorption does not match the two above mentioned curves  40 ,  41 , in particular, when the current consumption significantly exceeds the curve before reaching the closed position, it can be expected that an undesirable obstacle is located between the assemblies or that the system is jammed or suffers from another malfunction. Consequently, a safety input can be activated. The safety input preferably comprises the operation of inverting the motor action to move the movable assembly back into the open position. Alternatively, the safety input may amount to reducing or stopping the drive action of the motor. This safety measure protects for example the user from jamming a finger in the running mechanism. For example, the safety input may be triggered when the resistance against closure of the assemblies exceeds 50, 80, 100, 125 or 150 N before reaching the closed position. For instance, the safety input may be triggered when an excessive resistance occurs at a distance between the assemblies before closure which is greater than 1 or 2 mm, in particular greater than 3 mm or 4 mm. 
         [0081]    The gear assembly is preferably configured to provide a gear ratio of at least 1:100, preferably comprised between 1:200 and 1:500 such as between 1:250 and 1:450, e.g. 1:300. Due to this relatively high gear ratio, another benefit of the present invention comes from the possibility to use relatively low power motor, for example comprised between 20-50 mNm. 
         [0082]    Motor  3  can be a low power motor configured to generate a maximum torque of no more than 50 mNm; and/or consume a maximum power of no more than 50 watt, for driving movable assembly  14  between the open and closed positions. and/or not exceeding 50 watt. For instance, motor  3  is arranged to generate a maximum torque of at least 20 mNm, in particular a maximum torque in the range of 25 to 40 mNm. Motor  3  can be arranged to consume a maximum power in the range of 7 to 25 watt, in particular 10 to 15 watt. 
         [0083]    The motor can have an angular speed of up to 10K RPM, such as from 0 to 5000 RPM. 
         [0084]    By providing a low power motor, it is possible to simplify the construction and control of the motorized machine. As compared to high power motors, a low power motor has a smaller inertia due to the reduced mechanical inertia and lower power load. Hence, temporary variations of the force (or torque) required from the motor, e.g. to overcome an obstacle or additional friction, is not or less absorbed by the dampening effect of the mechanical inertia and electric load of the motor but timely translated in a temporary increase of required electric powering of the motor. Moreover, since the motor has a lower mechanical and electric inertia, interrupting the powering of the motor is not followed by a significant discharge of the energy load (mechanical and electric) of the motor into the mechanical system. It follows that by using a low power motor, the actual mechanical behaviour of the relatively movable assemblies can be monitored via the power consumption of the motor. Moreover, the machine does not require end position sensors to stop the motor when it is about to reach the end positions. The reaching of an obstacle at the end position can be nearly instantaneously identified by monitoring the power consumption of the motor the powering of which can be stopped without the risk of the motor forcing the assemblies detrimentally beyond the end position by discharging its mechanical and electric inertia.