LEVER-OPERATED DISPENSING UNITS FOR COFFEE MACHINES

Abstract

A dispenser unit operated by a lever, for use in an espresso machine, comprising a housing, mainly extending along a vertical axis, between a lower base and an upper cross member, a shaft located within said housing and freely translating along said vertical axis. The dispensing unit comprises a rod-like lever with one free end and with the opposite end operably connected to the upper end of said shaft located within the housing, with a cam and a cam follower mechanism interposed therebetween. The base of the housing has conventional coupling means which are adapted to receive and retain a portafilter for a given dose of coffee grounds and the lever is susceptible of angularly moving between a rest position and a stall position and vice versa. The dispensing unit includes a braking device mounted to a shaft, which extends along an axis perpendicular to said vertical axis along which said shaft, located within the housing, moves, which is able to exert a braking action only during the axial movement of said shaft located within the housing in the direction toward said upper cross member of said housing against the axial thrust provided by an elastic member, thereby reducing the angular back movement of said lever from said stall position, toward said rest position when no dose of coffee grounds is placed in the portafilter or of the portafilter is not or wrongly positioned on the dispenser. Kinematic transmission means are provided to connect said shaft extending along the axis with said shaft located within the housing.

Claims

1. A dispenser unit operated by a lever for use in an espresso machine, comprising a housing mainly extending along a vertical axis between a lower base and an upper cross member, a shaft located within said housing and freely translating along said vertical axis, said shaft having an upper end and a lower end, a first opening formed in said lower base of the housing, said lower end of the shaft extending through said opening below the base, a disk attached to the lower end of said shaft perpendicular to the vertical axis thereof, a second opening formed in the upper cross member of said housing, aligned with the upper end of said shaft which projects out of said second opening, an elastic member, reacting between said disk carried by the lower end of the shaft and said upper cross member of said housing, a rod-like lever, with one free end and with the opposite end operably connected to said upper end of said shaft with a cam and a cam follower mechanism interposed therebetween, said base of the housing being equipped with coupling means adapted to receive and hold a portafilter, said lever being mounted so as to be able to be angularly displaced about a pivot supported by said housing with an axis perpendicular to the vertical axis of said shaft, and being susceptible to angularly move between a rest position and a stall position and vice versa; a braking device carried by a shaft arranged along an axis perpendicular to said vertical axis along which said shaft, placed within the housing, moves, said braking device performing a braking action only upon axial movement of said shaft placed within the housing in the direction that faces said upper cross member of said housing against the axial expansion thrust applied by said elastic member, thereby reducing the speed of the angular back movement of said lever from said stall position toward said rest position, kinematic transmission means being provided to connect said shaft extending along the axis with said shaft placed within the housing; characterized in that said braking device comprises a rotor keyed to said shaft extending along the axis, a housing for a viscous material, in which said rotor is rotated in a predetermined angular direction in which said housing of the braking device is conversely held stationary.

2. A dispenser unit as claimed in claim 1, characterized in that said kinematic means for connecting said shaft extending along the axis with said shaft located within the housing, comprise a pinion, keyed to said drive shaft extending along the axis, and engaged with the teeth of a rack that can be moved together with said shaft placed within the housing in the vertical direction defined by the axis of said shaft placed within the housing, connection means being provided between said pinion and said rotor of the braking device, and being adapted to be selected for operation during displacement of said shaft placed within the housing in the direction that faces said upper cross member of said housing against the axial expansion thrust applied by said elastic member.

3. A dispenser unit as claimed in claim 2, characterized in that it includes an auxiliary electric motor whose rotor is connected to said shaft extending along the axis of said rotor of the braking device, means being provided to select power supply to said electric motor and cause it to operate when said shaft extending along the axis is free to rotate in the direction in which said pinion, its respective rack and said shaft located within the housing, allow angular displacement of said lever from the rest position to the stall position.

4. A dispenser unit as claimed in claim 3, characterized in that said means for connecting and disconnecting power supply to said auxiliary motor are placed on said lever.

5. A dispenser unit as claimed in claim 3, characterized in that said means for connecting and disconnecting power supply to said auxiliary motor comprise a stress sensor, which senses the amount of force applied to said lever for angular displacement thereof and provides a corresponding signal, a receiving unit for receiving the signal corresponding to the amount of stress that has been sensed, a processing and transmitting unit for processing and transmitting a control signal for controlling power supply to said motor in proportion to the amount of the stress signal that has been sensed.

6. A dispenser unit as claimed in claim 4, characterized in that said means for connecting and disconnecting power supply to said auxiliary motor comprise a stress sensor, which senses the amount of force applied to said lever for angular displacement thereof and provides a corresponding signal, a receiving unit for receiving the signal corresponding to the amount of stress that has been sensed, a processing and transmitting unit for processing and transmitting a control signal for controlling power supply to said motor in proportion to the amount of the stress signal that has been sensed.

Description

[0020] The invention will be now described in greater detail with reference to a preferred embodiment thereof, given by way of exemplary illustration and without limitation, and shown in the annexed drawings, in which:

[0021] FIG. 1 shows a schematic perspective view of the assembly of a lever-operated dispenser unit of the invention, with the lever in the stand-by position;

[0022] FIG. 2 shows a schematic perspective exploded view of the assembly of the parts of a conventional viscous fluid-operated braking device for slowing down the angular movement of the lever of the dispensing unit; and

[0023] FIG. 3 shows a schematic side view of an espresso machine with a lever-operated dispenser unit showing the angular path covered by the lever as it moves from the stall position to the stand-by position and vice versa.

[0024] Referring to the aforementioned figures, the lever-operated dispenser unit is generally designated by numeral 1. It comprises a housing 2, mainly extending in a vertical direction (A-A), for example in the form of a cage, with a partially open lateral contour, extending between a lower base 3 and an upper cross member 4.

[0025] A shaft 5 with an upper end 6 and a lower end 7 is placed in said housing 2, and freely translates along said vertical extent (A-A). A first opening 8 is formed in said lower basement 3 of the housing 2. The lower end 7 of the shaft 5 extends through said opening 8 below the base 3 by penetrating a chamber 9.

[0026] A disk 10, which also acts as a piston, is attached to the lower end 7 of the shaft 5, perpendicular to the vertical axis of the shaft. The disk-piston 10 is equipped with conventional sealing rings, not shown, which are adapted to cooperate with the inner cylindrical wall of the chamber 9, while the beverage is being dispensed.

[0027] A second opening, not shown in the drawings, is formed in the upper cross member 4 of said housing 2 and is aligned with the upper end 6 of the shaft 5 that projects out of it.

[0028] An elastic member, which is represented by a helical spring 11, is placed coaxial with the shaft 5, between said disk-piston 10 carried by the lower end 7 of the shaft 5 and said upper cross member 4 of the housing 2. A lever in the form of a rod 12, with a free end 13 and an opposite fork-shaped end 14, is mounted to the housing 2 via a pin 15 and is adapted to be angularly displaced about the axis X-X, coinciding with said pin 15, between a first stand-by position A and a second stall position, S, both shown in FIG. 3, that will be further explained below.

[0029] Conventional cam means, referenced 19 and 20 are mounted to the same pin 15, and have their profiles slidingly engaged with respective cam followers, not shown because they are known in the art, which transversely engage the end 6 of the shaft 5.

[0030] Thus, the cams 19 and 20 and their cam followers, provide operable connection between the lever 12 and the upper end 6 of said shaft 5.

[0031] According to the invention, the rotor 21 of a conventional braking device with a housing 22 containing a viscous fluid, e.g. in the form of a gel, is keyed along an axis referenced B-B, here extending perpendicular to the axis X-X of the pin 15 and also perpendicular to the axis A-A, along which the shaft 5 is free to translate. This rotor 21, as schematically shown in FIG. 2, is connected to a shaft 23 arranged along the axis B-B via connecting mode-selecting means 24 and 24a, with a pinion 25 also keyed thereto.

[0032] In particular and by way of example, the means 24 consist of a freewheel bearing which allows the rotor 21 of the braking device to only operate in one predetermined direction of rotation.

[0033] In the illustrated example, the pinion 25 is engaged with the front teeth 26 of a rack 27, which extends along an axis A1-A1 parallel to the axis A-A of the shaft 5 driven in one direction by the lever 12 and in the opposite direction, toward the cross member 4, by the expansion thrust of the elastic means 11.

[0034] Therefore, the rack 27 shall be deemed to be structurally movable with the shaft 5.

[0035] As schematically shown in FIG. 1, the housing 22 of the braking device is mounted in a conventional manner to a wall 28 of the frame of the machine that is equipped with the dispensing unit 1.

[0036] In an alternative embodiment, the dispensing unit may be also equipped with an auxiliary electric motor, schematically referenced 29 in FIGS. 1 and 2.

[0037] The rotor of such auxiliary electric motor may be connected with the shaft 23, by means of the housing 22 of the braking device and selection means, referenced 30, which are carried, for instance, by the end 13 of the lever 12, and operate through an Electronic Control Unit (CPU) 32, which is also configured to operate in the management of the means 24 for coupling the rotor 21 with the housing 22 of the braking device.

[0038] Thus, in one embodiment of the invention, the CPU 32 allows the rotor of the auxiliary electric motor 29 and the pivot 15 of the lever 12 to be rotatably coupled in one angular displacement direction only, i.e. from the stand-by position A to stall position, S, using the pinion 25 and the rack 27 that are part of the braking device, which is only operable during the reverse angular displacement of the same lever 12, from the stall position S to the stand-by position A.

[0039] In order to prepare coffee using a lever unit of the invention, a portafilter 31 with a predetermined dose of coffee grounds therein, is placed below the dispensing chamber 9 using conventional coupling means to hold it in its proper position.

[0040] As is known in the art, the chamber 9 is in communication with a hot water source via a conduit that is shut off by a known and conventional controllable valve.

[0041] The hot water dispensing operation is set up by the operator by angularly displacing the lever 12 about the axis X-X, from its stand-by position A, as shown in FIG. 3, to its stall position, S, as shown in the same figure. Such angular movement of the lever 12 causes, as mentioned above the shaft 5 to be lifted with its disk-piston 10, by means of the cams 19 and 20, as is known in the art.

[0042] This causes the helical spring 11 to be compressed against the cross member 4 of the housing 2. The spring remains in this compressed position as long as the lever 12 remains in its stall position S as determined by a particular section of the profiles of the cams 19 and 20.

[0043] When a beverage is to be prepared, a small thrust manually exerted on the lever 12 will cause it to exit the stall position S, thereby releasing the spring 11 from its compression state, and causing the disk-piston 10 to fall down into the chamber 9 and press the hot water through the dose of coffee grounds in the underlying portafilter 31. The dispensed beverage is collected in an underlying cup, not shown on the drawings.

[0044] At the same time as the disk-piston 10 moves down, the lever 12 is angularly moved back to the stand-by position A at a slower speed, due to the opposition of the hot water flow that is forming the beverage within the chamber 9 against the disk-piston 10.

[0045] With such kind of movement, the angularly moving free end 13 of the lever 12 does not cause dangerous situations for the operator.

[0046] Conversely, if the portafilter 31 has been placed in a wrong position or with no dose of coffee grounds therein, the displacement of the lever 12 from the stall position S for dispensing the beverage will cause a quick return thereof to the stand-by position A, because no opposition force is exerted upon the disk-piston 10.

[0047] According to the invention, in these circumstances, the movement of the lever 12 is slowed down by the braking device whose rotor 21 moves in the viscous fluid within the housing 22.

[0048] That is, the rotor 21 that is keyed to the pinion 25, is rotated by the lifting movement of the shaft 5 and the rack 27 and its rotation is slowed down by the viscosity of the fluid within the housing 22, which acts against the rotor 21.

[0049] The safety of the operator is thus ensured even in this case of wrong placement of the unit.

[0050] According to a further embodiment of the invention, the CPU 32 may include a stress sensor, which senses the amount of force applied to the lever 12 for angular displacement thereof and provides a corresponding signal, a receiving unit for receiving the signal corresponding to the amount of stress that has been sensed, a processing and transmitting unit for processing and transmitting a control signal for controlling power supply to said motor in proportion to the amount of the stress signal that has been sensed.