MACHINE FOR PREPARING HOT BEVERAGES

Abstract

Machine to prepare hot beverages that uses means of heating a secondary liquid, which transfers temperature to the primary liquid that is used to prepare the hot drink. The machine is fully operated through software that allows the pressure and temperature parameters of each drink prepared in the machine to be saved and accurately reproduced.

Claims

1. A machine for preparing hot beverages, characterized in that it comprises a boiler (1); a pair of water pipes (2); at least one pair of flow meters to control the volume of liquid in relation to the required temperature in the pair of water conduits (2); a metal coil (18) located prior to the extraction duct (21); at least one pair of filling valves of the boiler (11); at least one filling valve for the primary liquid conduits (15); at least one pair of solenoid valves; at least one pair of electrical resistors (14) housed in the pair of conduits (2); at least four safety mechanisms (6) for the temperature of liquids; at least one pair of heat exchangers to raise the temperature of the primary liquid; At least one pair of temperature transmitting RTD probes; a stainless steel grooved ring and hermetic gasket (19), integrated to the boiler (1); a hydraulic pump with variable speed and pressure; at least one three-way solenoid valve (16) located at the base of the boiler (1); at least one pair of digital pressure readers; at least one pair of current transformers; a printed circuit board to control, by means of software, analog and digital outputs and wireless data connections such as wi-fi and bluetooth; at least one speed variator of the pump; a potentiometer; at least one touch screen; a plurality of electronic buttons; a plurality of solid state relays; a main on/off switch; a support structure, preferably made of lightweight metallic material; an outer casing (10), which covers all the internal components of the machine.

2. The machine for preparing hot beverages according to claim 1, characterized in that the pair of water pipes (2) are housed inside the boiler (1) and include heating elements controlled by RTD probes.

3. The machine for preparing hot beverages according to claim 1, characterized in that the boiler (1) forms a saturation means for the coil (17) that carries the primary liquid.

4. The machine for preparing hot beverages according to claim 1, characterized in that the pair of conduits (2) of the primary liquid are arranged in the center of the helical that makes up the coil (17) housed inside the boiler (1), said conduits (2) joining in a single one outside the boiler (1) and extending through the extraction head, first passing through the center of the coil (18) of said head.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] FIG. 1. It is a side view of the main body of the machine showing its internal components, among which can be seen: thermistors (13), electric resistances (14), the coil (17) in the body of the boiler, the coil (18) in the machine head, the extraction duct (21) and the three-way solenoid valve (16).

[0013] FIG. 2. Shows a rear view of the main body of the machine, where one of the electrical resistances (14), several of the thermistors (13) and the three-way solenoid valve (16) can be seen.

[0014] FIG. 3. It shows a front view of the main body of the machine, where the boiler body (1) and the three-way solenoid valve (16) are indicated.

[0015] FIG. 4. It shows a side view of the main body of the machine, where you can see several thermistors (13), the extraction duct (21), one of the electrical resistances (14), the coil (18) in the extraction head and the location secondary liquid fill coupling (11).

[0016] FIG. 5. It shows a side section of the machine where you can see the pair of conduits (2) in the center of the helical that makes up the coil (17), housing one of the electrical resistances (14), one of the thermistors (13) and the coil (18) in the head of the machine.

[0017] FIG. 6. It shows a top view of the main body of the machine where the location of several thermistors (13), one of the electrical resistances (14) and the secondary liquid filling couplings (11) can be seen.

[0018] FIG. 7. It shows a bottom view of the main body of the machine where the location of one of the surface mounting bolts (5), one of the safety couplings (6), of the valve mounting plate (7), of one of the resistors (14), of the primary liquid inlet coupling (15), of the three-way solenoid valve (16) and of the grooved ring (19).

DESCRIPTION OF THE INVENTION

[0019] It is a machine for preparing espresso coffee that comprises a boiler, preferably made of food grade stainless steel, which houses a pair of water pipes (2) that integrate heating elements controlled by RTD probes and flow meters or flow meters to control the volume of liquid in relation to the required temperature in the pair of water pipes (2).

[0020] The machine also includes a metal coil (18) located prior to the point of extraction of the coffee infusion which allows obtaining gain from the heat generated in the pair of ducts (2) and transferring it to the extraction duct (21), to carry the primary liquid at the temperature established as a parameter for the extraction of each shot of espresso, without mixing with the water contained in the pair of pipes (2), which we will call from here on secondary liquid, to differentiate it from water used for extraction (primary liquid).

[0021] In its integral composition, the machine comprises a boiler (1); at least one pair of filling valves of the boiler (11); at least one filling valve for the primary liquid conduits (15); at least one pair of solenoid valves to control the flow and flow of the water that is conducted through a coil (17) made of food grade stainless steel, housed inside the boiler (1); at least one pair of electric resistors (14) housed one in the upper part and the other in the lower part of the main body of the machine, at least four safety mechanisms (6) of the liquid temperature, consisting of current switches; at least one pair of heat exchangers to raise the temperature of the primary liquid; At least one pair of temperature transmitting RTD probes; a grooved stainless steel ring and hermetic gasket (19), integrated into the base of the boiler (1); a hydraulic pump with variable speed and pressure; at least one three-way solenoid valve (16), located at the base of the boiler (1); digital pressure readers; at least one pair of current transformers; a printed circuit board to control, by means of software, analog and digital outputs and wireless data connections such as wi-fi and bluetooth; at least one speed variator of the pump; a potentiometer; at least one touch screen; a plurality of electronic buttons; a plurality of solid state relays; a main on/off switch; a support structure, preferably made of light metallic material, which fulfills the function of housing all the internal components of the machine; an outer casing (10) that can be made of plastic materials, metal, carbon fiber, fiberglass, wood or a combination of these, which covers all the internal components of the machine, including the metal support structure.

[0022] The operation of the espresso machine is assisted by a computer program which completely automates its operation. Said computer program controls each pressure and temperature parameter of the machine by sending and receiving signals from the temperature sensors, pressure meters, flow meters, pump, valves and RTD probes, recording the parameters of each extraction to reproduce them. indefinitely from a data memory included in the hardware where the computer program runs, the main component of said hardware being a printed circuit board that has analog outputs, digital outputs and wireless data connection devices.

[0023] The operation of the espresso machine object of the present invention has as a first step the turning on of the machine and introducing, through the touch screen, the desired temperature and pressure parameters for the extraction of a shot of coffee, immediately The option to start extraction is selected, triggering signals to the heating resistors (14) and to the pump to start raising the temperature of the secondary liquid in the boiler (1) and raising the pressure of the primary liquid. As soon as the temperature signals sent by the RTD probes and by the pressure transmitter connected to the analog-digital converter, indicate that both the temperature and the pressure of the primary liquid have reached the established parameters, the computer program automatically sends a signal to the solenoid valve (16) to release the required amount of water for an extraction. In the internal operation of the machine, the primary liquid raises its temperature as it circulates through the first coil (17), located inside the boiler (1), where said first coil (17) is kept in a medium saturated by the secondary liquid, said secondary liquid being able to be distilled water or another non-toxic liquid, whose thermal qualities and coefficient of expansion make it an efficient medium for a first transfer of heat to the primary liquid. When the computer program that controls the machine sends the signal to the solenoid valve (19) to release the flow of the primary liquid towards the extraction head (21), the heating resistance (14) located prior to the extraction duct (21) and surrounded by the second coil (18), raising its temperature, where the primary liquid that flows through said extraction conduit section (21) has a sufficient temperature gain so that when said primary liquid passes through the extraction tablet It is precisely at the temperature initially established as a parameter for said extraction. At the same time, the speed variator of the pump maintains the operation of the pump in a range such that the pressure of the primary liquid when exiting the extraction conduit (21) is precisely the one initially established as the pressure parameter for said extraction.