Cooking appliance for processing food

Abstract

A cooking appliance for processing food, more specifically a cooking appliance of the type that include a body housing an electric motor, a shaft for actuating a processing tool, and an integral handle, the various processing tools being coupled to the body by means of an arm that comprises an implement, such as a grinding, whisking or mixing implement, where the operating control of the appliance (on, off, rotating speed of the implement, etc.) is carried out by means of a sensor system that can detect a characteristic or predetermined movement performed on the appliance and can interpret said movement as an operating instruction, for example, turning the implement on, turning it off, and establishing and controlling the rotating speed thereof, etc.

Claims

1. A cooking appliance for processing food, comprising: a body housing an electric motor, a shaft for actuating a processing tool, an integral handle, an arm integrating an implement for coupling several processing tools to the body, a sensor control system based on gyroscopic and accelerometer sensors that are configured to detect a characteristic or predetermined movement performed on the appliance, a microcontroller that is configured to interpret said movement as an operating instruction, and a control system for the motor associated with the microcontroller, wherein the microcontroller records and stores movement data obtained from the sensors and compares the movement data to predetermined patterns previously established in the microcontroller, and activates the control system to perform operations assigned to the predetermined patterns if the movement data coincide with the predetermined patterns, wherein the predetermined patterns relate to rotation of the device about a vertical axis, and wherein the operations performed in response to the predetermined patterns comprise changing a speed of the motor.

2. The cooking appliance for processing food according to claim 1, wherein the microcontroller also filters the movement data obtained from the sensors, eliminating potential parasitic data due to movements resulting from the inertia of the appliance or involuntary or random movements, in order to obtain a filtered signal for comparison with the predetermined pattern.

3. The cooking appliance for processing food according to claim 2, wherein the microcontroller filters the information obtained from the sensors when the user consciously determines, by pressing a sensor reading activation button associated with the microcontroller, so that the microcontroller will only compare the information values obtained to the predetermined parameters when these movements are performed intentionally and not due to involuntary actions, so that the microcontroller will not send actuation commands to the control of the associated motor unless the sensor reading is voluntarily activated.

4. The cooking appliance for processing food according to claim 1, wherein the microcontroller also records various angles of inclination of the appliance during its operation, wherein microcontroller causes the control system to start or stop operation when a maximum angle of deviation from a vertical position is reached.

5. The cooking appliance for processing food according to claim 4, wherein the maximum angles of deviation from the vertical position for the microcontroller to start or stop operation are +40 or 40 with respect to vertical.

6. The cooking appliance for processing food according to claim 4, wherein the maximum angles of deviation from the vertical position for the microcontroller to start or stop operation are programmed by the user in said microcontroller.

Description

(1) FIG. 1 shows the three spatial axes in which the aforementioned sensor system parametrises speed and angular velocity changes performed by the user on the appliance of the invention.

(2) FIG. 2A shows an example of the measurement signal for the rotating speed and acceleration parameters without filtering.

(3) FIG. 2B shows the signal after it is filtered.

(4) FIG. 3 shows a reading of the data gathered by the sensor system of the appliance indicating those that the microcontroller interprets as a pattern in order to send the correct operation command to the motor control system.

(5) FIG. 4 shows an example of the operating limits for the inclination of the appliance.

(6) In one embodiment of the invention the appliance, and specifically its sensor control system and its associated motor control system, also gathers and parametrises the various inclination angles of the appliance during the use thereof, so that the microcontroller identifies if the working position is correct; in a specific example, if the appliance is in an essentially vertical position, in which case the microcontroller commands the motor control system to change to operating status, or if it deviates from this correct position by a number of degrees, such as +40 or 40 to the vertical, in which case the microcontroller informs the motor control system to change to the stopped status, providing additional safety in use.

(7) For purposes of illustration and not limiting the invention, one example of embodiment is designed to provide five speed settings, in which the minimum speed corresponds to setting 1, such as 3,500 rpm, and the maximum speed corresponds to setting 5, such as 10,000 rpm.

(8) When the start button is pushed for a short time, for example 1 second, accompanied by a gentle wrist motion, such as turning the appliance to the left or the right while keeping it vertical, the gyroscopic sensors and accelerometers provide to the microcontroller the corresponding acceleration and speed parameters and said microcontroller interprets the signal which when filtered and compared to a start-up pattern will send the start-up command to the motor control system, turning on the implement at for example a medium speed on setting 3.

(9) Once started, a rotation of the wrist about a vertical axis, for example to the right, by some degrees, for example 15-20, returning to the initial position after a specific time, for example 1-2 seconds, will be detected by the appliance sensor control and the corresponding data signal will be sent to the microcomputer; when filtered this signal will be compared to a predetermined pattern, such as a pattern for increasing the rotating speed by one setting, such as change from speed setting 3 to speed setting 4, and if the patterns match the microcontroller will send a corresponding signal to the motor control system to increase the speed.

(10) In this case a rotation in the opposite direction, to the left about a vertical axis, such as from 33 to 35, returning to the initial position in a time of 1-2 seconds, will be interpreted by the microcontroller as a request to reduce the rotating speed, such as to speed setting 2.

(11) To stop the appliance the start/stop button is pressed or the appliance is inclined a certain angle to the vertical, such as +40 or 40, which will be interpreted by the microcontroller as a danger situation or as a stop command, so that the motor control system will issue the corresponding stopping command. The angle to the vertical can be predetermined as a stopping pattern in the microcontroller or be programmed as a stopping pattern by the user.