This application claims priority to Chinese Application No. 201410843394.7, filed on Dec. 30, 2014.
This disclosure relates to a bread maker, more particularly to a bread maker for automatically making bread using bread ingredients stored in a container.
A conventional bread maker can automatically make bread with a sequence of procedures including mixing bread ingredients disposed therein, rising, kneading and baking. However, the bread ingredients for making different kinds of bread vary significantly, and it is relatively cumbersome to measure the amounts of ingredients for each bread making.
Another conventional bread maker is designed for receiving a container therein and includes a barcode reader. The container stores bread ingredients therein, and is printed with a barcode thereon. The barcode contains information regarding the bread ingredients stored in the container. The barcode reader reads out the information of the barcode, and the conventional bread maker can automatically make bread using a bread making program according to the information thus read. However, the user cannot intuitively recognize containers storing different bread ingredients.
Therefore, the present disclosure is to provide a bread maker for mounting of a container with a color symbol disposed on an outer surface thereof.
According to this disclosure, a bread maker is for mounting a container. The container stores bread ingredients therein and has an outer surface provided with a color symbol. The bread maker includes a housing, an infrared transceiving device and a determining device. The housing is for mounting the container. The infrared transceiving device is mounted to the housing and includes an infrared emitting unit and a processing unit. The infrared emitting unit is operable to emit infrared ray toward the color symbol of the container when the container is mounted to the housing. The processing unit is configured for receiving a reflection ray reflected from the color symbol and is operable to output an identification signal according to intensity of the reflection ray. The determining device is communicatively connected to the processing unit for receiving the identification signal and is operable to determine, with reference to the identification signal, a bread making indicator that is associated with a bread making program, which the bread maker executes automatically to make bread using the bread ingredients stored in the container.
Other features and advantages of the present disclosure will become apparent in the following detailed description of the embodiment of the disclosure, with reference to the accompanying drawings, in which:
Referring to
The bread maker includes a housing 1, a plurality of infrared (IR) transceiving devices 2, a determining device 5 and a bread-making device 6. The number of the IR transceiving devices 2 corresponds to that of the color symbols 91 and is three in this embodiment. Each of the IR transceiving devices 2 includes an IR emitting unit 3 and a processing unit 4.
The housing 1 includes a main body 11 and a cover 12. The main body 11 is formed with a receiving space 13 for mounting of the container 9. The cover 12 is disposed to cover a top opening of the receiving space 13, and is formed with three grooves 14 that face the receiving space 13 and that respectively correspond in position to the color symbols 91 when the container 9 is properly disposed in the receiving space 13 and the cover 12 covers the top opening of the receiving space 13. The IR transceiving devices 2 are disposed in the grooves 14, respectively, such that the IR transceiving devices 2 respectively correspond in position to and are directed to the color symbols 91 when the container 9 is properly disposed in the receiving space 13 and the cover 12 covers the top opening of the receiving space 13.
The IR emitting unit 3 of each of the IR transceiving devices 2 is operable to emit infrared ray toward a respective one of the color symbols 91 of the container 9 when the container 9 is mounted to the housing 1. In this embodiment, the IR emitting unit 3 is an IR light emitting diode (LED) with a voltage drop equal to 1.4V across it, and is capable of emitting an invisible IR light having a wavelength that ranges from 850 nm to 950 nm.
Further referring to
The signal processing module 42 is electrically coupled to the receiving module 41 for receiving the measurement current signal, and is configured to process the measurement current signal. Specifically, the signal processing module 42 includes a current-to-voltage converter 421, a filter 422 and an alternating-current-to-direct-current (AC-to-DC) converter 423. The current-to-voltage converter 421 is for converting the measurement current signal into an electric voltage signal. The filter 422 is electrically coupled to the current-to-voltage converter 421 for filtering and amplifying the electric voltage signal to output a processed AC voltage signal. The AC-to-DC converter 423 is electrically coupled to the filter 422 for converting the processed AC voltage signal into a DC voltage signal as the identification signal. Since the feature of this disclosure does not reside in the specific configuration of the current-to-voltage converter 421, the filter 422, and the AC-to-DC converter 423, detailed structures of the same are omitted herein for the sake of brevity.
The determining device 5 is mounted in the main body 11 and is communicatively connected to the processing units 4 of the transceiving devices 2 for receiving the identification signals therefrom. The determining device 5 is operable to determine, with reference to the identification signals, a bread-making indicator that is associated with a bread making program, which the bread maker executes automatically to make bread using the bread ingredients stored in the container 9.
The determining device 5 includes a code-generating unit 51, a database 52 and a retrieving unit 53. The code-generating unit 51 includes three n-bit analog-to-digital converting (ADC) modules 511, and a combining module 512. Each of the ADC modules 511 is for calculating a discrete value based on a reference voltage value and a respective one of the identification signals. For example, each of the ADC modules 511 is coupled to a respective one of the processing units 4, and is configured to calculate the discrete value based on the reference voltage value and the identification signal received from the respective one of the processing units 4.
Each of the ADC modules 511 is configured to calculate the discrete value according to the following equation:
discrete value=2n×Vr/VDD,
where Vr represents a voltage value of the identification signal, VDD represents the reference voltage value, and n is an integer greater than or equal to 0.
In this embodiment, each of the ADC modules 511 is for receiving the respective one of the identification signals, and is an 8-bits analog-to-digital converter with the reference voltage value (VDD) of 5V, and thus n equals to 8.
As shown in Table 1 above, some examples of the discrete values calculated based on the reference voltage value of 5V and the respective one of the identification signals are illustrated. The discrete values are obtained by rounding off the calculation of 2n×Vr/VDD in this embodiment and maybe rounded to integer by other rounding means. It should be noted that the discrete value is 0 when the voltage value of the identification signal is 0, and the discrete value is 256 when the voltage value of the identification signal is equal to the reference voltage value.
The combining module 512 is for converting the discrete values into an identification code. In particular, the combining module 512 combines the discrete values into a single identification code, for example, by stringing the discrete values together into a single code. In a case that the color symbols 91 are red, blue and orange, respectively, the identification code is “106113154” accordingly.
The database 52 stores a plurality of reference codes and a plurality of bread-making parameter sets that correspond to the reference codes, respectively. Each of the bread-making parameter sets indicates a sequence of processes, and includes a plurality of parameters for making bread, such as time durations for mixing bread ingredients, rising dough, kneading and baking, temperature for baking, etc. It should be noted that the parameters for making bread are not limited to those described above.
The retrieving unit 53 is for comparing the identification code generated by the code-generating unit 5 with the reference codes stored in the database 52, and for retrieving, from the database 52, one of the bread-making parameter sets as the bread-making indicator which corresponds to one of the reference codes that conforms to the identification code.
The bread-making device 6 is mounted in the main body 11 and is communicatively connected to the determining device 5 so as to automatically execute the bread making program according to the bread-making indicator (i.e., the sequence of processes and parameters of the retrieved one of the bread-making parameter sets) to make bread using the bread ingredients stored in the container 9. The bread-making device 6 includes a piercing mechanism (not shown) for breaking the container 9, and the detailed structure of the mechanism is omitted herein.
In an alternative embodiment, the bread-making indicator maybe an index, and the bread-making parameter sets are stored in the bread-making device 6. Thus, the bread-making device 6 is operable to retrieve one of the bread-making parameter sets with reference to the index received from the determining device 5.
Additionally, when the container 9 is mounted improperly to the housing 1 and/or the retrieving unit 53 fails to retrieve a reference code conforming to the identification code, the determining device 5 would output an alerting signal, for example, in a form of a beep, or flashing light.
As shown in
Note that in this embodiment, the color symbols 91 maybe selected from black, green, red, blue, orange and white. Further referring to
In this embodiment, three color symbols 91 selected from six colors (black, green, red, blue, orange and white) are provided on the container 9. Thus, there are 6×6×6=216 permutations of three color symbols 91, resulting in 216 identification codes. Therefore, 216 kinds of bread ingredients used for making 216 different kinds of bread may be stored in the container 9.
It can be appreciated that the number of the color symbols 91, the number of the IR transceiving devices 2 and the number of the ADC modules 511 of the determining device 5 are not limited to three and may be varied according to the specific demands.
To sum up, in the present disclosure, by virtue of the IR transceiving devices 2 and the determining device 5, the bread making device 6 can automatically make bread by executing the bread making program according to the bread-making indicator that corresponds to one of the reference codes conforming to the identification code associated with the combination of the color symbols 91 on the container 9. It is convenient for the user to make bread without measuring amounts of various bread ingredients. Further, it is relatively simple for the user to recognize various containers 9 storing different bread ingredients by the color symbols 91 disposed on the containers 9. For instance, when the containers 9 storing different bread ingredients are to be storage in a warehouse, the staff of the warehouse can recognize different containers 9 by the color symbols 91 and so as to categorize and place the containers 9 effectively. In the case that a consumer who cannot read the name or description on the product package of the container 9, the consumer can easily recognize the container 9 by the color symbols 91.
While the present disclosure has been described in connection with what is considered the most practical embodiment, it is understood that this disclosure is not limited to the disclosed embodiment but is intended to cover various arrangements included within the spirit and scope of the broadest interpretations and equivalent arrangements.
Number | Date | Country | Kind |
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201410843394.7 | Dec 2014 | CN | national |